/**************************************************************************** ** ** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtOpenGL module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** Commercial Usage ** Licensees holding valid Qt Commercial licenses may use this file in ** accordance with the Qt Commercial License Agreement provided with the ** Software or, alternatively, in accordance with the terms contained in ** a written agreement between you and Nokia. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU ** General Public License version 3.0 as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU General Public License version 3.0 requirements will be ** met: http://www.gnu.org/copyleft/gpl.html. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qtriangulator_p.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include QT_BEGIN_NAMESPACE //#define Q_TRIANGULATOR_DEBUG #define Q_FIXED_POINT_SCALE 32 // Quick sort. template #ifdef Q_CC_RVCT // RVCT 2.2 doesn't see recursive _static_ template function void sort(T *array, int count, LessThan lessThan) #else static void sort(T *array, int count, LessThan lessThan) #endif { // If the number of elements fall below some threshold, use insertion sort. const int INSERTION_SORT_LIMIT = 7; // About 7 is fastest on my computer... if (count <= INSERTION_SORT_LIMIT) { for (int i = 1; i < count; ++i) { T temp = array[i]; int j = i; while (j > 0 && lessThan(temp, array[j - 1])) { array[j] = array[j - 1]; --j; } array[j] = temp; } return; } int high = count - 1; int low = 0; int mid = high / 2; if (lessThan(array[mid], array[low])) qSwap(array[mid], array[low]); if (lessThan(array[high], array[mid])) qSwap(array[high], array[mid]); if (lessThan(array[mid], array[low])) qSwap(array[mid], array[low]); --high; ++low; qSwap(array[mid], array[high]); int pivot = high; --high; while (low <= high) { while (!lessThan(array[pivot], array[low])) { ++low; if (low > high) goto sort_loop_end; } while (!lessThan(array[high], array[pivot])) { --high; if (low > high) goto sort_loop_end; } qSwap(array[low], array[high]); ++low; --high; } sort_loop_end: if (low != pivot) qSwap(array[pivot], array[low]); sort(array, low, lessThan); sort(array + low + 1, count - low - 1, lessThan); } // Quick sort. template #ifdef Q_CC_RVCT void sort(T *array, int count) // RVCT 2.2 doesn't see recursive _static_ template function #else static void sort(T *array, int count) #endif { // If the number of elements fall below some threshold, use insertion sort. const int INSERTION_SORT_LIMIT = 25; // About 25 is fastest on my computer... if (count <= INSERTION_SORT_LIMIT) { for (int i = 1; i < count; ++i) { T temp = array[i]; int j = i; while (j > 0 && (temp < array[j - 1])) { array[j] = array[j - 1]; --j; } array[j] = temp; } return; } int high = count - 1; int low = 0; int mid = high / 2; if ((array[mid] < array[low])) qSwap(array[mid], array[low]); if ((array[high] < array[mid])) qSwap(array[high], array[mid]); if ((array[mid] < array[low])) qSwap(array[mid], array[low]); --high; ++low; qSwap(array[mid], array[high]); int pivot = high; --high; while (low <= high) { while (!(array[pivot] < array[low])) { ++low; if (low > high) goto sort_loop_end; } while (!(array[high] < array[pivot])) { --high; if (low > high) goto sort_loop_end; } qSwap(array[low], array[high]); ++low; --high; } sort_loop_end: if (low != pivot) qSwap(array[pivot], array[low]); sort(array, low); sort(array + low + 1, count - low - 1); } //============================================================================// // QFraction // //============================================================================// // Fraction must be in the range [0, 1) struct QFraction { // Comparison operators must not be called on invalid fractions. inline bool operator < (const QFraction &other) const; inline bool operator == (const QFraction &other) const; inline bool operator != (const QFraction &other) const {return !(*this == other);} inline bool operator > (const QFraction &other) const {return other < *this;} inline bool operator >= (const QFraction &other) const {return !(*this < other);} inline bool operator <= (const QFraction &other) const {return !(*this > other);} inline bool isValid() const {return denominator != 0;} // numerator and denominator must not have common denominators. quint64 numerator, denominator; }; static inline quint64 gcd(quint64 x, quint64 y) { while (y != 0) { quint64 z = y; y = x % y; x = z; } return x; } static inline int compare(quint64 a, quint64 b) { return (a > b) - (a < b); } // Compare a/b with c/d. // Return negative if less, 0 if equal, positive if greater. // a < b, c < d static int qCompareFractions(quint64 a, quint64 b, quint64 c, quint64 d) { const quint64 LIMIT = Q_UINT64_C(0x100000000); for (;;) { // If the products 'ad' and 'bc' fit into 64 bits, they can be directly compared. if (b < LIMIT && d < LIMIT) return compare(a * d, b * c); if (a == 0 || c == 0) return compare(a, c); // a/b < c/d <=> d/c < b/a quint64 b_div_a = b / a; quint64 d_div_c = d / c; if (b_div_a != d_div_c) return compare(d_div_c, b_div_a); // floor(d/c) == floor(b/a) // frac(d/c) < frac(b/a) ? // frac(x/y) = (x%y)/y d -= d_div_c * c; //d %= c; b -= b_div_a * a; //b %= a; qSwap(a, d); qSwap(b, c); } } // Fraction must be in the range [0, 1) // Assume input is valid. static QFraction qFraction(quint64 n, quint64 d) { QFraction result; if (n == 0) { result.numerator = 0; result.denominator = 1; } else { quint64 g = gcd(n, d); result.numerator = n / g; result.denominator = d / g; } return result; } inline bool QFraction::operator < (const QFraction &other) const { return qCompareFractions(numerator, denominator, other.numerator, other.denominator) < 0; } inline bool QFraction::operator == (const QFraction &other) const { return numerator == other.numerator && denominator == other.denominator; } //============================================================================// // QPodPoint // //============================================================================// struct QPodPoint { inline bool operator < (const QPodPoint &other) const { if (y != other.y) return y < other.y; return x < other.x; } inline bool operator > (const QPodPoint &other) const {return other < *this;} inline bool operator <= (const QPodPoint &other) const {return !(*this > other);} inline bool operator >= (const QPodPoint &other) const {return !(*this < other);} inline bool operator == (const QPodPoint &other) const {return x == other.x && y == other.y;} inline bool operator != (const QPodPoint &other) const {return x != other.x || y != other.y;} inline QPodPoint &operator += (const QPodPoint &other) {x += other.x; y += other.y; return *this;} inline QPodPoint &operator -= (const QPodPoint &other) {x -= other.x; y -= other.y; return *this;} inline QPodPoint operator + (const QPodPoint &other) const {QPodPoint result = {x + other.x, y + other.y}; return result;} inline QPodPoint operator - (const QPodPoint &other) const {QPodPoint result = {x - other.x, y - other.y}; return result;} int x; int y; }; static inline qint64 qCross(const QPodPoint &u, const QPodPoint &v) { return qint64(u.x) * qint64(v.y) - qint64(u.y) * qint64(v.x); } static inline qint64 qDot(const QPodPoint &u, const QPodPoint &v) { return qint64(u.x) * qint64(v.x) + qint64(u.y) * qint64(v.y); } // Return positive value if 'p' is to the right of the line 'v1'->'v2', negative if left of the // line and zero if exactly on the line. // The returned value is the z-component of the qCross product between 'v2-v1' and 'p-v1', // which is twice the signed area of the triangle 'p'->'v1'->'v2' (positive for CW order). static inline qint64 qPointDistanceFromLine(const QPodPoint &p, const QPodPoint &v1, const QPodPoint &v2) { return qCross(v2 - v1, p - v1); } static inline bool qPointIsLeftOfLine(const QPodPoint &p, const QPodPoint &v1, const QPodPoint &v2) { return qPointDistanceFromLine(p, v1, v2) < 0; } // Return: // -1 if u < v // 0 if u == v // 1 if u > v static int comparePoints(const QPodPoint &u, const QPodPoint &v) { if (u.y < v.y) return -1; if (u.y > v.y) return 1; if (u.x < v.x) return -1; if (u.x > v.x) return 1; return 0; } //============================================================================// // QIntersectionPoint // //============================================================================// struct QIntersectionPoint { inline bool isValid() const {return xOffset.isValid() && yOffset.isValid();} QPodPoint round() const; inline bool isAccurate() const {return xOffset.numerator == 0 && yOffset.numerator == 0;} bool operator < (const QIntersectionPoint &other) const; bool operator == (const QIntersectionPoint &other) const; inline bool operator != (const QIntersectionPoint &other) const {return !(*this == other);} inline bool operator > (const QIntersectionPoint &other) const {return other < *this;} inline bool operator >= (const QIntersectionPoint &other) const {return !(*this < other);} inline bool operator <= (const QIntersectionPoint &other) const {return !(*this > other);} bool isOnLine(const QPodPoint &u, const QPodPoint &v) const; QPodPoint upperLeft; QFraction xOffset; QFraction yOffset; }; static inline QIntersectionPoint qIntersectionPoint(const QPodPoint &point) { // upperLeft = point, xOffset = 0/1, yOffset = 0/1. QIntersectionPoint p = {{point.x, point.y}, {0, 1}, {0, 1}}; return p; } static inline QIntersectionPoint qIntersectionPoint(int x, int y) { // upperLeft = (x, y), xOffset = 0/1, yOffset = 0/1. QIntersectionPoint p = {{x, y}, {0, 1}, {0, 1}}; return p; } static QIntersectionPoint qIntersectionPoint(const QPodPoint &u1, const QPodPoint &u2, const QPodPoint &v1, const QPodPoint &v2) { QIntersectionPoint result = {{0, 0}, {0, 0}, {0, 0}}; QPodPoint u = u2 - u1; QPodPoint v = v2 - v1; qint64 d1 = qCross(u, v1 - u1); qint64 d2 = qCross(u, v2 - u1); qint64 det = d2 - d1; qint64 d3 = qCross(v, u1 - v1); qint64 d4 = d3 - det; //qCross(v, u2 - v1); // Check that the math is correct. Q_ASSERT(d4 == qCross(v, u2 - v1)); // The intersection point can be expressed as: // v1 - v * d1/det // v2 - v * d2/det // u1 + u * d3/det // u2 + u * d4/det // I'm only interested in lines that are crossing, so ignore parallel lines even if they overlap. if (det == 0) return result; if (det < 0) { det = -det; d1 = -d1; d2 = -d2; d3 = -d3; d4 = -d4; } // I'm only interested in lines intersecting at their interior, not at their end points. // The lines intersect at their interior if and only if 'd1 < 0', 'd2 > 0', 'd3 < 0' and 'd4 > 0'. if (d1 >= 0 || d2 <= 0 || d3 <= 0 || d4 >= 0) return result; // Calculate the intersection point as follows: // v1 - v * d1/det | v1 <= v2 (component-wise) // v2 - v * d2/det | v2 < v1 (component-wise) // Assuming 21 bits per vector component. // TODO: Make code path for 31 bits per vector component. if (v.x >= 0) { result.upperLeft.x = v1.x + (-v.x * d1) / det; result.xOffset = qFraction(quint64(-v.x * d1) % quint64(det), quint64(det)); } else { result.upperLeft.x = v2.x + (-v.x * d2) / det; result.xOffset = qFraction(quint64(-v.x * d2) % quint64(det), quint64(det)); } if (v.y >= 0) { result.upperLeft.y = v1.y + (-v.y * d1) / det; result.yOffset = qFraction(quint64(-v.y * d1) % quint64(det), quint64(det)); } else { result.upperLeft.y = v2.y + (-v.y * d2) / det; result.yOffset = qFraction(quint64(-v.y * d2) % quint64(det), quint64(det)); } Q_ASSERT(result.xOffset.isValid()); Q_ASSERT(result.yOffset.isValid()); return result; } QPodPoint QIntersectionPoint::round() const { QPodPoint result = upperLeft; if (2 * xOffset.numerator >= xOffset.denominator) ++result.x; if (2 * yOffset.numerator >= yOffset.denominator) ++result.y; return result; } bool QIntersectionPoint::operator < (const QIntersectionPoint &other) const { if (upperLeft.y != other.upperLeft.y) return upperLeft.y < other.upperLeft.y; if (yOffset != other.yOffset) return yOffset < other.yOffset; if (upperLeft.x != other.upperLeft.x) return upperLeft.x < other.upperLeft.x; return xOffset < other.xOffset; } bool QIntersectionPoint::operator == (const QIntersectionPoint &other) const { return upperLeft == other.upperLeft && xOffset == other.xOffset && yOffset == other.yOffset; } // Returns true if this point is on the infinite line passing through 'u' and 'v'. bool QIntersectionPoint::isOnLine(const QPodPoint &u, const QPodPoint &v) const { // TODO: Make code path for coordinates with more than 21 bits. const QPodPoint p = upperLeft - u; const QPodPoint q = v - u; bool isHorizontal = p.y == 0 && yOffset.numerator == 0; bool isVertical = p.x == 0 && xOffset.numerator == 0; if (isHorizontal && isVertical) return true; if (isHorizontal) return q.y == 0; if (q.y == 0) return false; if (isVertical) return q.x == 0; if (q.x == 0) return false; // At this point, 'p+offset' and 'q' cannot lie on the x or y axis. if (((q.x < 0) == (q.y < 0)) != ((p.x < 0) == (p.y < 0))) return false; // 'p + offset' and 'q' pass through different quadrants. // Move all coordinates into the first quadrant. quint64 nx, ny; if (p.x < 0) nx = quint64(-p.x) * xOffset.denominator - xOffset.numerator; else nx = quint64(p.x) * xOffset.denominator + xOffset.numerator; if (p.y < 0) ny = quint64(-p.y) * yOffset.denominator - yOffset.numerator; else ny = quint64(p.y) * yOffset.denominator + yOffset.numerator; return qFraction(quint64(qAbs(q.x)) * xOffset.denominator, quint64(qAbs(q.y)) * yOffset.denominator) == qFraction(nx, ny); } //============================================================================// // QMaxHeap // //============================================================================// template class QMaxHeap { public: QMaxHeap() : m_data(0) {} inline int size() const {return m_data.size();} inline bool empty() const {return m_data.isEmpty();} inline bool isEmpty() const {return m_data.isEmpty();} void push(const T &x); T pop(); inline const T &top() const {return m_data.first();} private: static inline int parent(int i) {return (i - 1) / 2;} static inline int left(int i) {return 2 * i + 1;} static inline int right(int i) {return 2 * i + 2;} QDataBuffer m_data; }; template void QMaxHeap::push(const T &x) { int current = m_data.size(); int parent = QMaxHeap::parent(current); m_data.add(x); while (current != 0 && m_data.at(parent) < x) { m_data.at(current) = m_data.at(parent); current = parent; parent = QMaxHeap::parent(current); } m_data.at(current) = x; } template T QMaxHeap::pop() { T result = m_data.first(); T back = m_data.last(); m_data.pop_back(); if (!m_data.isEmpty()) { int current = 0; for (;;) { int left = QMaxHeap::left(current); int right = QMaxHeap::right(current); if (left >= m_data.size()) break; int greater = left; if (right < m_data.size() && m_data.at(left) < m_data.at(right)) greater = right; if (m_data.at(greater) < back) break; m_data.at(current) = m_data.at(greater); current = greater; } m_data.at(current) = back; } return result; } //============================================================================// // QRBTree // //============================================================================// template struct QRBTree { struct Node { inline Node() : parent(0), left(0), right(0), red(true) { } inline ~Node() {if (left) delete left; if (right) delete right;} T data; Node *parent; Node *left; Node *right; bool red; }; inline QRBTree() : root(0), freeList(0) { } inline ~QRBTree(); inline void clear(); void attachBefore(Node *parent, Node *child); void attachAfter(Node *parent, Node *child); inline Node *front(Node *node) const; inline Node *back(Node *node) const; Node *next(Node *node) const; Node *previous(Node *node) const; inline void deleteNode(Node *&node); inline Node *newNode(); // Return 1 if 'left' comes after 'right', 0 if equal, and -1 otherwise. // 'left' and 'right' cannot be null. int order(Node *left, Node *right); inline bool verify() const; private: void rotateLeft(Node *node); void rotateRight(Node *node); void update(Node *node); inline void attachLeft(Node *parent, Node *child); inline void attachRight(Node *parent, Node *child); int blackDepth(Node *top) const; bool checkRedBlackProperty(Node *top) const; void swapNodes(Node *n1, Node *n2); void detach(Node *node); // 'node' must be black. rebalance will reduce the depth of black nodes by one in the sibling tree. void rebalance(Node *node); public: Node *root; private: Node *freeList; }; template inline QRBTree::~QRBTree() { clear(); while (freeList) { // Avoid recursively calling the destructor, as this list may become large. Node *next = freeList->right; freeList->right = 0; delete freeList; freeList = next; } } template inline void QRBTree::clear() { if (root) delete root; root = 0; } template void QRBTree::rotateLeft(Node *node) { // | | // // N B // // / \ / \ // // A B ---> N D // // / \ / \ // // C D A C // Node *&ref = (node->parent ? (node == node->parent->left ? node->parent->left : node->parent->right) : root); ref = node->right; node->right->parent = node->parent; // : // // N // // / :| // // A B // // / \ // // C D // node->right = ref->left; if (ref->left) ref->left->parent = node; // : | // // N B // // / \ : \ // // A C D // ref->left = node; node->parent = ref; // | // // B // // / \ // // N D // // / \ // // A C // } template void QRBTree::rotateRight(Node *node) { // | | // // N A // // / \ / \ // // A B ---> C N // // / \ / \ // // C D D B // Node *&ref = (node->parent ? (node == node->parent->left ? node->parent->left : node->parent->right) : root); ref = node->left; node->left->parent = node->parent; node->left = ref->right; if (ref->right) ref->right->parent = node; ref->right = node; node->parent = ref; } template void QRBTree::update(Node *node) // call this after inserting a node { for (;;) { Node *parent = node->parent; // if the node is the root, color it black if (!parent) { node->red = false; return; } // if the parent is black, the node can be left red if (!parent->red) return; // at this point, the parent is red and cannot be the root Node *grandpa = parent->parent; Q_ASSERT(grandpa); Node *uncle = (parent == grandpa->left ? grandpa->right : grandpa->left); if (uncle && uncle->red) { // grandpa's black, parent and uncle are red. // let parent and uncle be black, grandpa red and recursively update grandpa. Q_ASSERT(!grandpa->red); parent->red = false; uncle->red = false; grandpa->red = true; node = grandpa; continue; } // at this point, uncle is black if (node == parent->right && parent == grandpa->left) rotateLeft(node = parent); else if (node == parent->left && parent == grandpa->right) rotateRight(node = parent); parent = node->parent; if (parent == grandpa->left) { rotateRight(grandpa); parent->red = false; grandpa->red = true; } else { rotateLeft(grandpa); parent->red = false; grandpa->red = true; } return; } } template inline void QRBTree::attachLeft(Node *parent, Node *child) { Q_ASSERT(!parent->left); parent->left = child; child->parent = parent; update(child); } template inline void QRBTree::attachRight(Node *parent, Node *child) { Q_ASSERT(!parent->right); parent->right = child; child->parent = parent; update(child); } template void QRBTree::attachBefore(Node *parent, Node *child) { if (!root) update(root = child); else if (!parent) attachRight(back(root), child); else if (parent->left) attachRight(back(parent->left), child); else attachLeft(parent, child); } template void QRBTree::attachAfter(Node *parent, Node *child) { if (!root) update(root = child); else if (!parent) attachLeft(front(root), child); else if (parent->right) attachLeft(front(parent->right), child); else attachRight(parent, child); } template void QRBTree::swapNodes(Node *n1, Node *n2) { // Since iterators must not be invalidated, it is not sufficient to only swap the data. if (n1->parent == n2) { n1->parent = n2->parent; n2->parent = n1; } else if (n2->parent == n1) { n2->parent = n1->parent; n1->parent = n2; } else { qSwap(n1->parent, n2->parent); } qSwap(n1->left, n2->left); qSwap(n1->right, n2->right); qSwap(n1->red, n2->red); if (n1->parent) { if (n1->parent->left == n2) n1->parent->left = n1; else n1->parent->right = n1; } else { root = n1; } if (n2->parent) { if (n2->parent->left == n1) n2->parent->left = n2; else n2->parent->right = n2; } else { root = n2; } if (n1->left) n1->left->parent = n1; if (n1->right) n1->right->parent = n1; if (n2->left) n2->left->parent = n2; if (n2->right) n2->right->parent = n2; } template void QRBTree::detach(Node *node) // call this before removing a node. { if (node->right) swapNodes(node, front(node->right)); Node *child = (node->left ? node->left : node->right); if (!node->red) { if (child && child->red) child->red = false; else rebalance(node); } Node *&ref = (node->parent ? (node == node->parent->left ? node->parent->left : node->parent->right) : root); ref = child; if (child) child->parent = node->parent; node->left = node->right = node->parent = 0; } // 'node' must be black. rebalance will reduce the depth of black nodes by one in the sibling tree. template void QRBTree::rebalance(Node *node) { Q_ASSERT(!node->red); for (;;) { if (!node->parent) return; // at this point, node is not a parent, it is black, thus it must have a sibling. Node *sibling = (node == node->parent->left ? node->parent->right : node->parent->left); Q_ASSERT(sibling); if (sibling->red) { sibling->red = false; node->parent->red = true; if (node == node->parent->left) rotateLeft(node->parent); else rotateRight(node->parent); sibling = (node == node->parent->left ? node->parent->right : node->parent->left); Q_ASSERT(sibling); } // at this point, the sibling is black. Q_ASSERT(!sibling->red); if ((!sibling->left || !sibling->left->red) && (!sibling->right || !sibling->right->red)) { bool parentWasRed = node->parent->red; sibling->red = true; node->parent->red = false; if (parentWasRed) return; node = node->parent; continue; } // at this point, at least one of the sibling's children is red. if (node == node->parent->left) { if (!sibling->right || !sibling->right->red) { Q_ASSERT(sibling->left); sibling->red = true; sibling->left->red = false; rotateRight(sibling); sibling = sibling->parent; Q_ASSERT(sibling); } sibling->red = node->parent->red; node->parent->red = false; Q_ASSERT(sibling->right->red); sibling->right->red = false; rotateLeft(node->parent); } else { if (!sibling->left || !sibling->left->red) { Q_ASSERT(sibling->right); sibling->red = true; sibling->right->red = false; rotateLeft(sibling); sibling = sibling->parent; Q_ASSERT(sibling); } sibling->red = node->parent->red; node->parent->red = false; Q_ASSERT(sibling->left->red); sibling->left->red = false; rotateRight(node->parent); } return; } } template inline typename QRBTree::Node *QRBTree::front(Node *node) const { while (node->left) node = node->left; return node; } template inline typename QRBTree::Node *QRBTree::back(Node *node) const { while (node->right) node = node->right; return node; } template typename QRBTree::Node *QRBTree::next(Node *node) const { if (node->right) return front(node->right); while (node->parent && node == node->parent->right) node = node->parent; return node->parent; } template typename QRBTree::Node *QRBTree::previous(Node *node) const { if (node->left) return back(node->left); while (node->parent && node == node->parent->left) node = node->parent; return node->parent; } template int QRBTree::blackDepth(Node *top) const { if (!top) return 0; int leftDepth = blackDepth(top->left); int rightDepth = blackDepth(top->right); if (leftDepth != rightDepth) return -1; if (!top->red) ++leftDepth; return leftDepth; } template bool QRBTree::checkRedBlackProperty(Node *top) const { if (!top) return true; if (top->left && !checkRedBlackProperty(top->left)) return false; if (top->right && !checkRedBlackProperty(top->right)) return false; return !(top->red && ((top->left && top->left->red) || (top->right && top->right->red))); } template inline bool QRBTree::verify() const { return checkRedBlackProperty(root) && blackDepth(root) != -1; } template inline void QRBTree::deleteNode(Node *&node) { Q_ASSERT(node); detach(node); node->right = freeList; freeList = node; node = 0; } template inline typename QRBTree::Node *QRBTree::newNode() { if (freeList) { Node *node = freeList; freeList = freeList->right; node->parent = node->left = node->right = 0; node->red = true; return node; } return new Node; } // Return 1 if 'left' comes after 'right', 0 if equal, and -1 otherwise. // 'left' and 'right' cannot be null. template int QRBTree::order(Node *left, Node *right) { Q_ASSERT(left && right); if (left == right) return 0; QVector leftAncestors; QVector rightAncestors; while (left) { leftAncestors.push_back(left); left = left->parent; } while (right) { rightAncestors.push_back(right); right = right->parent; } Q_ASSERT(leftAncestors.back() == root && rightAncestors.back() == root); while (!leftAncestors.empty() && !rightAncestors.empty() && leftAncestors.back() == rightAncestors.back()) { leftAncestors.pop_back(); rightAncestors.pop_back(); } if (!leftAncestors.empty()) return (leftAncestors.back() == leftAncestors.back()->parent->left ? -1 : 1); if (!rightAncestors.empty()) return (rightAncestors.back() == rightAncestors.back()->parent->right ? -1 : 1); // The code should never reach this point. Q_ASSERT(!leftAncestors.empty() || !rightAncestors.empty()); return 0; } //============================================================================// // QInt64Hash // //============================================================================// // Copied from qhash.cpp static const uchar prime_deltas[] = { 0, 0, 1, 3, 1, 5, 3, 3, 1, 9, 7, 5, 3, 9, 25, 3, 1, 21, 3, 21, 7, 15, 9, 5, 3, 29, 15, 0, 0, 0, 0, 0 }; // Copied from qhash.cpp static inline int primeForNumBits(int numBits) { return (1 << numBits) + prime_deltas[numBits]; } static inline int primeForCount(int count) { int low = 0; int high = 32; for (int i = 0; i < 5; ++i) { int mid = (high + low) / 2; if (count >= 1 << mid) low = mid; else high = mid; } return primeForNumBits(high); } // Hash set of quint64s. Elements cannot be removed without clearing the // entire set. A value of -1 is used to mark unused entries. class QInt64Set { public: inline QInt64Set(int capacity = 64); inline ~QInt64Set() {if (m_array) delete[] m_array;} inline bool isValid() const {return m_array;} void insert(quint64 key); bool contains(quint64 key) const; inline void clear(); private: bool rehash(int capacity); static const quint64 UNUSED; quint64 *m_array; int m_capacity; int m_count; }; const quint64 QInt64Set::UNUSED = quint64(-1); inline QInt64Set::QInt64Set(int capacity) { m_capacity = primeForCount(capacity); m_array = new quint64[m_capacity]; if (m_array) clear(); else m_capacity = 0; } bool QInt64Set::rehash(int capacity) { quint64 *oldArray = m_array; int oldCapacity = m_capacity; m_capacity = capacity; m_array = new quint64[m_capacity]; if (m_array) { clear(); if (oldArray) { for (int i = 0; i < oldCapacity; ++i) { if (oldArray[i] != UNUSED) insert(oldArray[i]); } delete[] oldArray; } return true; } else { m_capacity = oldCapacity; m_array = oldArray; return false; } } void QInt64Set::insert(quint64 key) { if (m_count > 3 * m_capacity / 4) rehash(primeForCount(2 * m_capacity)); Q_ASSERT_X(m_array, "QInt64Hash::insert", "Hash set not allocated."); int index = int(key % m_capacity); for (int i = 0; i < m_capacity; ++i) { index += i; if (index >= m_capacity) index -= m_capacity; if (m_array[index] == key) return; if (m_array[index] == UNUSED) { ++m_count; m_array[index] = key; return; } } Q_ASSERT_X(0, "QInt64Hash::insert", "Hash set full."); } bool QInt64Set::contains(quint64 key) const { Q_ASSERT_X(m_array, "QInt64Hash::contains", "Hash set not allocated."); int index = int(key % m_capacity); for (int i = 0; i < m_capacity; ++i) { index += i; if (index >= m_capacity) index -= m_capacity; if (m_array[index] == key) return true; if (m_array[index] == UNUSED) return false; } return false; } inline void QInt64Set::clear() { Q_ASSERT_X(m_array, "QInt64Hash::clear", "Hash set not allocated."); for (int i = 0; i < m_capacity; ++i) m_array[i] = UNUSED; m_count = 0; } //============================================================================// // QRingBuffer // //============================================================================// // T must be POD. template class QRingBuffer { public: inline QRingBuffer() : m_array(0), m_head(0), m_size(0), m_capacity(0) { } inline ~QRingBuffer() {if (m_array) delete[] m_array;} bool reallocate(int capacity); inline const T &head() const {Q_ASSERT(m_size > 0); return m_array[m_head];} inline const T &dequeue(); inline void enqueue(const T &x); inline bool isEmpty() const {return m_size == 0;} private: T *m_array; int m_head; int m_size; int m_capacity; }; template bool QRingBuffer::reallocate(int capacity) { T *oldArray = m_array; m_array = new T[capacity]; if (m_array) { if (oldArray) { if (m_head + m_size > m_capacity) { memcpy(m_array, oldArray + m_head, (m_capacity - m_head) * sizeof(T)); memcpy(m_array + (m_capacity - m_head), oldArray, (m_head + m_size - m_capacity) * sizeof(T)); } else { memcpy(m_array, oldArray + m_head, m_size * sizeof(T)); } delete[] oldArray; } m_capacity = capacity; m_head = 0; return true; } else { m_array = oldArray; return false; } } template inline const T &QRingBuffer::dequeue() { Q_ASSERT(m_size > 0); Q_ASSERT(m_array); Q_ASSERT(m_capacity >= m_size); int index = m_head; if (++m_head >= m_capacity) m_head -= m_capacity; --m_size; return m_array[index]; } template inline void QRingBuffer::enqueue(const T &x) { if (m_size == m_capacity) reallocate(qMax(2 * m_capacity, 64)); int index = m_head + m_size; if (index >= m_capacity) index -= m_capacity; m_array[index] = x; ++m_size; } //============================================================================// // QTriangulator // //============================================================================// class QTriangulator { public: typedef QVarLengthArray ShortArray; //================================// // QTriangulator::ComplexToSimple // //================================// friend class ComplexToSimple; class ComplexToSimple { public: inline ComplexToSimple(QTriangulator *parent) : m_parent(parent), m_edges(0), m_events(0), m_splits(0) { } void decompose(); private: struct Edge { inline int &upper() {return pointingUp ? to : from;} inline int &lower() {return pointingUp ? from : to;} inline int upper() const {return pointingUp ? to : from;} inline int lower() const {return pointingUp ? from : to;} QRBTree::Node *node; int from, to; // vertex int next, previous; // edge int winding; bool mayIntersect; bool pointingUp, originallyPointingUp; }; friend class CompareEdges; class CompareEdges { public: inline CompareEdges(ComplexToSimple *parent) : m_parent(parent) { } bool operator () (int i, int j) const; private: ComplexToSimple *m_parent; }; struct Intersection { bool operator < (const Intersection &other) const {return other.intersectionPoint < intersectionPoint;} QIntersectionPoint intersectionPoint; int vertex; int leftEdge; int rightEdge; }; struct Split { int vertex; int edge; bool accurate; }; struct Event { enum Type {Upper, Lower}; inline bool operator < (const Event &other) const; QPodPoint point; Type type; int edge; }; #ifdef Q_TRIANGULATOR_DEBUG friend class DebugDialog; friend class QTriangulator; class DebugDialog : public QDialog { public: DebugDialog(ComplexToSimple *parent, int currentVertex); protected: void paintEvent(QPaintEvent *); void wheelEvent(QWheelEvent *); void mouseMoveEvent(QMouseEvent *); void mousePressEvent(QMouseEvent *); private: ComplexToSimple *m_parent; QRectF m_window; QPoint m_lastMousePos; int m_vertex; }; #endif void initEdges(); bool calculateIntersection(int left, int right); bool edgeIsLeftOfEdge(int leftEdgeIndex, int rightEdgeIndex) const; QRBTree::Node *searchEdgeLeftOf(int edgeIndex) const; QRBTree::Node *searchEdgeLeftOf(int edgeIndex, QRBTree::Node *after) const; QPair::Node *, QRBTree::Node *> bounds(const QPodPoint &point) const; QPair::Node *, QRBTree::Node *> outerBounds(const QPodPoint &point) const; void splitEdgeListRange(QRBTree::Node *leftmost, QRBTree::Node *rightmost, int vertex, const QIntersectionPoint &intersectionPoint); void reorderEdgeListRange(QRBTree::Node *leftmost, QRBTree::Node *rightmost); void sortEdgeList(const QPodPoint eventPoint); void fillPriorityQueue(); void calculateIntersections(); int splitEdge(int splitIndex); bool splitEdgesAtIntersections(); void insertEdgeIntoVectorIfWanted(ShortArray &orderedEdges, int i); void removeUnwantedEdgesAndConnect(); void removeUnusedPoints(); QTriangulator *m_parent; QDataBuffer m_edges; QRBTree m_edgeList; QDataBuffer m_events; QDataBuffer m_splits; QMaxHeap m_topIntersection; QInt64Set m_processedEdgePairs; int m_initialPointCount; }; #ifdef Q_TRIANGULATOR_DEBUG friend class ComplexToSimple::DebugDialog; #endif //=================================// // QTriangulator::SimpleToMonotone // //=================================// friend class SimpleToMonotone; class SimpleToMonotone { public: inline SimpleToMonotone(QTriangulator *parent) : m_parent(parent), m_edges(0), m_upperVertex(0) { } void decompose(); private: enum VertexType {MergeVertex, EndVertex, RegularVertex, StartVertex, SplitVertex}; struct Edge { QRBTree::Node *node; int helper, twin, next, previous; quint32 from, to; VertexType type; bool pointingUp; int upper() const {return (pointingUp ? to : from);} int lower() const {return (pointingUp ? from : to);} }; friend class CompareVertices; class CompareVertices { public: CompareVertices(SimpleToMonotone *parent) : m_parent(parent) { } bool operator () (int i, int j) const; private: SimpleToMonotone *m_parent; }; void setupDataStructures(); void removeZeroLengthEdges(); void fillPriorityQueue(); bool edgeIsLeftOfEdge(int leftEdgeIndex, int rightEdgeIndex) const; // Returns the rightmost edge not to the right of the given edge. QRBTree::Node *searchEdgeLeftOfEdge(int edgeIndex) const; // Returns the rightmost edge left of the given point. QRBTree::Node *searchEdgeLeftOfPoint(int pointIndex) const; void classifyVertex(int i); void classifyVertices(); bool pointIsInSector(const QPodPoint &p, const QPodPoint &v1, const QPodPoint &v2, const QPodPoint &v3); bool pointIsInSector(int vertex, int sector); int findSector(int edge, int vertex); void createDiagonal(int lower, int upper); void monotoneDecomposition(); QTriangulator *m_parent; QRBTree m_edgeList; QDataBuffer m_edges; QDataBuffer m_upperVertex; bool m_clockwiseOrder; }; //====================================// // QTriangulator::MonotoneToTriangles // //====================================// friend class MonotoneToTriangles; class MonotoneToTriangles { public: inline MonotoneToTriangles(QTriangulator *parent) : m_parent(parent) { } void decompose(); private: inline quint32 indices(int index) const {return m_parent->m_indices.at(index + m_first);} inline int next(int index) const {return (index + 1) % m_length;} inline int previous(int index) const {return (index + m_length - 1) % m_length;} inline bool less(int i, int j) const {return m_parent->m_vertices.at(indices(i)) < m_parent->m_vertices.at(indices(j));} inline bool leftOfEdge(int i, int j, int k) const { return qPointIsLeftOfLine(m_parent->m_vertices.at(indices(i)), m_parent->m_vertices.at(indices(j)), m_parent->m_vertices.at(indices(k))); } QTriangulator *m_parent; int m_first; int m_length; }; inline QTriangulator() : m_vertices(0) { } // Call this only once. void initialize(const qreal *polygon, int count, uint hint, const QTransform &matrix); // Call this only once. void initialize(const QVectorPath &path, const QTransform &matrix, qreal lod); // Call this only once. void initialize(const QPainterPath &path, const QTransform &matrix, qreal lod); // Call either triangulate() or polyline() only once. QTriangleSet triangulate(); QPolylineSet polyline(); private: QDataBuffer m_vertices; QVector m_indices; uint m_hint; }; //============================================================================// // QTriangulator // //============================================================================// QTriangleSet QTriangulator::triangulate() { for (int i = 0; i < m_vertices.size(); ++i) { Q_ASSERT(qAbs(m_vertices.at(i).x) < (1 << 21)); Q_ASSERT(qAbs(m_vertices.at(i).y) < (1 << 21)); } if (!(m_hint & (QVectorPath::OddEvenFill | QVectorPath::WindingFill))) m_hint |= QVectorPath::OddEvenFill; if (m_hint & QVectorPath::NonConvexShapeMask) { ComplexToSimple c2s(this); c2s.decompose(); SimpleToMonotone s2m(this); s2m.decompose(); } MonotoneToTriangles m2t(this); m2t.decompose(); QTriangleSet result; result.indices = m_indices; result.vertices.resize(2 * m_vertices.size()); for (int i = 0; i < m_vertices.size(); ++i) { result.vertices[2 * i + 0] = qreal(m_vertices.at(i).x) / Q_FIXED_POINT_SCALE; result.vertices[2 * i + 1] = qreal(m_vertices.at(i).y) / Q_FIXED_POINT_SCALE; } return result; } QPolylineSet QTriangulator::polyline() { QPolylineSet result; result.indices = m_indices; result.vertices.resize(2 * m_vertices.size()); for (int i = 0; i < m_vertices.size(); ++i) { result.vertices[2 * i + 0] = qreal(m_vertices.at(i).x) / Q_FIXED_POINT_SCALE; result.vertices[2 * i + 1] = qreal(m_vertices.at(i).y) / Q_FIXED_POINT_SCALE; } return result; } void QTriangulator::initialize(const qreal *polygon, int count, uint hint, const QTransform &matrix) { m_hint = hint; m_vertices.resize(count); m_indices.resize(count + 1); for (int i = 0; i < count; ++i) { qreal x, y; matrix.map(polygon[2 * i + 0], polygon[2 * i + 1], &x, &y); m_vertices.at(i).x = qRound(x * Q_FIXED_POINT_SCALE); m_vertices.at(i).y = qRound(y * Q_FIXED_POINT_SCALE); m_indices[i] = i; } m_indices[count] = Q_TRIANGULATE_END_OF_POLYGON; } void QTriangulator::initialize(const QVectorPath &path, const QTransform &matrix, qreal lod) { m_hint = path.hints(); // Curved paths will be converted to complex polygons. m_hint &= ~QVectorPath::CurvedShapeMask; const qreal *p = path.points(); const QPainterPath::ElementType *e = path.elements(); if (e) { for (int i = 0; i < path.elementCount(); ++i, ++e, p += 2) { switch (*e) { case QPainterPath::MoveToElement: if (!m_indices.isEmpty()) m_indices.push_back(Q_TRIANGULATE_END_OF_POLYGON); // Fall through. case QPainterPath::LineToElement: m_indices.push_back(quint32(m_vertices.size())); m_vertices.resize(m_vertices.size() + 1); qreal x, y; matrix.map(p[0], p[1], &x, &y); m_vertices.last().x = qRound(x * Q_FIXED_POINT_SCALE); m_vertices.last().y = qRound(y * Q_FIXED_POINT_SCALE); break; case QPainterPath::CurveToElement: { qreal pts[8]; for (int i = 0; i < 4; ++i) matrix.map(p[2 * i - 2], p[2 * i - 1], &pts[2 * i + 0], &pts[2 * i + 1]); for (int i = 0; i < 8; ++i) pts[i] *= lod; QBezier bezier = QBezier::fromPoints(QPointF(pts[0], pts[1]), QPointF(pts[2], pts[3]), QPointF(pts[4], pts[5]), QPointF(pts[6], pts[7])); QPolygonF poly = bezier.toPolygon(); // Skip first point, it already exists in 'm_vertices'. for (int j = 1; j < poly.size(); ++j) { m_indices.push_back(quint32(m_vertices.size())); m_vertices.resize(m_vertices.size() + 1); m_vertices.last().x = qRound(poly.at(j).x() * Q_FIXED_POINT_SCALE / lod); m_vertices.last().y = qRound(poly.at(j).y() * Q_FIXED_POINT_SCALE / lod); } } i += 2; e += 2; p += 4; break; default: Q_ASSERT_X(0, "QTriangulator::triangulate", "Unexpected element type."); break; } } } else { for (int i = 0; i < path.elementCount(); ++i, p += 2) { m_indices.push_back(quint32(m_vertices.size())); m_vertices.resize(m_vertices.size() + 1); qreal x, y; matrix.map(p[0], p[1], &x, &y); m_vertices.last().x = qRound(x * Q_FIXED_POINT_SCALE); m_vertices.last().y = qRound(y * Q_FIXED_POINT_SCALE); } } m_indices.push_back(Q_TRIANGULATE_END_OF_POLYGON); } void QTriangulator::initialize(const QPainterPath &path, const QTransform &matrix, qreal lod) { initialize(qtVectorPathForPath(path), matrix, lod); } //============================================================================// // QTriangulator::ComplexToSimple // //============================================================================// void QTriangulator::ComplexToSimple::decompose() { m_initialPointCount = m_parent->m_vertices.size(); initEdges(); do { calculateIntersections(); } while (splitEdgesAtIntersections()); removeUnwantedEdgesAndConnect(); removeUnusedPoints(); m_parent->m_indices.clear(); QBitArray processed(m_edges.size(), false); for (int first = 0; first < m_edges.size(); ++first) { // If already processed, or if unused path, skip. if (processed.at(first) || m_edges.at(first).next == -1) continue; int i = first; do { Q_ASSERT(!processed.at(i)); Q_ASSERT(m_edges.at(m_edges.at(i).next).previous == i); m_parent->m_indices.push_back(m_edges.at(i).from); processed.setBit(i); i = m_edges.at(i).next; // CCW order } while (i != first); m_parent->m_indices.push_back(Q_TRIANGULATE_END_OF_POLYGON); } } void QTriangulator::ComplexToSimple::initEdges() { // Initialize edge structure. // 'next' and 'previous' are not being initialized at this point. int first = 0; for (int i = 0; i < m_parent->m_indices.size(); ++i) { if (m_parent->m_indices.at(i) == Q_TRIANGULATE_END_OF_POLYGON) { if (m_edges.size() != first) m_edges.last().to = m_edges.at(first).from; first = m_edges.size(); } else { Q_ASSERT(i + 1 < m_parent->m_indices.size()); // {node, from, to, next, previous, winding, mayIntersect, pointingUp, originallyPointingUp} Edge edge = {0, m_parent->m_indices.at(i), m_parent->m_indices.at(i + 1), -1, -1, 0, true, false, false}; m_edges.add(edge); } } if (first != m_edges.size()) m_edges.last().to = m_edges.at(first).from; for (int i = 0; i < m_edges.size(); ++i) { m_edges.at(i).originallyPointingUp = m_edges.at(i).pointingUp = m_parent->m_vertices.at(m_edges.at(i).to) < m_parent->m_vertices.at(m_edges.at(i).from); } } // Return true if new intersection was found bool QTriangulator::ComplexToSimple::calculateIntersection(int left, int right) { const Edge &e1 = m_edges.at(left); const Edge &e2 = m_edges.at(right); const QPodPoint &u1 = m_parent->m_vertices.at(e1.from); const QPodPoint &u2 = m_parent->m_vertices.at(e1.to); const QPodPoint &v1 = m_parent->m_vertices.at(e2.from); const QPodPoint &v2 = m_parent->m_vertices.at(e2.to); if (qMax(u1.x, u2.x) <= qMin(v1.x, v2.x)) return false; quint64 key = (left > right ? (quint64(right) << 32) | quint64(left) : (quint64(left) << 32) | quint64(right)); if (m_processedEdgePairs.contains(key)) return false; m_processedEdgePairs.insert(key); Intersection intersection; intersection.leftEdge = left; intersection.rightEdge = right; intersection.intersectionPoint = qIntersectionPoint(u1, u2, v1, v2); if (!intersection.intersectionPoint.isValid()) return false; Q_ASSERT(intersection.intersectionPoint.isOnLine(u1, u2)); Q_ASSERT(intersection.intersectionPoint.isOnLine(v1, v2)); intersection.vertex = m_parent->m_vertices.size(); m_topIntersection.push(intersection); m_parent->m_vertices.add(intersection.intersectionPoint.round()); return true; } bool QTriangulator::ComplexToSimple::edgeIsLeftOfEdge(int leftEdgeIndex, int rightEdgeIndex) const { const Edge &leftEdge = m_edges.at(leftEdgeIndex); const Edge &rightEdge = m_edges.at(rightEdgeIndex); const QPodPoint &u = m_parent->m_vertices.at(rightEdge.upper()); const QPodPoint &l = m_parent->m_vertices.at(rightEdge.lower()); const QPodPoint &upper = m_parent->m_vertices.at(leftEdge.upper()); if (upper.x < qMin(l.x, u.x)) return true; if (upper.x > qMax(l.x, u.x)) return false; qint64 d = qPointDistanceFromLine(upper, l, u); // d < 0: left, d > 0: right, d == 0: on top if (d == 0) d = qPointDistanceFromLine(m_parent->m_vertices.at(leftEdge.lower()), l, u); return d < 0; } QRBTree::Node *QTriangulator::ComplexToSimple::searchEdgeLeftOf(int edgeIndex) const { QRBTree::Node *current = m_edgeList.root; QRBTree::Node *result = 0; while (current) { if (edgeIsLeftOfEdge(edgeIndex, current->data)) { current = current->left; } else { result = current; current = current->right; } } return result; } QRBTree::Node *QTriangulator::ComplexToSimple::searchEdgeLeftOf(int edgeIndex, QRBTree::Node *after) const { if (!m_edgeList.root) return after; QRBTree::Node *result = after; QRBTree::Node *current = (after ? m_edgeList.next(after) : m_edgeList.front(m_edgeList.root)); while (current) { if (edgeIsLeftOfEdge(edgeIndex, current->data)) return result; result = current; current = m_edgeList.next(current); } return result; } QPair::Node *, QRBTree::Node *> QTriangulator::ComplexToSimple::bounds(const QPodPoint &point) const { QRBTree::Node *current = m_edgeList.root; QPair::Node *, QRBTree::Node *> result(0, 0); while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); if (d == 0) { result.first = result.second = current; break; } current = (d < 0 ? current->left : current->right); } if (current == 0) return result; current = result.first->left; while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); Q_ASSERT(d >= 0); if (d == 0) { result.first = current; current = current->left; } else { current = current->right; } } current = result.second->right; while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); Q_ASSERT(d <= 0); if (d == 0) { result.second = current; current = current->right; } else { current = current->left; } } return result; } QPair::Node *, QRBTree::Node *> QTriangulator::ComplexToSimple::outerBounds(const QPodPoint &point) const { QRBTree::Node *current = m_edgeList.root; QPair::Node *, QRBTree::Node *> result(0, 0); while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); if (d == 0) break; if (d < 0) { result.second = current; current = current->left; } else { result.first = current; current = current->right; } } if (!current) return result; QRBTree::Node *mid = current; current = mid->left; while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); Q_ASSERT(d >= 0); if (d == 0) { current = current->left; } else { result.first = current; current = current->right; } } current = mid->right; while (current) { const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &v2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(point, v1, v2); Q_ASSERT(d <= 0); if (d == 0) { current = current->right; } else { result.second = current; current = current->left; } } return result; } void QTriangulator::ComplexToSimple::splitEdgeListRange(QRBTree::Node *leftmost, QRBTree::Node *rightmost, int vertex, const QIntersectionPoint &intersectionPoint) { Q_ASSERT(leftmost && rightmost); // Split. for (;;) { const QPodPoint &u = m_parent->m_vertices.at(m_edges.at(leftmost->data).from); const QPodPoint &v = m_parent->m_vertices.at(m_edges.at(leftmost->data).to); Q_ASSERT(intersectionPoint.isOnLine(u, v)); const Split split = {vertex, leftmost->data, intersectionPoint.isAccurate()}; if (intersectionPoint.xOffset.numerator != 0 || intersectionPoint.yOffset.numerator != 0 || (intersectionPoint.upperLeft != u && intersectionPoint.upperLeft != v)) m_splits.add(split); if (leftmost == rightmost) break; leftmost = m_edgeList.next(leftmost); } } void QTriangulator::ComplexToSimple::reorderEdgeListRange(QRBTree::Node *leftmost, QRBTree::Node *rightmost) { Q_ASSERT(leftmost && rightmost); QRBTree::Node *storeLeftmost = leftmost; QRBTree::Node *storeRightmost = rightmost; // Reorder. while (leftmost != rightmost) { Edge &left = m_edges.at(leftmost->data); Edge &right = m_edges.at(rightmost->data); qSwap(left.node, right.node); qSwap(leftmost->data, rightmost->data); leftmost = m_edgeList.next(leftmost); if (leftmost == rightmost) break; rightmost = m_edgeList.previous(rightmost); } rightmost = m_edgeList.next(storeRightmost); leftmost = m_edgeList.previous(storeLeftmost); if (leftmost) calculateIntersection(leftmost->data, storeLeftmost->data); if (rightmost) calculateIntersection(storeRightmost->data, rightmost->data); } void QTriangulator::ComplexToSimple::sortEdgeList(const QPodPoint eventPoint) { QIntersectionPoint eventPoint2 = qIntersectionPoint(eventPoint); while (!m_topIntersection.isEmpty() && m_topIntersection.top().intersectionPoint < eventPoint2) { Intersection intersection = m_topIntersection.pop(); QIntersectionPoint currentIntersectionPoint = intersection.intersectionPoint; int currentVertex = intersection.vertex; QRBTree::Node *leftmost = m_edges.at(intersection.leftEdge).node; QRBTree::Node *rightmost = m_edges.at(intersection.rightEdge).node; for (;;) { QRBTree::Node *previous = m_edgeList.previous(leftmost); if (!previous) break; const Edge &edge = m_edges.at(previous->data); const QPodPoint &u = m_parent->m_vertices.at(edge.from); const QPodPoint &v = m_parent->m_vertices.at(edge.to); if (!currentIntersectionPoint.isOnLine(u, v)) { Q_ASSERT(!currentIntersectionPoint.isAccurate() || qCross(currentIntersectionPoint.upperLeft - u, v - u) != 0); break; } leftmost = previous; } for (;;) { QRBTree::Node *next = m_edgeList.next(rightmost); if (!next) break; const Edge &edge = m_edges.at(next->data); const QPodPoint &u = m_parent->m_vertices.at(edge.from); const QPodPoint &v = m_parent->m_vertices.at(edge.to); if (!currentIntersectionPoint.isOnLine(u, v)) { Q_ASSERT(!currentIntersectionPoint.isAccurate() || qCross(currentIntersectionPoint.upperLeft - u, v - u) != 0); break; } rightmost = next; } Q_ASSERT(leftmost && rightmost); splitEdgeListRange(leftmost, rightmost, currentVertex, currentIntersectionPoint); reorderEdgeListRange(leftmost, rightmost); while (!m_topIntersection.isEmpty() && m_topIntersection.top().intersectionPoint <= currentIntersectionPoint) m_topIntersection.pop(); #ifdef Q_TRIANGULATOR_DEBUG DebugDialog dialog(this, intersection.vertex); dialog.exec(); #endif } } void QTriangulator::ComplexToSimple::fillPriorityQueue() { m_events.reset(); m_events.reserve(m_edges.size() * 2); for (int i = 0; i < m_edges.size(); ++i) { Q_ASSERT(m_edges.at(i).previous == -1 && m_edges.at(i).next == -1); Q_ASSERT(m_edges.at(i).node == 0); Q_ASSERT(m_edges.at(i).pointingUp == m_edges.at(i).originallyPointingUp); Q_ASSERT(m_edges.at(i).pointingUp == (m_parent->m_vertices.at(m_edges.at(i).to) < m_parent->m_vertices.at(m_edges.at(i).from))); // Ignore zero-length edges. if (m_parent->m_vertices.at(m_edges.at(i).to) != m_parent->m_vertices.at(m_edges.at(i).from)) { QPodPoint upper = m_parent->m_vertices.at(m_edges.at(i).upper()); QPodPoint lower = m_parent->m_vertices.at(m_edges.at(i).lower()); Event upperEvent = {{upper.x, upper.y}, Event::Upper, i}; Event lowerEvent = {{lower.x, lower.y}, Event::Lower, i}; m_events.add(upperEvent); m_events.add(lowerEvent); } } //qSort(m_events.data(), m_events.data() + m_events.size()); sort(m_events.data(), m_events.size()); } void QTriangulator::ComplexToSimple::calculateIntersections() { fillPriorityQueue(); Q_ASSERT(m_topIntersection.empty()); Q_ASSERT(m_edgeList.root == 0); // Find all intersection points. while (!m_events.isEmpty()) { Event event = m_events.last(); sortEdgeList(event.point); // Find all edges in the edge list that contain the current vertex and mark them to be split later. QPair::Node *, QRBTree::Node *> range = bounds(event.point); QRBTree::Node *leftNode = range.first ? m_edgeList.previous(range.first) : 0; int vertex = (event.type == Event::Upper ? m_edges.at(event.edge).upper() : m_edges.at(event.edge).lower()); QIntersectionPoint eventPoint = qIntersectionPoint(event.point); if (range.first != 0) { splitEdgeListRange(range.first, range.second, vertex, eventPoint); reorderEdgeListRange(range.first, range.second); } // Handle the edges with start or end point in the current vertex. while (!m_events.isEmpty() && m_events.last().point == event.point) { event = m_events.last(); m_events.pop_back(); int i = event.edge; if (m_edges.at(i).node) { // Remove edge from edge list. Q_ASSERT(event.type == Event::Lower); QRBTree::Node *left = m_edgeList.previous(m_edges.at(i).node); QRBTree::Node *right = m_edgeList.next(m_edges.at(i).node); m_edgeList.deleteNode(m_edges.at(i).node); if (!left || !right) continue; calculateIntersection(left->data, right->data); } else { // Insert edge into edge list. Q_ASSERT(event.type == Event::Upper); QRBTree::Node *left = searchEdgeLeftOf(i, leftNode); m_edgeList.attachAfter(left, m_edges.at(i).node = m_edgeList.newNode()); m_edges.at(i).node->data = i; QRBTree::Node *right = m_edgeList.next(m_edges.at(i).node); if (left) calculateIntersection(left->data, i); if (right) calculateIntersection(i, right->data); } } while (!m_topIntersection.isEmpty() && m_topIntersection.top().intersectionPoint <= eventPoint) m_topIntersection.pop(); #ifdef Q_TRIANGULATOR_DEBUG DebugDialog dialog(this, vertex); dialog.exec(); #endif } m_processedEdgePairs.clear(); } // Split an edge into two pieces at the given point. // The upper piece is pushed to the end of the 'm_edges' vector. // The lower piece replaces the old edge. // Return the edge whose 'from' is 'pointIndex'. int QTriangulator::ComplexToSimple::splitEdge(int splitIndex) { const Split &split = m_splits.at(splitIndex); Edge &lowerEdge = m_edges.at(split.edge); Q_ASSERT(lowerEdge.node == 0); Q_ASSERT(lowerEdge.previous == -1 && lowerEdge.next == -1); if (lowerEdge.from == split.vertex) return split.edge; if (lowerEdge.to == split.vertex) return lowerEdge.next; // Check that angle >= 90 degrees. //Q_ASSERT(qDot(m_points.at(m_edges.at(edgeIndex).from) - m_points.at(pointIndex), // m_points.at(m_edges.at(edgeIndex).to) - m_points.at(pointIndex)) <= 0); Edge upperEdge = lowerEdge; upperEdge.mayIntersect |= !split.accurate; // The edge may have been split before at an inaccurate split point. lowerEdge.mayIntersect = !split.accurate; if (lowerEdge.pointingUp) { lowerEdge.to = upperEdge.from = split.vertex; m_edges.add(upperEdge); return m_edges.size() - 1; } else { lowerEdge.from = upperEdge.to = split.vertex; m_edges.add(upperEdge); return split.edge; } } bool QTriangulator::ComplexToSimple::splitEdgesAtIntersections() { for (int i = 0; i < m_edges.size(); ++i) m_edges.at(i).mayIntersect = false; bool checkForNewIntersections = false; for (int i = 0; i < m_splits.size(); ++i) { splitEdge(i); checkForNewIntersections |= !m_splits.at(i).accurate; } for (int i = 0; i < m_edges.size(); ++i) { m_edges.at(i).originallyPointingUp = m_edges.at(i).pointingUp = m_parent->m_vertices.at(m_edges.at(i).to) < m_parent->m_vertices.at(m_edges.at(i).from); } m_splits.reset(); return checkForNewIntersections; } void QTriangulator::ComplexToSimple::insertEdgeIntoVectorIfWanted(ShortArray &orderedEdges, int i) { // Edges with zero length should not reach this part. Q_ASSERT(m_parent->m_vertices.at(m_edges.at(i).from) != m_parent->m_vertices.at(m_edges.at(i).to)); // Skip edges with unwanted winding number. int windingNumber = m_edges.at(i).winding; if (m_edges.at(i).originallyPointingUp) ++windingNumber; // Make sure exactly one fill rule is specified. Q_ASSERT(((m_parent->m_hint & QVectorPath::WindingFill) != 0) != ((m_parent->m_hint & QVectorPath::OddEvenFill) != 0)); if ((m_parent->m_hint & QVectorPath::WindingFill) && windingNumber != 0 && windingNumber != 1) return; // Skip cancelling edges. if (!orderedEdges.isEmpty()) { int j = orderedEdges[orderedEdges.size() - 1]; // If the last edge is already connected in one end, it should not be cancelled. if (m_edges.at(j).next == -1 && m_edges.at(j).previous == -1 && (m_parent->m_vertices.at(m_edges.at(i).from) == m_parent->m_vertices.at(m_edges.at(j).to)) && (m_parent->m_vertices.at(m_edges.at(i).to) == m_parent->m_vertices.at(m_edges.at(j).from))) { orderedEdges.removeLast(); return; } } orderedEdges.append(i); } void QTriangulator::ComplexToSimple::removeUnwantedEdgesAndConnect() { Q_ASSERT(m_edgeList.root == 0); // Initialize priority queue. fillPriorityQueue(); ShortArray orderedEdges; while (!m_events.isEmpty()) { Event event = m_events.last(); int edgeIndex = event.edge; // Check that all the edges in the list crosses the current scanline //if (m_edgeList.root) { // for (QRBTree::Node *node = m_edgeList.front(m_edgeList.root); node; node = m_edgeList.next(node)) { // Q_ASSERT(event.point <= m_points.at(m_edges.at(node->data).lower())); // } //} orderedEdges.clear(); QPair::Node *, QRBTree::Node *> b = outerBounds(event.point); if (m_edgeList.root) { QRBTree::Node *current = (b.first ? m_edgeList.next(b.first) : m_edgeList.front(m_edgeList.root)); // Process edges that are going to be removed from the edge list at the current event point. while (current != b.second) { Q_ASSERT(current); Q_ASSERT(m_edges.at(current->data).node == current); Q_ASSERT(qIntersectionPoint(event.point).isOnLine(m_parent->m_vertices.at(m_edges.at(current->data).from), m_parent->m_vertices.at(m_edges.at(current->data).to))); Q_ASSERT(m_parent->m_vertices.at(m_edges.at(current->data).from) == event.point || m_parent->m_vertices.at(m_edges.at(current->data).to) == event.point); insertEdgeIntoVectorIfWanted(orderedEdges, current->data); current = m_edgeList.next(current); } } // Remove edges above the event point, insert edges below the event point. do { event = m_events.last(); m_events.pop_back(); edgeIndex = event.edge; // Edges with zero length should not reach this part. Q_ASSERT(m_parent->m_vertices.at(m_edges.at(edgeIndex).from) != m_parent->m_vertices.at(m_edges.at(edgeIndex).to)); if (m_edges.at(edgeIndex).node) { Q_ASSERT(event.type == Event::Lower); Q_ASSERT(event.point == m_parent->m_vertices.at(m_edges.at(event.edge).lower())); m_edgeList.deleteNode(m_edges.at(edgeIndex).node); } else { Q_ASSERT(event.type == Event::Upper); Q_ASSERT(event.point == m_parent->m_vertices.at(m_edges.at(event.edge).upper())); QRBTree::Node *left = searchEdgeLeftOf(edgeIndex, b.first); m_edgeList.attachAfter(left, m_edges.at(edgeIndex).node = m_edgeList.newNode()); m_edges.at(edgeIndex).node->data = edgeIndex; } } while (!m_events.isEmpty() && m_events.last().point == event.point); if (m_edgeList.root) { QRBTree::Node *current = (b.first ? m_edgeList.next(b.first) : m_edgeList.front(m_edgeList.root)); // Calculate winding number and turn counter-clockwise. int currentWindingNumber = (b.first ? m_edges.at(b.first->data).winding : 0); while (current != b.second) { Q_ASSERT(current); //Q_ASSERT(b.second == 0 || m_edgeList.order(current, b.second) < 0); int i = current->data; Q_ASSERT(m_edges.at(i).node == current); // Winding number. int ccwWindingNumber = m_edges.at(i).winding = currentWindingNumber; if (m_edges.at(i).originallyPointingUp) { --m_edges.at(i).winding; } else { ++m_edges.at(i).winding; ++ccwWindingNumber; } currentWindingNumber = m_edges.at(i).winding; // Turn counter-clockwise. if ((ccwWindingNumber & 1) == 0) { Q_ASSERT(m_edges.at(i).previous == -1 && m_edges.at(i).next == -1); qSwap(m_edges.at(i).from, m_edges.at(i).to); m_edges.at(i).pointingUp = !m_edges.at(i).pointingUp; } current = m_edgeList.next(current); } // Process edges that were inserted into the edge list at the current event point. current = (b.second ? m_edgeList.previous(b.second) : m_edgeList.back(m_edgeList.root)); while (current != b.first) { Q_ASSERT(current); Q_ASSERT(m_edges.at(current->data).node == current); insertEdgeIntoVectorIfWanted(orderedEdges, current->data); current = m_edgeList.previous(current); } } if (orderedEdges.isEmpty()) continue; Q_ASSERT((orderedEdges.size() & 1) == 0); // Connect edges. // First make sure the first edge point towards the current point. int i; if (m_parent->m_vertices.at(m_edges.at(orderedEdges[0]).from) == event.point) { i = 1; int copy = orderedEdges[0]; // Make copy in case the append() will cause a reallocation. orderedEdges.append(copy); } else { Q_ASSERT(m_parent->m_vertices.at(m_edges.at(orderedEdges[0]).to) == event.point); i = 0; } // Remove references to duplicate points. First find the point with lowest index. int pointIndex = INT_MAX; for (int j = i; j < orderedEdges.size(); j += 2) { Q_ASSERT(j + 1 < orderedEdges.size()); Q_ASSERT(m_parent->m_vertices.at(m_edges.at(orderedEdges[j]).to) == event.point); Q_ASSERT(m_parent->m_vertices.at(m_edges.at(orderedEdges[j + 1]).from) == event.point); if (m_edges.at(orderedEdges[j]).to < pointIndex) pointIndex = m_edges.at(orderedEdges[j]).to; if (m_edges.at(orderedEdges[j + 1]).from < pointIndex) pointIndex = m_edges.at(orderedEdges[j + 1]).from; } for (; i < orderedEdges.size(); i += 2) { // Remove references to duplicate points by making all edges reference one common point. m_edges.at(orderedEdges[i]).to = m_edges.at(orderedEdges[i + 1]).from = pointIndex; Q_ASSERT(m_edges.at(orderedEdges[i]).pointingUp || m_edges.at(orderedEdges[i]).previous != -1); Q_ASSERT(!m_edges.at(orderedEdges[i + 1]).pointingUp || m_edges.at(orderedEdges[i + 1]).next != -1); m_edges.at(orderedEdges[i]).next = orderedEdges[i + 1]; m_edges.at(orderedEdges[i + 1]).previous = orderedEdges[i]; } } // end while } void QTriangulator::ComplexToSimple::removeUnusedPoints() { QBitArray used(m_parent->m_vertices.size(), false); for (int i = 0; i < m_edges.size(); ++i) { Q_ASSERT((m_edges.at(i).previous == -1) == (m_edges.at(i).next == -1)); if (m_edges.at(i).next != -1) used.setBit(m_edges.at(i).from); } QDataBuffer newMapping(m_parent->m_vertices.size()); newMapping.resize(m_parent->m_vertices.size()); int count = 0; for (int i = 0; i < m_parent->m_vertices.size(); ++i) { if (used.at(i)) { m_parent->m_vertices.at(count) = m_parent->m_vertices.at(i); newMapping.at(i) = count; ++count; } } m_parent->m_vertices.resize(count); for (int i = 0; i < m_edges.size(); ++i) { m_edges.at(i).from = newMapping.at(m_edges.at(i).from); m_edges.at(i).to = newMapping.at(m_edges.at(i).to); } } bool QTriangulator::ComplexToSimple::CompareEdges::operator () (int i, int j) const { int cmp = comparePoints(m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(i).from), m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(j).from)); if (cmp == 0) { cmp = comparePoints(m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(i).to), m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(j).to)); } return cmp > 0; } inline bool QTriangulator::ComplexToSimple::Event::operator < (const Event &other) const { if (point == other.point) return type < other.type; // 'Lower' has higher priority than 'Upper'. return other.point < point; } //============================================================================// // QTriangulator::ComplexToSimple::DebugDialog // //============================================================================// #ifdef Q_TRIANGULATOR_DEBUG QTriangulator::ComplexToSimple::DebugDialog::DebugDialog(ComplexToSimple *parent, int currentVertex) : m_parent(parent), m_vertex(currentVertex) { QDataBuffer &vertices = m_parent->m_parent->m_vertices; if (vertices.isEmpty()) return; int minX, maxX, minY, maxY; minX = maxX = vertices.at(0).x; minY = maxY = vertices.at(0).y; for (int i = 1; i < vertices.size(); ++i) { minX = qMin(minX, vertices.at(i).x); maxX = qMax(maxX, vertices.at(i).x); minY = qMin(minY, vertices.at(i).y); maxY = qMax(maxY, vertices.at(i).y); } int w = maxX - minX; int h = maxY - minY; qreal border = qMin(w, h) / 10.0; m_window = QRectF(minX - border, minY - border, (maxX - minX + 2 * border), (maxY - minY + 2 * border)); } void QTriangulator::ComplexToSimple::DebugDialog::paintEvent(QPaintEvent *) { QPainter p(this); p.setRenderHint(QPainter::Antialiasing, true); p.fillRect(rect(), Qt::black); QDataBuffer &vertices = m_parent->m_parent->m_vertices; if (vertices.isEmpty()) return; qreal halfPointSize = qMin(m_window.width(), m_window.height()) / 300.0; p.setWindow(m_window.toRect()); p.setPen(Qt::white); QDataBuffer &edges = m_parent->m_edges; for (int i = 0; i < edges.size(); ++i) { QPodPoint u = vertices.at(edges.at(i).from); QPodPoint v = vertices.at(edges.at(i).to); p.drawLine(u.x, u.y, v.x, v.y); } for (int i = 0; i < vertices.size(); ++i) { QPodPoint q = vertices.at(i); p.fillRect(QRectF(q.x - halfPointSize, q.y - halfPointSize, 2 * halfPointSize, 2 * halfPointSize), Qt::red); } Qt::GlobalColor colors[6] = {Qt::red, Qt::green, Qt::blue, Qt::cyan, Qt::magenta, Qt::yellow}; p.setOpacity(0.5); int count = 0; if (m_parent->m_edgeList.root) { QRBTree::Node *current = m_parent->m_edgeList.front(m_parent->m_edgeList.root); while (current) { p.setPen(colors[count++ % 6]); QPodPoint u = vertices.at(edges.at(current->data).from); QPodPoint v = vertices.at(edges.at(current->data).to); p.drawLine(u.x, u.y, v.x, v.y); current = m_parent->m_edgeList.next(current); } } p.setOpacity(1.0); QPodPoint q = vertices.at(m_vertex); p.fillRect(QRectF(q.x - halfPointSize, q.y - halfPointSize, 2 * halfPointSize, 2 * halfPointSize), Qt::green); p.setPen(Qt::gray); QDataBuffer &splits = m_parent->m_splits; for (int i = 0; i < splits.size(); ++i) { QPodPoint q = vertices.at(splits.at(i).vertex); QPodPoint u = vertices.at(edges.at(splits.at(i).edge).from) - q; QPodPoint v = vertices.at(edges.at(splits.at(i).edge).to) - q; qreal uLen = sqrt(qreal(qDot(u, u))); qreal vLen = sqrt(qreal(qDot(v, v))); if (uLen) { u.x *= 2 * halfPointSize / uLen; u.y *= 2 * halfPointSize / uLen; } if (vLen) { v.x *= 2 * halfPointSize / vLen; v.y *= 2 * halfPointSize / vLen; } u += q; v += q; p.drawLine(u.x, u.y, v.x, v.y); } } void QTriangulator::ComplexToSimple::DebugDialog::wheelEvent(QWheelEvent *event) { qreal scale = exp(-0.001 * event->delta()); QPointF center = m_window.center(); QPointF delta = scale * (m_window.bottomRight() - center); m_window = QRectF(center - delta, center + delta); event->accept(); update(); } void QTriangulator::ComplexToSimple::DebugDialog::mouseMoveEvent(QMouseEvent *event) { if (event->buttons() & Qt::LeftButton) { QPointF delta = event->pos() - m_lastMousePos; delta.setX(delta.x() * m_window.width() / width()); delta.setY(delta.y() * m_window.height() / height()); m_window.translate(-delta.x(), -delta.y()); m_lastMousePos = event->pos(); event->accept(); update(); } } void QTriangulator::ComplexToSimple::DebugDialog::mousePressEvent(QMouseEvent *event) { if (event->button() == Qt::LeftButton) m_lastMousePos = event->pos(); event->accept(); } #endif //============================================================================// // QTriangulator::SimpleToMonotone // //============================================================================// void QTriangulator::SimpleToMonotone::decompose() { setupDataStructures(); removeZeroLengthEdges(); monotoneDecomposition(); m_parent->m_indices.clear(); QBitArray processed(m_edges.size(), false); for (int first = 0; first < m_edges.size(); ++first) { if (processed.at(first)) continue; int i = first; do { Q_ASSERT(!processed.at(i)); Q_ASSERT(m_edges.at(m_edges.at(i).next).previous == i); m_parent->m_indices.push_back(m_edges.at(i).from); processed.setBit(i); i = m_edges.at(i).next; } while (i != first); if (m_parent->m_indices.size() > 0 && m_parent->m_indices.back() != Q_TRIANGULATE_END_OF_POLYGON) m_parent->m_indices.push_back(Q_TRIANGULATE_END_OF_POLYGON); } } void QTriangulator::SimpleToMonotone::setupDataStructures() { int i = 0; Edge e; e.node = 0; e.twin = -1; while (i + 3 <= m_parent->m_indices.size()) { int start = m_edges.size(); do { e.from = m_parent->m_indices.at(i); e.type = RegularVertex; e.next = m_edges.size() + 1; e.previous = m_edges.size() - 1; m_edges.add(e); ++i; Q_ASSERT(i < m_parent->m_indices.size()); } while (m_parent->m_indices.at(i) != Q_TRIANGULATE_END_OF_POLYGON); m_edges.last().next = start; m_edges.at(start).previous = m_edges.size() - 1; ++i; // Skip Q_TRIANGULATE_END_OF_POLYGON. } for (i = 0; i < m_edges.size(); ++i) { m_edges.at(i).to = m_edges.at(m_edges.at(i).next).from; m_edges.at(i).pointingUp = m_parent->m_vertices.at(m_edges.at(i).to) < m_parent->m_vertices.at(m_edges.at(i).from); m_edges.at(i).helper = -1; // Not initialized here. } } void QTriangulator::SimpleToMonotone::removeZeroLengthEdges() { for (int i = 0; i < m_edges.size(); ++i) { if (m_parent->m_vertices.at(m_edges.at(i).from) == m_parent->m_vertices.at(m_edges.at(i).to)) { m_edges.at(m_edges.at(i).previous).next = m_edges.at(i).next; m_edges.at(m_edges.at(i).next).previous = m_edges.at(i).previous; m_edges.at(m_edges.at(i).next).from = m_edges.at(i).from; m_edges.at(i).next = -1; // Mark as removed. } } QDataBuffer newMapping(m_edges.size()); newMapping.resize(m_edges.size()); int count = 0; for (int i = 0; i < m_edges.size(); ++i) { if (m_edges.at(i).next != -1) { m_edges.at(count) = m_edges.at(i); newMapping.at(i) = count; ++count; } } m_edges.resize(count); for (int i = 0; i < m_edges.size(); ++i) { m_edges.at(i).next = newMapping.at(m_edges.at(i).next); m_edges.at(i).previous = newMapping.at(m_edges.at(i).previous); } } void QTriangulator::SimpleToMonotone::fillPriorityQueue() { m_upperVertex.reset(); m_upperVertex.reserve(m_edges.size()); for (int i = 0; i < m_edges.size(); ++i) m_upperVertex.add(i); CompareVertices cmp(this); //qSort(m_upperVertex.data(), m_upperVertex.data() + m_upperVertex.size(), cmp); sort(m_upperVertex.data(), m_upperVertex.size(), cmp); //for (int i = 1; i < m_upperVertex.size(); ++i) { // Q_ASSERT(!cmp(m_upperVertex.at(i), m_upperVertex.at(i - 1))); //} } bool QTriangulator::SimpleToMonotone::edgeIsLeftOfEdge(int leftEdgeIndex, int rightEdgeIndex) const { const Edge &leftEdge = m_edges.at(leftEdgeIndex); const Edge &rightEdge = m_edges.at(rightEdgeIndex); const QPodPoint &u = m_parent->m_vertices.at(rightEdge.upper()); const QPodPoint &l = m_parent->m_vertices.at(rightEdge.lower()); qint64 d = qPointDistanceFromLine(m_parent->m_vertices.at(leftEdge.upper()), l, u); // d < 0: left, d > 0: right, d == 0: on top if (d == 0) d = qPointDistanceFromLine(m_parent->m_vertices.at(leftEdge.lower()), l, u); return d < 0; } // Returns the rightmost edge not to the right of the given edge. QRBTree::Node *QTriangulator::SimpleToMonotone::searchEdgeLeftOfEdge(int edgeIndex) const { QRBTree::Node *current = m_edgeList.root; QRBTree::Node *result = 0; while (current) { if (edgeIsLeftOfEdge(edgeIndex, current->data)) { current = current->left; } else { result = current; current = current->right; } } return result; } // Returns the rightmost edge left of the given point. QRBTree::Node *QTriangulator::SimpleToMonotone::searchEdgeLeftOfPoint(int pointIndex) const { QRBTree::Node *current = m_edgeList.root; QRBTree::Node *result = 0; while (current) { const QPodPoint &p1 = m_parent->m_vertices.at(m_edges.at(current->data).lower()); const QPodPoint &p2 = m_parent->m_vertices.at(m_edges.at(current->data).upper()); qint64 d = qPointDistanceFromLine(m_parent->m_vertices.at(pointIndex), p1, p2); if (d <= 0) { current = current->left; } else { result = current; current = current->right; } } return result; } void QTriangulator::SimpleToMonotone::classifyVertex(int i) { Edge &e2 = m_edges.at(i); const Edge &e1 = m_edges.at(e2.previous); bool startOrSplit = (e1.pointingUp && !e2.pointingUp); bool endOrMerge = (!e1.pointingUp && e2.pointingUp); const QPodPoint &p1 = m_parent->m_vertices.at(e1.from); const QPodPoint &p2 = m_parent->m_vertices.at(e2.from); const QPodPoint &p3 = m_parent->m_vertices.at(e2.to); qint64 d = qPointDistanceFromLine(p1, p2, p3); Q_ASSERT(d != 0 || (!startOrSplit && !endOrMerge)); e2.type = RegularVertex; if (m_clockwiseOrder) { if (startOrSplit) e2.type = (d < 0 ? SplitVertex : StartVertex); else if (endOrMerge) e2.type = (d < 0 ? MergeVertex : EndVertex); } else { if (startOrSplit) e2.type = (d > 0 ? SplitVertex : StartVertex); else if (endOrMerge) e2.type = (d > 0 ? MergeVertex : EndVertex); } } void QTriangulator::SimpleToMonotone::classifyVertices() { for (int i = 0; i < m_edges.size(); ++i) classifyVertex(i); } bool QTriangulator::SimpleToMonotone::pointIsInSector(const QPodPoint &p, const QPodPoint &v1, const QPodPoint &v2, const QPodPoint &v3) { bool leftOfPreviousEdge = !qPointIsLeftOfLine(p, v2, v1); bool leftOfNextEdge = !qPointIsLeftOfLine(p, v3, v2); if (qPointIsLeftOfLine(v1, v2, v3)) return leftOfPreviousEdge && leftOfNextEdge; else return leftOfPreviousEdge || leftOfNextEdge; } bool QTriangulator::SimpleToMonotone::pointIsInSector(int vertex, int sector) { const QPodPoint ¢er = m_parent->m_vertices.at(m_edges.at(sector).from); // Handle degenerate edges. while (m_parent->m_vertices.at(m_edges.at(vertex).from) == center) vertex = m_edges.at(vertex).next; int next = m_edges.at(sector).next; while (m_parent->m_vertices.at(m_edges.at(next).from) == center) next = m_edges.at(next).next; int previous = m_edges.at(sector).previous; while (m_parent->m_vertices.at(m_edges.at(previous).from) == center) previous = m_edges.at(previous).previous; const QPodPoint &p = m_parent->m_vertices.at(m_edges.at(vertex).from); const QPodPoint &v1 = m_parent->m_vertices.at(m_edges.at(previous).from); const QPodPoint &v3 = m_parent->m_vertices.at(m_edges.at(next).from); if (m_clockwiseOrder) return pointIsInSector(p, v3, center, v1); else return pointIsInSector(p, v1, center, v3); } int QTriangulator::SimpleToMonotone::findSector(int edge, int vertex) { while (!pointIsInSector(vertex, edge)) { edge = m_edges.at(m_edges.at(edge).previous).twin; Q_ASSERT(edge != -1); } return edge; } void QTriangulator::SimpleToMonotone::createDiagonal(int lower, int upper) { lower = findSector(lower, upper); upper = findSector(upper, lower); int prevLower = m_edges.at(lower).previous; int prevUpper = m_edges.at(upper).previous; Edge e; e.twin = m_edges.size() + 1; e.next = upper; e.previous = prevLower; e.from = m_edges.at(lower).from; e.to = m_edges.at(upper).from; m_edges.at(upper).previous = m_edges.at(prevLower).next = int(m_edges.size()); m_edges.add(e); e.twin = m_edges.size() - 1; e.next = lower; e.previous = prevUpper; e.from = m_edges.at(upper).from; e.to = m_edges.at(lower).from; m_edges.at(lower).previous = m_edges.at(prevUpper).next = int(m_edges.size()); m_edges.add(e); } void QTriangulator::SimpleToMonotone::monotoneDecomposition() { if (m_edges.isEmpty()) return; Q_ASSERT(!m_edgeList.root); QDataBuffer > diagonals(m_upperVertex.size()); int i = 0; for (int index = 1; index < m_edges.size(); ++index) { if (m_parent->m_vertices.at(m_edges.at(index).from) < m_parent->m_vertices.at(m_edges.at(i).from)) i = index; } Q_ASSERT(i < m_edges.size()); int j = m_edges.at(i).previous; Q_ASSERT(j < m_edges.size()); m_clockwiseOrder = qPointIsLeftOfLine(m_parent->m_vertices.at(m_edges.at(i).from), m_parent->m_vertices.at(m_edges.at(j).from), m_parent->m_vertices.at(m_edges.at(i).to)); classifyVertices(); fillPriorityQueue(); // debug: set helpers explicitly (shouldn't be necessary) //for (int i = 0; i < m_edges.size(); ++i) // m_edges.at(i).helper = m_edges.at(i).upper(); while (!m_upperVertex.isEmpty()) { i = m_upperVertex.last(); Q_ASSERT(i < m_edges.size()); m_upperVertex.pop_back(); j = m_edges.at(i).previous; Q_ASSERT(j < m_edges.size()); QRBTree::Node *leftEdgeNode = 0; switch (m_edges.at(i).type) { case RegularVertex: // If polygon interior is to the right of the vertex... if (m_edges.at(i).pointingUp == m_clockwiseOrder) { if (m_edges.at(i).node) { Q_ASSERT(!m_edges.at(j).node); if (m_edges.at(m_edges.at(i).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(i).helper)); m_edges.at(j).node = m_edges.at(i).node; m_edges.at(i).node = 0; m_edges.at(j).node->data = j; m_edges.at(j).helper = i; } else if (m_edges.at(j).node) { Q_ASSERT(!m_edges.at(i).node); if (m_edges.at(m_edges.at(j).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(j).helper)); m_edges.at(i).node = m_edges.at(j).node; m_edges.at(j).node = 0; m_edges.at(i).node->data = i; m_edges.at(i).helper = i; } else { qWarning("Inconsistent polygon. (#1)"); } } else { leftEdgeNode = searchEdgeLeftOfPoint(m_edges.at(i).from); if (leftEdgeNode) { if (m_edges.at(m_edges.at(leftEdgeNode->data).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(leftEdgeNode->data).helper)); m_edges.at(leftEdgeNode->data).helper = i; } else { qWarning("Inconsistent polygon. (#2)"); } } break; case SplitVertex: leftEdgeNode = searchEdgeLeftOfPoint(m_edges.at(i).from); if (leftEdgeNode) { diagonals.add(QPair(i, m_edges.at(leftEdgeNode->data).helper)); m_edges.at(leftEdgeNode->data).helper = i; } else { qWarning("Inconsistent polygon. (#3)"); } // Fall through. case StartVertex: if (m_clockwiseOrder) { leftEdgeNode = searchEdgeLeftOfEdge(j); QRBTree::Node *node = m_edgeList.newNode(); node->data = j; m_edges.at(j).node = node; m_edges.at(j).helper = i; m_edgeList.attachAfter(leftEdgeNode, node); Q_ASSERT(m_edgeList.verify()); } else { leftEdgeNode = searchEdgeLeftOfEdge(i); QRBTree::Node *node = m_edgeList.newNode(); node->data = i; m_edges.at(i).node = node; m_edges.at(i).helper = i; m_edgeList.attachAfter(leftEdgeNode, node); Q_ASSERT(m_edgeList.verify()); } break; case MergeVertex: leftEdgeNode = searchEdgeLeftOfPoint(m_edges.at(i).from); if (leftEdgeNode) { if (m_edges.at(m_edges.at(leftEdgeNode->data).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(leftEdgeNode->data).helper)); m_edges.at(leftEdgeNode->data).helper = i; } else { qWarning("Inconsistent polygon. (#4)"); } // Fall through. case EndVertex: if (m_clockwiseOrder) { if (m_edges.at(m_edges.at(i).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(i).helper)); if (m_edges.at(i).node) { m_edgeList.deleteNode(m_edges.at(i).node); Q_ASSERT(m_edgeList.verify()); } else { qWarning("Inconsistent polygon. (#5)"); } } else { if (m_edges.at(m_edges.at(j).helper).type == MergeVertex) diagonals.add(QPair(i, m_edges.at(j).helper)); if (m_edges.at(j).node) { m_edgeList.deleteNode(m_edges.at(j).node); Q_ASSERT(m_edgeList.verify()); } else { qWarning("Inconsistent polygon. (#6)"); } } break; } } for (int i = 0; i < diagonals.size(); ++i) createDiagonal(diagonals.at(i).first, diagonals.at(i).second); } bool QTriangulator::SimpleToMonotone::CompareVertices::operator () (int i, int j) const { if (m_parent->m_edges.at(i).from == m_parent->m_edges.at(j).from) return m_parent->m_edges.at(i).type > m_parent->m_edges.at(j).type; return m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(i).from) > m_parent->m_parent->m_vertices.at(m_parent->m_edges.at(j).from); } //============================================================================// // QTriangulator::MonotoneToTriangles // //============================================================================// void QTriangulator::MonotoneToTriangles::decompose() { QVector result; QDataBuffer stack(m_parent->m_indices.size()); m_first = 0; // Require at least three more indices. while (m_first + 3 <= m_parent->m_indices.size()) { m_length = 0; while (m_parent->m_indices.at(m_first + m_length) != Q_TRIANGULATE_END_OF_POLYGON) { ++m_length; Q_ASSERT(m_first + m_length < m_parent->m_indices.size()); } if (m_length < 3) { m_first += m_length + 1; continue; } int minimum = 0; while (less(next(minimum), minimum)) minimum = next(minimum); while (less(previous(minimum), minimum)) minimum = previous(minimum); stack.reset(); stack.add(minimum); int left = previous(minimum); int right = next(minimum); bool stackIsOnLeftSide; bool clockwiseOrder = leftOfEdge(minimum, left, right); if (less(left, right)) { stack.add(left); left = previous(left); stackIsOnLeftSide = true; } else { stack.add(right); right = next(right); stackIsOnLeftSide = false; } for (int count = 0; count + 2 < m_length; ++count) { Q_ASSERT(stack.size() >= 2); if (less(left, right)) { if (stackIsOnLeftSide == false) { for (int i = 0; i + 1 < stack.size(); ++i) { result.push_back(indices(stack.at(i + 1))); result.push_back(indices(left)); result.push_back(indices(stack.at(i))); } stack.first() = stack.last(); stack.resize(1); } else { while (stack.size() >= 2 && (clockwiseOrder ^ !leftOfEdge(left, stack.at(stack.size() - 2), stack.last()))) { result.push_back(indices(stack.at(stack.size() - 2))); result.push_back(indices(left)); result.push_back(indices(stack.last())); stack.pop_back(); } } stack.add(left); left = previous(left); stackIsOnLeftSide = true; } else { if (stackIsOnLeftSide == true) { for (int i = 0; i + 1 < stack.size(); ++i) { result.push_back(indices(stack.at(i))); result.push_back(indices(right)); result.push_back(indices(stack.at(i + 1))); } stack.first() = stack.last(); stack.resize(1); } else { while (stack.size() >= 2 && (clockwiseOrder ^ !leftOfEdge(right, stack.last(), stack.at(stack.size() - 2)))) { result.push_back(indices(stack.last())); result.push_back(indices(right)); result.push_back(indices(stack.at(stack.size() - 2))); stack.pop_back(); } } stack.add(right); right = next(right); stackIsOnLeftSide = false; } } m_first += m_length + 1; } m_parent->m_indices = result; } //============================================================================// // qTriangulate // //============================================================================// QTriangleSet qTriangulate(const qreal *polygon, int count, uint hint, const QTransform &matrix) { QTriangulator triangulator; triangulator.initialize(polygon, count, hint, matrix); return triangulator.triangulate(); } QTriangleSet qTriangulate(const QVectorPath &path, const QTransform &matrix, qreal lod) { QTriangulator triangulator; triangulator.initialize(path, matrix, lod); return triangulator.triangulate(); } QTriangleSet qTriangulate(const QPainterPath &path, const QTransform &matrix, qreal lod) { QTriangulator triangulator; triangulator.initialize(path, matrix, lod); return triangulator.triangulate(); } QPolylineSet qPolyline(const QVectorPath &path, const QTransform &matrix, qreal lod) { QTriangulator triangulator; triangulator.initialize(path, matrix, lod); return triangulator.polyline(); } QPolylineSet qPolyline(const QPainterPath &path, const QTransform &matrix, qreal lod) { QTriangulator triangulator; triangulator.initialize(path, matrix, lod); return triangulator.polyline(); } QT_END_NAMESPACE