// META: global=window,dedicatedworker // META: variant=?av1 // META: variant=?vp8 // META: variant=?vp9 // META: variant=?h264_avc // META: variant=?h264_annexb // META: variant=?h265_hevc // META: variant=?h265_annexb const AV1_DATA = { src: 'av1.mp4', config: { codec: 'av01.0.04M.08', codedWidth: 320, codedHeight: 240, visibleRect: {x: 0, y: 0, width: 320, height: 240}, displayWidth: 320, displayHeight: 240, }, chunks: [ {offset: 48, size: 1938}, {offset: 1986, size: 848}, {offset: 2834, size: 3}, {offset: 2837, size: 47}, {offset: 2884, size: 3}, {offset: 2887, size: 116}, {offset: 3003, size: 3}, {offset: 3006, size: 51}, {offset: 3057, size: 25}, {offset: 3082, size: 105} ] }; const VP8_DATA = { src: 'vp8.webm', config: { codec: 'vp8', codedWidth: 320, codedHeight: 240, visibleRect: {x: 0, y: 0, width: 320, height: 240}, displayWidth: 320, displayHeight: 240, }, chunks: [ {offset: 522, size: 4826}, {offset: 5355, size: 394}, {offset: 5756, size: 621}, {offset: 6384, size: 424}, {offset: 6815, size: 532}, {offset: 7354, size: 655}, {offset: 8016, size: 670}, {offset: 8693, size: 2413}, {offset: 11113, size: 402}, {offset: 11522, size: 686} ] }; const VP9_DATA = { src: 'vp9.mp4', // TODO(sandersd): Verify that the file is actually level 1. config: { codec: 'vp09.00.10.08', codedWidth: 320, codedHeight: 240, displayAspectWidth: 320, displayAspectHeight: 240, }, chunks: [ {offset: 44, size: 3315}, {offset: 3359, size: 203}, {offset: 3562, size: 245}, {offset: 3807, size: 172}, {offset: 3979, size: 312}, {offset: 4291, size: 170}, {offset: 4461, size: 195}, {offset: 4656, size: 181}, {offset: 4837, size: 356}, {offset: 5193, size: 159} ] }; const H264_AVC_DATA = { src: 'h264.mp4', config: { codec: 'avc1.64000b', description: {offset: 9490, size: 45}, codedWidth: 320, codedHeight: 240, displayAspectWidth: 320, displayAspectHeight: 240, }, chunks: [ {offset: 48, size: 4140}, {offset: 4188, size: 604}, {offset: 4792, size: 475}, {offset: 5267, size: 561}, {offset: 5828, size: 587}, {offset: 6415, size: 519}, {offset: 6934, size: 532}, {offset: 7466, size: 523}, {offset: 7989, size: 454}, {offset: 8443, size: 528} ] }; const H264_ANNEXB_DATA = { src: 'h264.annexb', config: { codec: 'avc1.64000b', codedWidth: 320, codedHeight: 240, displayAspectWidth: 320, displayAspectHeight: 240, }, chunks: [ {offset: 0, size: 4175}, {offset: 4175, size: 602}, {offset: 4777, size: 473}, {offset: 5250, size: 559}, {offset: 5809, size: 585}, {offset: 6394, size: 517}, {offset: 6911, size: 530}, {offset: 7441, size: 521}, {offset: 7962, size: 452}, {offset: 8414, size: 526} ] }; const H265_HEVC_DATA = { src: 'h265.mp4', config: { codec: 'hev1.1.6.L60.90', description: {offset: 5821, size: 2406}, codedWidth: 320, codedHeight: 240, displayAspectWidth: 320, displayAspectHeight: 240, }, chunks: [ {offset: 44, size: 2515}, {offset: 2559, size: 279}, {offset: 2838, size: 327}, {offset: 3165, size: 329}, {offset: 3494, size: 308}, {offset: 3802, size: 292}, {offset: 4094, size: 352}, {offset: 4446, size: 296}, {offset: 4742, size: 216}, {offset: 4958, size: 344} ] }; const H265_ANNEXB_DATA = { src: 'h265.annexb', config: { codec: 'hev1.1.6.L60.90', codedWidth: 320, codedHeight: 240, displayAspectWidth: 320, displayAspectHeight: 240, }, chunks: [ {offset: 0, size: 4894}, {offset: 4894, size: 279}, {offset: 5173, size: 327}, {offset: 5500, size: 329}, {offset: 5829, size: 308}, {offset: 6137, size: 292}, {offset: 6429, size: 352}, {offset: 6781, size: 296}, {offset: 7077, size: 216}, {offset: 7293, size: 344} ] }; // Allows mutating `callbacks` after constructing the VideoDecoder, wraps calls // in t.step(). function createVideoDecoder(t, callbacks) { return new VideoDecoder({ output(frame) { if (callbacks && callbacks.output) { t.step(() => callbacks.output(frame)); } else { t.unreached_func('unexpected output()'); } }, error(e) { if (callbacks && callbacks.error) { t.step(() => callbacks.error(e)); } else { t.unreached_func('unexpected error()'); } } }); } function createCorruptChunk(index) { let bad_data = CHUNK_DATA[index]; for (var i = 0; i < bad_data.byteLength; i += 4) bad_data[i] = 0xFF; return new EncodedVideoChunk( {type: 'delta', timestamp: index, data: bad_data}); } // Create a view of an ArrayBuffer. function view(buffer, {offset, size}) { return new Uint8Array(buffer, offset, size); } async function checkImplements() { // Don't run any tests if the codec is not supported. assert_equals("function", typeof VideoDecoder.isConfigSupported); let supported = false; try { // TODO(sandersd): To properly support H.264 in AVC format, this should // include the `description`. For now this test assumes that H.264 Annex B // support is the same as H.264 AVC support. const support = await VideoDecoder.isConfigSupported({codec: CONFIG.codec}); supported = support.supported; } catch (e) { } assert_implements_optional(supported, CONFIG.codec + ' unsupported'); } let CONFIG = null; let CHUNK_DATA = null; let CHUNKS = null; promise_setup(async () => { const data = { '?av1': AV1_DATA, '?vp8': VP8_DATA, '?vp9': VP9_DATA, '?h264_avc': H264_AVC_DATA, '?h264_annexb': H264_ANNEXB_DATA, '?h265_hevc': H265_HEVC_DATA, '?h265_annexb': H265_ANNEXB_DATA }[location.search]; // Fetch the media data and prepare buffers. const response = await fetch(data.src); const buf = await response.arrayBuffer(); CONFIG = {...data.config}; if (data.config.description) { CONFIG.description = view(buf, data.config.description); } CHUNK_DATA = data.chunks.map((chunk, i) => view(buf, chunk)); CHUNKS = CHUNK_DATA.map( (data, i) => new EncodedVideoChunk( {type: i == 0 ? 'key' : 'delta', timestamp: i, duration: 1, data})); }); promise_test(async t => { await checkImplements(); const support = await VideoDecoder.isConfigSupported(CONFIG); assert_true(support.supported, 'supported'); }, 'Test isConfigSupported()'); promise_test(async t => { await checkImplements(); // TODO(sandersd): Create a 1080p `description` for H.264 in AVC format. // This version is testing only the H.264 Annex B path. const config = { codec: CONFIG.codec, codedWidth: 1920, codedHeight: 1088, displayAspectWidth: 1920, displayAspectHeight: 1080, }; const support = await VideoDecoder.isConfigSupported(config); assert_true(support.supported, 'supported'); }, 'Test isConfigSupported() with 1080p crop'); promise_test(async t => { await checkImplements(); // Define a valid config that includes a hypothetical `futureConfigFeature`, // which is not yet recognized by the User Agent. const config = { ...CONFIG, colorSpace: {primaries: 'bt709'}, futureConfigFeature: 'foo', }; // The UA will evaluate validConfig as being "valid", ignoring the // `futureConfigFeature` it doesn't recognize. const support = await VideoDecoder.isConfigSupported(config); assert_true(support.supported, 'supported'); assert_equals(support.config.codec, config.codec, 'codec'); assert_equals(support.config.codedWidth, config.codedWidth, 'codedWidth'); assert_equals(support.config.codedHeight, config.codedHeight, 'codedHeight'); assert_equals(support.config.displayAspectWidth, config.displayAspectWidth, 'displayAspectWidth'); assert_equals(support.config.displayAspectHeight, config.displayAspectHeight, 'displayAspectHeight'); assert_equals(support.config.colorSpace.primaries, config.colorSpace.primaries, 'color primaries'); assert_equals(support.config.colorSpace.transfer, null, 'color transfer'); assert_equals(support.config.colorSpace.matrix, null, 'color matrix'); assert_equals(support.config.colorSpace.fullRange, null, 'color range'); assert_false(support.config.hasOwnProperty('futureConfigFeature'), 'futureConfigFeature'); if (config.description) { // The description must be copied. assert_false( support.config.description === config.description, 'description is unique'); assert_array_equals( new Uint8Array(support.config.description, 0), new Uint8Array(config.description, 0), 'description'); } else { assert_false(support.config.hasOwnProperty('description'), 'description'); } }, 'Test that isConfigSupported() returns a parsed configuration'); promise_test(async t => { await checkImplements(); async function test(t, config, description) { await promise_rejects_js( t, TypeError, VideoDecoder.isConfigSupported(config), description); const decoder = createVideoDecoder(t); assert_throws_js(TypeError, () => decoder.configure(config), description); assert_equals(decoder.state, 'unconfigured', 'state'); } await test(t, {...CONFIG, codedWidth: 0}, 'invalid codedWidth'); await test(t, {...CONFIG, displayAspectWidth: 0}, 'invalid displayAspectWidth'); }, 'Test invalid configs'); promise_test(async t => { await checkImplements(); const decoder = createVideoDecoder(t); decoder.configure(CONFIG); assert_equals(decoder.state, 'configured', 'state'); }, 'Test configure()'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); let outputs = 0; callbacks.output = frame => { outputs++; assert_equals(frame.timestamp, CHUNKS[0].timestamp, 'timestamp'); assert_equals(frame.duration, CHUNKS[0].duration, 'duration'); frame.close(); }; await decoder.flush(); assert_equals(outputs, 1, 'outputs'); }, 'Decode a key frame'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); // Ensure type value is verified. assert_equals(CHUNKS[1].type, 'delta'); assert_throws_dom('DataError', () => decoder.decode(CHUNKS[1], 'decode')); }, 'Decode a non key frame first fails'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); for (let i = 0; i < 16; i++) { decoder.decode(new EncodedVideoChunk( {type: 'key', timestamp: 0, data: CHUNK_DATA[0]})); } assert_greater_than(decoder.decodeQueueSize, 0); // Wait for the first output, then reset the decoder. let outputs = 0; await new Promise(resolve => { callbacks.output = frame => { outputs++; assert_equals(outputs, 1, 'outputs'); assert_equals(frame.timestamp, 0, 'timestamp'); frame.close(); decoder.reset(); assert_equals(decoder.decodeQueueSize, 0, 'decodeQueueSize'); resolve(); }; }); decoder.configure(CONFIG); for (let i = 0; i < 4; i++) { decoder.decode(new EncodedVideoChunk( {type: 'key', timestamp: 1, data: CHUNK_DATA[0]})); } // Expect future outputs to come from after the reset. callbacks.output = frame => { outputs++; assert_equals(frame.timestamp, 1, 'timestamp'); frame.close(); }; await decoder.flush(); assert_equals(outputs, 5); assert_equals(decoder.decodeQueueSize, 0); }, 'Verify reset() suppresses outputs'); promise_test(async t => { await checkImplements(); const decoder = createVideoDecoder(t); assert_equals(decoder.state, 'unconfigured'); decoder.reset(); assert_equals(decoder.state, 'unconfigured'); assert_throws_dom( 'InvalidStateError', () => decoder.decode(CHUNKS[0]), 'decode'); await promise_rejects_dom(t, 'InvalidStateError', decoder.flush(), 'flush'); }, 'Test unconfigured VideoDecoder operations'); promise_test(async t => { await checkImplements(); const decoder = createVideoDecoder(t); decoder.close(); assert_equals(decoder.state, 'closed'); assert_throws_dom( 'InvalidStateError', () => decoder.configure(CONFIG), 'configure'); assert_throws_dom('InvalidStateError', () => decoder.reset(), 'reset'); assert_throws_dom('InvalidStateError', () => decoder.close(), 'close'); assert_throws_dom( 'InvalidStateError', () => decoder.decode(CHUNKS[0]), 'decode'); await promise_rejects_dom(t, 'InvalidStateError', decoder.flush(), 'flush'); }, 'Test closed VideoDecoder operations'); promise_test(async t => { await checkImplements(); const callbacks = {}; let errors = 0; let gotError = new Promise(resolve => callbacks.error = e => { errors++; resolve(e); }); callbacks.output = frame => { frame.close(); }; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); // Decode keyframe first. decoder.decode(new EncodedVideoChunk( {type: 'key', timestamp: 1, data: new ArrayBuffer(0)})); await promise_rejects_dom(t, "EncodingError", decoder.flush().catch((e) => { assert_equals(errors, 1); throw e; }) ); let e = await gotError; assert_true(e instanceof DOMException); assert_equals(e.name, 'EncodingError'); assert_equals(decoder.state, 'closed', 'state'); }, 'Decode empty frame'); promise_test(async t => { await checkImplements(); const callbacks = {}; let errors = 0; let gotError = new Promise(resolve => callbacks.error = e => { errors++; resolve(e); }); let outputs = 0; callbacks.output = frame => { outputs++; frame.close(); }; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); // Decode keyframe first. decoder.decode(createCorruptChunk(2)); await promise_rejects_dom(t, "EncodingError", decoder.flush().catch((e) => { assert_equals(errors, 1); throw e; }) ); assert_less_than_equal(outputs, 1); let e = await gotError; assert_true(e instanceof DOMException); assert_equals(e.name, 'EncodingError'); assert_equals(decoder.state, 'closed', 'state'); }, 'Decode corrupt frame'); promise_test(async t => { await checkImplements(); const decoder = createVideoDecoder(t); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); // Decode keyframe first. decoder.decode(createCorruptChunk(1)); let flushDone = decoder.flush(); decoder.close(); // Flush should have been synchronously rejected, with no output() or error() // callbacks. await promise_rejects_dom(t, 'AbortError', flushDone); }, 'Close while decoding corrupt frame'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); let outputs = 0; callbacks.output = frame => { outputs++; frame.close(); }; await decoder.flush(); assert_equals(outputs, 1, 'outputs'); decoder.decode(CHUNKS[0]); await decoder.flush(); assert_equals(outputs, 2, 'outputs'); }, 'Test decoding after flush'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(new EncodedVideoChunk( {type: 'key', timestamp: -42, data: CHUNK_DATA[0]})); let outputs = 0; callbacks.output = frame => { outputs++; assert_equals(frame.timestamp, -42, 'timestamp'); frame.close(); }; await decoder.flush(); assert_equals(outputs, 1, 'outputs'); }, 'Test decoding a with negative timestamp'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure(CONFIG); decoder.decode(CHUNKS[0]); decoder.decode(CHUNKS[1]); const flushDone = decoder.flush(); // Wait for the first output, then reset. let outputs = 0; await new Promise(resolve => { callbacks.output = frame => { outputs++; assert_equals(outputs, 1, 'outputs'); decoder.reset(); frame.close(); resolve(); }; }); // Flush should have been synchronously rejected. await promise_rejects_dom(t, 'AbortError', flushDone); assert_equals(outputs, 1, 'outputs'); }, 'Test reset during flush'); promise_test(async t => { await checkImplements(); const callbacks = {}; const decoder = createVideoDecoder(t, callbacks); decoder.configure({...CONFIG, optimizeForLatency: true}); decoder.decode(CHUNKS[0]); // The frame should be output without flushing. await new Promise(resolve => { callbacks.output = frame => { frame.close(); resolve(); }; }); }, 'Test low-latency decoding'); promise_test(async t => { await checkImplements(); const callbacks = {}; callbacks.output = frame => { frame.close(); }; const decoder = createVideoDecoder(t, callbacks); // No decodes yet. assert_equals(decoder.decodeQueueSize, 0); decoder.configure(CONFIG); // Still no decodes. assert_equals(decoder.decodeQueueSize, 0); let lastDequeueSize = Infinity; decoder.ondequeue = () => { assert_greater_than(lastDequeueSize, 0, "Dequeue event after queue empty"); assert_greater_than(lastDequeueSize, decoder.decodeQueueSize, "Dequeue event without decreased queue size"); lastDequeueSize = decoder.decodeQueueSize; }; for (let chunk of CHUNKS) decoder.decode(chunk); assert_greater_than_equal(decoder.decodeQueueSize, 0); assert_less_than_equal(decoder.decodeQueueSize, CHUNKS.length); await decoder.flush(); // We can guarantee that all decodes are processed after a flush. assert_equals(decoder.decodeQueueSize, 0); // Last dequeue event should fire when the queue is empty. assert_equals(lastDequeueSize, 0); // Reset this to Infinity to track the decline of queue size for this next // batch of decodes. lastDequeueSize = Infinity; for (let chunk of CHUNKS) decoder.decode(chunk); assert_greater_than_equal(decoder.decodeQueueSize, 0); decoder.reset(); assert_equals(decoder.decodeQueueSize, 0); }, 'VideoDecoder decodeQueueSize test');