Mercurial > hg > orthanc-stone
view OrthancStone/Sources/Toolbox/UnionOfRectangles.cpp @ 1952:a1e0aae9c17f deep-learning
support interruption of deep learning
author | Sebastien Jodogne <s.jodogne@gmail.com> |
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date | Tue, 16 Aug 2022 13:49:52 +0200 |
parents | 925aaf49150c |
children | 07964689cb0b |
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/** * Stone of Orthanc * Copyright (C) 2012-2016 Sebastien Jodogne, Medical Physics * Department, University Hospital of Liege, Belgium * Copyright (C) 2017-2022 Osimis S.A., Belgium * Copyright (C) 2021-2022 Sebastien Jodogne, ICTEAM UCLouvain, Belgium * * This program is free software: you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public License * as published by the Free Software Foundation, either version 3 of * the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this program. If not, see * <http://www.gnu.org/licenses/>. **/ #include "UnionOfRectangles.h" #include "Internals/OrientedIntegerLine2D.h" #include "Internals/RectanglesIntegerProjection.h" #include "SegmentTree.h" #include <OrthancException.h> #include <stack> namespace OrthancStone { class UnionOfRectangles::Payload : public Orthanc::IDynamicObject { private: int counter_; Status status_; public: Payload() : counter_(0), status_(Status_Empty) { } int GetCounter() const { return counter_; } Status GetStatus() const { return status_; } void SetStatus(Status status) { status_ = status; } void Increment() { counter_ ++; } void Decrement() { if (counter_ == 0) { throw Orthanc::OrthancException(Orthanc::ErrorCode_InternalError); } else { counter_ --; } } }; class UnionOfRectangles::Factory : public SegmentTree::IPayloadFactory { public: virtual Orthanc::IDynamicObject* Create() ORTHANC_OVERRIDE { return new Payload; } }; class UnionOfRectangles::Visitor : public SegmentTree::IVisitor { private: Operation operation_; public: explicit Visitor(Operation operation) : operation_(operation) { } virtual void Visit(const SegmentTree& node, bool fullyInside) ORTHANC_OVERRIDE { Payload& payload = node.GetTypedPayload<Payload>(); if (fullyInside) { switch (operation_) { case Operation_Insert: payload.Increment(); break; case Operation_Delete: payload.Decrement(); break; default: throw Orthanc::OrthancException(Orthanc::ErrorCode_InternalError); } } if (payload.GetCounter() > 0) { payload.SetStatus(Status_Full); } else if (node.IsLeaf()) { payload.SetStatus(Status_Empty); } else if (node.GetLeftChild().GetTypedPayload<Payload>().GetStatus() == Status_Empty && node.GetRightChild().GetTypedPayload<Payload>().GetStatus() == Status_Empty) { payload.SetStatus(Status_Empty); } else { payload.SetStatus(Status_Partial); } } // This is the "CONTR()" function from the textbook static void IntersectComplement(std::stack<size_t>& stack, size_t low, size_t high, const SegmentTree& node) { if (low >= high) { throw Orthanc::OrthancException(Orthanc::ErrorCode_ParameterOutOfRange); } Status status = node.GetTypedPayload<Payload>().GetStatus(); if (status != Status_Full) { assert(status == Status_Partial || status == Status_Empty); // Aliases to use the same variable names as in the textbook const size_t& b = low; const size_t& e = high; const size_t& bv = node.GetLowBound(); const size_t& ev = node.GetHighBound(); if (b <= bv && ev <= e && status == Status_Empty) { // [B[v], E[v]] is contributed if (!stack.empty() && stack.top() == bv) { stack.pop(); // Merge continuous segments } else { stack.push(bv); // Beginning of edge } stack.push(ev); // Current termination of edge } else { size_t middle = (bv + ev) / 2; if (b < middle) { IntersectComplement(stack, b, e, node.GetLeftChild()); } if (middle < e) { IntersectComplement(stack, b, e, node.GetRightChild()); } } } } }; static void AddVerticalEdges(std::list<Internals::OrientedIntegerLine2D>& edges, std::stack<size_t>& stack, size_t x, bool isLeft) { if (stack.size() % 2 != 0) { throw Orthanc::OrthancException(Orthanc::ErrorCode_InternalError); } typedef std::pair<size_t, size_t> Interval; std::list<Interval> intervals; while (!stack.empty()) { size_t high = stack.top(); stack.pop(); size_t low = stack.top(); stack.pop(); if (!intervals.empty() && intervals.back().second == low) { // Extend the previous interval intervals.back().second = high; } else { intervals.push_back(std::make_pair(low, high)); } } for (std::list<Interval>::const_iterator it = intervals.begin(); it != intervals.end(); ++it) { if (it->first >= it->second) { throw Orthanc::OrthancException(Orthanc::ErrorCode_ParameterOutOfRange); } // By convention, the left sides go downward, and the right go upward if (isLeft) { if (!edges.empty() && edges.back().GetX1() == x && edges.back().GetX2() == x && edges.back().GetY1() == it->second && edges.back().GetY2() == it->first) { // The two successive vertical segments cancel each other edges.pop_back(); } else { edges.push_back(Internals::OrientedIntegerLine2D(x, it->first, x, it->second)); } } else { if (!edges.empty() && edges.back().GetX1() == x && edges.back().GetX2() == x && edges.back().GetY1() == it->first && edges.back().GetY2() == it->second) { // The two successive vertical segments cancel each other edges.pop_back(); } else { edges.push_back(Internals::OrientedIntegerLine2D(x, it->second, x, it->first)); } } } } class UnionOfRectangles::VerticalSide { private: size_t x_; bool isLeft_; size_t y1_; size_t y2_; public: VerticalSide(size_t x, bool isLeft, size_t y1, size_t y2) : x_(x), isLeft_(isLeft), y1_(y1), y2_(y2) { assert(y1 < y2); } size_t GetX() const { return x_; } bool IsLeft() const { return isLeft_; } size_t GetY1() const { return y1_; } size_t GetY2() const { return y2_; } bool operator< (const VerticalSide& other) const { if (x_ < other.x_) { return true; } else if (x_ == other.x_) { return static_cast<int>(isLeft_) < static_cast<int>(other.isLeft_); } else { return false; } } bool Equals(const VerticalSide& other) const { return (x_ == other.x_ && isLeft_ == other.isLeft_); } }; class UnionOfRectangles::HorizontalJunction { private: size_t x_; size_t y_; size_t ybis_; bool downward_; public: HorizontalJunction(size_t x, size_t y, size_t ybis, bool downward) : x_(x), y_(y), ybis_(ybis), downward_(downward) { } size_t GetX() const { return x_; } size_t GetY() const { return y_; } size_t GetYBis() const { return ybis_; } bool IsDownward() const { return downward_; } bool operator< (const HorizontalJunction& other) const { if (y_ > other.y_) { return true; } else if (y_ == other.y_) { return x_ < other.x_; } else { return false; } } }; void UnionOfRectangles::Apply(std::list< std::vector<ScenePoint2D> >& contours, const std::list<Extent2D>& rectangles) { contours.clear(); /** * STEP 1 **/ Internals::RectanglesIntegerProjection horizontalProjection(rectangles, true); Internals::RectanglesIntegerProjection verticalProjection(rectangles, false); assert(horizontalProjection.GetProjectedRectanglesCount() == verticalProjection.GetProjectedRectanglesCount()); /** * STEP 2 **/ if (verticalProjection.GetEndpointsCount() == 0) { return; } Factory factory; SegmentTree tree(0, verticalProjection.GetEndpointsCount() - 1, factory); /** * STEP 3 **/ std::vector<VerticalSide> verticalSides; const size_t countRectangles = horizontalProjection.GetProjectedRectanglesCount(); verticalSides.reserve(2 * countRectangles); for (size_t i = 0; i < countRectangles; i++) { size_t horizontalLow = horizontalProjection.GetProjectedRectangleLow(i); size_t horizontalHigh = horizontalProjection.GetProjectedRectangleHigh(i); size_t verticalLow = verticalProjection.GetProjectedRectangleLow(i); size_t verticalHigh = verticalProjection.GetProjectedRectangleHigh(i); verticalSides.push_back(VerticalSide(horizontalLow, true, verticalLow, verticalHigh)); verticalSides.push_back(VerticalSide(horizontalHigh, false, verticalLow, verticalHigh)); } assert(verticalSides.size() == 2 * countRectangles); std::sort(verticalSides.begin(), verticalSides.end()); /** * STEP 4 **/ std::list<Internals::OrientedIntegerLine2D> verticalEdges; std::stack<size_t> stack; for (size_t i = 0; i < verticalSides.size(); i++) { if (i > 0 && !verticalSides[i].Equals(verticalSides[i - 1])) { // Output the stack AddVerticalEdges(verticalEdges, stack, verticalSides[i - 1].GetX(), verticalSides[i - 1].IsLeft()); } size_t y1 = verticalSides[i].GetY1(); size_t y2 = verticalSides[i].GetY2(); if (verticalSides[i].IsLeft()) { Visitor::IntersectComplement(stack, y1, y2, tree); Visitor visitor(Operation_Insert); tree.VisitSegment(y1, y2, visitor); } else { Visitor visitor(Operation_Delete); tree.VisitSegment(y1, y2, visitor); Visitor::IntersectComplement(stack, y1, y2, tree); } } if (!verticalSides.empty() && !stack.empty()) { AddVerticalEdges(verticalEdges, stack, verticalSides.back().GetX(), verticalSides.back().IsLeft()); } /** * STEP 5: Horizontal edges **/ std::vector<HorizontalJunction> horizontalJunctions; horizontalJunctions.reserve(2 * verticalEdges.size()); for (std::list<Internals::OrientedIntegerLine2D>::const_iterator it = verticalEdges.begin(); it != verticalEdges.end(); ++it) { assert(it->GetX1() == it->GetX2()); horizontalJunctions.push_back(HorizontalJunction(it->GetX1(), it->GetY1(), it->GetY2(), it->IsDownward())); horizontalJunctions.push_back(HorizontalJunction(it->GetX1(), it->GetY2(), it->GetY1(), it->IsDownward())); } assert(horizontalJunctions.size() == 2 * verticalEdges.size()); std::sort(horizontalJunctions.begin(), horizontalJunctions.end()); std::list<Internals::OrientedIntegerLine2D> horizontalEdges; for (size_t i = 0; i < horizontalJunctions.size(); i += 2) { size_t x1 = horizontalJunctions[i].GetX(); size_t x2 = horizontalJunctions[i + 1].GetX(); size_t y = horizontalJunctions[i].GetY(); if ((horizontalJunctions[i].IsDownward() && y > horizontalJunctions[i].GetYBis()) || (!horizontalJunctions[i].IsDownward() && y < horizontalJunctions[i].GetYBis())) { horizontalEdges.push_back(Internals::OrientedIntegerLine2D(x1, y, x2, y)); } else { horizontalEdges.push_back(Internals::OrientedIntegerLine2D(x2, y, x1, y)); } } /** * POST-PROCESSING: Combine the separate sets of horizontal and * vertical edges, into a set of 2D chains **/ std::vector<Internals::OrientedIntegerLine2D> allEdges; allEdges.reserve(horizontalEdges.size() + verticalEdges.size()); for (std::list<Internals::OrientedIntegerLine2D>::const_iterator it = horizontalEdges.begin(); it != horizontalEdges.end(); ++it) { allEdges.push_back(*it); } for (std::list<Internals::OrientedIntegerLine2D>::const_iterator it = verticalEdges.begin(); it != verticalEdges.end(); ++it) { allEdges.push_back(*it); } assert(allEdges.size() == horizontalEdges.size() + verticalEdges.size()); std::list<Internals::OrientedIntegerLine2D::Chain> chains; Internals::OrientedIntegerLine2D::ExtractChains(chains, allEdges); for (std::list<Internals::OrientedIntegerLine2D::Chain>::const_iterator it = chains.begin(); it != chains.end(); ++it) { assert(!it->empty()); std::vector<ScenePoint2D> chain; chain.reserve(it->size()); for (Internals::OrientedIntegerLine2D::Chain::const_iterator it2 = it->begin(); it2 != it->end(); ++it2) { chain.push_back(ScenePoint2D(horizontalProjection.GetEndpointCoordinate(it2->first), verticalProjection.GetEndpointCoordinate(it2->second))); } assert(!chain.empty()); contours.push_back(chain); } } }