const test = require('tap').test; const Sensing = require('../../src/blocks/scratch3_sensing'); const Runtime = require('../../src/engine/runtime'); const Sprite = require('../../src/sprites/sprite'); const RenderedTarget = require('../../src/sprites/rendered-target'); const BlockUtility = require('../../src/engine/block-utility'); test('getPrimitives', t => { const rt = new Runtime(); const s = new Sensing(rt); t.type(s.getPrimitives(), 'object'); t.end(); }); test('ask and answer with a hidden target', t => { const rt = new Runtime(); const s = new Sensing(rt); const util = {target: {visible: false}}; const expectedQuestion = 'a question'; const expectedAnswer = 'the answer'; // Test is written out of order because of promises, follow the (#) comments. rt.addListener('QUESTION', question => { // (2) Assert the question is correct, then emit the answer t.strictEqual(question, expectedQuestion); rt.emit('ANSWER', expectedAnswer); }); // (1) Emit the question. const promise = s.askAndWait({QUESTION: expectedQuestion}, util); // (3) Ask block resolves after the answer is emitted. promise.then(() => { t.strictEqual(s.getAnswer(), expectedAnswer); t.end(); }); }); test('ask and stop all dismisses question', t => { const rt = new Runtime(); const s = new Sensing(rt); const util = {target: {visible: false}}; const expectedQuestion = 'a question'; let call = 0; rt.addListener('QUESTION', question => { if (call === 0) { // (2) Assert the question was passed. t.strictEqual(question, expectedQuestion); } else if (call === 1) { // (4) Assert the question was dismissed. t.strictEqual(question, null); t.end(); } call += 1; }); // (1) Emit the question. s.askAndWait({QUESTION: expectedQuestion}, util); // (3) Emit the stop all event. rt.stopAll(); }); test('ask and stop other scripts dismisses if it is the last question', t => { const rt = new Runtime(); const s = new Sensing(rt); const util = {target: {visible: false}, thread: {}}; const expectedQuestion = 'a question'; let call = 0; rt.addListener('QUESTION', question => { if (call === 0) { // (2) Assert the question was passed. t.strictEqual(question, expectedQuestion); } else if (call === 1) { // (4) Assert the question was dismissed. t.strictEqual(question, null); t.end(); } call += 1; }); // (1) Emit the questions. s.askAndWait({QUESTION: expectedQuestion}, util); // (3) Emit the stop for target event. rt.stopForTarget(util.target, util.thread); }); test('ask and stop other scripts asks next question', t => { const rt = new Runtime(); const s = new Sensing(rt); const util = {target: {visible: false}, thread: {}}; const util2 = {target: {visible: false}, thread: {}}; const expectedQuestion = 'a question'; const nextQuestion = 'a followup'; let call = 0; rt.addListener('QUESTION', question => { if (call === 0) { // (2) Assert the question was passed. t.strictEqual(question, expectedQuestion); } else if (call === 1) { // (4) Assert the next question was passed. t.strictEqual(question, nextQuestion); t.end(); } call += 1; }); // (1) Emit the questions. s.askAndWait({QUESTION: expectedQuestion}, util); s.askAndWait({QUESTION: nextQuestion}, util2); // (3) Emit the stop for target event. rt.stopForTarget(util.target, util.thread); }); test('ask and answer with a visible target', t => { const rt = new Runtime(); const s = new Sensing(rt); const util = {target: {visible: true}}; const expectedQuestion = 'a question'; const expectedAnswer = 'the answer'; rt.removeAllListeners('SAY'); // Prevent say blocks from executing rt.addListener('SAY', (target, type, question) => { // Should emit SAY with the question t.strictEqual(question, expectedQuestion); }); rt.addListener('QUESTION', question => { // Question should be blank for a visible target t.strictEqual(question, ''); // Remove the say listener and add a new one to assert bubble is cleared // by setting say to empty string after answer is received. rt.removeAllListeners('SAY'); rt.addListener('SAY', (target, type, text) => { t.strictEqual(text, ''); t.end(); }); rt.emit('ANSWER', expectedAnswer); }); s.askAndWait({QUESTION: expectedQuestion}, util); }); test('set drag mode', t => { const runtime = new Runtime(); runtime.requestTargetsUpdate = () => {}; // noop for testing const sensing = new Sensing(runtime); const s = new Sprite(); const rt = new RenderedTarget(s, runtime); sensing.setDragMode({DRAG_MODE: 'not draggable'}, {target: rt}); t.strictEqual(rt.draggable, false); sensing.setDragMode({DRAG_MODE: 'draggable'}, {target: rt}); t.strictEqual(rt.draggable, true); t.end(); }); test('get loudness with caching', t => { const rt = new Runtime(); const sensing = new Sensing(rt); // It should report -1 when audio engine is not available. t.strictEqual(sensing.getLoudness(), -1); // Stub the audio engine with its getLoudness function, and set up different // values to simulate it changing over time. const firstLoudness = 1; const secondLoudness = 2; let simulatedLoudness = firstLoudness; rt.audioEngine = {getLoudness: () => simulatedLoudness}; // It should report -1 when current step time is null. t.strictEqual(sensing.getLoudness(), -1); // Stub the current step time. rt.currentStepTime = 1000 / 30; // The first time it works, it should report the result from the stubbed audio engine. t.strictEqual(sensing.getLoudness(), firstLoudness); // Update the simulated loudness to a new value. simulatedLoudness = secondLoudness; // Simulate time passing by advancing the timer forward a little bit. // After less than a step, it should still report cached loudness. let simulatedTime = Date.now() + (rt.currentStepTime / 2); sensing._timer = {time: () => simulatedTime}; t.strictEqual(sensing.getLoudness(), firstLoudness); // Simulate more than a step passing. It should now request the value // from the audio engine again. simulatedTime += rt.currentStepTime; t.strictEqual(sensing.getLoudness(), secondLoudness); t.end(); }); test('loud? boolean', t => { const rt = new Runtime(); const sensing = new Sensing(rt); // The simplest way to test this is to actually override the getLoudness // method, which isLoud uses. let simulatedLoudness = 0; sensing.getLoudness = () => simulatedLoudness; t.false(sensing.isLoud()); // Check for GREATER than 10, not equal. simulatedLoudness = 10; t.false(sensing.isLoud()); simulatedLoudness = 11; t.true(sensing.isLoud()); t.end(); }); test('username block', t => { const rt = new Runtime(); const sensing = new Sensing(rt); const util = new BlockUtility(rt.sequencer); t.equal(sensing.getUsername({}, util), ''); t.end(); });