third_party/blink/web_tests/external/wpt/webrtc/RTCDataChannel-bufferedAmount.html - chromium/src - Git at Google

 <!doctype html>
 <meta charset=utf-8>
 <title>RTCDataChannel.prototype.bufferedAmount</title>
 <script src="/resources/testharness.js"></script>
 <script src="/resources/testharnessreport.js"></script>
 <script src="RTCPeerConnection-helper.js"></script>
 <script>
 'use strict';

 // Test is based on the following revision:
 // https://rawgit.com/w3c/webrtc-pc/1cc5bfc3ff18741033d804c4a71f7891242fb5b3/webrtc.html

 // The following helper functions are called from RTCPeerConnection-helper.js:
 //  createDataChannelPair
 //  awaitMessage

 /*
   6.2.  RTCDataChannel
     interface RTCDataChannel : EventTarget {
       ...
       readonly  attribute unsigned long       bufferedAmount;
       void send(USVString data);
       void send(Blob data);
       void send(ArrayBuffer data);
       void send(ArrayBufferView data);
     };

     bufferedAmount
       The bufferedAmount attribute must return the number of bytes of application
       data (UTF-8 text and binary data) that have been queued using send() but that,
       as of the last time the event loop started executing a task, had not yet been
       transmitted to the network. (This thus includes any text sent during the
       execution of the current task, regardless of whether the user agent is able
       to transmit text asynchronously with script execution.) This does not include
       framing overhead incurred by the protocol, or buffering done by the operating
       system or network hardware. The value of the [[BufferedAmount]] slot will only
       increase with each call to the send() method as long as the [[ReadyState]] slot
       is open; however, the slot does not reset to zero once the channel closes. When
       the underlying data transport sends data from its queue, the user agent MUST
       queue a task that reduces [[BufferedAmount]] with the number of bytes that was
       sent.


   [WebMessaging]
   interface MessageEvent : Event {
     readonly attribute any data;
     ...
   };
  */

 // Simple ASCII encoded string
 const helloString = 'hello';
 // ASCII encoded buffer representation of the string
 const helloBuffer = Uint8Array.of(0x68, 0x65, 0x6c, 0x6c, 0x6f);
 const helloBlob = new Blob([helloBuffer]);

 // Unicode string with multiple code units
 const unicodeString = '世界你好';
 // UTF-8 encoded buffer representation of the string
 const unicodeBuffer = Uint8Array.of(
   0xe4, 0xb8, 0x96, 0xe7, 0x95, 0x8c,
   0xe4, 0xbd, 0xa0, 0xe5, 0xa5, 0xbd);

 /*
   Ensure .bufferedAmount is 0 initially for both sides.
  */
 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

   assert_equals(dc1.bufferedAmount, 0, 'Expect bufferedAmount to be 0');
   assert_equals(dc2.bufferedAmount, 0, 'Expect bufferedAmount to be 0');
 }, 'bufferedAmount initial value should be 0 for both peers');

 /*
   6.2.  send()
     3.  Execute the sub step that corresponds to the type of the methods argument:

         string object
           Let data be the object and increase the bufferedAmount attribute
           by the number of bytes needed to express data as UTF-8.
  */
 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

   dc1.send(unicodeString);
   assert_equals(dc1.bufferedAmount, unicodeBuffer.byteLength,
     'Expect bufferedAmount to be the byte length of the unicode string');

   await awaitMessage(dc2);
   assert_equals(dc1.bufferedAmount, 0,
     'Expect sender bufferedAmount to be reduced after message is sent');
 }, 'bufferedAmount should increase to byte length of encoded unicode string sent');

 /*
   6.2. send()
     3.  Execute the sub step that corresponds to the type of the methods argument:
         ArrayBuffer object
           Let data be the data stored in the buffer described by the ArrayBuffer
           object and increase the bufferedAmount attribute by the length of the
           ArrayBuffer in bytes.
  */
 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

   dc1.send(helloBuffer.buffer);
   assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
     'Expect bufferedAmount to increase to byte length of sent buffer');

   await awaitMessage(dc2);
   assert_equals(dc1.bufferedAmount, 0,
     'Expect sender bufferedAmount to be reduced after message is sent');
 }, 'bufferedAmount should increase to byte length of buffer sent');

 /*
   6.2. send()
     3.  Execute the sub step that corresponds to the type of the methods argument:
         Blob object
           Let data be the raw data represented by the Blob object and increase
           the bufferedAmount attribute by the size of data, in bytes.
  */
 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

   dc1.send(helloBlob);
   assert_equals(dc1.bufferedAmount, helloBlob.size,
     'Expect bufferedAmount to increase to size of sent blob');

   await awaitMessage(dc2);
   assert_equals(dc1.bufferedAmount, 0,
     'Expect sender bufferedAmount to be reduced after message is sent');
 }, 'bufferedAmount should increase to size of blob sent');

 // Test sending 3 messages: helloBuffer, unicodeString, helloBlob
 promise_test(async (t) => {
   const resolver = new Resolver();
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   let messageCount = 0;

   const [dc1, dc2] = await createDataChannelPair(pc1, pc2);
   const onMessage = t.step_func(() => {
     if (++messageCount === 3) {
       assert_equals(dc1.bufferedAmount, 0,
         'Expect sender bufferedAmount to be reduced after message is sent');
       resolver.resolve();
     }
   });

   dc2.addEventListener('message', onMessage);

   dc1.send(helloBuffer);
   assert_equals(dc1.bufferedAmount, helloString.length,
     'Expect bufferedAmount to be the total length of all messages queued to send');

   dc1.send(unicodeString);
   assert_equals(dc1.bufferedAmount,
     helloString.length + unicodeBuffer.byteLength,
     'Expect bufferedAmount to be the total length of all messages queued to send');

   dc1.send(helloBlob);
   assert_equals(dc1.bufferedAmount,
     helloString.length*2 + unicodeBuffer.byteLength,
     'Expect bufferedAmount to be the total length of all messages queued to send');

   await resolver;
 }, 'bufferedAmount should increase by byte length for each message sent');

 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1] = await createDataChannelPair(pc1, pc2);

   dc1.send(helloBuffer.buffer);
   assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
     'Expect bufferedAmount to increase to byte length of sent buffer');

   dc1.close();
   assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
     'Expect bufferedAmount to not decrease immediately after closing the channel');
 }, 'bufferedAmount should not decrease immediately after initiating closure');

 promise_test(async (t) => {
   const pc1 = new RTCPeerConnection();
   const pc2 = new RTCPeerConnection();
   t.add_cleanup(() => pc1.close());
   t.add_cleanup(() => pc2.close());

   const [dc1] = await createDataChannelPair(pc1, pc2);

   dc1.send(helloBuffer.buffer);
   assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
     'Expect bufferedAmount to increase to byte length of sent buffer');

   pc1.close();
   assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
     'Expect bufferedAmount to not decrease after closing the peer connection');
 }, 'bufferedAmount should not decrease after closing the peer connection');

   promise_test(async t => {
     const [channel1, channel2] = await createDataChannelPair();
     channel1.addEventListener('bufferedamountlow', t.step_func_done(() => {
       assert_true(channel1.bufferedAmount <= channel1.bufferedAmountLowThreshold);
     }));
     const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
     channel1.send(helloString);
     await eventWatcher.wait_for(['bufferedamountlow']);
   }, 'Data channel bufferedamountlow event fires after send() is complete');

   promise_test(async t => {
     const [channel1, channel2] = await createDataChannelPair();
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, helloString.length);
     await awaitMessage(channel2);
     assert_equals(channel1.bufferedAmount, 0);
   }, 'Data channel bufferedamount is data.length on send(data)');

   promise_test(async t => {
     const [channel1, channel2] = await createDataChannelPair();
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, helloString.length);
     assert_equals(channel1.bufferedAmount, helloString.length);
   }, 'Data channel bufferedamount returns the same amount if no more data is' +
      ' sent on the channel');

   promise_test(async t => {
     const [channel1, channel2] = await createDataChannelPair();
     let eventFireCount = 0;
     channel1.addEventListener('bufferedamountlow', t.step_func(() => {
       assert_true(channel1.bufferedAmount <= channel1.bufferedAmountLowThreshold);
       assert_equals(++eventFireCount, 1);
     }));
     const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, helloString.length);
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, 2 * helloString.length);
     await eventWatcher.wait_for(['bufferedamountlow']);
   }, 'Data channel bufferedamountlow event fires only once after multiple' +
     ' consecutive send() calls');

   promise_test(async t => {
     const [channel1, channel2] = await createDataChannelPair();
     const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, helloString.length);
     await eventWatcher.wait_for(['bufferedamountlow']);
     assert_equals(await awaitMessage(channel2), helloString);
     channel1.send(helloString);
     assert_equals(channel1.bufferedAmount, helloString.length);
     await eventWatcher.wait_for(['bufferedamountlow']);
     assert_equals(await awaitMessage(channel2), helloString);
   }, 'Data channel bufferedamountlow event fires after each sent message');

 </script>
	<!doctype html>
	<meta charset=utf-8>
	<title>RTCDataChannel.prototype.bufferedAmount</title>
	<script src="/resources/testharness.js"></script>
	<script src="/resources/testharnessreport.js"></script>
	<script src="RTCPeerConnection-helper.js"></script>
	<script>
	'use strict';

	// Test is based on the following revision:
	// https://rawgit.com/w3c/webrtc-pc/1cc5bfc3ff18741033d804c4a71f7891242fb5b3/webrtc.html

	// The following helper functions are called from RTCPeerConnection-helper.js:
	// createDataChannelPair
	// awaitMessage

	/*
	6.2. RTCDataChannel
	interface RTCDataChannel : EventTarget {
	...
	readonly attribute unsigned long bufferedAmount;
	void send(USVString data);
	void send(Blob data);
	void send(ArrayBuffer data);
	void send(ArrayBufferView data);
	};

	bufferedAmount
	The bufferedAmount attribute must return the number of bytes of application
	data (UTF-8 text and binary data) that have been queued using send() but that,
	as of the last time the event loop started executing a task, had not yet been
	transmitted to the network. (This thus includes any text sent during the
	execution of the current task, regardless of whether the user agent is able
	to transmit text asynchronously with script execution.) This does not include
	framing overhead incurred by the protocol, or buffering done by the operating
	system or network hardware. The value of the [[BufferedAmount]] slot will only
	increase with each call to the send() method as long as the [[ReadyState]] slot
	is open; however, the slot does not reset to zero once the channel closes. When
	the underlying data transport sends data from its queue, the user agent MUST
	queue a task that reduces [[BufferedAmount]] with the number of bytes that was
	sent.


	[WebMessaging]
	interface MessageEvent : Event {
	readonly attribute any data;
	...
	};
	*/

	// Simple ASCII encoded string
	const helloString = 'hello';
	// ASCII encoded buffer representation of the string
	const helloBuffer = Uint8Array.of(0x68, 0x65, 0x6c, 0x6c, 0x6f);
	const helloBlob = new Blob([helloBuffer]);

	// Unicode string with multiple code units
	const unicodeString = '世界你好';
	// UTF-8 encoded buffer representation of the string
	const unicodeBuffer = Uint8Array.of(
	0xe4, 0xb8, 0x96, 0xe7, 0x95, 0x8c,
	0xe4, 0xbd, 0xa0, 0xe5, 0xa5, 0xbd);

	/*
	Ensure .bufferedAmount is 0 initially for both sides.
	*/
	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

	assert_equals(dc1.bufferedAmount, 0, 'Expect bufferedAmount to be 0');
	assert_equals(dc2.bufferedAmount, 0, 'Expect bufferedAmount to be 0');
	}, 'bufferedAmount initial value should be 0 for both peers');

	/*
	6.2. send()
	3. Execute the sub step that corresponds to the type of the methods argument:

	string object
	Let data be the object and increase the bufferedAmount attribute
	by the number of bytes needed to express data as UTF-8.
	*/
	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

	dc1.send(unicodeString);
	assert_equals(dc1.bufferedAmount, unicodeBuffer.byteLength,
	'Expect bufferedAmount to be the byte length of the unicode string');

	await awaitMessage(dc2);
	assert_equals(dc1.bufferedAmount, 0,
	'Expect sender bufferedAmount to be reduced after message is sent');
	}, 'bufferedAmount should increase to byte length of encoded unicode string sent');

	/*
	6.2. send()
	3. Execute the sub step that corresponds to the type of the methods argument:
	ArrayBuffer object
	Let data be the data stored in the buffer described by the ArrayBuffer
	object and increase the bufferedAmount attribute by the length of the
	ArrayBuffer in bytes.
	*/
	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

	dc1.send(helloBuffer.buffer);
	assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
	'Expect bufferedAmount to increase to byte length of sent buffer');

	await awaitMessage(dc2);
	assert_equals(dc1.bufferedAmount, 0,
	'Expect sender bufferedAmount to be reduced after message is sent');
	}, 'bufferedAmount should increase to byte length of buffer sent');

	/*
	6.2. send()
	3. Execute the sub step that corresponds to the type of the methods argument:
	Blob object
	Let data be the raw data represented by the Blob object and increase
	the bufferedAmount attribute by the size of data, in bytes.
	*/
	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1, dc2] = await createDataChannelPair(pc1, pc2);

	dc1.send(helloBlob);
	assert_equals(dc1.bufferedAmount, helloBlob.size,
	'Expect bufferedAmount to increase to size of sent blob');

	await awaitMessage(dc2);
	assert_equals(dc1.bufferedAmount, 0,
	'Expect sender bufferedAmount to be reduced after message is sent');
	}, 'bufferedAmount should increase to size of blob sent');

	// Test sending 3 messages: helloBuffer, unicodeString, helloBlob
	promise_test(async (t) => {
	const resolver = new Resolver();
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	let messageCount = 0;

	const [dc1, dc2] = await createDataChannelPair(pc1, pc2);
	const onMessage = t.step_func(() => {
	if (++messageCount === 3) {
	assert_equals(dc1.bufferedAmount, 0,
	'Expect sender bufferedAmount to be reduced after message is sent');
	resolver.resolve();
	}
	});

	dc2.addEventListener('message', onMessage);

	dc1.send(helloBuffer);
	assert_equals(dc1.bufferedAmount, helloString.length,
	'Expect bufferedAmount to be the total length of all messages queued to send');

	dc1.send(unicodeString);
	assert_equals(dc1.bufferedAmount,
	helloString.length + unicodeBuffer.byteLength,
	'Expect bufferedAmount to be the total length of all messages queued to send');

	dc1.send(helloBlob);
	assert_equals(dc1.bufferedAmount,
	helloString.length*2 + unicodeBuffer.byteLength,
	'Expect bufferedAmount to be the total length of all messages queued to send');

	await resolver;
	}, 'bufferedAmount should increase by byte length for each message sent');

	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1] = await createDataChannelPair(pc1, pc2);

	dc1.send(helloBuffer.buffer);
	assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
	'Expect bufferedAmount to increase to byte length of sent buffer');

	dc1.close();
	assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
	'Expect bufferedAmount to not decrease immediately after closing the channel');
	}, 'bufferedAmount should not decrease immediately after initiating closure');

	promise_test(async (t) => {
	const pc1 = new RTCPeerConnection();
	const pc2 = new RTCPeerConnection();
	t.add_cleanup(() => pc1.close());
	t.add_cleanup(() => pc2.close());

	const [dc1] = await createDataChannelPair(pc1, pc2);

	dc1.send(helloBuffer.buffer);
	assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
	'Expect bufferedAmount to increase to byte length of sent buffer');

	pc1.close();
	assert_equals(dc1.bufferedAmount, helloBuffer.byteLength,
	'Expect bufferedAmount to not decrease after closing the peer connection');
	}, 'bufferedAmount should not decrease after closing the peer connection');

	promise_test(async t => {
	const [channel1, channel2] = await createDataChannelPair();
	channel1.addEventListener('bufferedamountlow', t.step_func_done(() => {
	assert_true(channel1.bufferedAmount <= channel1.bufferedAmountLowThreshold);
	}));
	const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
	channel1.send(helloString);
	await eventWatcher.wait_for(['bufferedamountlow']);
	}, 'Data channel bufferedamountlow event fires after send() is complete');

	promise_test(async t => {
	const [channel1, channel2] = await createDataChannelPair();
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, helloString.length);
	await awaitMessage(channel2);
	assert_equals(channel1.bufferedAmount, 0);
	}, 'Data channel bufferedamount is data.length on send(data)');

	promise_test(async t => {
	const [channel1, channel2] = await createDataChannelPair();
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, helloString.length);
	assert_equals(channel1.bufferedAmount, helloString.length);
	}, 'Data channel bufferedamount returns the same amount if no more data is' +
	' sent on the channel');

	promise_test(async t => {
	const [channel1, channel2] = await createDataChannelPair();
	let eventFireCount = 0;
	channel1.addEventListener('bufferedamountlow', t.step_func(() => {
	assert_true(channel1.bufferedAmount <= channel1.bufferedAmountLowThreshold);
	assert_equals(++eventFireCount, 1);
	}));
	const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, helloString.length);
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, 2 * helloString.length);
	await eventWatcher.wait_for(['bufferedamountlow']);
	}, 'Data channel bufferedamountlow event fires only once after multiple' +
	' consecutive send() calls');

	promise_test(async t => {
	const [channel1, channel2] = await createDataChannelPair();
	const eventWatcher = new EventWatcher(t, channel1, ['bufferedamountlow']);
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, helloString.length);
	await eventWatcher.wait_for(['bufferedamountlow']);
	assert_equals(await awaitMessage(channel2), helloString);
	channel1.send(helloString);
	assert_equals(channel1.bufferedAmount, helloString.length);
	await eventWatcher.wait_for(['bufferedamountlow']);
	assert_equals(await awaitMessage(channel2), helloString);
	}, 'Data channel bufferedamountlow event fires after each sent message');

	</script>