cc/output/bsp_tree.cc - chromium/src - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "cc/output/bsp_tree.h"

 #include <vector>

 #include "base/memory/scoped_ptr.h"
 #include "cc/base/scoped_ptr_deque.h"
 #include "cc/base/scoped_ptr_vector.h"
 #include "cc/output/bsp_compare_result.h"
 #include "cc/quads/draw_polygon.h"

 namespace cc {

 BspNode::BspNode(scoped_ptr<DrawPolygon> data) : node_data(data.Pass()) {
 }

 BspNode::~BspNode() {
 }

 BspTree::BspTree(ScopedPtrDeque<DrawPolygon>* list) {
   if (list->size() == 0)
     return;

   root_ = make_scoped_ptr(new BspNode(list->take_front()));
   BuildTree(root_.get(), list);
 }

 // The idea behind using a deque for BuildTree's input is that we want to be
 // able to place polygons that we've decided aren't splitting plane candidates
 // at the back of the queue while moving the candidate splitting planes to the
 // front when the heuristic decides that they're a better choice. This way we
 // can always simply just take from the front of the deque for our node's
 // data.
 void BspTree::BuildTree(BspNode* node,
                         ScopedPtrDeque<DrawPolygon>* polygon_list) {
   ScopedPtrDeque<DrawPolygon> front_list;
   ScopedPtrDeque<DrawPolygon> back_list;

   // We take in a list of polygons at this level of the tree, and have to
   // find a splitting plane, then classify polygons as either in front of
   // or behind that splitting plane.
   while (polygon_list->size() > 0) {
     // Is this particular polygon in front of or behind our splitting polygon.
     BspCompareResult comparer_result =
         GetNodePositionRelative(*polygon_list->front(), *(node->node_data));

     // If it's clearly behind or in front of the splitting plane, we use the
     // heuristic to decide whether or not we should put it at the back
     // or front of the list.
     switch (comparer_result) {
       case BSP_FRONT:
         front_list.push_back(polygon_list->take_front().Pass());
         break;
       case BSP_BACK:
         back_list.push_back(polygon_list->take_front().Pass());
         break;
       case BSP_SPLIT:
       {
         scoped_ptr<DrawPolygon> polygon;
         scoped_ptr<DrawPolygon> new_front;
         scoped_ptr<DrawPolygon> new_back;
         // Time to split this geometry, *it needs to be split by node_data.
         polygon = polygon_list->take_front();
         bool split_result =
             polygon->Split(*(node->node_data), &new_front, &new_back);
         DCHECK(split_result);
         if (!split_result) {
           break;
         }
         front_list.push_back(new_front.Pass());
         back_list.push_back(new_back.Pass());
         break;
       }
       case BSP_COPLANAR_FRONT:
         node->coplanars_front.push_back(polygon_list->take_front());
         break;
       case BSP_COPLANAR_BACK:
         node->coplanars_back.push_back(polygon_list->take_front());
         break;
       default:
         NOTREACHED();
         break;
     }
   }

   // Build the back subtree using the front of the back_list as our splitter.
   if (back_list.size() > 0) {
     node->back_child = make_scoped_ptr(new BspNode(back_list.take_front()));
     BuildTree(node->back_child.get(), &back_list);
   }

   // Build the front subtree using the front of the front_list as our splitter.
   if (front_list.size() > 0) {
     node->front_child =
         scoped_ptr<BspNode>(new BspNode(front_list.take_front()));
     BuildTree(node->front_child.get(), &front_list);
   }
 }

 BspCompareResult BspTree::GetNodePositionRelative(const DrawPolygon& node_a,
                                                   const DrawPolygon& node_b) {
   return DrawPolygon::SideCompare(node_a, node_b);
 }

 // The base comparer with 0,0,0 as camera position facing forward
 BspCompareResult BspTree::GetCameraPositionRelative(const DrawPolygon& node) {
   if (node.normal().z() > 0.0f) {
     return BSP_FRONT;
   }
   return BSP_BACK;
 }

 BspTree::~BspTree() {
 }

 }  // namespace cc
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "cc/output/bsp_tree.h"

	#include <vector>

	#include "base/memory/scoped_ptr.h"
	#include "cc/base/scoped_ptr_deque.h"
	#include "cc/base/scoped_ptr_vector.h"
	#include "cc/output/bsp_compare_result.h"
	#include "cc/quads/draw_polygon.h"

	namespace cc {

	BspNode::BspNode(scoped_ptr<DrawPolygon> data) : node_data(data.Pass()) {
	}

	BspNode::~BspNode() {
	}

	BspTree::BspTree(ScopedPtrDeque<DrawPolygon>* list) {
	if (list->size() == 0)
	return;

	root_ = make_scoped_ptr(new BspNode(list->take_front()));
	BuildTree(root_.get(), list);
	}

	// The idea behind using a deque for BuildTree's input is that we want to be
	// able to place polygons that we've decided aren't splitting plane candidates
	// at the back of the queue while moving the candidate splitting planes to the
	// front when the heuristic decides that they're a better choice. This way we
	// can always simply just take from the front of the deque for our node's
	// data.
	void BspTree::BuildTree(BspNode* node,
	ScopedPtrDeque<DrawPolygon>* polygon_list) {
	ScopedPtrDeque<DrawPolygon> front_list;
	ScopedPtrDeque<DrawPolygon> back_list;

	// We take in a list of polygons at this level of the tree, and have to
	// find a splitting plane, then classify polygons as either in front of
	// or behind that splitting plane.
	while (polygon_list->size() > 0) {
	// Is this particular polygon in front of or behind our splitting polygon.
	BspCompareResult comparer_result =
	GetNodePositionRelative(polygon_list->front(), (node->node_data));

	// If it's clearly behind or in front of the splitting plane, we use the
	// heuristic to decide whether or not we should put it at the back
	// or front of the list.
	switch (comparer_result) {
	case BSP_FRONT:
	front_list.push_back(polygon_list->take_front().Pass());
	break;
	case BSP_BACK:
	back_list.push_back(polygon_list->take_front().Pass());
	break;
	case BSP_SPLIT:
	{
	scoped_ptr<DrawPolygon> polygon;
	scoped_ptr<DrawPolygon> new_front;
	scoped_ptr<DrawPolygon> new_back;
	// Time to split this geometry, *it needs to be split by node_data.
	polygon = polygon_list->take_front();
	bool split_result =
	polygon->Split(*(node->node_data), &new_front, &new_back);
	DCHECK(split_result);
	if (!split_result) {
	break;
	}
	front_list.push_back(new_front.Pass());
	back_list.push_back(new_back.Pass());
	break;
	}
	case BSP_COPLANAR_FRONT:
	node->coplanars_front.push_back(polygon_list->take_front());
	break;
	case BSP_COPLANAR_BACK:
	node->coplanars_back.push_back(polygon_list->take_front());
	break;
	default:
	NOTREACHED();
	break;
	}
	}

	// Build the back subtree using the front of the back_list as our splitter.
	if (back_list.size() > 0) {
	node->back_child = make_scoped_ptr(new BspNode(back_list.take_front()));
	BuildTree(node->back_child.get(), &back_list);
	}

	// Build the front subtree using the front of the front_list as our splitter.
	if (front_list.size() > 0) {
	node->front_child =
	scoped_ptr<BspNode>(new BspNode(front_list.take_front()));
	BuildTree(node->front_child.get(), &front_list);
	}
	}

	BspCompareResult BspTree::GetNodePositionRelative(const DrawPolygon& node_a,
	const DrawPolygon& node_b) {
	return DrawPolygon::SideCompare(node_a, node_b);
	}

	// The base comparer with 0,0,0 as camera position facing forward
	BspCompareResult BspTree::GetCameraPositionRelative(const DrawPolygon& node) {
	if (node.normal().z() > 0.0f) {
	return BSP_FRONT;
	}
	return BSP_BACK;
	}

	BspTree::~BspTree() {
	}

	} // namespace cc