import Cartesian3 from "../Core/Cartesian3.js";
import defined from "../Core/defined.js";
import CesiumMath from "../Core/Math.js";
import SceneMode from "./SceneMode.js";

/**
 * Blends the atmosphere to geometry far from the camera for horizon views. Allows for additional
 * performance improvements by rendering less geometry and dispatching less terrain requests.
 *
 * @alias Fog
 * @constructor
 */
function Fog() {
  /**
   * <code>true</code> if fog is enabled, <code>false</code> otherwise.
   * @type {Boolean}
   * @default true
   */
  this.enabled = true;
  /**
   * A scalar that determines the density of the fog. Terrain that is in full fog are culled.
   * The density of the fog increases as this number approaches 1.0 and becomes less dense as it approaches zero.
   * The more dense the fog is, the more aggressively the terrain is culled. For example, if the camera is a height of
   * 1000.0m above the ellipsoid, increasing the value to 3.0e-3 will cause many tiles close to the viewer be culled.
   * Decreasing the value will push the fog further from the viewer, but decrease performance as more of the terrain is rendered.
   * @type {Number}
   * @default 2.0e-4
   */
  this.density = 2.0e-4;
  /**
   * A factor used to increase the screen space error of terrain tiles when they are partially in fog. The effect is to reduce
   * the number of terrain tiles requested for rendering. If set to zero, the feature will be disabled. If the value is increased
   * for mountainous regions, less tiles will need to be requested, but the terrain meshes near the horizon may be a noticeably
   * lower resolution. If the value is increased in a relatively flat area, there will be little noticeable change on the horizon.
   * @type {Number}
   * @default 2.0
   */
  this.screenSpaceErrorFactor = 2.0;
  /**
   * The minimum brightness of the fog color from lighting. A value of 0.0 can cause the fog to be completely black. A value of 1.0 will not affect
   * the brightness at all.
   * @type {Number}
   * @default 0.03
   */
  this.minimumBrightness = 0.03;
}

// These values were found by sampling the density at certain views and finding at what point culled tiles impacted the view at the horizon.
var heightsTable = [
  359.393,
  800.749,
  1275.6501,
  2151.1192,
  3141.7763,
  4777.5198,
  6281.2493,
  12364.307,
  15900.765,
  49889.0549,
  78026.8259,
  99260.7344,
  120036.3873,
  151011.0158,
  156091.1953,
  203849.3112,
  274866.9803,
  319916.3149,
  493552.0528,
  628733.5874,
];
var densityTable = [
  2.0e-5,
  2.0e-4,
  1.0e-4,
  7.0e-5,
  5.0e-5,
  4.0e-5,
  3.0e-5,
  1.9e-5,
  1.0e-5,
  8.5e-6,
  6.2e-6,
  5.8e-6,
  5.3e-6,
  5.2e-6,
  5.1e-6,
  4.2e-6,
  4.0e-6,
  3.4e-6,
  2.6e-6,
  2.2e-6,
];

// Scale densities by 1e6 to bring lowest value to ~1. Prevents divide by zero.
for (var i = 0; i < densityTable.length; ++i) {
  densityTable[i] *= 1.0e6;
}
// Change range to [0, 1].
var tableStartDensity = densityTable[1];
var tableEndDensity = densityTable[densityTable.length - 1];
for (var j = 0; j < densityTable.length; ++j) {
  densityTable[j] =
    (densityTable[j] - tableEndDensity) / (tableStartDensity - tableEndDensity);
}

var tableLastIndex = 0;

function findInterval(height) {
  var heights = heightsTable;
  var length = heights.length;

  if (height < heights[0]) {
    tableLastIndex = 0;
    return tableLastIndex;
  } else if (height > heights[length - 1]) {
    tableLastIndex = length - 2;
    return tableLastIndex;
  }

  // Take advantage of temporal coherence by checking current, next and previous intervals
  // for containment of time.
  if (height >= heights[tableLastIndex]) {
    if (tableLastIndex + 1 < length && height < heights[tableLastIndex + 1]) {
      return tableLastIndex;
    } else if (
      tableLastIndex + 2 < length &&
      height < heights[tableLastIndex + 2]
    ) {
      ++tableLastIndex;
      return tableLastIndex;
    }
  } else if (tableLastIndex - 1 >= 0 && height >= heights[tableLastIndex - 1]) {
    --tableLastIndex;
    return tableLastIndex;
  }

  // The above failed so do a linear search.
  var i;
  for (i = 0; i < length - 2; ++i) {
    if (height >= heights[i] && height < heights[i + 1]) {
      break;
    }
  }

  tableLastIndex = i;
  return tableLastIndex;
}

var scratchPositionNormal = new Cartesian3();

Fog.prototype.update = function (frameState) {
  var enabled = (frameState.fog.enabled = this.enabled);
  if (!enabled) {
    return;
  }

  var camera = frameState.camera;
  var positionCartographic = camera.positionCartographic;

  // Turn off fog in space.
  if (
    !defined(positionCartographic) ||
    positionCartographic.height > 800000.0 ||
    frameState.mode !== SceneMode.SCENE3D
  ) {
    frameState.fog.enabled = false;
    return;
  }

  var height = positionCartographic.height;
  var i = findInterval(height);
  var t = CesiumMath.clamp(
    (height - heightsTable[i]) / (heightsTable[i + 1] - heightsTable[i]),
    0.0,
    1.0
  );
  var density = CesiumMath.lerp(densityTable[i], densityTable[i + 1], t);

  // Again, scale value to be in the range of densityTable (prevents divide by zero) and change to new range.
  var startDensity = this.density * 1.0e6;
  var endDensity = (startDensity / tableStartDensity) * tableEndDensity;
  density = density * (startDensity - endDensity) * 1.0e-6;

  // Fade fog in as the camera tilts toward the horizon.
  var positionNormal = Cartesian3.normalize(
    camera.positionWC,
    scratchPositionNormal
  );
  var dot = Math.abs(Cartesian3.dot(camera.directionWC, positionNormal));
  density *= 1.0 - dot;

  frameState.fog.density = density;
  frameState.fog.sse = this.screenSpaceErrorFactor;
  frameState.fog.minimumBrightness = this.minimumBrightness;
};
export default Fog;