fune/toolkit/modules/tests/xpcshell/test_DeferredTask.js

/* Any copyright is dedicated to the Public Domain.
   http://creativecommons.org/publicdomain/zero/1.0/ */

/**
 * This file tests the DeferredTask.jsm module.
 */

// Globals

ChromeUtils.defineModuleGetter(
  this,
  "DeferredTask",
  "resource://gre/modules/DeferredTask.jsm"
);

/**
 * Due to the nature of this module, most of the tests are time-dependent.  All
 * the timeouts are designed to occur at multiples of this granularity value,
 * in milliseconds, that should be high enough to prevent intermittent failures,
 * but low enough to prevent an excessive overall test execution time.
 */
const T = 100;

const originalIdleDispatch = DeferredTask.prototype._startIdleDispatch;
function replaceIdleDispatch(handleIdleDispatch) {
  DeferredTask.prototype._startIdleDispatch = function(callback, timeout) {
    handleIdleDispatch(callback, timeout);
  };
}
function restoreIdleDispatch() {
  DeferredTask.prototype.idleDispatch = originalIdleDispatch;
}

/**
 * Waits for the specified timeout before resolving the returned promise.
 */
function promiseTimeout(aTimeoutMs) {
  return new Promise(resolve => {
    do_timeout(aTimeoutMs, resolve);
  });
}

// Tests

/**
 * Creates a simple DeferredTask and executes it once.
 */
add_test(function test_arm_simple() {
  new DeferredTask(run_next_test, 10).arm();
});

/**
 * Checks that the delay set for the task is respected.
 */
add_test(function test_arm_delay_respected() {
  let executed1 = false;
  let executed2 = false;

  new DeferredTask(function() {
    executed1 = true;
    Assert.ok(!executed2);
  }, 1 * T).arm();

  new DeferredTask(function() {
    executed2 = true;
    Assert.ok(executed1);
    run_next_test();
  }, 2 * T).arm();
});

/**
 * Checks that calling "arm" again does not introduce further delay.
 */
add_test(function test_arm_delay_notrestarted() {
  let executed = false;

  // Create a task that will run later.
  let deferredTask = new DeferredTask(() => {
    executed = true;
  }, 4 * T);
  deferredTask.arm();

  // Before the task starts, call "arm" again.
  do_timeout(2 * T, () => deferredTask.arm());

  // The "arm" call should not have introduced further delays.
  do_timeout(5 * T, function() {
    Assert.ok(executed);
    run_next_test();
  });
});

/**
 * Checks that a task runs only once when armed multiple times synchronously.
 */
add_test(function test_arm_coalesced() {
  let executed = false;

  let deferredTask = new DeferredTask(function() {
    Assert.ok(!executed);
    executed = true;
    run_next_test();
  }, 50);

  deferredTask.arm();
  deferredTask.arm();
});

/**
 * Checks that a task runs only once when armed multiple times synchronously,
 * even when it has been created with a delay of zero milliseconds.
 */
add_test(function test_arm_coalesced_nodelay() {
  let executed = false;

  let deferredTask = new DeferredTask(function() {
    Assert.ok(!executed);
    executed = true;
    run_next_test();
  }, 0);

  deferredTask.arm();
  deferredTask.arm();
});

/**
 * Checks that a task can be armed again while running.
 */
add_test(function test_arm_recursive() {
  let executed = false;

  let deferredTask = new DeferredTask(function() {
    if (!executed) {
      executed = true;
      deferredTask.arm();
    } else {
      run_next_test();
    }
  }, 50);

  deferredTask.arm();
});

/**
 * Checks that calling "arm" while an asynchronous task is running waits until
 * the task is finished before restarting the delay.
 */
add_test(function test_arm_async() {
  let finishedExecution = false;
  let finishedExecutionAgain = false;

  // Create a task that will run later.
  let deferredTask = new DeferredTask(async function() {
    await promiseTimeout(4 * T);
    if (!finishedExecution) {
      finishedExecution = true;
    } else if (!finishedExecutionAgain) {
      finishedExecutionAgain = true;
    }
  }, 2 * T);
  deferredTask.arm();

  // While the task is running, call "arm" again.  This will result in a wait
  // of 2*T until the task finishes, then another 2*T for the normal task delay
  // specified on construction.
  do_timeout(4 * T, function() {
    Assert.ok(deferredTask.isRunning);
    Assert.ok(!finishedExecution);
    deferredTask.arm();
  });

  // This will fail in case the task was started without waiting 2*T after it
  // has finished.
  do_timeout(7 * T, function() {
    Assert.ok(!deferredTask.isRunning);
    Assert.ok(finishedExecution);
  });

  // This is in the middle of the second execution.
  do_timeout(10 * T, function() {
    Assert.ok(deferredTask.isRunning);
    Assert.ok(!finishedExecutionAgain);
  });

  // Wait enough time to verify that the task was executed as expected.
  do_timeout(13 * T, function() {
    Assert.ok(!deferredTask.isRunning);
    Assert.ok(finishedExecutionAgain);
    run_next_test();
  });
});

/**
 * Checks that an armed task can be disarmed.
 */
add_test(function test_disarm() {
  // Create a task that will run later.
  let deferredTask = new DeferredTask(function() {
    do_throw("This task should not run.");
  }, 2 * T);
  deferredTask.arm();

  // Disable execution later, but before the task starts.
  do_timeout(1 * T, () => deferredTask.disarm());

  // Wait enough time to verify that the task did not run.
  do_timeout(3 * T, run_next_test);
});

/**
 * Checks that calling "disarm" allows the delay to be restarted.
 */
add_test(function test_disarm_delay_restarted() {
  let executed = false;

  let deferredTask = new DeferredTask(() => {
    executed = true;
  }, 4 * T);
  deferredTask.arm();

  do_timeout(2 * T, function() {
    deferredTask.disarm();
    deferredTask.arm();
  });

  do_timeout(5 * T, function() {
    Assert.ok(!executed);
  });

  do_timeout(7 * T, function() {
    Assert.ok(executed);
    run_next_test();
  });
});

/**
 * Checks that calling "disarm" while an asynchronous task is running does not
 * prevent the task to finish.
 */
add_test(function test_disarm_async() {
  let finishedExecution = false;

  let deferredTask = new DeferredTask(async function() {
    deferredTask.arm();
    await promiseTimeout(2 * T);
    finishedExecution = true;
  }, 1 * T);
  deferredTask.arm();

  do_timeout(2 * T, function() {
    Assert.ok(deferredTask.isRunning);
    Assert.ok(deferredTask.isArmed);
    Assert.ok(!finishedExecution);
    deferredTask.disarm();
  });

  do_timeout(4 * T, function() {
    Assert.ok(!deferredTask.isRunning);
    Assert.ok(!deferredTask.isArmed);
    Assert.ok(finishedExecution);
    run_next_test();
  });
});

/**
 * Checks that calling "arm" immediately followed by "disarm" while an
 * asynchronous task is running does not cause it to run again.
 */
add_test(function test_disarm_immediate_async() {
  let executed = false;

  let deferredTask = new DeferredTask(async function() {
    Assert.ok(!executed);
    executed = true;
    await promiseTimeout(2 * T);
  }, 1 * T);
  deferredTask.arm();

  do_timeout(2 * T, function() {
    Assert.ok(deferredTask.isRunning);
    Assert.ok(!deferredTask.isArmed);
    deferredTask.arm();
    deferredTask.disarm();
  });

  do_timeout(4 * T, function() {
    Assert.ok(executed);
    Assert.ok(!deferredTask.isRunning);
    Assert.ok(!deferredTask.isArmed);
    run_next_test();
  });
});

/**
 * Checks the isArmed and isRunning properties with a synchronous task.
 */
add_test(function test_isArmed_isRunning() {
  let deferredTask = new DeferredTask(function() {
    Assert.ok(deferredTask.isRunning);
    Assert.ok(!deferredTask.isArmed);
    deferredTask.arm();
    Assert.ok(deferredTask.isArmed);
    deferredTask.disarm();
    Assert.ok(!deferredTask.isArmed);
    run_next_test();
  }, 50);

  Assert.ok(!deferredTask.isArmed);
  deferredTask.arm();
  Assert.ok(deferredTask.isArmed);
  Assert.ok(!deferredTask.isRunning);
});

/**
 * Checks that task execution is delayed when the idle task has no deadline.
 */
add_test(function test_idle_without_deadline() {
  let idleStarted = false;
  let executed = false;

  // When idleDispatch is not passed a deadline/timeout, let it take a while.
  replaceIdleDispatch((callback, timeout) => {
    Assert.ok(!idleStarted);
    idleStarted = true;
    do_timeout(timeout || 2 * T, callback);
  });

  let deferredTask = new DeferredTask(function() {
    Assert.ok(!executed);
    executed = true;
  }, 1 * T);
  deferredTask.arm();

  do_timeout(2 * T, () => {
    Assert.ok(idleStarted);
    Assert.ok(!executed);
  });

  do_timeout(4 * T, () => {
    Assert.ok(executed);
    restoreIdleDispatch();
    run_next_test();
  });
});

/**
 * Checks that the third parameter can be used to enforce an execution deadline.
 */
add_test(function test_idle_deadline() {
  let idleStarted = false;
  let executed = false;

  // Let idleDispatch wait until the deadline.
  replaceIdleDispatch((callback, timeout) => {
    Assert.ok(!idleStarted);
    idleStarted = true;
    do_timeout(timeout || 0, callback);
  });

  let deferredTask = new DeferredTask(
    function() {
      Assert.ok(!executed);
      executed = true;
    },
    1 * T,
    2 * T
  );
  deferredTask.arm();

  // idleDispatch is expected to be called after 1 * T,
  // the task is expected to be executed after 1 * T + 2 * T.
  do_timeout(2 * T, () => {
    Assert.ok(idleStarted);
    Assert.ok(!executed);
  });

  do_timeout(4 * T, () => {
    Assert.ok(executed);
    restoreIdleDispatch();
    run_next_test();
  });
});

/**
 * Checks that the "finalize" method executes a synchronous task.
 */
add_test(function test_finalize() {
  let executed = false;
  let timePassed = false;
  let idleStarted = false;
  let finalized = false;

  // Let idleDispatch take longer.
  replaceIdleDispatch((callback, timeout) => {
    Assert.ok(!idleStarted);
    idleStarted = true;
    do_timeout(T, callback);
  });

  let deferredTask = new DeferredTask(function() {
    Assert.ok(!timePassed);
    executed = true;
  }, 2 * T);
  deferredTask.arm();

  do_timeout(1 * T, () => {
    timePassed = true;
    Assert.ok(finalized);
    Assert.ok(!idleStarted);
  });

  // This should trigger the immediate execution of the task.
  deferredTask.finalize().then(function() {
    finalized = true;
    Assert.ok(executed);
  });

  // idleDispatch was originally supposed to start at 2 * T,
  // so if the task did not run at T * 3, then the finalization was successful.
  do_timeout(3 * T, () => {
    // Because the timer was canceled, the idle task shouldn't even start.
    Assert.ok(!idleStarted);
    restoreIdleDispatch();
    run_next_test();
  });
});

/**
 * Checks that the "finalize" method executes the task again from start to
 * finish in case it is already running.
 */
add_test(function test_finalize_executes_entirely() {
  let executed = false;
  let executedAgain = false;
  let timePassed = false;

  let deferredTask = new DeferredTask(async function() {
    // The first time, we arm the timer again and set up the finalization.
    if (!executed) {
      deferredTask.arm();
      Assert.ok(deferredTask.isArmed);
      Assert.ok(deferredTask.isRunning);

      deferredTask.finalize().then(function() {
        // When we reach this point, the task must be finished.
        Assert.ok(executedAgain);
        Assert.ok(!timePassed);
        Assert.ok(!deferredTask.isArmed);
        Assert.ok(!deferredTask.isRunning);
        run_next_test();
      });

      // The second execution triggered by the finalization waits 1*T for the
      // current task to finish (see the timeout below), but then it must not
      // wait for the 2*T specified on construction as normal task delay.  The
      // second execution will finish after the timeout below has passed again,
      // for a total of 2*T of wait time.
      do_timeout(3 * T, () => {
        timePassed = true;
      });
    }

    await promiseTimeout(1 * T);

    // Just before finishing, indicate if we completed the second execution.
    if (executed) {
      Assert.ok(deferredTask.isRunning);
      executedAgain = true;
    } else {
      executed = true;
    }
  }, 2 * T);

  deferredTask.arm();
});