import "../core/functor";
import "../svg/line";
import "geom";

d3.geom.quadtree = function(points, x1, y1, x2, y2) {
  var x = d3_svg_lineX,
      y = d3_svg_lineY,
      compat;

  // For backwards-compatibility.
  if (compat = arguments.length) {
    x = d3_geom_quadtreeCompatX;
    y = d3_geom_quadtreeCompatY;
    if (compat === 3) {
      y2 = y1;
      x2 = x1;
      y1 = x1 = 0;
    }
    return quadtree(points);
  }

  function quadtree(data) {
    var d,
        fx = d3_functor(x),
        fy = d3_functor(y),
        xs,
        ys,
        i,
        n,
        x1_,
        y1_,
        x2_,
        y2_;

    if (x1 != null) {
      x1_ = x1, y1_ = y1, x2_ = x2, y2_ = y2;
    } else {
      // Compute bounds, and cache points temporarily.
      x2_ = y2_ = -(x1_ = y1_ = Infinity);
      xs = [], ys = [];
      n = data.length;
      if (compat) for (i = 0; i < n; ++i) {
        d = data[i];
        if (d.x < x1_) x1_ = d.x;
        if (d.y < y1_) y1_ = d.y;
        if (d.x > x2_) x2_ = d.x;
        if (d.y > y2_) y2_ = d.y;
        xs.push(d.x);
        ys.push(d.y);
      } else for (i = 0; i < n; ++i) {
        var x_ = +fx(d = data[i], i),
            y_ = +fy(d, i);
        if (x_ < x1_) x1_ = x_;
        if (y_ < y1_) y1_ = y_;
        if (x_ > x2_) x2_ = x_;
        if (y_ > y2_) y2_ = y_;
        xs.push(x_);
        ys.push(y_);
      }
    }

    // Squarify the bounds.
    var dx = x2_ - x1_,
        dy = y2_ - y1_;
    if (dx > dy) y2_ = y1_ + dx;
    else x2_ = x1_ + dy;

    // Recursively inserts the specified point p at the node n or one of its
    // descendants. The bounds are defined by [x1, x2] and [y1, y2].
    function insert(n, d, x, y, x1, y1, x2, y2) {
      if (isNaN(x) || isNaN(y)) return; // ignore invalid points
      if (n.leaf) {
        var nx = n.x,
            ny = n.y;
        if (nx != null) {
          // If the point at this leaf node is at the same position as the new
          // point we are adding, we leave the point associated with the
          // internal node while adding the new point to a child node. This
          // avoids infinite recursion.
          if ((Math.abs(nx - x) + Math.abs(ny - y)) < .01) {
            insertChild(n, d, x, y, x1, y1, x2, y2);
          } else {
            var nPoint = n.point;
            n.x = n.y = n.point = null;
            insertChild(n, nPoint, nx, ny, x1, y1, x2, y2);
            insertChild(n, d, x, y, x1, y1, x2, y2);
          }
        } else {
          n.x = x, n.y = y, n.point = d;
        }
      } else {
        insertChild(n, d, x, y, x1, y1, x2, y2);
      }
    }

    // Recursively inserts the specified point [x, y] into a descendant of node
    // n. The bounds are defined by [x1, x2] and [y1, y2].
    function insertChild(n, d, x, y, x1, y1, x2, y2) {
      // Compute the split point, and the quadrant in which to insert p.
      var sx = (x1 + x2) * .5,
          sy = (y1 + y2) * .5,
          right = x >= sx,
          bottom = y >= sy,
          i = (bottom << 1) + right;

      // Recursively insert into the child node.
      n.leaf = false;
      n = n.nodes[i] || (n.nodes[i] = d3_geom_quadtreeNode());

      // Update the bounds as we recurse.
      if (right) x1 = sx; else x2 = sx;
      if (bottom) y1 = sy; else y2 = sy;
      insert(n, d, x, y, x1, y1, x2, y2);
    }

    // Create the root node.
    var root = d3_geom_quadtreeNode();

    root.add = function(d) {
      insert(root, d, +fx(d, ++i), +fy(d, i), x1_, y1_, x2_, y2_);
    };

    root.visit = function(f) {
      d3_geom_quadtreeVisit(f, root, x1_, y1_, x2_, y2_);
    };

    // Insert all points.
    i = -1;
    if (x1 == null) {
      while (++i < n) {
        insert(root, data[i], xs[i], ys[i], x1_, y1_, x2_, y2_);
      }
      --i; // index of last insertion
    } else data.forEach(root.add);

    // Discard captured fields.
    xs = ys = data = d = null;

    return root;
  }

  quadtree.x = function(_) {
    return arguments.length ? (x = _, quadtree) : x;
  };

  quadtree.y = function(_) {
    return arguments.length ? (y = _, quadtree) : y;
  };

  quadtree.extent = function(_) {
    if (!arguments.length) return x1 == null ? null : [[x1, y1], [x2, y2]];
    if (_ == null) x1 = y1 = x2 = y2 = null;
    else x1 = +_[0][0], y1 = +_[0][1], x2 = +_[1][0], y2 = +_[1][1];
    return quadtree;
  };

  quadtree.size = function(_) {
    if (!arguments.length) return x1 == null ? null : [x2 - x1, y2 - y1];
    if (_ == null) x1 = y1 = x2 = y2 = null;
    else x1 = y1 = 0, x2 = +_[0], y2 = +_[1];
    return quadtree;
  };

  return quadtree;
};

function d3_geom_quadtreeCompatX(d) { return d.x; }
function d3_geom_quadtreeCompatY(d) { return d.y; }

function d3_geom_quadtreeNode() {
  return {
    leaf: true,
    nodes: [],
    point: null,
    x: null,
    y: null
  };
}

function d3_geom_quadtreeVisit(f, node, x1, y1, x2, y2) {
  if (!f(node, x1, y1, x2, y2)) {
    var sx = (x1 + x2) * .5,
        sy = (y1 + y2) * .5,
        children = node.nodes;
    if (children[0]) d3_geom_quadtreeVisit(f, children[0], x1, y1, sx, sy);
    if (children[1]) d3_geom_quadtreeVisit(f, children[1], sx, y1, x2, sy);
    if (children[2]) d3_geom_quadtreeVisit(f, children[2], x1, sy, sx, y2);
    if (children[3]) d3_geom_quadtreeVisit(f, children[3], sx, sy, x2, y2);
  }
}