interleaved-cursors-common.js

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// Infrastructure shared by interleaved-cursors-{small,large}.html

// Number of objects that each iterator goes over.

const itemCount = 10;

// Ratio of small objects to large objects.

const largeObjectRatio = 5;

// Size of large objects. This should exceed the size of a block in the storage

// method underlying the browser's IndexedDB implementation. For example, this

// needs to exceed the LevelDB block size on Chrome, and the SQLite block size

// on Firefox.

const largeObjectSize = 48 * 1024;

function objectKey(cursorIndex, itemIndex) {

  return `${cursorIndex}-key-${itemIndex}`;

function objectValue(cursorIndex, itemIndex) {

  if ((cursorIndex * itemCount + itemIndex) % largeObjectRatio === 0) {

    // We use a typed array (as opposed to a string) because IndexedDB

    // implementations may serialize strings using UTF-8 or UTF-16, yielding

    // larger IndexedDB entries than we'd expect. It's very unlikely that an

    // IndexedDB implementation would use anything other than the raw buffer to

    // serialize a typed array.

    const buffer = new Uint8Array(largeObjectSize);

    // Some IndexedDB implementations, like LevelDB, compress their data blocks

    // before storing them to disk. We use a simple 32-bit xorshift PRNG, which

    // should be sufficient to foil any fast generic-purpose compression scheme.

    // 32-bit xorshift - the seed can't be zero

    let state = 1000 + (cursorIndex * itemCount + itemIndex);

    for (let i = 0; i < largeObjectSize; ++i) {

      state ^= state << 13;

      state ^= state >> 17;

      state ^= state << 5;

      buffer[i] = state & 0xff;

    return buffer;

  return [cursorIndex, 'small', itemIndex];

// Writes the objects to be read by one cursor. Returns a promise that resolves

// when the write completes.

//

// We want to avoid creating a large transaction, because that is outside the

// test's scope, and it's a bad practice. So we break up the writes across

// multiple transactions. For simplicity, each transaction writes all the

// objects that will be read by a cursor.

function writeCursorObjects(database, cursorIndex) {

  return new Promise((resolve, reject) => {

    const transaction = database.transaction('cache', 'readwrite', {durability: 'relaxed'});

    transaction.onabort = () => { reject(transaction.error); };

    const store = transaction.objectStore('cache');

    for (let i = 0; i < itemCount; ++i) {

      store.put({

          key: objectKey(cursorIndex, i), value: objectValue(cursorIndex, i)});

    transaction.oncomplete = resolve;

});

// Returns a promise that resolves when the store has been populated.

function populateTestStore(testCase, database, cursorCount) {

  let promiseChain = Promise.resolve();

  for (let i = 0; i < cursorCount; ++i)

    promiseChain = promiseChain.then(() => writeCursorObjects(database, i));

  return promiseChain;

// Reads cursors in an interleaved fashion, as shown below.

//

// Given N cursors, each of which points to the beginning of a K-item sequence,

// the following accesses will be made.

//

// OC(i)    = open cursor i

// RD(i, j) = read result of cursor i, which should be at item j

// CC(i)    = continue cursor i

// |        = wait for onsuccess on the previous OC or CC

//

// OC(1)            | RD(1, 1) OC(2) | RD(2, 1) OC(3) | ... | RD(n-1, 1) CC(n) |

// RD(n, 1)   CC(1) | RD(1, 2) CC(2) | RD(2, 2) CC(3) | ... | RD(n-1, 2) CC(n) |

// RD(n, 2)   CC(1) | RD(1, 3) CC(2) | RD(2, 3) CC(3) | ... | RD(n-1, 3) CC(n) |

// ...

// RD(n, k-1) CC(1) | RD(1, k) CC(2) | RD(2, k) CC(3) | ... | RD(n-1, k) CC(n) |

// RD(n, k)           done

function interleaveCursors(testCase, store, cursorCount) {

  return new Promise((resolve, reject) => {

    // The cursors used for iteration are stored here so each cursor's onsuccess

    // handler can call continue() on the next cursor.

    const cursors = [];

    // The results of IDBObjectStore.openCursor() calls are stored here so we

    // we can change the requests' onsuccess handler after every

    // IDBCursor.continue() call.

    const requests = [];

    const checkCursorState = (cursorIndex, itemIndex) => {

      const cursor = cursors[cursorIndex];

      assert_equals(cursor.key, objectKey(cursorIndex, itemIndex));

      assert_equals(cursor.value.key, objectKey(cursorIndex, itemIndex));

      assert_equals(

          cursor.value.value.join('-'),

          objectValue(cursorIndex, itemIndex).join('-'));

};

    const openCursor = (cursorIndex, callback) => {

      const request = store.openCursor(

          IDBKeyRange.lowerBound(objectKey(cursorIndex, 0)));

      requests[cursorIndex] = request;

      request.onsuccess = testCase.step_func(() => {

        const cursor = request.result;

        cursors[cursorIndex] = cursor;

        checkCursorState(cursorIndex, 0);

        callback();

});

      request.onerror = event => reject(request.error);

};

    const readItemFromCursor = (cursorIndex, itemIndex, callback) => {

      const request = requests[cursorIndex];

      request.onsuccess = testCase.step_func(() => {

        const cursor = request.result;

        cursors[cursorIndex] = cursor;

        checkCursorState(cursorIndex, itemIndex);

        callback();

});

      const cursor = cursors[cursorIndex];

      cursor.continue();

};

    // We open all the cursors one at a time, then cycle through the cursors and

    // call continue() on each of them. This access pattern causes maximal

    // trashing to an LRU cursor cache. Eviction scheme aside, any cache will

    // have to evict some cursors, and this access pattern verifies that the

    // cache correctly restores the state of evicted cursors.

    const steps = [];

    for (let cursorIndex = 0; cursorIndex < cursorCount; ++cursorIndex)

      steps.push(openCursor.bind(null, cursorIndex));

    for (let itemIndex = 1; itemIndex < itemCount; ++itemIndex) {

      for (let cursorIndex = 0; cursorIndex < cursorCount; ++cursorIndex)

        steps.push(readItemFromCursor.bind(null, cursorIndex, itemIndex));

    const runStep = (stepIndex) => {

      if (stepIndex === steps.length) {

        resolve();

        return;

      steps[stepIndex](() => { runStep(stepIndex + 1); });

};

    runStep(0);

});

function cursorTest(cursorCount) {

  promise_test(testCase => {

    return createDatabase(testCase, (database, transaction) => {

      const store = database.createObjectStore('cache',

          { keyPath: 'key', autoIncrement: true });

    }).then(database => {

      return populateTestStore(testCase, database, cursorCount).then(

          () => database);

    }).then(database => {

      database.close();

    }).then(() => {

      return openDatabase(testCase);

    }).then(database => {

      const transaction = database.transaction('cache', 'readonly', {durability: 'relaxed'});

      transaction.onabort = () => { reject(transaction.error); };

      const store = transaction.objectStore('cache');

      return interleaveCursors(testCase, store, cursorCount).then(

          () => database);

    }).then(database => {

      database.close();

});

  }, `${cursorCount} cursors`);