pdf.js/web/ui_utils.js

/* Copyright 2012 Mozilla Foundation
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *     http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

const CSS_UNITS = 96.0 / 72.0;
const DEFAULT_SCALE_VALUE = 'auto';
const DEFAULT_SCALE = 1.0;
const MIN_SCALE = 0.10;
const MAX_SCALE = 10.0;
const UNKNOWN_SCALE = 0;
const MAX_AUTO_SCALE = 1.25;
const SCROLLBAR_PADDING = 40;
const VERTICAL_PADDING = 5;

const PresentationModeState = {
  UNKNOWN: 0,
  NORMAL: 1,
  CHANGING: 2,
  FULLSCREEN: 3,
};

const RendererType = {
  CANVAS: 'canvas',
  SVG: 'svg',
};

const TextLayerMode = {
  DISABLE: 0,
  ENABLE: 1,
  ENABLE_ENHANCE: 2,
};

// Replaces {{arguments}} with their values.
function formatL10nValue(text, args) {
  if (!args) {
    return text;
  }
  return text.replace(/\{\{\s*(\w+)\s*\}\}/g, (all, name) => {
    return (name in args ? args[name] : '{{' + name + '}}');
  });
}

/**
 * No-op implementation of the localization service.
 * @implements {IL10n}
 */
let NullL10n = {
  getLanguage() {
    return Promise.resolve('en-us');
  },

  getDirection() {
    return Promise.resolve('ltr');
  },

  get(property, args, fallback) {
    return Promise.resolve(formatL10nValue(fallback, args));
  },

  translate(element) {
    return Promise.resolve();
  },
};

/**
 * Returns scale factor for the canvas. It makes sense for the HiDPI displays.
 * @return {Object} The object with horizontal (sx) and vertical (sy)
                    scales. The scaled property is set to false if scaling is
                    not required, true otherwise.
 */
function getOutputScale(ctx) {
  let devicePixelRatio = window.devicePixelRatio || 1;
  let backingStoreRatio = ctx.webkitBackingStorePixelRatio ||
                          ctx.mozBackingStorePixelRatio ||
                          ctx.msBackingStorePixelRatio ||
                          ctx.oBackingStorePixelRatio ||
                          ctx.backingStorePixelRatio || 1;
  let pixelRatio = devicePixelRatio / backingStoreRatio;
  return {
    sx: pixelRatio,
    sy: pixelRatio,
    scaled: pixelRatio !== 1,
  };
}

/**
 * Scrolls specified element into view of its parent.
 * @param {Object} element - The element to be visible.
 * @param {Object} spot - An object with optional top and left properties,
 *   specifying the offset from the top left edge.
 * @param {boolean} skipOverflowHiddenElements - Ignore elements that have
 *   the CSS rule `overflow: hidden;` set. The default is false.
 */
function scrollIntoView(element, spot, skipOverflowHiddenElements = false) {
  // Assuming offsetParent is available (it's not available when viewer is in
  // hidden iframe or object). We have to scroll: if the offsetParent is not set
  // producing the error. See also animationStarted.
  let parent = element.offsetParent;
  if (!parent) {
    console.error('offsetParent is not set -- cannot scroll');
    return;
  }
  let offsetY = element.offsetTop + element.clientTop;
  let offsetX = element.offsetLeft + element.clientLeft;
  while ((parent.clientHeight === parent.scrollHeight &&
          parent.clientWidth === parent.scrollWidth) ||
         (skipOverflowHiddenElements &&
          getComputedStyle(parent).overflow === 'hidden')) {
    if (parent.dataset._scaleY) {
      offsetY /= parent.dataset._scaleY;
      offsetX /= parent.dataset._scaleX;
    }
    offsetY += parent.offsetTop;
    offsetX += parent.offsetLeft;
    parent = parent.offsetParent;
    if (!parent) {
      return; // no need to scroll
    }
  }
  if (spot) {
    if (spot.top !== undefined) {
      offsetY += spot.top;
    }
    if (spot.left !== undefined) {
      offsetX += spot.left;
      parent.scrollLeft = offsetX;
    }
  }
  parent.scrollTop = offsetY;
}

/**
 * Helper function to start monitoring the scroll event and converting them into
 * PDF.js friendly one: with scroll debounce and scroll direction.
 */
function watchScroll(viewAreaElement, callback) {
  let debounceScroll = function(evt) {
    if (rAF) {
      return;
    }
    // schedule an invocation of scroll for next animation frame.
    rAF = window.requestAnimationFrame(function viewAreaElementScrolled() {
      rAF = null;

      let currentX = viewAreaElement.scrollLeft;
      let lastX = state.lastX;
      if (currentX !== lastX) {
        state.right = currentX > lastX;
      }
      state.lastX = currentX;
      let currentY = viewAreaElement.scrollTop;
      let lastY = state.lastY;
      if (currentY !== lastY) {
        state.down = currentY > lastY;
      }
      state.lastY = currentY;
      callback(state);
    });
  };

  let state = {
    right: true,
    down: true,
    lastX: viewAreaElement.scrollLeft,
    lastY: viewAreaElement.scrollTop,
    _eventHandler: debounceScroll,
  };

  let rAF = null;
  viewAreaElement.addEventListener('scroll', debounceScroll, true);
  return state;
}

/**
 * Helper function to parse query string (e.g. ?param1=value&parm2=...).
 */
function parseQueryString(query) {
  let parts = query.split('&');
  let params = Object.create(null);
  for (let i = 0, ii = parts.length; i < ii; ++i) {
    let param = parts[i].split('=');
    let key = param[0].toLowerCase();
    let value = param.length > 1 ? param[1] : null;
    params[decodeURIComponent(key)] = decodeURIComponent(value);
  }
  return params;
}

/**
 * Use binary search to find the index of the first item in a given array which
 * passes a given condition. The items are expected to be sorted in the sense
 * that if the condition is true for one item in the array, then it is also true
 * for all following items.
 *
 * @returns {Number} Index of the first array element to pass the test,
 *                   or |items.length| if no such element exists.
 */
function binarySearchFirstItem(items, condition) {
  let minIndex = 0;
  let maxIndex = items.length - 1;

  if (items.length === 0 || !condition(items[maxIndex])) {
    return items.length;
  }
  if (condition(items[minIndex])) {
    return minIndex;
  }

  while (minIndex < maxIndex) {
    let currentIndex = (minIndex + maxIndex) >> 1;
    let currentItem = items[currentIndex];
    if (condition(currentItem)) {
      maxIndex = currentIndex;
    } else {
      minIndex = currentIndex + 1;
    }
  }
  return minIndex; /* === maxIndex */
}

/**
 *  Approximates float number as a fraction using Farey sequence (max order
 *  of 8).
 *  @param {number} x - Positive float number.
 *  @returns {Array} Estimated fraction: the first array item is a numerator,
 *                   the second one is a denominator.
 */
function approximateFraction(x) {
  // Fast paths for int numbers or their inversions.
  if (Math.floor(x) === x) {
    return [x, 1];
  }
  let xinv = 1 / x;
  let limit = 8;
  if (xinv > limit) {
    return [1, limit];
  } else if (Math.floor(xinv) === xinv) {
    return [1, xinv];
  }

  let x_ = x > 1 ? xinv : x;
  // a/b and c/d are neighbours in Farey sequence.
  let a = 0, b = 1, c = 1, d = 1;
  // Limiting search to order 8.
  while (true) {
    // Generating next term in sequence (order of q).
    let p = a + c, q = b + d;
    if (q > limit) {
      break;
    }
    if (x_ <= p / q) {
      c = p; d = q;
    } else {
      a = p; b = q;
    }
  }
  let result;
  // Select closest of the neighbours to x.
  if (x_ - a / b < c / d - x_) {
    result = x_ === x ? [a, b] : [b, a];
  } else {
    result = x_ === x ? [c, d] : [d, c];
  }
  return result;
}

function roundToDivide(x, div) {
  let r = x % div;
  return r === 0 ? x : Math.round(x - r + div);
}

/**
 * Gets the size of the specified page, converted from PDF units to inches.
 * @param {Object} An Object containing the properties: {Array} `view`,
 *   {number} `userUnit`, and {number} `rotate`.
 * @return {Object} An Object containing the properties: {number} `width`
 *   and {number} `height`, given in inches.
 */
function getPageSizeInches({ view, userUnit, rotate, }) {
  const [x1, y1, x2, y2] = view;
  // We need to take the page rotation into account as well.
  const changeOrientation = rotate % 180 !== 0;

  const width = (x2 - x1) / 72 * userUnit;
  const height = (y2 - y1) / 72 * userUnit;

  return {
    width: (changeOrientation ? height : width),
    height: (changeOrientation ? width : height),
  };
}

/**
 * Helper function for getVisibleElements.
 *
 * @param {number} index - initial guess at the first visible element
 * @param {Array} views - array of pages, into which `index` is an index
 * @param {number} top - the top of the scroll pane
 * @returns {number} less than or equal to `index` that is definitely at or
 *   before the first visible element in `views`, but not by too much. (Usually,
 *   this will be the first element in the first partially visible row in
 *   `views`, although sometimes it goes back one row further.)
 */
function backtrackBeforeAllVisibleElements(index, views, top) {
  // binarySearchFirstItem's assumption is that the input is ordered, with only
  // one index where the conditions flips from false to true: [false ...,
  // true...]. With vertical scrolling and spreads, it is possible to have
  // [false ..., true, false, true ...]. With wrapped scrolling we can have a
  // similar sequence, with many more mixed true and false in the middle.
  //
  // So there is no guarantee that the binary search yields the index of the
  // first visible element. It could have been any of the other visible elements
  // that were preceded by a hidden element.

  // Of course, if either this element or the previous (hidden) element is also
  // the first element, there's nothing to worry about.
  if (index < 2) {
    return index;
  }

  // That aside, the possible cases are represented below.
  //
  //     ****  = fully hidden
  //     A*B*  = mix of partially visible and/or hidden pages
  //     CDEF  = fully visible
  //
  // (1) Binary search could have returned A, in which case we can stop.
  // (2) Binary search could also have returned B, in which case we need to
  // check the whole row.
  // (3) Binary search could also have returned C, in which case we need to
  // check the whole previous row.
  //
  // There's one other possibility:
  //
  //     ****  = fully hidden
  //     ABCD  = mix of fully and/or partially visible pages
  //
  // (4) Binary search could only have returned A.

  // Initially assume that we need to find the beginning of the current row
  // (case 1, 2, or 4), which means finding a page that is above the current
  // page's top. If the found page is partially visible, we're definitely not in
  // case 3, and this assumption is correct.
  let elt = views[index].div;
  let pageTop = elt.offsetTop + elt.clientTop;

  if (pageTop >= top) {
    // The found page is fully visible, so we're actually either in case 3 or 4,
    // and unfortunately we can't tell the difference between them without
    // scanning the entire previous row, so we just conservatively assume that
    // we do need to backtrack to that row. In both cases, the previous page is
    // in the previous row, so use its top instead.
    elt = views[index - 1].div;
    pageTop = elt.offsetTop + elt.clientTop;
  }

  // Now we backtrack to the first page that still has its bottom below
  // `pageTop`, which is the top of a page in the first visible row (unless
  // we're in case 4, in which case it's the row before that).
  // `index` is found by binary search, so the page at `index - 1` is
  // invisible and we can start looking for potentially visible pages from
  // `index - 2`. (However, if this loop terminates on its first iteration,
  // which is the case when pages are stacked vertically, `index` should remain
  // unchanged, so we use a distinct loop variable.)
  for (let i = index - 2; i >= 0; --i) {
    elt = views[i].div;
    if (elt.offsetTop + elt.clientTop + elt.clientHeight <= pageTop) {
      // We have reached the previous row, so stop now.
      // This loop is expected to terminate relatively quickly because the
      // number of pages per row is expected to be small.
      break;
    }
    index = i;
  }
  return index;
}

/**
 * Generic helper to find out what elements are visible within a scroll pane.
 *
 * Well, pretty generic. There are some assumptions placed on the elements
 * referenced by `views`:
 *   - If `horizontal`, no left of any earlier element is to the right of the
 *     left of any later element.
 *   - Otherwise, `views` can be split into contiguous rows where, within a row,
 *     no top of any element is below the bottom of any other element, and
 *     between rows, no bottom of any element in an earlier row is below the
 *     top of any element in a later row.
 *
 * (Here, top, left, etc. all refer to the padding edge of the element in
 * question. For pages, that ends up being equivalent to the bounding box of the
 * rendering canvas. Earlier and later refer to index in `views`, not page
 * layout.)
 *
 * @param scrollEl {HTMLElement} - a container that can possibly scroll
 * @param views {Array} - objects with a `div` property that contains an
 *   HTMLElement, which should all be descendents of `scrollEl` satisfying the
 *   above layout assumptions
 * @param sortByVisibility {boolean} - if true, the returned elements are sorted
 *   in descending order of the percent of their padding box that is visible
 * @param horizontal {boolean} - if true, the elements are assumed to be laid
 *   out horizontally instead of vertically
 * @returns {Object} `{ first, last, views: [{ id, x, y, view, percent }] }`
 */
function getVisibleElements(scrollEl, views, sortByVisibility = false,
                            horizontal = false) {
  let top = scrollEl.scrollTop, bottom = top + scrollEl.clientHeight;
  let left = scrollEl.scrollLeft, right = left + scrollEl.clientWidth;

  // Throughout this "generic" function, comments will assume we're working with
  // PDF document pages, which is the most important and complex case. In this
  // case, the visible elements we're actually interested is the page canvas,
  // which is contained in a wrapper which adds no padding/border/margin, which
  // is itself contained in `view.div` which adds no padding (but does add a
  // border). So, as specified in this function's doc comment, this function
  // does all of its work on the padding edge of the provided views, starting at
  // offsetLeft/Top (which includes margin) and adding clientLeft/Top (which is
  // the border). Adding clientWidth/Height gets us the bottom-right corner of
  // the padding edge.
  function isElementBottomAfterViewTop(view) {
    let element = view.div;
    let elementBottom =
      element.offsetTop + element.clientTop + element.clientHeight;
    return elementBottom > top;
  }
  function isElementRightAfterViewLeft(view) {
    let element = view.div;
    let elementRight =
      element.offsetLeft + element.clientLeft + element.clientWidth;
    return elementRight > left;
  }

  let visible = [], view, element;
  let currentHeight, viewHeight, viewBottom, hiddenHeight;
  let currentWidth, viewWidth, viewRight, hiddenWidth;
  let percentVisible;
  let firstVisibleElementInd = views.length === 0 ? 0 :
    binarySearchFirstItem(views, horizontal ? isElementRightAfterViewLeft :
                                              isElementBottomAfterViewTop);

  if (views.length > 0 && !horizontal) {
    // In wrapped scrolling (or vertical scrolling with spreads), with some page
    // sizes, isElementBottomAfterViewTop doesn't satisfy the binary search
    // condition: there can be pages with bottoms above the view top between
    // pages with bottoms below. This function detects and corrects that error;
    // see it for more comments.
    firstVisibleElementInd =
      backtrackBeforeAllVisibleElements(firstVisibleElementInd, views, top);
  }

  // lastEdge acts as a cutoff for us to stop looping, because we know all
  // subsequent pages will be hidden.
  //
  // When using wrapped scrolling or vertical scrolling with spreads, we can't
  // simply stop the first time we reach a page below the bottom of the view;
  // the tops of subsequent pages on the same row could still be visible. In
  // horizontal scrolling, we don't have that issue, so we can stop as soon as
  // we pass `right`, without needing the code below that handles the -1 case.
  let lastEdge = horizontal ? right : -1;

  for (let i = firstVisibleElementInd, ii = views.length; i < ii; i++) {
    view = views[i];
    element = view.div;
    currentWidth = element.offsetLeft + element.clientLeft;
    currentHeight = element.offsetTop + element.clientTop;
    viewWidth = element.clientWidth;
    viewHeight = element.clientHeight;
    viewRight = currentWidth + viewWidth;
    viewBottom = currentHeight + viewHeight;

    if (lastEdge === -1) {
      // As commented above, this is only needed in non-horizontal cases.
      // Setting lastEdge to the bottom of the first page that is partially
      // visible ensures that the next page fully below lastEdge is on the
      // next row, which has to be fully hidden along with all subsequent rows.
      if (viewBottom >= bottom) {
        lastEdge = viewBottom;
      }
    } else if ((horizontal ? currentWidth : currentHeight) > lastEdge) {
      break;
    }

    if (viewBottom <= top || currentHeight >= bottom ||
        viewRight <= left || currentWidth >= right) {
      continue;
    }

    hiddenHeight = Math.max(0, top - currentHeight) +
      Math.max(0, viewBottom - bottom);
    hiddenWidth = Math.max(0, left - currentWidth) +
      Math.max(0, viewRight - right);
    percentVisible = ((viewHeight - hiddenHeight) * (viewWidth - hiddenWidth) *
      100 / viewHeight / viewWidth) | 0;

    visible.push({
      id: view.id,
      x: currentWidth,
      y: currentHeight,
      view,
      percent: percentVisible,
    });
  }

  let first = visible[0];
  let last = visible[visible.length - 1];

  if (sortByVisibility) {
    visible.sort(function(a, b) {
      let pc = a.percent - b.percent;
      if (Math.abs(pc) > 0.001) {
        return -pc;
      }
      return a.id - b.id; // ensure stability
    });
  }
  return { first, last, views: visible, };
}

/**
 * Event handler to suppress context menu.
 */
function noContextMenuHandler(evt) {
  evt.preventDefault();
}

function isDataSchema(url) {
  let i = 0, ii = url.length;
  while (i < ii && url[i].trim() === '') {
    i++;
  }
  return url.substr(i, 5).toLowerCase() === 'data:';
}

/**
 * Returns the filename or guessed filename from the url (see issue 3455).
 * @param {string} url - The original PDF location.
 * @param {string} defaultFilename - The value returned if the filename is
 *   unknown, or the protocol is unsupported.
 * @returns {string} Guessed PDF filename.
 */
function getPDFFileNameFromURL(url, defaultFilename = 'document.pdf') {
  if (isDataSchema(url)) {
    console.warn('getPDFFileNameFromURL: ' +
                 'ignoring "data:" URL for performance reasons.');
    return defaultFilename;
  }
  const reURI = /^(?:(?:[^:]+:)?\/\/[^\/]+)?([^?#]*)(\?[^#]*)?(#.*)?$/;
  //            SCHEME        HOST         1.PATH  2.QUERY   3.REF
  // Pattern to get last matching NAME.pdf
  const reFilename = /[^\/?#=]+\.pdf\b(?!.*\.pdf\b)/i;
  let splitURI = reURI.exec(url);
  let suggestedFilename = reFilename.exec(splitURI[1]) ||
                          reFilename.exec(splitURI[2]) ||
                          reFilename.exec(splitURI[3]);
  if (suggestedFilename) {
    suggestedFilename = suggestedFilename[0];
    if (suggestedFilename.includes('%')) {
      // URL-encoded %2Fpath%2Fto%2Ffile.pdf should be file.pdf
      try {
        suggestedFilename =
          reFilename.exec(decodeURIComponent(suggestedFilename))[0];
      } catch (ex) { // Possible (extremely rare) errors:
        // URIError "Malformed URI", e.g. for "%AA.pdf"
        // TypeError "null has no properties", e.g. for "%2F.pdf"
      }
    }
  }
  return suggestedFilename || defaultFilename;
}

function normalizeWheelEventDelta(evt) {
  let delta = Math.sqrt(evt.deltaX * evt.deltaX + evt.deltaY * evt.deltaY);
  let angle = Math.atan2(evt.deltaY, evt.deltaX);
  if (-0.25 * Math.PI < angle && angle < 0.75 * Math.PI) {
    // All that is left-up oriented has to change the sign.
    delta = -delta;
  }

  const MOUSE_DOM_DELTA_PIXEL_MODE = 0;
  const MOUSE_DOM_DELTA_LINE_MODE = 1;
  const MOUSE_PIXELS_PER_LINE = 30;
  const MOUSE_LINES_PER_PAGE = 30;

  // Converts delta to per-page units
  if (evt.deltaMode === MOUSE_DOM_DELTA_PIXEL_MODE) {
    delta /= MOUSE_PIXELS_PER_LINE * MOUSE_LINES_PER_PAGE;
  } else if (evt.deltaMode === MOUSE_DOM_DELTA_LINE_MODE) {
    delta /= MOUSE_LINES_PER_PAGE;
  }
  return delta;
}

function isValidRotation(angle) {
  return Number.isInteger(angle) && angle % 90 === 0;
}

function isPortraitOrientation(size) {
  return size.width <= size.height;
}

const WaitOnType = {
  EVENT: 'event',
  TIMEOUT: 'timeout',
};

/**
 * @typedef {Object} WaitOnEventOrTimeoutParameters
 * @property {Object} target - The event target, can for example be:
 *   `window`, `document`, a DOM element, or an {EventBus} instance.
 * @property {string} name - The name of the event.
 * @property {number} delay - The delay, in milliseconds, after which the
 *   timeout occurs (if the event wasn't already dispatched).
 */

/**
 * Allows waiting for an event or a timeout, whichever occurs first.
 * Can be used to ensure that an action always occurs, even when an event
 * arrives late or not at all.
 *
 * @param {WaitOnEventOrTimeoutParameters}
 * @returns {Promise} A promise that is resolved with a {WaitOnType} value.
 */
function waitOnEventOrTimeout({ target, name, delay = 0, }) {
  return new Promise(function(resolve, reject) {
    if (typeof target !== 'object' || !(name && typeof name === 'string') ||
        !(Number.isInteger(delay) && delay >= 0)) {
      throw new Error('waitOnEventOrTimeout - invalid parameters.');
    }

    function handler(type) {
      if (target instanceof EventBus) {
        target.off(name, eventHandler);
      } else {
        target.removeEventListener(name, eventHandler);
      }

      if (timeout) {
        clearTimeout(timeout);
      }
      resolve(type);
    }

    const eventHandler = handler.bind(null, WaitOnType.EVENT);
    if (target instanceof EventBus) {
      target.on(name, eventHandler);
    } else {
      target.addEventListener(name, eventHandler);
    }

    const timeoutHandler = handler.bind(null, WaitOnType.TIMEOUT);
    let timeout = setTimeout(timeoutHandler, delay);
  });
}

/**
 * Promise that is resolved when DOM window becomes visible.
 */
let animationStarted = new Promise(function (resolve) {
  if ((typeof PDFJSDev !== 'undefined' && PDFJSDev.test('LIB')) &&
      typeof window === 'undefined') {
    // Prevent "ReferenceError: window is not defined" errors when running the
    // unit-tests in Node.js/Travis.
    setTimeout(resolve, 20);
    return;
  }
  window.requestAnimationFrame(resolve);
});

/**
 * Simple event bus for an application. Listeners are attached using the
 * `on` and `off` methods. To raise an event, the `dispatch` method shall be
 * used.
 */
class EventBus {
  constructor({ dispatchToDOM = false, } = {}) {
    this._listeners = Object.create(null);
    this._dispatchToDOM = dispatchToDOM === true;
  }

  on(eventName, listener) {
    let eventListeners = this._listeners[eventName];
    if (!eventListeners) {
      eventListeners = [];
      this._listeners[eventName] = eventListeners;
    }
    eventListeners.push(listener);
  }

  off(eventName, listener) {
    let eventListeners = this._listeners[eventName];
    let i;
    if (!eventListeners || ((i = eventListeners.indexOf(listener)) < 0)) {
      return;
    }
    eventListeners.splice(i, 1);
  }

  dispatch(eventName) {
    let eventListeners = this._listeners[eventName];
    if (!eventListeners || eventListeners.length === 0) {
      if (this._dispatchToDOM) {
        this._dispatchDOMEvent(eventName);
      }
      return;
    }
    // Passing all arguments after the eventName to the listeners.
    let args = Array.prototype.slice.call(arguments, 1);
    // Making copy of the listeners array in case if it will be modified
    // during dispatch.
    eventListeners.slice(0).forEach(function (listener) {
      listener.apply(null, args);
    });
    if (this._dispatchToDOM) {
      this._dispatchDOMEvent(eventName, args);
    }
  }

  /**
   * @private
   */
  _dispatchDOMEvent(eventName, args = null) {
    if (!this._dispatchToDOM) {
      return;
    }
    const details = Object.create(null);
    if (args && args.length > 0) {
      const obj = args[0];
      for (let key in obj) {
        const value = obj[key];
        if (key === 'source') {
          if (value === window || value === document) {
            return; // No need to re-dispatch (already) global events.
          }
          continue; // Ignore the `source` property.
        }
        details[key] = value;
      }
    }
    const event = document.createEvent('CustomEvent');
    event.initCustomEvent(eventName, true, true, details);
    document.dispatchEvent(event);
  }
}

function clamp(v, min, max) {
  return Math.min(Math.max(v, min), max);
}

class ProgressBar {
  constructor(id, { height, width, units, } = {}) {
    this.visible = true;

    // Fetch the sub-elements for later.
    this.div = document.querySelector(id + ' .progress');
    // Get the loading bar element, so it can be resized to fit the viewer.
    this.bar = this.div.parentNode;

    // Get options, with sensible defaults.
    this.height = height || 100;
    this.width = width || 100;
    this.units = units || '%';

    // Initialize heights.
    this.div.style.height = this.height + this.units;
    this.percent = 0;
  }

  _updateBar() {
    if (this._indeterminate) {
      this.div.classList.add('indeterminate');
      this.div.style.width = this.width + this.units;
      return;
    }

    this.div.classList.remove('indeterminate');
    let progressSize = this.width * this._percent / 100;
    this.div.style.width = progressSize + this.units;
  }

  get percent() {
    return this._percent;
  }

  set percent(val) {
    this._indeterminate = isNaN(val);
    this._percent = clamp(val, 0, 100);
    this._updateBar();
  }

  setWidth(viewer) {
    if (!viewer) {
      return;
    }
    let container = viewer.parentNode;
    let scrollbarWidth = container.offsetWidth - viewer.offsetWidth;
    if (scrollbarWidth > 0) {
      this.bar.setAttribute('style', 'width: calc(100% - ' +
                                     scrollbarWidth + 'px);');
    }
  }

  hide() {
    if (!this.visible) {
      return;
    }
    this.visible = false;
    this.bar.classList.add('hidden');
    document.body.classList.remove('loadingInProgress');
  }

  show() {
    if (this.visible) {
      return;
    }
    this.visible = true;
    document.body.classList.add('loadingInProgress');
    this.bar.classList.remove('hidden');
  }
}

/**
 * Moves all elements of an array that satisfy condition to the end of the
 * array, preserving the order of the rest.
 */
function moveToEndOfArray(arr, condition) {
  const moved = [], len = arr.length;
  let write = 0;
  for (let read = 0; read < len; ++read) {
    if (condition(arr[read])) {
      moved.push(arr[read]);
    } else {
      arr[write] = arr[read];
      ++write;
    }
  }
  for (let read = 0; write < len; ++read, ++write) {
    arr[write] = moved[read];
  }
}

export {
  CSS_UNITS,
  DEFAULT_SCALE_VALUE,
  DEFAULT_SCALE,
  MIN_SCALE,
  MAX_SCALE,
  UNKNOWN_SCALE,
  MAX_AUTO_SCALE,
  SCROLLBAR_PADDING,
  VERTICAL_PADDING,
  isValidRotation,
  isPortraitOrientation,
  PresentationModeState,
  RendererType,
  TextLayerMode,
  NullL10n,
  EventBus,
  ProgressBar,
  getPDFFileNameFromURL,
  noContextMenuHandler,
  parseQueryString,
  backtrackBeforeAllVisibleElements, // only exported for testing
  getVisibleElements,
  roundToDivide,
  getPageSizeInches,
  approximateFraction,
  getOutputScale,
  scrollIntoView,
  watchScroll,
  binarySearchFirstItem,
  normalizeWheelEventDelta,
  animationStarted,
  WaitOnType,
  waitOnEventOrTimeout,
  moveToEndOfArray,
};