test/basic/specificClass.test.js

// Basic unit tests for PumpingStation (domain logic, no Node-RED).
// Run with:  node --test test/basic/specificClass.test.js

const test = require('node:test');
const assert = require('node:assert/strict');

const PumpingStation = require('../../src/specificClass');

// Standard config shape. Override any section by passing { section: {...} }.
function makeConfig(overrides = {}) {
  const base = {
    general: {
      name: 'TestStation',
      id: 'ps-test',
      unit: 'm3/h',
      logging: { enabled: false, logLevel: 'error' },
      flowThreshold: 1e-4,
    },
    functionality: {
      softwareType: 'pumpingStation',
      role: 'stationcontroller',
      positionVsParent: 'atEquipment',
    },
    basin: {
      volume: 50,
      height: 5,
      inflowLevel: 3,
      outflowLevel: 0.2,
      overflowLevel: 4.5,
    },
    hydraulics: {
      refHeight: 'NAP',
      basinBottomRef: 0,
      minHeightBasedOn: 'outlet',
    },
    control: {
      mode: 'levelbased',
      allowedModes: new Set(['levelbased', 'manual']),
      levelbased: { minLevel: 1, startLevel: 2, maxLevel: 4 },
    },
    safety: {
      enableDryRunProtection: false,
      enableOverfillProtection: false,
      dryRunThresholdPercent: 2,
      overfillThresholdPercent: 98,
      timeleftToFullOrEmptyThresholdSeconds: 0,
    },
  };
  for (const k of Object.keys(overrides)) {
    base[k] = typeof overrides[k] === 'object' && !Array.isArray(overrides[k])
      ? { ...base[k], ...overrides[k] }
      : overrides[k];
  }
  return base;
}

test('Basin geometry — derived values', async (t) => {
  const ps = new PumpingStation(makeConfig());

  await t.test('surfaceArea = volume / height', () => {
    assert.equal(ps.basin.surfaceArea, 10);  // 50 / 5
  });
  await t.test('maxVol = height × area ≡ volEmptyBasin', () => {
    assert.equal(ps.basin.maxVol, 50);
    assert.equal(ps.basin.maxVol, ps.basin.volEmptyBasin);
  });
  await t.test('maxVolAtOverflow = overflowLevel × area', () => {
    assert.equal(ps.basin.maxVolAtOverflow, 45);  // 4.5 × 10
  });
  await t.test('minVolAtInflow = inflowLevel × area', () => {
    assert.equal(ps.basin.minVolAtInflow, 30);  // 3 × 10
  });
  await t.test('minVolAtOutflow = outflowLevel × area', () => {
    assert.ok(Math.abs(ps.basin.minVolAtOutflow - 2) < 1e-9);  // 0.2 × 10
  });
  await t.test('minVol honours minHeightBasedOn=outlet', () => {
    assert.ok(Math.abs(ps.basin.minVol - 2) < 1e-9);
  });
  await t.test('minVol honours minHeightBasedOn=inlet', () => {
    const ps2 = new PumpingStation(makeConfig({ hydraulics: { minHeightBasedOn: 'inlet' } }));
    assert.equal(ps2.basin.minVol, 30);
  });
});

test('Level ↔ volume roundtrip', async (t) => {
  const ps = new PumpingStation(makeConfig());

  await t.test('_calcVolumeFromLevel multiplies by area', () => {
    assert.equal(ps._calcVolumeFromLevel(2), 20);
  });
  await t.test('_calcVolumeFromLevel clamps negatives to 0', () => {
    assert.equal(ps._calcVolumeFromLevel(-3), 0);
  });
  await t.test('_calcLevelFromVolume divides by area', () => {
    assert.equal(ps._calcLevelFromVolume(20), 2);
  });
  await t.test('_calcLevelFromVolume clamps negatives to 0', () => {
    assert.equal(ps._calcLevelFromVolume(-10), 0);
  });
  await t.test('roundtrip preserves level', () => {
    const v = ps._calcVolumeFromLevel(2.7);
    assert.ok(Math.abs(ps._calcLevelFromVolume(v) - 2.7) < 1e-10);
  });
});

test('Threshold guardrails — _validateThresholdOrdering', async (t) => {
  await t.test('valid config returns no issues', () => {
    const ps = new PumpingStation(makeConfig());
    assert.equal(ps.thresholdIssues.length, 0);
  });

  await t.test('minLevel > startLevel flagged', () => {
    const ps = new PumpingStation(makeConfig({
      control: {
        mode: 'levelbased',
        allowedModes: new Set(['levelbased']),
        levelbased: { minLevel: 3, startLevel: 2, maxLevel: 4 },
      },
    }));
    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'minLevel'));
  });

  await t.test('startLevel == maxLevel flagged (must be strict <)', () => {
    const ps = new PumpingStation(makeConfig({
      control: {
        mode: 'levelbased',
        allowedModes: new Set(['levelbased']),
        levelbased: { minLevel: 1, startLevel: 4, maxLevel: 4 },
      },
    }));
    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'startLevel'));
  });

  await t.test('outflowLevel >= inflowLevel flagged', () => {
    const ps = new PumpingStation(makeConfig({
      basin: { volume: 50, height: 5, inflowLevel: 0.1, outflowLevel: 0.5, overflowLevel: 4.5 },
    }));
    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'outflowLevel'));
  });

  await t.test('overflowLevel > basinHeight flagged', () => {
    const ps = new PumpingStation(makeConfig({
      basin: { volume: 50, height: 5, inflowLevel: 3, outflowLevel: 0.2, overflowLevel: 6 },
    }));
    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'overflowLevel'));
  });

  await t.test('dryRunLevel > minLevel flagged (safety band inverted)', () => {
    // With minHeightBasedOn=inlet, refLowLevel=inflowLevel=3.
    // dryRunLevel = 3 × (1 + 100/100) = 6; minLevel=1 → 6 ≤ 1 fails.
    const ps = new PumpingStation(makeConfig({
      hydraulics: { minHeightBasedOn: 'inlet' },
      safety: { enableDryRunProtection: true, dryRunThresholdPercent: 100 },
    }));
    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'dryRunLevel'));
  });
});

test('Direction derivation — _deriveDirection', async (t) => {
  const ps = new PumpingStation(makeConfig());

  await t.test('positive flow above dead-band → filling', () => {
    assert.equal(ps._deriveDirection(0.01), 'filling');
  });
  await t.test('negative flow below dead-band → draining', () => {
    assert.equal(ps._deriveDirection(-0.01), 'draining');
  });
  await t.test('flow inside dead-band → steady', () => {
    assert.equal(ps._deriveDirection(0), 'steady');
    assert.equal(ps._deriveDirection(1e-5), 'steady');
    assert.equal(ps._deriveDirection(-1e-5), 'steady');
  });
});

test('Mode change — changeMode', async (t) => {
  const ps = new PumpingStation(makeConfig());

  await t.test('valid mode swap updates this.mode', () => {
    ps.changeMode('manual');
    assert.equal(ps.mode, 'manual');
  });
  await t.test('rejected mode leaves this.mode unchanged', () => {
    ps.changeMode('manual');
    ps.changeMode('notamode');
    assert.equal(ps.mode, 'manual');
  });
});

test('Calibration — predicted volume and level', async (t) => {
  const ps = new PumpingStation(makeConfig());

  await t.test('calibratePredictedVolume rewrites volume series', () => {
    ps.calibratePredictedVolume(25);
    const vol = ps.measurements.type('volume').variant('predicted').position('atequipment').getCurrentValue('m3');
    assert.ok(Math.abs(vol - 25) < 1e-9);
  });
  await t.test('calibratePredictedVolume also writes level (= vol / area)', () => {
    ps.calibratePredictedVolume(30);
    const lvl = ps.measurements.type('level').variant('predicted').position('atequipment').getCurrentValue('m');
    assert.ok(Math.abs(lvl - 3) < 1e-9);  // 30 / 10
  });
  await t.test('calibratePredictedLevel writes level + volume = level × area', () => {
    ps.calibratePredictedLevel(2.5);
    const lvl = ps.measurements.type('level').variant('predicted').position('atequipment').getCurrentValue('m');
    const vol = ps.measurements.type('volume').variant('predicted').position('atequipment').getCurrentValue('m3');
    assert.ok(Math.abs(lvl - 2.5) < 1e-9);
    assert.ok(Math.abs(vol - 25) < 1e-9);  // 2.5 × 10
  });
});

test('Levelbased control zones — _controlLevelBased', async (t) => {
  await t.test('level < minLevel → percControl=0 and MGC turnOff called', async () => {
    const ps = new PumpingStation(makeConfig());
    let turnOffCalls = 0;
    ps.machineGroups['mgc1'] = {
      config: { general: { name: 'mgc1' } },
      turnOffAllMachines: () => { turnOffCalls++; },
      handleInput: async () => {},
    };
    ps.calibratePredictedLevel(0.5);  // below minLevel=1
    await ps._controlLevelBased();
    assert.equal(ps.percControl, 0);
    assert.equal(turnOffCalls, 1);
  });

  await t.test('minLevel ≤ level < startLevel → dead zone, percControl unchanged', async () => {
    const ps = new PumpingStation(makeConfig());
    ps.percControl = 42;  // simulated previous demand
    ps.machineGroups['mgc1'] = {
      config: { general: { name: 'mgc1' } },
      turnOffAllMachines: () => {},
      handleInput: async () => { throw new Error('should not be called in dead zone'); },
    };
    ps.calibratePredictedLevel(1.5);  // between minLevel=1 and startLevel=2
    await ps._controlLevelBased();
    assert.equal(ps.percControl, 42);  // unchanged
  });

  await t.test('level ≥ startLevel → percControl linearly scaled to [0,100]', async () => {
    const ps = new PumpingStation(makeConfig());
    const demands = [];
    ps.machineGroups['mgc1'] = {
      config: { general: { name: 'mgc1' } },
      turnOffAllMachines: () => {},
      handleInput: async (_src, d) => { demands.push(d); },
    };
    ps.calibratePredictedLevel(3);  // midpoint of startLevel=2 and maxLevel=4
    await ps._controlLevelBased();
    // lerp(3, [2,4], [0,100]) = 50
    assert.ok(Math.abs(ps.percControl - 50) < 1e-9);
    assert.equal(demands.length, 1);
    assert.ok(Math.abs(demands[0] - 50) < 1e-9);
  });

  await t.test('level > maxLevel → percControl ≥ 100 (MGC clamps internally)', async () => {
    const ps = new PumpingStation(makeConfig());
    ps.machineGroups['mgc1'] = {
      config: { general: { name: 'mgc1' } },
      turnOffAllMachines: () => {},
      handleInput: async () => {},
    };
    ps.calibratePredictedLevel(4.5);  // above maxLevel=4
    await ps._controlLevelBased();
    assert.ok(ps.percControl >= 100);
  });
});

test('getOutput — flattens basin + state + demand', async (t) => {
  const ps = new PumpingStation(makeConfig());
  ps.percControl = 37;

  await t.test('includes basin geometry fields', () => {
    const out = ps.getOutput();
    assert.equal(out.volEmptyBasin, 50);
    assert.equal(out.maxVolAtOverflow, 45);
    assert.equal(out.minVolAtInflow, 30);
    assert.ok(Math.abs(out.minVolAtOutflow - 2) < 1e-9);
  });
  await t.test('includes state fields (direction, flowSource, timeleft)', () => {
    const out = ps.getOutput();
    assert.ok('direction' in out);
    assert.ok('flowSource' in out);
    assert.ok('timeleft' in out);
  });
  await t.test('includes percControl', () => {
    assert.equal(ps.getOutput().percControl, 37);
  });
});

test('Manual inflow — setManualInflow stores predicted inflow', async (t) => {
  const ps = new PumpingStation(makeConfig());
  ps.setManualInflow(0.05, Date.now(), 'm3/s');  // 0.05 m³/s
  const v = ps.measurements.type('flow').variant('predicted').position('in').child('manual-qin').getCurrentValue('m3/s');
  assert.ok(Math.abs(v - 0.05) < 1e-9);
});
-												Add threshold guardrails, fix calibratePredictedLevel bug, rewrite tests

### Guardrails (specificClass.js)

New _validateThresholdOrdering() runs in the constructor. Checks every
ordered pair of basin + control + derived-safety levels and logs a
warning for each violation; returns the list as this.thresholdIssues
so tests and the eval harness can inspect. Non-fatal — we prefer a
running-but-warned station to a refusal-to-start (availability-first).

Strict invariants (bottom → top):
  0 < outflowLevel < inflowLevel < overflowLevel ≤ basinHeight
  dryRunLevel ≤ minLevel ≤ startLevel < maxLevel ≤ overfillLevel

Uses a list-of-checks pattern rather than a switch — easier to add new
invariants without reflowing cases, and the list itself is readable
documentation.

### Bug fix (specificClass.js)

calibratePredictedLevel was writing the volume value into the LEVEL
slot. Root cause: MeasurementContainer is stateful — its type()/
variant()/position() calls mutate the container's own cursor, so
caching chain references (const levelChain = ...; const volumeChain
= ...) doesn't isolate them. The second cached chain ended up sharing
the state of the last type() call. Rebuilt chains fresh each time,
matching the calibratePredictedVolume pattern that already worked.

### Tests (test/basic/specificClass.test.js)

Ported from Jest to node:test + node:assert — the project's standard
per .claude/rules/testing.md. Deleted the stale test/specificClass.test.js
(tests referenced methods that no longer exist post-rename).

New coverage, 42 passing subtests:
- Basin geometry derivations + minHeightBasedOn
- Level/volume roundtrip
- Threshold guardrails (5 violation cases)
- Direction derivation
- Mode change accept/reject
- Calibration (volume and level paths — catches the bug above)
- Levelbased control zones (STOP / DEAD ZONE / RAMP / saturate)
- getOutput flattening
- setManualInflow

Run with: node --test test/basic/*.test.js

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

											
										
										
											2026-04-22 16:38:41 +02:00
+								// Basic unit tests for PumpingStation (domain logic, no Node-RED).
 								// Run with:  node --test test/basic/specificClass.test.js
 								const test = require('node:test');
 								const assert = require('node:assert/strict');
 								const PumpingStation = require('../../src/specificClass');
 								// Standard config shape. Override any section by passing { section: {...} }.
 								function makeConfig(overrides = {}) {
 								  const base = {
 								    general: {
 								      name: 'TestStation',
 								      id: 'ps-test',
 								      unit: 'm3/h',
 								      logging: { enabled: false, logLevel: 'error' },
 								      flowThreshold: 1e-4,
 								    },
 								    functionality: {
 								      softwareType: 'pumpingStation',
 								      role: 'stationcontroller',
 								      positionVsParent: 'atEquipment',
 								    },
 								    basin: {
 								      volume: 50,
 								      height: 5,
 								      inflowLevel: 3,
 								      outflowLevel: 0.2,
 								      overflowLevel: 4.5,
 								    },
 								    hydraulics: {
 								      refHeight: 'NAP',
 								      basinBottomRef: 0,
 								      minHeightBasedOn: 'outlet',
 								    },
 								    control: {
 								      mode: 'levelbased',
 								      allowedModes: new Set(['levelbased', 'manual']),
 								      levelbased: { minLevel: 1, startLevel: 2, maxLevel: 4 },
 								    },
 								    safety: {
 								      enableDryRunProtection: false,
 								      enableOverfillProtection: false,
 								      dryRunThresholdPercent: 2,
 								      overfillThresholdPercent: 98,
 								      timeleftToFullOrEmptyThresholdSeconds: 0,
 								    },
 								  };
 								  for (const k of Object.keys(overrides)) {
 								    base[k] = typeof overrides[k] === 'object' && !Array.isArray(overrides[k])
 								      ? { ...base[k], ...overrides[k] }
 								      : overrides[k];
 								  }
 								  return base;
 								}
 								test('Basin geometry — derived values', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  await t.test('surfaceArea = volume / height', () => {
 								    assert.equal(ps.basin.surfaceArea, 10);  // 50 / 5
 								  });
 								  await t.test('maxVol = height × area ≡ volEmptyBasin', () => {
 								    assert.equal(ps.basin.maxVol, 50);
 								    assert.equal(ps.basin.maxVol, ps.basin.volEmptyBasin);
 								  });
 								  await t.test('maxVolAtOverflow = overflowLevel × area', () => {
 								    assert.equal(ps.basin.maxVolAtOverflow, 45);  // 4.5 × 10
 								  });
 								  await t.test('minVolAtInflow = inflowLevel × area', () => {
 								    assert.equal(ps.basin.minVolAtInflow, 30);  // 3 × 10
 								  });
 								  await t.test('minVolAtOutflow = outflowLevel × area', () => {
 								    assert.ok(Math.abs(ps.basin.minVolAtOutflow - 2) < 1e-9);  // 0.2 × 10
 								  });
 								  await t.test('minVol honours minHeightBasedOn=outlet', () => {
 								    assert.ok(Math.abs(ps.basin.minVol - 2) < 1e-9);
 								  });
 								  await t.test('minVol honours minHeightBasedOn=inlet', () => {
 								    const ps2 = new PumpingStation(makeConfig({ hydraulics: { minHeightBasedOn: 'inlet' } }));
 								    assert.equal(ps2.basin.minVol, 30);
 								  });
 								});
 								test('Level ↔ volume roundtrip', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  await t.test('_calcVolumeFromLevel multiplies by area', () => {
 								    assert.equal(ps._calcVolumeFromLevel(2), 20);
 								  });
 								  await t.test('_calcVolumeFromLevel clamps negatives to 0', () => {
 								    assert.equal(ps._calcVolumeFromLevel(-3), 0);
 								  });
 								  await t.test('_calcLevelFromVolume divides by area', () => {
 								    assert.equal(ps._calcLevelFromVolume(20), 2);
 								  });
 								  await t.test('_calcLevelFromVolume clamps negatives to 0', () => {
 								    assert.equal(ps._calcLevelFromVolume(-10), 0);
 								  });
 								  await t.test('roundtrip preserves level', () => {
 								    const v = ps._calcVolumeFromLevel(2.7);
 								    assert.ok(Math.abs(ps._calcLevelFromVolume(v) - 2.7) < 1e-10);
 								  });
 								});
 								test('Threshold guardrails — _validateThresholdOrdering', async (t) => {
 								  await t.test('valid config returns no issues', () => {
 								    const ps = new PumpingStation(makeConfig());
 								    assert.equal(ps.thresholdIssues.length, 0);
 								  });
 								  await t.test('minLevel > startLevel flagged', () => {
 								    const ps = new PumpingStation(makeConfig({
 								      control: {
 								        mode: 'levelbased',
 								        allowedModes: new Set(['levelbased']),
 								        levelbased: { minLevel: 3, startLevel: 2, maxLevel: 4 },
 								      },
 								    }));
 								    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'minLevel'));
 								  });
 								  await t.test('startLevel == maxLevel flagged (must be strict <)', () => {
 								    const ps = new PumpingStation(makeConfig({
 								      control: {
 								        mode: 'levelbased',
 								        allowedModes: new Set(['levelbased']),
 								        levelbased: { minLevel: 1, startLevel: 4, maxLevel: 4 },
 								      },
 								    }));
 								    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'startLevel'));
 								  });
 								  await t.test('outflowLevel >= inflowLevel flagged', () => {
 								    const ps = new PumpingStation(makeConfig({
 								      basin: { volume: 50, height: 5, inflowLevel: 0.1, outflowLevel: 0.5, overflowLevel: 4.5 },
 								    }));
 								    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'outflowLevel'));
 								  });
 								  await t.test('overflowLevel > basinHeight flagged', () => {
 								    const ps = new PumpingStation(makeConfig({
 								      basin: { volume: 50, height: 5, inflowLevel: 3, outflowLevel: 0.2, overflowLevel: 6 },
 								    }));
 								    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'overflowLevel'));
 								  });
 								  await t.test('dryRunLevel > minLevel flagged (safety band inverted)', () => {
 								    // With minHeightBasedOn=inlet, refLowLevel=inflowLevel=3.
 								    // dryRunLevel = 3 × (1 + 100/100) = 6; minLevel=1 → 6 ≤ 1 fails.
 								    const ps = new PumpingStation(makeConfig({
 								      hydraulics: { minHeightBasedOn: 'inlet' },
 								      safety: { enableDryRunProtection: true, dryRunThresholdPercent: 100 },
 								    }));
 								    assert.ok(ps.thresholdIssues.some((i) => i.aName === 'dryRunLevel'));
 								  });
 								});
 								test('Direction derivation — _deriveDirection', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  await t.test('positive flow above dead-band → filling', () => {
 								    assert.equal(ps._deriveDirection(0.01), 'filling');
 								  });
 								  await t.test('negative flow below dead-band → draining', () => {
 								    assert.equal(ps._deriveDirection(-0.01), 'draining');
 								  });
 								  await t.test('flow inside dead-band → steady', () => {
 								    assert.equal(ps._deriveDirection(0), 'steady');
 								    assert.equal(ps._deriveDirection(1e-5), 'steady');
 								    assert.equal(ps._deriveDirection(-1e-5), 'steady');
 								  });
 								});
 								test('Mode change — changeMode', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  await t.test('valid mode swap updates this.mode', () => {
 								    ps.changeMode('manual');
 								    assert.equal(ps.mode, 'manual');
 								  });
 								  await t.test('rejected mode leaves this.mode unchanged', () => {
 								    ps.changeMode('manual');
 								    ps.changeMode('notamode');
 								    assert.equal(ps.mode, 'manual');
 								  });
 								});
 								test('Calibration — predicted volume and level', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  await t.test('calibratePredictedVolume rewrites volume series', () => {
 								    ps.calibratePredictedVolume(25);
 								    const vol = ps.measurements.type('volume').variant('predicted').position('atequipment').getCurrentValue('m3');
 								    assert.ok(Math.abs(vol - 25) < 1e-9);
 								  });
 								  await t.test('calibratePredictedVolume also writes level (= vol / area)', () => {
 								    ps.calibratePredictedVolume(30);
 								    const lvl = ps.measurements.type('level').variant('predicted').position('atequipment').getCurrentValue('m');
 								    assert.ok(Math.abs(lvl - 3) < 1e-9);  // 30 / 10
 								  });
 								  await t.test('calibratePredictedLevel writes level + volume = level × area', () => {
 								    ps.calibratePredictedLevel(2.5);
 								    const lvl = ps.measurements.type('level').variant('predicted').position('atequipment').getCurrentValue('m');
 								    const vol = ps.measurements.type('volume').variant('predicted').position('atequipment').getCurrentValue('m3');
 								    assert.ok(Math.abs(lvl - 2.5) < 1e-9);
 								    assert.ok(Math.abs(vol - 25) < 1e-9);  // 2.5 × 10
 								  });
 								});
 								test('Levelbased control zones — _controlLevelBased', async (t) => {
 								  await t.test('level < minLevel → percControl=0 and MGC turnOff called', async () => {
 								    const ps = new PumpingStation(makeConfig());
 								    let turnOffCalls = 0;
 								    ps.machineGroups['mgc1'] = {
 								      config: { general: { name: 'mgc1' } },
 								      turnOffAllMachines: () => { turnOffCalls++; },
 								      handleInput: async () => {},
 								    };
 								    ps.calibratePredictedLevel(0.5);  // below minLevel=1
 								    await ps._controlLevelBased();
 								    assert.equal(ps.percControl, 0);
 								    assert.equal(turnOffCalls, 1);
 								  });
 								  await t.test('minLevel ≤ level < startLevel → dead zone, percControl unchanged', async () => {
 								    const ps = new PumpingStation(makeConfig());
 								    ps.percControl = 42;  // simulated previous demand
 								    ps.machineGroups['mgc1'] = {
 								      config: { general: { name: 'mgc1' } },
 								      turnOffAllMachines: () => {},
 								      handleInput: async () => { throw new Error('should not be called in dead zone'); },
 								    };
 								    ps.calibratePredictedLevel(1.5);  // between minLevel=1 and startLevel=2
 								    await ps._controlLevelBased();
 								    assert.equal(ps.percControl, 42);  // unchanged
 								  });
 								  await t.test('level ≥ startLevel → percControl linearly scaled to [0,100]', async () => {
 								    const ps = new PumpingStation(makeConfig());
 								    const demands = [];
 								    ps.machineGroups['mgc1'] = {
 								      config: { general: { name: 'mgc1' } },
 								      turnOffAllMachines: () => {},
 								      handleInput: async (_src, d) => { demands.push(d); },
 								    };
 								    ps.calibratePredictedLevel(3);  // midpoint of startLevel=2 and maxLevel=4
 								    await ps._controlLevelBased();
 								    // lerp(3, [2,4], [0,100]) = 50
 								    assert.ok(Math.abs(ps.percControl - 50) < 1e-9);
 								    assert.equal(demands.length, 1);
 								    assert.ok(Math.abs(demands[0] - 50) < 1e-9);
 								  });
 								  await t.test('level > maxLevel → percControl ≥ 100 (MGC clamps internally)', async () => {
 								    const ps = new PumpingStation(makeConfig());
 								    ps.machineGroups['mgc1'] = {
 								      config: { general: { name: 'mgc1' } },
 								      turnOffAllMachines: () => {},
 								      handleInput: async () => {},
 								    };
 								    ps.calibratePredictedLevel(4.5);  // above maxLevel=4
 								    await ps._controlLevelBased();
 								    assert.ok(ps.percControl >= 100);
 								  });
 								});
 								test('getOutput — flattens basin + state + demand', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  ps.percControl = 37;
 								  await t.test('includes basin geometry fields', () => {
 								    const out = ps.getOutput();
 								    assert.equal(out.volEmptyBasin, 50);
 								    assert.equal(out.maxVolAtOverflow, 45);
 								    assert.equal(out.minVolAtInflow, 30);
 								    assert.ok(Math.abs(out.minVolAtOutflow - 2) < 1e-9);
 								  });
 								  await t.test('includes state fields (direction, flowSource, timeleft)', () => {
 								    const out = ps.getOutput();
 								    assert.ok('direction' in out);
 								    assert.ok('flowSource' in out);
 								    assert.ok('timeleft' in out);
 								  });
 								  await t.test('includes percControl', () => {
 								    assert.equal(ps.getOutput().percControl, 37);
 								  });
 								});
 								test('Manual inflow — setManualInflow stores predicted inflow', async (t) => {
 								  const ps = new PumpingStation(makeConfig());
 								  ps.setManualInflow(0.05, Date.now(), 'm3/s');  // 0.05 m³/s
 								  const v = ps.measurements.type('flow').variant('predicted').position('in').child('manual-qin').getCurrentValue('m3/s');
 								  assert.ok(Math.abs(v - 0.05) < 1e-9);
 								});