separate_rects.cpp - platform/external/drm_hwcomposer - Git at Google

 /*
  * Copyright (C) 2015 The Android Open Source Project
  *
  * 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.
  */

 #include "separate_rects.h"
 #include <algorithm>
 #include <assert.h>
 #include <iostream>
 #include <map>
 #include <set>
 #include <utility>
 #include <vector>

 namespace separate_rects {

 enum EventType { START, END };

 template <typename TId, typename TNum>
 struct StartedRect {
   IdSet<TId> id_set;
   TNum left, top, bottom;

   // Note that this->left is not part of the key. That field is only to mark the
   // left edge of the rectangle.
   bool operator<(const StartedRect<TId, TNum> &rhs) const {
     return (top < rhs.top || (top == rhs.top && bottom < rhs.bottom)) ||
            (top == rhs.top && bottom == rhs.bottom && id_set < rhs.id_set);
   }
 };

 template <typename TId, typename TNum>
 struct SweepEvent {
   EventType type;
   union {
     TNum x;
     TNum y;
   };

   TId rect_id;

   bool operator<(const SweepEvent<TId, TNum> &rhs) const {
     return (y < rhs.y || (y == rhs.y && rect_id < rhs.rect_id));
   }
 };

 template <typename TNum>
 std::ostream &operator<<(std::ostream &os, const Rect<TNum> &rect) {
   return os << rect.bounds[0] << ", " << rect.bounds[1] << ", "
             << rect.bounds[2] << ", " << rect.bounds[3];
 }

 template <typename TUInt>
 std::ostream &operator<<(std::ostream &os, const IdSet<TUInt> &obj) {
   int bits = IdSet<TUInt>::max_elements;
   TUInt mask = ((TUInt)0x1) << (bits - 1);
   for (int i = 0; i < bits; i++)
     os << ((obj.getBits() & (mask >> i)) ? "1" : "0");
   return os;
 }

 template <typename TNum, typename TId>
 void separate_rects(const std::vector<Rect<TNum>> &in,
                     std::vector<RectSet<TId, TNum>> *out) {
   // Overview:
   // This algorithm is a line sweep algorithm that travels from left to right.
   // The sweep stops at each vertical edge of each input rectangle in sorted
   // order of x-coordinate. At each stop, the sweep line is examined in order of
   // y-coordinate from top to bottom. Along the way, a running set of rectangle
   // IDs is either added to or subtracted from as the top and bottom edges are
   // encountered, respectively. At each change of that running set, a copy of
   // that set is recorded in along with the the y-coordinate it happened at in a
   // list. This list is then interpreted as a sort of vertical cross section of
   // our output set of non-overlapping rectangles. Based of the algorithm found
   // at: http://stackoverflow.com/a/2755498

   if (in.size() > IdSet<TId>::max_elements) {
     return;
   }

   // Events are when the sweep line encounters the starting or ending edge of
   // any input rectangle.
   std::set<SweepEvent<TId, TNum>> sweep_h_events;  // Left or right bounds
   std::set<SweepEvent<TId, TNum>> sweep_v_events;  // Top or bottom bounds

   // A started rect is a rectangle whose left, top, bottom edge, and set of
   // rectangle IDs is known. The key of this map includes all that information
   // (except the left edge is never used to determine key equivalence or
   // ordering),
   std::map<StartedRect<TId, TNum>, bool> started_rects;

   // This is cleared after every event. Its declaration is here to avoid
   // reallocating a vector and its buffers every event.
   std::vector<std::pair<TNum, IdSet<TId>>> active_regions;

   // This pass will add rectangle start and end events to be triggered as the
   // algorithm sweeps from left to right.
   for (TId i = 0; i < in.size(); i++) {
     const Rect<TNum> &rect = in[i];

     // Filter out empty or invalid rects.
     if (rect.left >= rect.right || rect.top >= rect.bottom)
       continue;

     SweepEvent<TId, TNum> evt;
     evt.rect_id = i;

     evt.type = START;
     evt.x = rect.left;
     sweep_h_events.insert(evt);

     evt.type = END;
     evt.x = rect.right;
     sweep_h_events.insert(evt);
   }

   for (typename std::set<SweepEvent<TId, TNum>>::iterator it =
            sweep_h_events.begin();
        it != sweep_h_events.end(); ++it) {
     const SweepEvent<TId, TNum> &h_evt = *it;
     const Rect<TNum> &rect = in[h_evt.rect_id];

     // During this event, we have encountered a vertical starting or ending edge
     // of a rectangle so want to append or remove (respectively) that rectangles
     // top and bottom from the vertical sweep line.
     SweepEvent<TId, TNum> v_evt;
     v_evt.rect_id = h_evt.rect_id;
     if (h_evt.type == START) {
       v_evt.type = START;
       v_evt.y = rect.top;
       sweep_v_events.insert(v_evt);

       v_evt.type = END;
       v_evt.y = rect.bottom;
       sweep_v_events.insert(v_evt);
     } else {
       v_evt.type = START;
       v_evt.y = rect.top;
       typename std::set<SweepEvent<TId, TNum>>::iterator start_it =
           sweep_v_events.find(v_evt);
       assert(start_it != sweep_v_events.end());
       sweep_v_events.erase(start_it);

       v_evt.type = END;
       v_evt.y = rect.bottom;
       typename std::set<SweepEvent<TId, TNum>>::iterator end_it =
           sweep_v_events.find(v_evt);
       assert(end_it != sweep_v_events.end());
       sweep_v_events.erase(end_it);
     }

     // Peeks ahead to see if there are other rectangles sharing a vertical edge
     // with the current sweep line. If so, we want to continue marking up the
     // sweep line before actually processing the rectangles the sweep line is
     // intersecting.
     typename std::set<SweepEvent<TId, TNum>>::iterator next_it = it;
     ++next_it;
     if (next_it != sweep_h_events.end()) {
       if (next_it->x == h_evt.x) {
         continue;
       }
     }

 #ifdef RECTS_DEBUG
     std::cout << h_evt.x << std::endl;
 #endif

     // After the following for loop, active_regions will be a list of
     // y-coordinates paired with the set of rectangle IDs that are intersect at
     // that y-coordinate (and the current sweep line's x-coordinate). For
     // example if the current sweep line were the left edge of a scene with only
     // one rectangle of ID 0 and bounds (left, top, right, bottom) == (2, 3, 4,
     // 5), active_regions will be [({ 0 }, 3), {}, 5].
     active_regions.clear();
     IdSet<TId> active_set;
     for (typename std::set<SweepEvent<TId, TNum>>::iterator it =
              sweep_v_events.begin();
          it != sweep_v_events.end(); ++it) {
       const SweepEvent<TId, TNum> &v_evt = *it;

       if (v_evt.type == START) {
         active_set.add(v_evt.rect_id);
       } else {
         active_set.subtract(v_evt.rect_id);
       }

       if (active_regions.size() > 0 && active_regions.back().first == v_evt.y) {
         active_regions.back().second = active_set;
       } else {
         active_regions.push_back(std::make_pair(v_evt.y, active_set));
       }
     }

 #ifdef RECTS_DEBUG
     std::cout << "x:" << h_evt.x;
     for (std::vector<std::pair<TNum, IdSet>>::iterator it =
              active_regions.begin();
          it != active_regions.end(); ++it) {
       std::cout << " " << it->first << "(" << it->second << ")"
                 << ",";
     }
     std::cout << std::endl;
 #endif

     // To determine which started rectangles are ending this event, we make them
     // all as false, or unseen during this sweep line.
     for (typename std::map<StartedRect<TId, TNum>, bool>::iterator it =
              started_rects.begin();
          it != started_rects.end(); ++it) {
       it->second = false;
     }

     // This for loop will iterate all potential new rectangles and either
     // discover it was already started (and then mark it true), or that it is a
     // new rectangle and add it to the started rectangles. A started rectangle
     // is unique if it has a distinct top, bottom, and set of rectangle IDs.
     // This is tricky because a potential rectangle could be encountered here
     // that has a non-unique top and bottom, so it shares geometry with an
     // already started rectangle, but the set of rectangle IDs differs. In that
     // case, we have a new rectangle, and the already existing started rectangle
     // will not be marked as seen ("true" in the std::pair) and will get ended
     // by the for loop after this one. This is as intended.
     for (typename std::vector<std::pair<TNum, IdSet<TId>>>::iterator it =
              active_regions.begin();
          it != active_regions.end(); ++it) {
       IdSet<TId> region_set = it->second;

       if (region_set.isEmpty())
         continue;

       // An important property of active_regions is that each region where a set
       // of rectangles applies is bounded at the bottom by the next (in the
       // vector) region's starting y-coordinate.
       typename std::vector<std::pair<TNum, IdSet<TId>>>::iterator next_it = it;
       ++next_it;
       assert(next_it != active_regions.end());

       TNum region_top = it->first;
       TNum region_bottom = next_it->first;

       StartedRect<TId, TNum> rect_key;
       rect_key.id_set = region_set;
       rect_key.left = h_evt.x;
       rect_key.top = region_top;
       rect_key.bottom = region_bottom;

       // Remember that rect_key.left is ignored for the purposes of searching
       // the started rects. This follows from the fact that a previously started
       // rectangle would by definition have a left bound less than the current
       // event's x-coordinate. We are interested in continuing the started
       // rectangles by marking them seen (true) but we don't know, care, or wish
       // to change the left bound at this point. If there are no matching
       // rectangles for this region, start a new one and mark it as seen (true).
       typename std::map<StartedRect<TId, TNum>, bool>::iterator
           started_rect_it = started_rects.find(rect_key);
       if (started_rect_it == started_rects.end()) {
         started_rects[rect_key] = true;
       } else {
         started_rect_it->second = true;
       }
     }

     // This for loop ends all rectangles that were unseen during this event.
     // Because this is the first event where we didn't see this rectangle, it's
     // right edge is exactly the current event's x-coordinate. With this, we
     // have the final piece of information to output this rectangle's geometry
     // and set of input rectangle IDs. To end a started rectangle, we erase it
     // from the started_rects map and append the completed rectangle to the
     // output vector.
     for (typename std::map<StartedRect<TId, TNum>, bool>::iterator it =
              started_rects.begin();
          it != started_rects.end();
          /* inc in body */) {
       if (!it->second) {
         const StartedRect<TId, TNum> &proto_rect = it->first;
         Rect<TNum> out_rect;
         out_rect.left = proto_rect.left;
         out_rect.top = proto_rect.top;
         out_rect.right = h_evt.x;
         out_rect.bottom = proto_rect.bottom;
         out->push_back(RectSet<TId, TNum>(proto_rect.id_set, out_rect));
         started_rects.erase(it++);  // Also increments out iterator.

 #ifdef RECTS_DEBUG
         std::cout << "    <" << proto_rect.id_set << "(" << rect << ")"
                   << std::endl;
 #endif
       } else {
         // Remember this for loop has no built in increment step. We do it here.
         ++it;
       }
     }
   }
 }

 void separate_frects_64(const std::vector<Rect<float>> &in,
                         std::vector<RectSet<uint64_t, float>> *out) {
   separate_rects(in, out);
 }

 void separate_rects_64(const std::vector<Rect<int>> &in,
                        std::vector<RectSet<uint64_t, int>> *out) {
   separate_rects(in, out);
 }

 }  // namespace separate_rects

 #ifdef RECTS_TEST

 using namespace separate_rects;

 int main(int argc, char **argv) {
 #define RectSet RectSet<TId, TNum>
 #define Rect Rect<TNum>
 #define IdSet IdSet<TId>
   typedef uint64_t TId;
   typedef float TNum;

   std::vector<Rect> in;
   std::vector<RectSet> out;
   std::vector<RectSet> expected_out;

   in.push_back({0, 0, 4, 5});
   in.push_back({2, 0, 6, 6});
   in.push_back({4, 0, 8, 5});
   in.push_back({0, 7, 8, 9});

   in.push_back({10, 0, 18, 5});
   in.push_back({12, 0, 16, 5});

   in.push_back({20, 11, 24, 17});
   in.push_back({22, 13, 26, 21});
   in.push_back({32, 33, 36, 37});
   in.push_back({30, 31, 38, 39});

   in.push_back({40, 43, 48, 45});
   in.push_back({44, 41, 46, 47});

   in.push_back({50, 51, 52, 53});
   in.push_back({50, 51, 52, 53});
   in.push_back({50, 51, 52, 53});

   in.push_back({0, 0, 0, 10});
   in.push_back({0, 0, 10, 0});
   in.push_back({10, 0, 0, 10});
   in.push_back({0, 10, 10, 0});

   for (int i = 0; i < 100000; i++) {
     out.clear();
     separate_rects(in, &out);
   }

   for (int i = 0; i < out.size(); i++) {
     std::cout << out[i].id_set << "(" << out[i].rect << ")" << std::endl;
   }

   std::cout << "# of rects: " << out.size() << std::endl;

   expected_out.push_back(RectSet(IdSet(0), Rect(0, 0, 2, 5)));
   expected_out.push_back(RectSet(IdSet(1), Rect(2, 5, 6, 6)));
   expected_out.push_back(RectSet(IdSet(1) | 0, Rect(2, 0, 4, 5)));
   expected_out.push_back(RectSet(IdSet(1) | 2, Rect(4, 0, 6, 5)));
   expected_out.push_back(RectSet(IdSet(2), Rect(6, 0, 8, 5)));
   expected_out.push_back(RectSet(IdSet(3), Rect(0, 7, 8, 9)));
   expected_out.push_back(RectSet(IdSet(4), Rect(10, 0, 12, 5)));
   expected_out.push_back(RectSet(IdSet(5) | 4, Rect(12, 0, 16, 5)));
   expected_out.push_back(RectSet(IdSet(4), Rect(16, 0, 18, 5)));
   expected_out.push_back(RectSet(IdSet(6), Rect(20, 11, 22, 17)));
   expected_out.push_back(RectSet(IdSet(6) | 7, Rect(22, 13, 24, 17)));
   expected_out.push_back(RectSet(IdSet(6), Rect(22, 11, 24, 13)));
   expected_out.push_back(RectSet(IdSet(7), Rect(22, 17, 24, 21)));
   expected_out.push_back(RectSet(IdSet(7), Rect(24, 13, 26, 21)));
   expected_out.push_back(RectSet(IdSet(9), Rect(30, 31, 32, 39)));
   expected_out.push_back(RectSet(IdSet(8) | 9, Rect(32, 33, 36, 37)));
   expected_out.push_back(RectSet(IdSet(9), Rect(32, 37, 36, 39)));
   expected_out.push_back(RectSet(IdSet(9), Rect(32, 31, 36, 33)));
   expected_out.push_back(RectSet(IdSet(9), Rect(36, 31, 38, 39)));
   expected_out.push_back(RectSet(IdSet(10), Rect(40, 43, 44, 45)));
   expected_out.push_back(RectSet(IdSet(10) | 11, Rect(44, 43, 46, 45)));
   expected_out.push_back(RectSet(IdSet(11), Rect(44, 41, 46, 43)));
   expected_out.push_back(RectSet(IdSet(11), Rect(44, 45, 46, 47)));
   expected_out.push_back(RectSet(IdSet(10), Rect(46, 43, 48, 45)));
   expected_out.push_back(RectSet(IdSet(12) | 13 | 14, Rect(50, 51, 52, 53)));

   for (int i = 0; i < expected_out.size(); i++) {
     RectSet &ex_out = expected_out[i];
     if (std::find(out.begin(), out.end(), ex_out) == out.end()) {
       std::cout << "Missing Rect: " << ex_out.id_set << "(" << ex_out.rect
                 << ")" << std::endl;
     }
   }

   for (int i = 0; i < out.size(); i++) {
     RectSet &actual_out = out[i];
     if (std::find(expected_out.begin(), expected_out.end(), actual_out) ==
         expected_out.end()) {
       std::cout << "Extra Rect: " << actual_out.id_set << "(" << actual_out.rect
                 << ")" << std::endl;
     }
   }

   return 0;
 }

 #endif
	/*
	* Copyright (C) 2015 The Android Open Source Project
	*
	* 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.
	*/

	#include "separate_rects.h"
	#include <algorithm>
	#include <assert.h>
	#include <iostream>
	#include <map>
	#include <set>
	#include <utility>
	#include <vector>

	namespace separate_rects {

	enum EventType { START, END };

	template <typename TId, typename TNum>
	struct StartedRect {
	IdSet<TId> id_set;
	TNum left, top, bottom;

	// Note that this->left is not part of the key. That field is only to mark the
	// left edge of the rectangle.
	bool operator<(const StartedRect<TId, TNum> &rhs) const {
	return (top < rhs.top \|\| (top == rhs.top && bottom < rhs.bottom)) \|\|
	(top == rhs.top && bottom == rhs.bottom && id_set < rhs.id_set);
	}
	};

	template <typename TId, typename TNum>
	struct SweepEvent {
	EventType type;
	union {
	TNum x;
	TNum y;
	};

	TId rect_id;

	bool operator<(const SweepEvent<TId, TNum> &rhs) const {
	return (y < rhs.y \|\| (y == rhs.y && rect_id < rhs.rect_id));
	}
	};

	template <typename TNum>
	std::ostream &operator<<(std::ostream &os, const Rect<TNum> &rect) {
	return os << rect.bounds[0] << ", " << rect.bounds[1] << ", "
	<< rect.bounds[2] << ", " << rect.bounds[3];
	}

	template <typename TUInt>
	std::ostream &operator<<(std::ostream &os, const IdSet<TUInt> &obj) {
	int bits = IdSet<TUInt>::max_elements;
	TUInt mask = ((TUInt)0x1) << (bits - 1);
	for (int i = 0; i < bits; i++)
	os << ((obj.getBits() & (mask >> i)) ? "1" : "0");
	return os;
	}

	template <typename TNum, typename TId>
	void separate_rects(const std::vector<Rect<TNum>> &in,
	std::vector<RectSet<TId, TNum>> *out) {
	// Overview:
	// This algorithm is a line sweep algorithm that travels from left to right.
	// The sweep stops at each vertical edge of each input rectangle in sorted
	// order of x-coordinate. At each stop, the sweep line is examined in order of
	// y-coordinate from top to bottom. Along the way, a running set of rectangle
	// IDs is either added to or subtracted from as the top and bottom edges are
	// encountered, respectively. At each change of that running set, a copy of
	// that set is recorded in along with the the y-coordinate it happened at in a
	// list. This list is then interpreted as a sort of vertical cross section of
	// our output set of non-overlapping rectangles. Based of the algorithm found
	// at: http://stackoverflow.com/a/2755498

	if (in.size() > IdSet<TId>::max_elements) {
	return;
	}

	// Events are when the sweep line encounters the starting or ending edge of
	// any input rectangle.
	std::set<SweepEvent<TId, TNum>> sweep_h_events; // Left or right bounds
	std::set<SweepEvent<TId, TNum>> sweep_v_events; // Top or bottom bounds

	// A started rect is a rectangle whose left, top, bottom edge, and set of
	// rectangle IDs is known. The key of this map includes all that information
	// (except the left edge is never used to determine key equivalence or
	// ordering),
	std::map<StartedRect<TId, TNum>, bool> started_rects;

	// This is cleared after every event. Its declaration is here to avoid
	// reallocating a vector and its buffers every event.
	std::vector<std::pair<TNum, IdSet<TId>>> active_regions;

	// This pass will add rectangle start and end events to be triggered as the
	// algorithm sweeps from left to right.
	for (TId i = 0; i < in.size(); i++) {
	const Rect<TNum> &rect = in[i];

	// Filter out empty or invalid rects.
	if (rect.left >= rect.right \|\| rect.top >= rect.bottom)
	continue;

	SweepEvent<TId, TNum> evt;
	evt.rect_id = i;

	evt.type = START;
	evt.x = rect.left;
	sweep_h_events.insert(evt);

	evt.type = END;
	evt.x = rect.right;
	sweep_h_events.insert(evt);
	}

	for (typename std::set<SweepEvent<TId, TNum>>::iterator it =
	sweep_h_events.begin();
	it != sweep_h_events.end(); ++it) {
	const SweepEvent<TId, TNum> &h_evt = *it;
	const Rect<TNum> &rect = in[h_evt.rect_id];

	// During this event, we have encountered a vertical starting or ending edge
	// of a rectangle so want to append or remove (respectively) that rectangles
	// top and bottom from the vertical sweep line.
	SweepEvent<TId, TNum> v_evt;
	v_evt.rect_id = h_evt.rect_id;
	if (h_evt.type == START) {
	v_evt.type = START;
	v_evt.y = rect.top;
	sweep_v_events.insert(v_evt);

	v_evt.type = END;
	v_evt.y = rect.bottom;
	sweep_v_events.insert(v_evt);
	} else {
	v_evt.type = START;
	v_evt.y = rect.top;
	typename std::set<SweepEvent<TId, TNum>>::iterator start_it =
	sweep_v_events.find(v_evt);
	assert(start_it != sweep_v_events.end());
	sweep_v_events.erase(start_it);

	v_evt.type = END;
	v_evt.y = rect.bottom;
	typename std::set<SweepEvent<TId, TNum>>::iterator end_it =
	sweep_v_events.find(v_evt);
	assert(end_it != sweep_v_events.end());
	sweep_v_events.erase(end_it);
	}

	// Peeks ahead to see if there are other rectangles sharing a vertical edge
	// with the current sweep line. If so, we want to continue marking up the
	// sweep line before actually processing the rectangles the sweep line is
	// intersecting.
	typename std::set<SweepEvent<TId, TNum>>::iterator next_it = it;
	++next_it;
	if (next_it != sweep_h_events.end()) {
	if (next_it->x == h_evt.x) {
	continue;
	}
	}

	#ifdef RECTS_DEBUG
	std::cout << h_evt.x << std::endl;
	#endif

	// After the following for loop, active_regions will be a list of
	// y-coordinates paired with the set of rectangle IDs that are intersect at
	// that y-coordinate (and the current sweep line's x-coordinate). For
	// example if the current sweep line were the left edge of a scene with only
	// one rectangle of ID 0 and bounds (left, top, right, bottom) == (2, 3, 4,
	// 5), active_regions will be [({ 0 }, 3), {}, 5].
	active_regions.clear();
	IdSet<TId> active_set;
	for (typename std::set<SweepEvent<TId, TNum>>::iterator it =
	sweep_v_events.begin();
	it != sweep_v_events.end(); ++it) {
	const SweepEvent<TId, TNum> &v_evt = *it;

	if (v_evt.type == START) {
	active_set.add(v_evt.rect_id);
	} else {
	active_set.subtract(v_evt.rect_id);
	}

	if (active_regions.size() > 0 && active_regions.back().first == v_evt.y) {
	active_regions.back().second = active_set;
	} else {
	active_regions.push_back(std::make_pair(v_evt.y, active_set));
	}
	}

	#ifdef RECTS_DEBUG
	std::cout << "x:" << h_evt.x;
	for (std::vector<std::pair<TNum, IdSet>>::iterator it =
	active_regions.begin();
	it != active_regions.end(); ++it) {
	std::cout << " " << it->first << "(" << it->second << ")"
	<< ",";
	}
	std::cout << std::endl;
	#endif

	// To determine which started rectangles are ending this event, we make them
	// all as false, or unseen during this sweep line.
	for (typename std::map<StartedRect<TId, TNum>, bool>::iterator it =
	started_rects.begin();
	it != started_rects.end(); ++it) {
	it->second = false;
	}

	// This for loop will iterate all potential new rectangles and either
	// discover it was already started (and then mark it true), or that it is a
	// new rectangle and add it to the started rectangles. A started rectangle
	// is unique if it has a distinct top, bottom, and set of rectangle IDs.
	// This is tricky because a potential rectangle could be encountered here
	// that has a non-unique top and bottom, so it shares geometry with an
	// already started rectangle, but the set of rectangle IDs differs. In that
	// case, we have a new rectangle, and the already existing started rectangle
	// will not be marked as seen ("true" in the std::pair) and will get ended
	// by the for loop after this one. This is as intended.
	for (typename std::vector<std::pair<TNum, IdSet<TId>>>::iterator it =
	active_regions.begin();
	it != active_regions.end(); ++it) {
	IdSet<TId> region_set = it->second;

	if (region_set.isEmpty())
	continue;

	// An important property of active_regions is that each region where a set
	// of rectangles applies is bounded at the bottom by the next (in the
	// vector) region's starting y-coordinate.
	typename std::vector<std::pair<TNum, IdSet<TId>>>::iterator next_it = it;
	++next_it;
	assert(next_it != active_regions.end());

	TNum region_top = it->first;
	TNum region_bottom = next_it->first;

	StartedRect<TId, TNum> rect_key;
	rect_key.id_set = region_set;
	rect_key.left = h_evt.x;
	rect_key.top = region_top;
	rect_key.bottom = region_bottom;

	// Remember that rect_key.left is ignored for the purposes of searching
	// the started rects. This follows from the fact that a previously started
	// rectangle would by definition have a left bound less than the current
	// event's x-coordinate. We are interested in continuing the started
	// rectangles by marking them seen (true) but we don't know, care, or wish
	// to change the left bound at this point. If there are no matching
	// rectangles for this region, start a new one and mark it as seen (true).
	typename std::map<StartedRect<TId, TNum>, bool>::iterator
	started_rect_it = started_rects.find(rect_key);
	if (started_rect_it == started_rects.end()) {
	started_rects[rect_key] = true;
	} else {
	started_rect_it->second = true;
	}
	}

	// This for loop ends all rectangles that were unseen during this event.
	// Because this is the first event where we didn't see this rectangle, it's
	// right edge is exactly the current event's x-coordinate. With this, we
	// have the final piece of information to output this rectangle's geometry
	// and set of input rectangle IDs. To end a started rectangle, we erase it
	// from the started_rects map and append the completed rectangle to the
	// output vector.
	for (typename std::map<StartedRect<TId, TNum>, bool>::iterator it =
	started_rects.begin();
	it != started_rects.end();
	/* inc in body */) {
	if (!it->second) {
	const StartedRect<TId, TNum> &proto_rect = it->first;
	Rect<TNum> out_rect;
	out_rect.left = proto_rect.left;
	out_rect.top = proto_rect.top;
	out_rect.right = h_evt.x;
	out_rect.bottom = proto_rect.bottom;
	out->push_back(RectSet<TId, TNum>(proto_rect.id_set, out_rect));
	started_rects.erase(it++); // Also increments out iterator.

	#ifdef RECTS_DEBUG
	std::cout << " <" << proto_rect.id_set << "(" << rect << ")"
	<< std::endl;
	#endif
	} else {
	// Remember this for loop has no built in increment step. We do it here.
	++it;
	}
	}
	}
	}

	void separate_frects_64(const std::vector<Rect<float>> &in,
	std::vector<RectSet<uint64_t, float>> *out) {
	separate_rects(in, out);
	}

	void separate_rects_64(const std::vector<Rect<int>> &in,
	std::vector<RectSet<uint64_t, int>> *out) {
	separate_rects(in, out);
	}

	} // namespace separate_rects

	#ifdef RECTS_TEST

	using namespace separate_rects;

	int main(int argc, char **argv) {
	#define RectSet RectSet<TId, TNum>
	#define Rect Rect<TNum>
	#define IdSet IdSet<TId>
	typedef uint64_t TId;
	typedef float TNum;

	std::vector<Rect> in;
	std::vector<RectSet> out;
	std::vector<RectSet> expected_out;

	in.push_back({0, 0, 4, 5});
	in.push_back({2, 0, 6, 6});
	in.push_back({4, 0, 8, 5});
	in.push_back({0, 7, 8, 9});

	in.push_back({10, 0, 18, 5});
	in.push_back({12, 0, 16, 5});

	in.push_back({20, 11, 24, 17});
	in.push_back({22, 13, 26, 21});
	in.push_back({32, 33, 36, 37});
	in.push_back({30, 31, 38, 39});

	in.push_back({40, 43, 48, 45});
	in.push_back({44, 41, 46, 47});

	in.push_back({50, 51, 52, 53});
	in.push_back({50, 51, 52, 53});
	in.push_back({50, 51, 52, 53});

	in.push_back({0, 0, 0, 10});
	in.push_back({0, 0, 10, 0});
	in.push_back({10, 0, 0, 10});
	in.push_back({0, 10, 10, 0});

	for (int i = 0; i < 100000; i++) {
	out.clear();
	separate_rects(in, &out);
	}

	for (int i = 0; i < out.size(); i++) {
	std::cout << out[i].id_set << "(" << out[i].rect << ")" << std::endl;
	}

	std::cout << "# of rects: " << out.size() << std::endl;

	expected_out.push_back(RectSet(IdSet(0), Rect(0, 0, 2, 5)));
	expected_out.push_back(RectSet(IdSet(1), Rect(2, 5, 6, 6)));
	expected_out.push_back(RectSet(IdSet(1) \| 0, Rect(2, 0, 4, 5)));
	expected_out.push_back(RectSet(IdSet(1) \| 2, Rect(4, 0, 6, 5)));
	expected_out.push_back(RectSet(IdSet(2), Rect(6, 0, 8, 5)));
	expected_out.push_back(RectSet(IdSet(3), Rect(0, 7, 8, 9)));
	expected_out.push_back(RectSet(IdSet(4), Rect(10, 0, 12, 5)));
	expected_out.push_back(RectSet(IdSet(5) \| 4, Rect(12, 0, 16, 5)));
	expected_out.push_back(RectSet(IdSet(4), Rect(16, 0, 18, 5)));
	expected_out.push_back(RectSet(IdSet(6), Rect(20, 11, 22, 17)));
	expected_out.push_back(RectSet(IdSet(6) \| 7, Rect(22, 13, 24, 17)));
	expected_out.push_back(RectSet(IdSet(6), Rect(22, 11, 24, 13)));
	expected_out.push_back(RectSet(IdSet(7), Rect(22, 17, 24, 21)));
	expected_out.push_back(RectSet(IdSet(7), Rect(24, 13, 26, 21)));
	expected_out.push_back(RectSet(IdSet(9), Rect(30, 31, 32, 39)));
	expected_out.push_back(RectSet(IdSet(8) \| 9, Rect(32, 33, 36, 37)));
	expected_out.push_back(RectSet(IdSet(9), Rect(32, 37, 36, 39)));
	expected_out.push_back(RectSet(IdSet(9), Rect(32, 31, 36, 33)));
	expected_out.push_back(RectSet(IdSet(9), Rect(36, 31, 38, 39)));
	expected_out.push_back(RectSet(IdSet(10), Rect(40, 43, 44, 45)));
	expected_out.push_back(RectSet(IdSet(10) \| 11, Rect(44, 43, 46, 45)));
	expected_out.push_back(RectSet(IdSet(11), Rect(44, 41, 46, 43)));
	expected_out.push_back(RectSet(IdSet(11), Rect(44, 45, 46, 47)));
	expected_out.push_back(RectSet(IdSet(10), Rect(46, 43, 48, 45)));
	expected_out.push_back(RectSet(IdSet(12) \| 13 \| 14, Rect(50, 51, 52, 53)));

	for (int i = 0; i < expected_out.size(); i++) {
	RectSet &ex_out = expected_out[i];
	if (std::find(out.begin(), out.end(), ex_out) == out.end()) {
	std::cout << "Missing Rect: " << ex_out.id_set << "(" << ex_out.rect
	<< ")" << std::endl;
	}
	}

	for (int i = 0; i < out.size(); i++) {
	RectSet &actual_out = out[i];
	if (std::find(expected_out.begin(), expected_out.end(), actual_out) ==
	expected_out.end()) {
	std::cout << "Extra Rect: " << actual_out.id_set << "(" << actual_out.rect
	<< ")" << std::endl;
	}
	}

	return 0;
	}

	#endif