WebSVN - public iLand - Blame - Rev 708

Rev	Author	Line No.	Line
		1
671	werner	2	/********************************************************************************************
		3	** iLand - an individual based forest landscape and disturbance model
		4	** http://iland.boku.ac.at
		5	** Copyright (C) 2009- Werner Rammer, Rupert Seidl
		6	**
		7	** This program is free software: you can redistribute it and/or modify
		8	** it under the terms of the GNU General Public License as published by
		9	** the Free Software Foundation, either version 3 of the License, or
		10	** (at your option) any later version.
		11	**
		12	** This program is distributed in the hope that it will be useful,
		13	** but WITHOUT ANY WARRANTY; without even the implied warranty of
		14	** MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
		15	** GNU General Public License for more details.
		16	**
		17	** You should have received a copy of the GNU General Public License
		18	** along with this program. If not, see <http://www.gnu.org/licenses/>.
		19	********************************************************************************************/
		20
15	Werner	21	#ifndef GRID_H
		22	#define GRID_H
		23
22	Werner	24	#include <QtCore>
15	Werner	25
		26
		27	#include <stdexcept>
145	Werner	28	#include <limits>
150	iland	29	#include <cstring>
15	Werner	30
373	werner	31	#include "global.h"
		32
247	werner	33	/** Grid class (template).
697	werner	34	@ingroup tools
74	Werner	35	Orientation
656	werner	36	The grid is oriented as typically coordinates on the northern hemisphere: higher y-values -> north, higher x-values-> east.
490	werner	37	The projection is reversed for drawing on screen (Viewport).
74	Werner	38	N
490	werner	39	(0/2) (1/2) (2/2)
656	werner	40	W (0/1) (1/1) (2/1) E
74	Werner	41	(0/0) (1/0) (2/0)
		42	S
		43	*/
15	Werner	44	template <class T>
		45	class Grid {
		46	public:
		47
		48	Grid();
		49	Grid(int cellsize, int sizex, int sizey) { mData=0; setup(cellsize, sizex, sizey); }
58	Werner	50	Grid(const QRectF rect_metric, const float cellsize) { mData=0; setup(rect_metric,cellsize); }
33	Werner	51	// copy ctor
		52	Grid(const Grid<T>& toCopy);
105	Werner	53	~Grid() { clear(); }
		54	void clear() { if (mData) delete[] mData; mData=0; }
15	Werner	55
18	Werner	56	bool setup(const float cellsize, const int sizex, const int sizey);
22	Werner	57	bool setup(const QRectF& rect, const double cellsize);
453	werner	58	bool setup(Grid<T>& source) { mData = 0; mRect = source.mRect; return setup(source.cellsize(), source.sizeX(), source.sizeY()); }
75	Werner	59	void initialize(const T& value) {for( T p = begin();p!=end(); ++p) p=value; }
150	iland	60	void wipe(); ///< write 0-bytes with memcpy to the whole area
154	werner	61	void wipe(const T value); ///< overwrite the whole area with "value" size of T must be the size of "int" ERRORNOUS!!!
15	Werner	62
145	Werner	63	int sizeX() const { return mSizeX; }
		64	int sizeY() const { return mSizeY; }
		65	float metricSizeX() const { return mSizeX*mCellsize; }
		66	float metricSizeY() const { return mSizeY*mCellsize; }
49	Werner	67	QRectF metricRect() const { return mRect; }
145	Werner	68	float cellsize() const { return mCellsize; }
373	werner	69	int count() const { return mCount; } ///< returns the number of elements of the grid
		70	bool isEmpty() const { return mData==NULL; } ///< returns false if the grid was not setup
32	Werner	71	// operations
15	Werner	72	// query
33	Werner	73	/// access (const) with index variables. use int.
		74	inline const T& operator()(const int ix, const int iy) const { return constValueAtIndex(ix, iy); }
		75	/// access (const) using metric variables. use float.
		76	inline const T& operator()(const float x, const float y) const { return constValueAt(x, y); }
48	Werner	77	inline const T& operator[] (const QPointF &p) const { return constValueAt(p); }
33	Werner	78
705	werner	79	inline T& valueAtIndex(const QPoint& pos) {return valueAtIndex(pos.x(), pos.y());} ///< value at position defined by a QPoint defining the two indices (x,y)
		80	T& valueAtIndex(const int ix, const int iy) { return mData[iy*mSizeX + ix]; } ///< const value at position defined by indices (x,y)
285	werner	81	T& valueAtIndex(const int index) {return mData[index]; } ///< get a ref ot value at (one-dimensional) index 'index'.
33	Werner	82
705	werner	83	/// value at position defined by a (integer) QPoint
		84	inline const T& constValueAtIndex(const QPoint& pos) const {return constValueAtIndex(pos.x(), pos.y()); }
		85	/// value at position defined by a pair of integer coordinates
		86	inline const T& constValueAtIndex(const int ix, const int iy) const { return mData[iy*mSizeX + ix]; }
		87	/// value at position defined by the index within the grid
549	werner	88	const T& constValueAtIndex(const int index) const {return mData[index]; } ///< get a ref ot value at (one-dimensional) index 'index'.
33	Werner	89
		90	T& valueAt(const QPointF& posf); ///< value at position defined by metric coordinates (QPointF)
		91	const T& constValueAt(const QPointF& posf) const; ///< value at position defined by metric coordinates (QPointF)
		92
		93	T& valueAt(const float x, const float y); ///< value at position defined by metric coordinates (x,y)
		94	const T& constValueAt(const float x, const float y) const; ///< value at position defined by metric coordinates (x,y)
		95
105	Werner	96	bool coordValid(const float x, const float y) const { return x>=mRect.left() && x<mRect.right() && y>=mRect.top() && y<mRect.bottom(); }
49	Werner	97	bool coordValid(const QPointF &pos) const { return coordValid(pos.x(), pos.y()); }
75	Werner	98
55	Werner	99	QPoint indexAt(const QPointF& pos) const { return QPoint(int((pos.x()-mRect.left()) / mCellsize), int((pos.y()-mRect.top())/mCellsize)); } ///< get index of value at position pos (metric)
538	werner	100	/// get index (x/y) of the (linear) index 'index' (0..count-1)
		101	QPoint indexOf(const int index) const {return QPoint(index % mSizeX, index / mSizeX); }
373	werner	102	bool isIndexValid(const QPoint& pos) const { return (pos.x()>=0 && pos.x()<mSizeX && pos.y()>=0 && pos.y()<mSizeY); } ///< return true, if position is within the grid
		103	bool isIndexValid(const int x, const int y) const {return (x>=0 && x<mSizeX && y>=0 && y<mSizeY); } ///< return true, if index is within the grid
75	Werner	104	/// force @param pos to contain valid indices with respect to this grid.
55	Werner	105	void validate(QPoint &pos) const{ pos.setX( qMax(qMin(pos.x(), mSizeX-1), 0) ); pos.setY( qMax(qMin(pos.y(), mSizeY-1), 0) );} ///< ensure that "pos" is a valid key. if out of range, pos is set to minimum/maximum values.
105	Werner	106	/// get the (metric) centerpoint of cell with index @p pos
549	werner	107	QPointF cellCenterPoint(const QPoint &pos) const { return QPointF( (pos.x()+0.5)mCellsize+mRect.left(), (pos.y()+0.5)mCellsize + mRect.top());} ///< get metric coordinates of the cells center
105	Werner	108	/// get the metric rectangle of the cell with index @pos
439	werner	109	QRectF cellRect(const QPoint &pos) const { QRectF r( QPointF(mRect.left() + mCellsizepos.x(), mRect.top() + pos.y()mCellsize),
55	Werner	110	QSizeF(mCellsize, mCellsize)); return r; } ///< return coordinates of rect given by @param pos.
105	Werner	111
27	Werner	112	inline T* begin() const { return mData; } ///< get "iterator" pointer
37	Werner	113	inline T* end() const { return mEnd; } ///< get iterator end-pointer
487	werner	114	inline QPoint indexOf(T* element) const; ///< retrieve index (x/y) of the pointer element. returns -1/-1 if element is not valid.
27	Werner	115	// special queries
33	Werner	116	T max() const; ///< retrieve the maximum value of a grid
		117	T sum() const; ///< retrieve the sum of the grid
		118	T avg() const; ///< retrieve the average value of a grid
391	werner	119	// modifying operations
		120	void add(const T& summand);
		121	void multiply(const T& factor);
33	Werner	122	/// creates a grid with lower resolution and averaged cell values.
		123	/// @param factor factor by which grid size is reduced (e.g. 3 -> 3x3=9 pixels are averaged to 1 result pixel)
		124	/// @param offsetx, offsety: start averaging with an offset from 0/0 (e.g.: x=1, y=2, factor=3: -> 1/2-3/4 -> 0/0)
		125	/// @return Grid with size sizeX()/factor x sizeY()/factor
		126	Grid<T> averaged(const int factor, const int offsetx=0, const int offsety=0) const;
		127	/// normalized returns a normalized grid, in a way that the sum() = @param targetvalue.
		128	/// if the grid is empty or the sum is 0, no modifications are performed.
		129	Grid<T> normalized(const T targetvalue) const;
373	werner	130	T* ptr(int x, int y) { return &(mData[y*mSizeX + x]); } ///< get a pointer to the element denoted by "x" and "y"
		131	inline double distance(const QPoint &p1, const QPoint &p2); ///< distance (metric) between p1 and p2
		132	const QPoint randomPosition() const; ///< returns a (valid) random position within the grid
15	Werner	133	private:
77	Werner	134
15	Werner	135	T* mData;
37	Werner	136	T* mEnd; ///< pointer to 1 element behind the last
49	Werner	137	QRectF mRect;
36	Werner	138	float mCellsize; ///< size of a cell in meter
		139	int mSizeX; ///< count of cells in x-direction
		140	int mSizeY; ///< count of cells in y-direction
		141	int mCount; ///< total number of cells in the grid
15	Werner	142	};
		143
		144	typedef Grid<float> FloatGrid;
		145
643	werner	146	enum GridViewType { GridViewRainbow, GridViewRainbowReverse, GridViewGray, GridViewGrayReverse };
		147
438	werner	148	/** @class GridRunner is a helper class to iterate over a rectangular fraction of a grid
		149	*/
		150	template <class T>
		151	class GridRunner {
		152	public:
650	werner	153	// constructors with a QRectF (metric coordinates)
617	werner	154	GridRunner(Grid<T> &target_grid, const QRectF &rectangle) {setup(&target_grid, rectangle);}
		155	GridRunner(const Grid<T> &target_grid, const QRectF &rectangle) {setup(&target_grid, rectangle);}
		156	GridRunner(Grid<T> *target_grid, const QRectF &rectangle) {setup(target_grid, rectangle);}
650	werner	157	// constructors with a QRect (indices within the grid)
		158	GridRunner(Grid<T> &target_grid, const QRect &rectangle) {setup(&target_grid, rectangle);}
		159	GridRunner(const Grid<T> &target_grid, const QRect &rectangle) {setup(&target_grid, rectangle);}
		160	GridRunner(Grid<T> *target_grid, const QRect &rectangle) {setup(target_grid, rectangle);}
438	werner	161	T* next(); ///< to to next element, return NULL if finished
662	werner	162	T* current() const { return mCurrent; }
650	werner	163	void reset() { mCurrent = mFirst-1; mCurrentCol = -1; }
		164	// helpers
		165	/// fill array with pointers to neighbors (north, east, west, south)
		166	/// or Null-pointers if out of range.
		167	/// the target array (rArray) is not checked and must be valid!
		168	void neighbors4(T** rArray);
		169	void neighbors8(T** rArray);
438	werner	170	private:
617	werner	171	void setup(const Grid<T> *target_grid, const QRectF &rectangle);
650	werner	172	void setup(const Grid<T> *target_grid, const QRect &rectangle);
		173	T* mFirst; // points to the first element of the grid
		174	T* mLast; // points to the last element of the grid
438	werner	175	T* mCurrent;
		176	size_t mLineLength;
		177	size_t mCols;
		178	size_t mCurrentCol;
		179	};
		180
646	werner	181	/** @class Vector3D is a simple 3d vector.
		182	QVector3D (from Qt) is in QtGui so we needed a replacement.
		183	*/
		184	class Vector3D
		185	{
		186	public:
		187	Vector3D(): mX(0.), mY(0.), mZ(0.) {}
		188	Vector3D(const double x, const double y, const double z): mX(x), mY(y), mZ(z) {}
		189	double x() const { return mX; } ///< get x-coordinate
		190	double y() const { return mY; } ///< get y-coordinate
		191	double z() const { return mZ; } ///< get z-coordinate
		192	// set variables
		193	void setX(const double x) { mX=x; } ///< set value of the x-coordinate
		194	void setY(const double y) { mY=y; } ///< set value of the y-coordinate
		195	void setZ(const double z) { mZ=z; } ///< set value of the z-coordinate
		196	private:
		197	double mX;
		198	double mY;
		199	double mZ;
		200	};
438	werner	201
33	Werner	202	// copy constructor
		203	template <class T>
		204	Grid<T>::Grid(const Grid<T>& toCopy)
		205	{
40	Werner	206	mData = 0;
50	Werner	207	mRect = toCopy.mRect;
33	Werner	208	setup(toCopy.cellsize(), toCopy.sizeX(), toCopy.sizeY());
		209	const T* end = toCopy.end();
		210	T* ptr = begin();
		211	for (T* i= toCopy.begin(); i!=end; ++i, ++ptr)
		212	ptr = i;
		213	}
22	Werner	214
33	Werner	215	// normalize function
32	Werner	216	template <class T>
33	Werner	217	Grid<T> Grid<T>::normalized(const T targetvalue) const
32	Werner	218	{
33	Werner	219	Grid<T> target(*this);
		220	T total = sum();
		221	T multiplier;
		222	if (total)
		223	multiplier = targetvalue / total;
		224	else
		225	return target;
		226	for (T* p=target.begin();p!=target.end();++p)
		227	p = multiplier;
40	Werner	228	return target;
33	Werner	229	}
		230
		231
		232	template <class T>
		233	Grid<T> Grid<T>::averaged(const int factor, const int offsetx, const int offsety) const
		234	{
32	Werner	235	Grid<T> target;
		236	target.setup(cellsize()*factor, sizeX()/factor, sizeY()/factor);
		237	int x,y;
		238	T sum=0;
		239	target.initialize(sum);
		240	// sum over array of 2x2, 3x3, 4x4, ...
		241	for (x=offsetx;x<mSizeX;x++)
		242	for (y=offsety;y<mSizeY;y++) {
		243	target.valueAtIndex((x-offsetx)/factor, (y-offsety)/factor) += constValueAtIndex(x,y);
		244	}
		245	// divide
		246	double fsquare = factor*factor;
		247	for (T* p=target.begin();p!=target.end();++p)
		248	*p /= fsquare;
		249	return target;
		250	}
22	Werner	251
36	Werner	252
27	Werner	253	template <class T>
33	Werner	254	T& Grid<T>::valueAt(const float x, const float y)
		255	{
		256	return valueAtIndex( indexAt(QPointF(x,y)) );
		257	}
36	Werner	258
33	Werner	259	template <class T>
		260	const T& Grid<T>::constValueAt(const float x, const float y) const
		261	{
		262	return constValueAtIndex( indexAt(QPointF(x,y)) );
		263	}
36	Werner	264
33	Werner	265	template <class T>
22	Werner	266	T& Grid<T>::valueAt(const QPointF& posf)
		267	{
		268	return valueAtIndex( indexAt(posf) );
		269	}
36	Werner	270
33	Werner	271	template <class T>
		272	const T& Grid<T>::constValueAt(const QPointF& posf) const
		273	{
		274	return constValueAtIndex( indexAt(posf) );
		275	}
22	Werner	276
		277	template <class T>
15	Werner	278	Grid<T>::Grid()
		279	{
37	Werner	280	mData = 0; mCellsize=0.f;
		281	mEnd = 0;
15	Werner	282	}
		283
		284	template <class T>
18	Werner	285	bool Grid<T>::setup(const float cellsize, const int sizex, const int sizey)
15	Werner	286	{
37	Werner	287	mSizeX=sizex; mSizeY=sizey; mCellsize=cellsize;
50	Werner	288	if (mRect.isNull()) // only set rect if not set before
		289	mRect.setCoords(0., 0., cellsizesizex, cellsizesizey);
15	Werner	290	mCount = mSizeX*mSizeY;
37	Werner	291	if (mData) {
		292	delete[] mData; mData=NULL;
		293	}
15	Werner	294	if (mCount>0)
37	Werner	295	mData = new T[mCount];
		296	mEnd = &(mData[mCount]);
15	Werner	297	return true;
		298	}
		299
		300	template <class T>
22	Werner	301	bool Grid<T>::setup(const QRectF& rect, const double cellsize)
15	Werner	302	{
49	Werner	303	mRect = rect;
22	Werner	304	int dx = int(rect.width()/cellsize);
49	Werner	305	if (mRect.left()+cellsize*dx<rect.right())
22	Werner	306	dx++;
		307	int dy = int(rect.height()/cellsize);
49	Werner	308	if (mRect.top()+cellsize*dy<rect.bottom())
22	Werner	309	dy++;
		310	return setup(cellsize, dx, dy);
15	Werner	311	}
		312
261	werner	313	/** retrieve from the index from an element reversely from a pointer to that element.
		314	The internal memory layout is (for dimx=6, dimy=3):
		315
		316	6 7 8 9 10 11
		317	12 13 14 15 16 17
		318	Note: north and south are reversed, thus the item with index 0 is located in the south-western edge of the grid! */
487	werner	319	template <class T> inline
27	Werner	320	QPoint Grid<T>::indexOf(T* element) const
25	Werner	321	{
487	werner	322	// QPoint result(-1,-1);
25	Werner	323	if (element==NULL \|\| element<mData \|\| element>=end())
487	werner	324	return QPoint(-1, -1);
25	Werner	325	int idx = element - mData;
487	werner	326	return QPoint(idx % mSizeX, idx / mSizeX);
		327	// result.setX( idx % mSizeX);
		328	// result.setY( idx / mSizeX);
		329	// return result;
25	Werner	330	}
22	Werner	331
27	Werner	332	template <class T>
		333	T Grid<T>::max() const
		334	{
143	Werner	335	T maxv = -std::numeric_limits<T>::max();
27	Werner	336	T* p;
		337	T* pend = end();
		338	for (p=begin(); p!=pend;++p)
		339	maxv = std::max(maxv, *p);
		340	return maxv;
		341	}
		342
33	Werner	343	template <class T>
		344	T Grid<T>::sum() const
		345	{
		346	T* pend = end();
		347	T total = 0;
		348	for (T *p=begin(); p!=pend;++p)
		349	total += *p;
		350	return total;
		351	}
		352
		353	template <class T>
		354	T Grid<T>::avg() const
		355	{
		356	if (count())
		357	return sum() / T(count());
		358	else return 0;
		359	}
		360
150	iland	361	template <class T>
391	werner	362	void Grid<T>::add(const T& summand)
		363	{
		364	T* pend = end();
		365	for (T p=begin(); p!=pend;p+=summand,++p)
		366	;
		367	}
		368
		369	template <class T>
		370	void Grid<T>::multiply(const T& factor)
		371	{
		372	T* pend = end();
		373	for (T p=begin(); p!=pend;p*=factor,++p)
		374	;
		375	}
		376
		377
		378
		379	template <class T>
150	iland	380	void Grid<T>::wipe()
		381	{
		382	memset(mData, 0, mCount*sizeof(T));
		383	}
		384	template <class T>
		385	void Grid<T>::wipe(const T value)
		386	{
154	werner	387	/* this does not work properly !!! */
153	werner	388	if (sizeof(T)==sizeof(int)) {
		389	float temp = value;
		390	float *pf = &temp;
		391
		392	memset(mData, ((int)pf), mCount*sizeof(T));
		393	} else
150	iland	394	initialize(value);
		395	}
		396
373	werner	397	template <class T>
		398	double Grid<T>::distance(const QPoint &p1, const QPoint &p2)
		399	{
		400	QPointF fp1=cellCenterPoint(p1);
		401	QPointF fp2=cellCenterPoint(p2);
		402	double distance = sqrt( (fp1.x()-fp2.x())(fp1.x()-fp2.x()) + (fp1.y()-fp2.y())(fp1.y()-fp2.y()));
		403	return distance;
		404	}
		405
		406	template <class T>
		407	const QPoint Grid<T>::randomPosition() const
		408	{
		409	return QPoint(irandom(0,mSizeX-1), irandom(0, mSizeY-1));
		410	}
438	werner	411
373	werner	412	////////////////////////////////////////////////////////////
438	werner	413	// grid runner
		414	////////////////////////////////////////////////////////////
		415	template <class T>
650	werner	416	void GridRunner<T>::setup(const Grid<T> *target_grid, const QRect &rectangle)
438	werner	417	{
650	werner	418	QPoint upper_left = rectangle.topLeft();
651	werner	419	// due to the strange behavior of QRect::bottom() and right():
650	werner	420	QPoint lower_right = rectangle.bottomRight();
617	werner	421	mCurrent = const_cast<Grid<T> *>(target_grid)->ptr(upper_left.x(), upper_left.y());
650	werner	422	mFirst = mCurrent;
585	werner	423	mCurrent--; // point to first element -1
617	werner	424	mLast = const_cast<Grid<T> *>(target_grid)->ptr(lower_right.x()-1, lower_right.y()-1);
438	werner	425	mCols = lower_right.x() - upper_left.x(); //
617	werner	426	mLineLength = target_grid->sizeX() - mCols;
585	werner	427	mCurrentCol = -1;
		428	// qDebug() << "GridRunner: rectangle:" << rectangle
		429	// << "upper_left:" << target_grid.cellCenterPoint(target_grid.indexOf(mCurrent))
		430	// << "lower_right:" << target_grid.cellCenterPoint(target_grid.indexOf(mLast));
438	werner	431	}
		432
		433	template <class T>
650	werner	434	void GridRunner<T>::setup(const Grid<T> *target_grid, const QRectF &rectangle_metric)
		435	{
		436	QRect rect(target_grid->indexAt(rectangle_metric.topLeft()),
		437	target_grid->indexAt(rectangle_metric.bottomRight()) );
		438	setup (target_grid, rect);
		439	}
		440
		441	template <class T>
438	werner	442	T* GridRunner<T>::next()
		443	{
		444	if (mCurrent>mLast)
		445	return NULL;
		446	mCurrent++;
		447	mCurrentCol++;
585	werner	448
438	werner	449	if (mCurrentCol >= mCols) {
		450	mCurrent += mLineLength; // skip to next line
		451	mCurrentCol = 0;
		452	}
585	werner	453	if (mCurrent>mLast)
		454	return NULL;
		455	else
		456	return mCurrent;
438	werner	457	}
		458
650	werner	459	template <class T>
656	werner	460	/// get pointers the the 4-neighborhood
		461	/// north, east, south, west
650	werner	462	void GridRunner<T>::neighbors4(T** rArray)
		463	{
		464	// north:
651	werner	465	rArray[0] = mCurrent + mCols + mLineLength > mLast?0: mCurrent + mCols + mLineLength;
650	werner	466	// south:
651	werner	467	rArray[3] = mCurrent - (mCols + mLineLength) < mFirst?0: mCurrent - (mCols + mLineLength);
650	werner	468	// east / west
656	werner	469	rArray[1] = mCurrentCol<mCols? mCurrent + 1 : 0;
		470	rArray[2] = mCurrentCol>0? mCurrent-1 : 0;
650	werner	471	}
		472
		473	/// get pointers to the 8-neighbor-hood
		474	/// north/east/west/south/NE/NW/SE/SW
		475	template <class T>
		476	void GridRunner<T>::neighbors8(T** rArray)
		477	{
		478	neighbors4(rArray);
		479	// north-east
656	werner	480	rArray[4] = rArray[0] && rArray[1]? rArray[0]+1: 0;
650	werner	481	// north-west
656	werner	482	rArray[5] = rArray[0] && rArray[2]? rArray[0]-1: 0;
650	werner	483	// south-east
656	werner	484	rArray[6] = rArray[3] && rArray[1]? rArray[3]+1: 0;
650	werner	485	// south-west
656	werner	486	rArray[7] = rArray[3] && rArray[2]? rArray[3]-1: 0;
650	werner	487
		488	}
		489
438	werner	490	////////////////////////////////////////////////////////////
36	Werner	491	// global functions
373	werner	492	////////////////////////////////////////////////////////////
36	Werner	493
		494	/// dumps a FloatGrid to a String.
46	Werner	495	/// rows will be y-lines, columns x-values. (see grid.cpp)
599	werner	496	QString gridToString(const FloatGrid &grid, const QChar sep=QChar(';'), const int newline_after=-1);
36	Werner	497
		498	/// creates and return a QImage from Grid-Data.
		499	/// @param black_white true: max_value = white, min_value = black, false: color-mode: uses a HSV-color model from blue (min_value) to red (max_value), default: color mode (false)
		500	/// @param min_value, max_value min/max bounds for color calcuations. values outside bounds are limited to these values. defaults: min=0, max=1
		501	/// @param reverse if true, color ramps are inversed (to: min_value = white (black and white mode) or red (color mode). default = false.
		502	/// @return a QImage with the Grids size of pixels. Pixel coordinates relate to the index values of the grid.
		503	QImage gridToImage(const FloatGrid &grid,
		504	bool black_white=false,
		505	double min_value=0., double max_value=1.,
		506	bool reverse=false);
		507
556	werner	508
285	werner	509	/** load into 'rGrid' the content of the image pointed at by 'fileName'.
		510	Pixels are converted to grey-scale and then transformend to a value ranging from 0..1 (black..white).
		511	*/
		512	bool loadGridFromImage(const QString &fileName, FloatGrid &rGrid);
		513
46	Werner	514	/// template version for non-float grids (see also version for FloatGrid)
599	werner	515	/// @param sep string separator
		516	/// @param newline_after if <>-1 a newline is added after every 'newline_after' data values
36	Werner	517	template <class T>
599	werner	518	QString gridToString(const Grid<T> &grid, const QChar sep=QChar(';'), const int newline_after=-1)
36	Werner	519	{
		520	QString res;
		521	QTextStream ts(&res);
		522
599	werner	523	int newl_counter = newline_after;
708	werner	524	for (int y=grid.sizeY()-1;y>=0;--y){
46	Werner	525	for (int x=0;x<grid.sizeX();x++){
599	werner	526	ts << grid.constValueAtIndex(x,y) << sep;
		527	if (--newl_counter==0) {
		528	ts << "\r\n";
		529	newl_counter = newline_after;
		530	}
36	Werner	531	}
		532	ts << "\r\n";
		533	}
		534
		535	return res;
		536	}
46	Werner	537
599	werner	538	/// template version for non-float grids (see also version for FloatGrid)
		539	/// @param valueFunction pointer to a function with the signature: QString func(const T&) : this should return a QString
		540	/// @param sep string separator
		541	/// @param newline_after if <>-1 a newline is added after every 'newline_after' data values
		542	template <class T>
		543	QString gridToString(const Grid<T> &grid, QString (*valueFunction)(const T& value), const QChar sep=QChar(';'), const int newline_after=-1 )
708	werner	544	{
		545	QString res;
		546	QTextStream ts(&res);
599	werner	547
708	werner	548	int newl_counter = newline_after;
		549	for (int y=grid.sizeY()-1;y>=0;--y){
		550	for (int x=0;x<grid.sizeX();x++){
		551	ts << (*valueFunction)(grid.constValueAtIndex(x,y)) << sep;
599	werner	552
708	werner	553	if (--newl_counter==0) {
		554	ts << "\r\n";
		555	newl_counter = newline_after;
		556	}
		557	}
599	werner	558	ts << "\r\n";
		559	}
708	werner	560
		561	return res;
599	werner	562	}
646	werner	563	void modelToWorld(const Vector3D &From, Vector3D &To);
599	werner	564
		565	template <class T>
		566	QString gridToESRIRaster(const Grid<T> &grid, QString (*valueFunction)(const T& value) )
		567	{
646	werner	568	Vector3D model(grid.metricRect().left(), grid.metricRect().top(), 0.);
		569	Vector3D world;
599	werner	570	modelToWorld(model, world);
607	werner	571	QString result = QString("ncols %1\r\nnrows %2\r\nxllcorner %3\r\nyllcorner %4\r\ncellsize %5\r\nNODATA_value %6\r\n")
599	werner	572	.arg(grid.sizeX())
		573	.arg(grid.sizeY())
600	werner	574	.arg(world.x(),0,'f').arg(world.y(),0,'f')
599	werner	575	.arg(grid.cellsize()).arg(-9999);
694	werner	576	QString line = gridToString(grid, valueFunction, QChar(' ')); // for special grids
		577	return result + line;
		578	}
599	werner	579
		580	template <class T>
		581	QString gridToESRIRaster(const Grid<T> &grid )
		582	{
646	werner	583	Vector3D model(grid.metricRect().left(), grid.metricRect().top(), 0.);
		584	Vector3D world;
599	werner	585	modelToWorld(model, world);
683	werner	586	QString result = QString("ncols %1\r\nnrows %2\r\nxllcorner %3\r\nyllcorner %4\r\ncellsize %5\r\nNODATA_value %6\r\n")
599	werner	587	.arg(grid.sizeX())
		588	.arg(grid.sizeY())
680	werner	589	.arg(world.x(),0,'f').arg(world.y(),0,'f')
599	werner	590	.arg(grid.cellsize()).arg(-9999);
694	werner	591	QString line = gridToString(grid, QChar(' ')); // for normal grids (e.g. float)
		592	return result + line;
599	werner	593	}
		594
15	Werner	595	#endif // GRID_H

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(root)/src/core/grid.h @ 1222 - Rev 708