/** @license React v0.20.1
 * scheduler.development.js
 *
 * Copyright (c) Facebook, Inc. and its affiliates.
 *
 * This source code is licensed under the MIT license found in the
 * LICENSE file in the root directory of this source tree.
 */

'use strict';

if (process.env.NODE_ENV !== "production") {
  (function() {
'use strict';

var enableSchedulerDebugging = false;
var enableProfiling = true;

var requestHostCallback;
var requestHostTimeout;
var cancelHostTimeout;
var requestPaint;
var hasPerformanceNow = typeof performance === 'object' && typeof performance.now === 'function';

if (hasPerformanceNow) {
  var localPerformance = performance;

  exports.unstable_now = function () {
    return localPerformance.now();
  };
} else {
  var localDate = Date;
  var initialTime = localDate.now();

  exports.unstable_now = function () {
    return localDate.now() - initialTime;
  };
}

if ( // If Scheduler runs in a non-DOM environment, it falls back to a naive
// implementation using setTimeout.
typeof window === 'undefined' || // Check if MessageChannel is supported, too.
typeof MessageChannel !== 'function') {
  // If this accidentally gets imported in a non-browser environment, e.g. JavaScriptCore,
  // fallback to a naive implementation.
  var _callback = null;
  var _timeoutID = null;

  var _flushCallback = function () {
    if (_callback !== null) {
      try {
        var currentTime = exports.unstable_now();
        var hasRemainingTime = true;

        _callback(hasRemainingTime, currentTime);

        _callback = null;
      } catch (e) {
        setTimeout(_flushCallback, 0);
        throw e;
      }
    }
  };

  requestHostCallback = function (cb) {
    if (_callback !== null) {
      // Protect against re-entrancy.
      setTimeout(requestHostCallback, 0, cb);
    } else {
      _callback = cb;
      setTimeout(_flushCallback, 0);
    }
  };

  requestHostTimeout = function (cb, ms) {
    _timeoutID = setTimeout(cb, ms);
  };

  cancelHostTimeout = function () {
    clearTimeout(_timeoutID);
  };

  exports.unstable_shouldYield = function () {
    return false;
  };

  requestPaint = exports.unstable_forceFrameRate = function () {};
} else {
  // Capture local references to native APIs, in case a polyfill overrides them.
  var _setTimeout = window.setTimeout;
  var _clearTimeout = window.clearTimeout;

  if (typeof console !== 'undefined') {
    // TODO: Scheduler no longer requires these methods to be polyfilled. But
    // maybe we want to continue warning if they don't exist, to preserve the
    // option to rely on it in the future?
    var requestAnimationFrame = window.requestAnimationFrame;
    var cancelAnimationFrame = window.cancelAnimationFrame;

    if (typeof requestAnimationFrame !== 'function') {
      // Using console['error'] to evade Babel and ESLint
      console['error']("This browser doesn't support requestAnimationFrame. " + 'Make sure that you load a ' + 'polyfill in older browsers. https://reactjs.org/link/react-polyfills');
    }

    if (typeof cancelAnimationFrame !== 'function') {
      // Using console['error'] to evade Babel and ESLint
      console['error']("This browser doesn't support cancelAnimationFrame. " + 'Make sure that you load a ' + 'polyfill in older browsers. https://reactjs.org/link/react-polyfills');
    }
  }

  var isMessageLoopRunning = false;
  var scheduledHostCallback = null;
  var taskTimeoutID = -1; // Scheduler periodically yields in case there is other work on the main
  // thread, like user events. By default, it yields multiple times per frame.
  // It does not attempt to align with frame boundaries, since most tasks don't
  // need to be frame aligned; for those that do, use requestAnimationFrame.

  var yieldInterval = 5;
  var deadline = 0; // TODO: Make this configurable

  {
    // `isInputPending` is not available. Since we have no way of knowing if
    // there's pending input, always yield at the end of the frame.
    exports.unstable_shouldYield = function () {
      return exports.unstable_now() >= deadline;
    }; // Since we yield every frame regardless, `requestPaint` has no effect.


    requestPaint = function () {};
  }

  exports.unstable_forceFrameRate = function (fps) {
    if (fps < 0 || fps > 125) {
      // Using console['error'] to evade Babel and ESLint
      console['error']('forceFrameRate takes a positive int between 0 and 125, ' + 'forcing frame rates higher than 125 fps is not supported');
      return;
    }

    if (fps > 0) {
      yieldInterval = Math.floor(1000 / fps);
    } else {
      // reset the framerate
      yieldInterval = 5;
    }
  };

  var performWorkUntilDeadline = function () {
    if (scheduledHostCallback !== null) {
      var currentTime = exports.unstable_now(); // Yield after `yieldInterval` ms, regardless of where we are in the vsync
      // cycle. This means there's always time remaining at the beginning of
      // the message event.

      deadline = currentTime + yieldInterval;
      var hasTimeRemaining = true;

      try {
        var hasMoreWork = scheduledHostCallback(hasTimeRemaining, currentTime);

        if (!hasMoreWork) {
          isMessageLoopRunning = false;
          scheduledHostCallback = null;
        } else {
          // If there's more work, schedule the next message event at the end
          // of the preceding one.
          port.postMessage(null);
        }
      } catch (error) {
        // If a scheduler task throws, exit the current browser task so the
        // error can be observed.
        port.postMessage(null);
        throw error;
      }
    } else {
      isMessageLoopRunning = false;
    } // Yielding to the browser will give it a chance to paint, so we can
  };

  var channel = new MessageChannel();
  var port = channel.port2;
  channel.port1.onmessage = performWorkUntilDeadline;

  requestHostCallback = function (callback) {
    scheduledHostCallback = callback;

    if (!isMessageLoopRunning) {
      isMessageLoopRunning = true;
      port.postMessage(null);
    }
  };

  requestHostTimeout = function (callback, ms) {
    taskTimeoutID = _setTimeout(function () {
      callback(exports.unstable_now());
    }, ms);
  };

  cancelHostTimeout = function () {
    _clearTimeout(taskTimeoutID);

    taskTimeoutID = -1;
  };
}

function push(heap, node) {
  var index = heap.length;
  heap.push(node);
  siftUp(heap, node, index);
}
function peek(heap) {
  var first = heap[0];
  return first === undefined ? null : first;
}
function pop(heap) {
  var first = heap[0];

  if (first !== undefined) {
    var last = heap.pop();

    if (last !== first) {
      heap[0] = last;
      siftDown(heap, last, 0);
    }

    return first;
  } else {
    return null;
  }
}

function siftUp(heap, node, i) {
  var index = i;

  while (true) {
    var parentIndex = index - 1 >>> 1;
    var parent = heap[parentIndex];

    if (parent !== undefined && compare(parent, node) > 0) {
      // The parent is larger. Swap positions.
      heap[parentIndex] = node;
      heap[index] = parent;
      index = parentIndex;
    } else {
      // The parent is smaller. Exit.
      return;
    }
  }
}

function siftDown(heap, node, i) {
  var index = i;
  var length = heap.length;

  while (index < length) {
    var leftIndex = (index + 1) * 2 - 1;
    var left = heap[leftIndex];
    var rightIndex = leftIndex + 1;
    var right = heap[rightIndex]; // If the left or right node is smaller, swap with the smaller of those.

    if (left !== undefined && compare(left, node) < 0) {
      if (right !== undefined && compare(right, left) < 0) {
        heap[index] = right;
        heap[rightIndex] = node;
        index = rightIndex;
      } else {
        heap[index] = left;
        heap[leftIndex] = node;
        index = leftIndex;
      }
    } else if (right !== undefined && compare(right, node) < 0) {
      heap[index] = right;
      heap[rightIndex] = node;
      index = rightIndex;
    } else {
      // Neither child is smaller. Exit.
      return;
    }
  }
}

function compare(a, b) {
  // Compare sort index first, then task id.
  var diff = a.sortIndex - b.sortIndex;
  return diff !== 0 ? diff : a.id - b.id;
}

// TODO: Use symbols?
var NoPriority = 0;
var ImmediatePriority = 1;
var UserBlockingPriority = 2;
var NormalPriority = 3;
var LowPriority = 4;
var IdlePriority = 5;

var runIdCounter = 0;
var mainThreadIdCounter = 0;
var profilingStateSize = 4;
var sharedProfilingBuffer =  // $FlowFixMe Flow doesn't know about SharedArrayBuffer
typeof SharedArrayBuffer === 'function' ? new SharedArrayBuffer(profilingStateSize * Int32Array.BYTES_PER_ELEMENT) : // $FlowFixMe Flow doesn't know about ArrayBuffer
typeof ArrayBuffer === 'function' ? new ArrayBuffer(profilingStateSize * Int32Array.BYTES_PER_ELEMENT) : null // Don't crash the init path on IE9
;
var profilingState =  sharedProfilingBuffer !== null ? new Int32Array(sharedProfilingBuffer) : []; // We can't read this but it helps save bytes for null checks

var PRIORITY = 0;
var CURRENT_TASK_ID = 1;
var CURRENT_RUN_ID = 2;
var QUEUE_SIZE = 3;

{
  profilingState[PRIORITY] = NoPriority; // This is maintained with a counter, because the size of the priority queue
  // array might include canceled tasks.

  profilingState[QUEUE_SIZE] = 0;
  profilingState[CURRENT_TASK_ID] = 0;
} // Bytes per element is 4


var INITIAL_EVENT_LOG_SIZE = 131072;
var MAX_EVENT_LOG_SIZE = 524288; // Equivalent to 2 megabytes

var eventLogSize = 0;
var eventLogBuffer = null;
var eventLog = null;
var eventLogIndex = 0;
var TaskStartEvent = 1;
var TaskCompleteEvent = 2;
var TaskErrorEvent = 3;
var TaskCancelEvent = 4;
var TaskRunEvent = 5;
var TaskYieldEvent = 6;
var SchedulerSuspendEvent = 7;
var SchedulerResumeEvent = 8;

function logEvent(entries) {
  if (eventLog !== null) {
    var offset = eventLogIndex;
    eventLogIndex += entries.length;

    if (eventLogIndex + 1 > eventLogSize) {
      eventLogSize *= 2;

      if (eventLogSize > MAX_EVENT_LOG_SIZE) {
        // Using console['error'] to evade Babel and ESLint
        console['error']("Scheduler Profiling: Event log exceeded maximum size. Don't " + 'forget to call `stopLoggingProfilingEvents()`.');
        stopLoggingProfilingEvents();
        return;
      }

      var newEventLog = new Int32Array(eventLogSize * 4);
      newEventLog.set(eventLog);
      eventLogBuffer = newEventLog.buffer;
      eventLog = newEventLog;
    }

    eventLog.set(entries, offset);
  }
}

function startLoggingProfilingEvents() {
  eventLogSize = INITIAL_EVENT_LOG_SIZE;
  eventLogBuffer = new ArrayBuffer(eventLogSize * 4);
  eventLog = new Int32Array(eventLogBuffer);
  eventLogIndex = 0;
}
function stopLoggingProfilingEvents() {
  var buffer = eventLogBuffer;
  eventLogSize = 0;
  eventLogBuffer = null;
  eventLog = null;
  eventLogIndex = 0;
  return buffer;
}
function markTaskStart(task, ms) {
  {
    profilingState[QUEUE_SIZE]++;

    if (eventLog !== null) {
      // performance.now returns a float, representing milliseconds. When the
      // event is logged, it's coerced to an int. Convert to microseconds to
      // maintain extra degrees of precision.
      logEvent([TaskStartEvent, ms * 1000, task.id, task.priorityLevel]);
    }
  }
}
function markTaskCompleted(task, ms) {
  {
    profilingState[PRIORITY] = NoPriority;
    profilingState[CURRENT_TASK_ID] = 0;
    profilingState[QUEUE_SIZE]--;

    if (eventLog !== null) {
      logEvent([TaskCompleteEvent, ms * 1000, task.id]);
    }
  }
}
function markTaskCanceled(task, ms) {
  {
    profilingState[QUEUE_SIZE]--;

    if (eventLog !== null) {
      logEvent([TaskCancelEvent, ms * 1000, task.id]);
    }
  }
}
function markTaskErrored(task, ms) {
  {
    profilingState[PRIORITY] = NoPriority;
    profilingState[CURRENT_TASK_ID] = 0;
    profilingState[QUEUE_SIZE]--;

    if (eventLog !== null) {
      logEvent([TaskErrorEvent, ms * 1000, task.id]);
    }
  }
}
function markTaskRun(task, ms) {
  {
    runIdCounter++;
    profilingState[PRIORITY] = task.priorityLevel;
    profilingState[CURRENT_TASK_ID] = task.id;
    profilingState[CURRENT_RUN_ID] = runIdCounter;

    if (eventLog !== null) {
      logEvent([TaskRunEvent, ms * 1000, task.id, runIdCounter]);
    }
  }
}
function markTaskYield(task, ms) {
  {
    profilingState[PRIORITY] = NoPriority;
    profilingState[CURRENT_TASK_ID] = 0;
    profilingState[CURRENT_RUN_ID] = 0;

    if (eventLog !== null) {
      logEvent([TaskYieldEvent, ms * 1000, task.id, runIdCounter]);
    }
  }
}
function markSchedulerSuspended(ms) {
  {
    mainThreadIdCounter++;

    if (eventLog !== null) {
      logEvent([SchedulerSuspendEvent, ms * 1000, mainThreadIdCounter]);
    }
  }
}
function markSchedulerUnsuspended(ms) {
  {
    if (eventLog !== null) {
      logEvent([SchedulerResumeEvent, ms * 1000, mainThreadIdCounter]);
    }
  }
}

/* eslint-disable no-var */
// Math.pow(2, 30) - 1
// 0b111111111111111111111111111111

var maxSigned31BitInt = 1073741823; // Times out immediately

var IMMEDIATE_PRIORITY_TIMEOUT = -1; // Eventually times out

var USER_BLOCKING_PRIORITY_TIMEOUT = 250;
var NORMAL_PRIORITY_TIMEOUT = 5000;
var LOW_PRIORITY_TIMEOUT = 10000; // Never times out

var IDLE_PRIORITY_TIMEOUT = maxSigned31BitInt; // Tasks are stored on a min heap

var taskQueue = [];
var timerQueue = []; // Incrementing id counter. Used to maintain insertion order.

var taskIdCounter = 1; // Pausing the scheduler is useful for debugging.
var currentTask = null;
var currentPriorityLevel = NormalPriority; // This is set while performing work, to prevent re-entrancy.

var isPerformingWork = false;
var isHostCallbackScheduled = false;
var isHostTimeoutScheduled = false;

function advanceTimers(currentTime) {
  // Check for tasks that are no longer delayed and add them to the queue.
  var timer = peek(timerQueue);

  while (timer !== null) {
    if (timer.callback === null) {
      // Timer was cancelled.
      pop(timerQueue);
    } else if (timer.startTime <= currentTime) {
      // Timer fired. Transfer to the task queue.
      pop(timerQueue);
      timer.sortIndex = timer.expirationTime;
      push(taskQueue, timer);

      {
        markTaskStart(timer, currentTime);
        timer.isQueued = true;
      }
    } else {
      // Remaining timers are pending.
      return;
    }

    timer = peek(timerQueue);
  }
}

function handleTimeout(currentTime) {
  isHostTimeoutScheduled = false;
  advanceTimers(currentTime);

  if (!isHostCallbackScheduled) {
    if (peek(taskQueue) !== null) {
      isHostCallbackScheduled = true;
      requestHostCallback(flushWork);
    } else {
      var firstTimer = peek(timerQueue);

      if (firstTimer !== null) {
        requestHostTimeout(handleTimeout, firstTimer.startTime - currentTime);
      }
    }
  }
}

function flushWork(hasTimeRemaining, initialTime) {
  {
    markSchedulerUnsuspended(initialTime);
  } // We'll need a host callback the next time work is scheduled.


  isHostCallbackScheduled = false;

  if (isHostTimeoutScheduled) {
    // We scheduled a timeout but it's no longer needed. Cancel it.
    isHostTimeoutScheduled = false;
    cancelHostTimeout();
  }

  isPerformingWork = true;
  var previousPriorityLevel = currentPriorityLevel;

  try {
    if (enableProfiling) {
      try {
        return workLoop(hasTimeRemaining, initialTime);
      } catch (error) {
        if (currentTask !== null) {
          var currentTime = exports.unstable_now();
          markTaskErrored(currentTask, currentTime);
          currentTask.isQueued = false;
        }

        throw error;
      }
    } else {
      // No catch in prod code path.
      return workLoop(hasTimeRemaining, initialTime);
    }
  } finally {
    currentTask = null;
    currentPriorityLevel = previousPriorityLevel;
    isPerformingWork = false;

    {
      var _currentTime = exports.unstable_now();

      markSchedulerSuspended(_currentTime);
    }
  }
}

function workLoop(hasTimeRemaining, initialTime) {
  var currentTime = initialTime;
  advanceTimers(currentTime);
  currentTask = peek(taskQueue);

  while (currentTask !== null && !(enableSchedulerDebugging )) {
    if (currentTask.expirationTime > currentTime && (!hasTimeRemaining || exports.unstable_shouldYield())) {
      // This currentTask hasn't expired, and we've reached the deadline.
      break;
    }

    var callback = currentTask.callback;

    if (typeof callback === 'function') {
      currentTask.callback = null;
      currentPriorityLevel = currentTask.priorityLevel;
      var didUserCallbackTimeout = currentTask.expirationTime <= currentTime;
      markTaskRun(currentTask, currentTime);
      var continuationCallback = callback(didUserCallbackTimeout);
      currentTime = exports.unstable_now();

      if (typeof continuationCallback === 'function') {
        currentTask.callback = continuationCallback;
        markTaskYield(currentTask, currentTime);
      } else {
        {
          markTaskCompleted(currentTask, currentTime);
          currentTask.isQueued = false;
        }

        if (currentTask === peek(taskQueue)) {
          pop(taskQueue);
        }
      }

      advanceTimers(currentTime);
    } else {
      pop(taskQueue);
    }

    currentTask = peek(taskQueue);
  } // Return whether there's additional work


  if (currentTask !== null) {
    return true;
  } else {
    var firstTimer = peek(timerQueue);

    if (firstTimer !== null) {
      requestHostTimeout(handleTimeout, firstTimer.startTime - currentTime);
    }

    return false;
  }
}

function unstable_runWithPriority(priorityLevel, eventHandler) {
  switch (priorityLevel) {
    case ImmediatePriority:
    case UserBlockingPriority:
    case NormalPriority:
    case LowPriority:
    case IdlePriority:
      break;

    default:
      priorityLevel = NormalPriority;
  }

  var previousPriorityLevel = currentPriorityLevel;
  currentPriorityLevel = priorityLevel;

  try {
    return eventHandler();
  } finally {
    currentPriorityLevel = previousPriorityLevel;
  }
}

function unstable_next(eventHandler) {
  var priorityLevel;

  switch (currentPriorityLevel) {
    case ImmediatePriority:
    case UserBlockingPriority:
    case NormalPriority:
      // Shift down to normal priority
      priorityLevel = NormalPriority;
      break;

    default:
      // Anything lower than normal priority should remain at the current level.
      priorityLevel = currentPriorityLevel;
      break;
  }

  var previousPriorityLevel = currentPriorityLevel;
  currentPriorityLevel = priorityLevel;

  try {
    return eventHandler();
  } finally {
    currentPriorityLevel = previousPriorityLevel;
  }
}

function unstable_wrapCallback(callback) {
  var parentPriorityLevel = currentPriorityLevel;
  return function () {
    // This is a fork of runWithPriority, inlined for performance.
    var previousPriorityLevel = currentPriorityLevel;
    currentPriorityLevel = parentPriorityLevel;

    try {
      return callback.apply(this, arguments);
    } finally {
      currentPriorityLevel = previousPriorityLevel;
    }
  };
}

function unstable_scheduleCallback(priorityLevel, callback, options) {
  var currentTime = exports.unstable_now();
  var startTime;

  if (typeof options === 'object' && options !== null) {
    var delay = options.delay;

    if (typeof delay === 'number' && delay > 0) {
      startTime = currentTime + delay;
    } else {
      startTime = currentTime;
    }
  } else {
    startTime = currentTime;
  }

  var timeout;

  switch (priorityLevel) {
    case ImmediatePriority:
      timeout = IMMEDIATE_PRIORITY_TIMEOUT;
      break;

    case UserBlockingPriority:
      timeout = USER_BLOCKING_PRIORITY_TIMEOUT;
      break;

    case IdlePriority:
      timeout = IDLE_PRIORITY_TIMEOUT;
      break;

    case LowPriority:
      timeout = LOW_PRIORITY_TIMEOUT;
      break;

    case NormalPriority:
    default:
      timeout = NORMAL_PRIORITY_TIMEOUT;
      break;
  }

  var expirationTime = startTime + timeout;
  var newTask = {
    id: taskIdCounter++,
    callback: callback,
    priorityLevel: priorityLevel,
    startTime: startTime,
    expirationTime: expirationTime,
    sortIndex: -1
  };

  {
    newTask.isQueued = false;
  }

  if (startTime > currentTime) {
    // This is a delayed task.
    newTask.sortIndex = startTime;
    push(timerQueue, newTask);

    if (peek(taskQueue) === null && newTask === peek(timerQueue)) {
      // All tasks are delayed, and this is the task with the earliest delay.
      if (isHostTimeoutScheduled) {
        // Cancel an existing timeout.
        cancelHostTimeout();
      } else {
        isHostTimeoutScheduled = true;
      } // Schedule a timeout.


      requestHostTimeout(handleTimeout, startTime - currentTime);
    }
  } else {
    newTask.sortIndex = expirationTime;
    push(taskQueue, newTask);

    {
      markTaskStart(newTask, currentTime);
      newTask.isQueued = true;
    } // Schedule a host callback, if needed. If we're already performing work,
    // wait until the next time we yield.


    if (!isHostCallbackScheduled && !isPerformingWork) {
      isHostCallbackScheduled = true;
      requestHostCallback(flushWork);
    }
  }

  return newTask;
}

function unstable_pauseExecution() {
}

function unstable_continueExecution() {

  if (!isHostCallbackScheduled && !isPerformingWork) {
    isHostCallbackScheduled = true;
    requestHostCallback(flushWork);
  }
}

function unstable_getFirstCallbackNode() {
  return peek(taskQueue);
}

function unstable_cancelCallback(task) {
  {
    if (task.isQueued) {
      var currentTime = exports.unstable_now();
      markTaskCanceled(task, currentTime);
      task.isQueued = false;
    }
  } // Null out the callback to indicate the task has been canceled. (Can't
  // remove from the queue because you can't remove arbitrary nodes from an
  // array based heap, only the first one.)


  task.callback = null;
}

function unstable_getCurrentPriorityLevel() {
  return currentPriorityLevel;
}

var unstable_requestPaint = requestPaint;
var unstable_Profiling =  {
  startLoggingProfilingEvents: startLoggingProfilingEvents,
  stopLoggingProfilingEvents: stopLoggingProfilingEvents,
  sharedProfilingBuffer: sharedProfilingBuffer
} ;

exports.unstable_IdlePriority = IdlePriority;
exports.unstable_ImmediatePriority = ImmediatePriority;
exports.unstable_LowPriority = LowPriority;
exports.unstable_NormalPriority = NormalPriority;
exports.unstable_Profiling = unstable_Profiling;
exports.unstable_UserBlockingPriority = UserBlockingPriority;
exports.unstable_cancelCallback = unstable_cancelCallback;
exports.unstable_continueExecution = unstable_continueExecution;
exports.unstable_getCurrentPriorityLevel = unstable_getCurrentPriorityLevel;
exports.unstable_getFirstCallbackNode = unstable_getFirstCallbackNode;
exports.unstable_next = unstable_next;
exports.unstable_pauseExecution = unstable_pauseExecution;
exports.unstable_requestPaint = unstable_requestPaint;
exports.unstable_runWithPriority = unstable_runWithPriority;
exports.unstable_scheduleCallback = unstable_scheduleCallback;
exports.unstable_wrapCallback = unstable_wrapCallback;
  })();
}