xref: /aoo41x/main/vcl/source/gdi/outmap.cxx (revision e6f63103)
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21 
22 
23 
24 // MARKER(update_precomp.py): autogen include statement, do not remove
25 #include "precompiled_vcl.hxx"
26 
27 #include <limits.h>
28 
29 #include <tools/bigint.hxx>
30 #include <tools/debug.hxx>
31 #include <tools/poly.hxx>
32 
33 #include <vcl/virdev.hxx>
34 #include <vcl/region.hxx>
35 #include <vcl/wrkwin.hxx>
36 #include <vcl/cursor.hxx>
37 #include <vcl/metaact.hxx>
38 #include <vcl/gdimtf.hxx>
39 #include <vcl/lineinfo.hxx>
40 #include <vcl/outdev.hxx>
41 
42 #include <svdata.hxx>
43 #include <window.h>
44 #include <outdev.h>
45 #include <salgdi.hxx>
46 
47 #include <basegfx/matrix/b2dhommatrix.hxx>
48 #include <basegfx/polygon/b2dpolygon.hxx>
49 #include <basegfx/polygon/b2dpolypolygon.hxx>
50 
51 #define USE_64BIT_INTS
52 
53 // =======================================================================
54 
55 DBG_NAMEEX( OutputDevice )
56 DBG_NAMEEX( Polygon )
57 DBG_NAMEEX( PolyPolygon )
58 DBG_NAMEEX( Region )
59 
60 // =======================================================================
61 
62 static int const s_ImplArySize = MAP_PIXEL+1;
63 static long aImplNumeratorAry[s_ImplArySize] =
64 	{	 1,   1,   5,  50,	  1,   1,  1, 1,  1,	1, 1 };
65 static long aImplDenominatorAry[s_ImplArySize] =
66 	 { 2540, 254, 127, 127, 1000, 100, 10, 1, 72, 1440, 1 };
67 
68 // -----------------------------------------------------------------------
69 
70 /*
71 Reduziert die Genauigkeit bis eine Fraction draus wird (sollte mal
72 ein Fraction ctor werden) koennte man dann auch mit BigInts machen
73 */
74 
75 static Fraction ImplMakeFraction( long nN1, long nN2, long nD1, long nD2 )
76 {
77 	long i = 1;
78 
79 	if ( nN1 < 0 ) { i = -i; nN1 = -nN1; }
80 	if ( nN2 < 0 ) { i = -i; nN2 = -nN2; }
81 	if ( nD1 < 0 ) { i = -i; nD1 = -nD1; }
82 	if ( nD2 < 0 ) { i = -i; nD2 = -nD2; }
83 	// alle positiv; i Vorzeichen
84 
85 	Fraction aF( i*nN1, nD1 );
86 	aF *= Fraction( nN2, nD2 );
87 
88     if( nD1 == 0 || nD2 == 0 ) //under these bad circumstances the following while loop will be endless
89     {
90         DBG_ASSERT(false,"Invalid parameter for ImplMakeFraction");
91         return Fraction( 1, 1 );
92     }
93 
94 	while ( aF.GetDenominator() == -1 )
95 	{
96 		if ( nN1 > nN2 )
97 			nN1 = (nN1 + 1) / 2;
98 		else
99 			nN2 = (nN2 + 1) / 2;
100 		if ( nD1 > nD2 )
101 			nD1 = (nD1 + 1) / 2;
102 		else
103 			nD2 = (nD2 + 1) / 2;
104 
105 		aF = Fraction( i*nN1, nD1 );
106 		aF *= Fraction( nN2, nD2 );
107 	}
108 
109 	return aF;
110 }
111 
112 // -----------------------------------------------------------------------
113 
114 // Fraction.GetNumerator()
115 // Fraction.GetDenominator()	> 0
116 // rOutRes.nPixPerInch? 		> 0
117 // rMapRes.nMapScNum?
118 // rMapRes.nMapScDenom? 		> 0
119 
120 static void ImplCalcBigIntThreshold( long nDPIX, long nDPIY,
121 									 const ImplMapRes& rMapRes,
122 									 ImplThresholdRes& rThresRes )
123 {
124 	if ( nDPIX && (LONG_MAX / nDPIX < Abs( rMapRes.mnMapScNumX ) ) ) // #111139# avoid div by zero
125 	{
126 		rThresRes.mnThresLogToPixX = 0;
127 		rThresRes.mnThresPixToLogX = 0;
128 	}
129 	else
130 	{
131 		// Schwellenwerte fuer BigInt Arithmetik berechnen
132 		long	nDenomHalfX = rMapRes.mnMapScDenomX / 2;
133 		sal_uLong	nDenomX 	= rMapRes.mnMapScDenomX;
134 		long	nProductX	= nDPIX * rMapRes.mnMapScNumX;
135 
136 		if ( !nProductX )
137 			rThresRes.mnThresLogToPixX = LONG_MAX;
138 		else
139 			rThresRes.mnThresLogToPixX = Abs( (LONG_MAX - nDenomHalfX) / nProductX );
140 
141 		if ( !nDenomX )
142 			rThresRes.mnThresPixToLogX = LONG_MAX;
143 		else if ( nProductX >= 0 )
144 			rThresRes.mnThresPixToLogX = (long)(((sal_uLong)LONG_MAX - (sal_uLong)( nProductX/2)) / nDenomX);
145 		else
146 			rThresRes.mnThresPixToLogX = (long)(((sal_uLong)LONG_MAX + (sal_uLong)(-nProductX/2)) / nDenomX);
147 	}
148 
149 	if ( nDPIY && (LONG_MAX / nDPIY < Abs( rMapRes.mnMapScNumY ) ) ) // #111139# avoid div by zero
150 	{
151 		rThresRes.mnThresLogToPixY = 0;
152 		rThresRes.mnThresPixToLogY = 0;
153 	}
154 	else
155 	{
156 		// Schwellenwerte fuer BigInt Arithmetik berechnen
157 		long	nDenomHalfY = rMapRes.mnMapScDenomY / 2;
158 		sal_uLong	nDenomY 	= rMapRes.mnMapScDenomY;
159 		long	nProductY	= nDPIY * rMapRes.mnMapScNumY;
160 
161 		if ( !nProductY )
162 			rThresRes.mnThresLogToPixY = LONG_MAX;
163 		else
164 			rThresRes.mnThresLogToPixY = Abs( (LONG_MAX - nDenomHalfY) / nProductY );
165 
166 		if ( !nDenomY )
167 			rThresRes.mnThresPixToLogY = LONG_MAX;
168 		else if ( nProductY >= 0 )
169 			rThresRes.mnThresPixToLogY = (long)(((sal_uLong)LONG_MAX - (sal_uLong)( nProductY/2)) / nDenomY);
170 		else
171 			rThresRes.mnThresPixToLogY = (long)(((sal_uLong)LONG_MAX + (sal_uLong)(-nProductY/2)) / nDenomY);
172 	}
173 
174 #ifdef USE_64BIT_INTS
175     rThresRes.mnThresLogToPixX /= 2;
176     rThresRes.mnThresLogToPixY /= 2;
177     rThresRes.mnThresPixToLogX /= 2;
178     rThresRes.mnThresPixToLogY /= 2;
179 #endif
180 }
181 
182 // -----------------------------------------------------------------------
183 
184 static void ImplCalcMapResolution( const MapMode& rMapMode,
185 								   long nDPIX, long nDPIY, ImplMapRes& rMapRes )
186 {
187 	switch ( rMapMode.GetMapUnit() )
188 	{
189 		case MAP_RELATIVE:
190 			break;
191 		case MAP_100TH_MM:
192 			rMapRes.mnMapScNumX   = 1;
193 			rMapRes.mnMapScDenomX = 2540;
194 			rMapRes.mnMapScNumY   = 1;
195 			rMapRes.mnMapScDenomY = 2540;
196 			break;
197 		case MAP_10TH_MM:
198 			rMapRes.mnMapScNumX   = 1;
199 			rMapRes.mnMapScDenomX = 254;
200 			rMapRes.mnMapScNumY   = 1;
201 			rMapRes.mnMapScDenomY = 254;
202 			break;
203 		case MAP_MM:
204 			rMapRes.mnMapScNumX   = 5;		// 10
205 			rMapRes.mnMapScDenomX = 127;	// 254
206 			rMapRes.mnMapScNumY   = 5;		// 10
207 			rMapRes.mnMapScDenomY = 127;	// 254
208 			break;
209 		case MAP_CM:
210 			rMapRes.mnMapScNumX   = 50; 	// 100
211 			rMapRes.mnMapScDenomX = 127;	// 254
212 			rMapRes.mnMapScNumY   = 50; 	// 100
213 			rMapRes.mnMapScDenomY = 127;	// 254
214 			break;
215 		case MAP_1000TH_INCH:
216 			rMapRes.mnMapScNumX   = 1;
217 			rMapRes.mnMapScDenomX = 1000;
218 			rMapRes.mnMapScNumY   = 1;
219 			rMapRes.mnMapScDenomY = 1000;
220 			break;
221 		case MAP_100TH_INCH:
222 			rMapRes.mnMapScNumX   = 1;
223 			rMapRes.mnMapScDenomX = 100;
224 			rMapRes.mnMapScNumY   = 1;
225 			rMapRes.mnMapScDenomY = 100;
226 			break;
227 		case MAP_10TH_INCH:
228 			rMapRes.mnMapScNumX   = 1;
229 			rMapRes.mnMapScDenomX = 10;
230 			rMapRes.mnMapScNumY   = 1;
231 			rMapRes.mnMapScDenomY = 10;
232 			break;
233 		case MAP_INCH:
234 			rMapRes.mnMapScNumX   = 1;
235 			rMapRes.mnMapScDenomX = 1;
236 			rMapRes.mnMapScNumY   = 1;
237 			rMapRes.mnMapScDenomY = 1;
238 			break;
239 		case MAP_POINT:
240 			rMapRes.mnMapScNumX   = 1;
241 			rMapRes.mnMapScDenomX = 72;
242 			rMapRes.mnMapScNumY   = 1;
243 			rMapRes.mnMapScDenomY = 72;
244 			break;
245 		case MAP_TWIP:
246 			rMapRes.mnMapScNumX   = 1;
247 			rMapRes.mnMapScDenomX = 1440;
248 			rMapRes.mnMapScNumY   = 1;
249 			rMapRes.mnMapScDenomY = 1440;
250 			break;
251 		case MAP_PIXEL:
252 			rMapRes.mnMapScNumX   = 1;
253 			rMapRes.mnMapScDenomX = nDPIX;
254 			rMapRes.mnMapScNumY   = 1;
255 			rMapRes.mnMapScDenomY = nDPIY;
256 			break;
257 		case MAP_SYSFONT:
258 		case MAP_APPFONT:
259 		case MAP_REALAPPFONT:
260 			{
261 			ImplSVData* pSVData = ImplGetSVData();
262 			if ( !pSVData->maGDIData.mnAppFontX )
263 			{
264                 if( pSVData->maWinData.mpFirstFrame )
265                     Window::ImplInitAppFontData( pSVData->maWinData.mpFirstFrame );
266                 else
267                 {
268                     WorkWindow* pWin = new WorkWindow( NULL, 0 );
269                     Window::ImplInitAppFontData( pWin );
270                     delete pWin;
271                 }
272 			}
273 			if ( rMapMode.GetMapUnit() == MAP_REALAPPFONT )
274 				rMapRes.mnMapScNumX   = pSVData->maGDIData.mnRealAppFontX;
275 			else
276 				rMapRes.mnMapScNumX   = pSVData->maGDIData.mnAppFontX;
277 			rMapRes.mnMapScDenomX = nDPIX * 40;
278 			rMapRes.mnMapScNumY   = pSVData->maGDIData.mnAppFontY;;
279 			rMapRes.mnMapScDenomY = nDPIY * 80;
280 			}
281 			break;
282         default:
283             DBG_ERROR( "unhandled MapUnit" );
284             break;
285 	}
286 
287 	Fraction aScaleX = rMapMode.GetScaleX();
288 	Fraction aScaleY = rMapMode.GetScaleY();
289 
290 	// Offset laut MapMode setzen
291 	Point aOrigin = rMapMode.GetOrigin();
292 	if ( rMapMode.GetMapUnit() != MAP_RELATIVE )
293 	{
294 		rMapRes.mnMapOfsX = aOrigin.X();
295 		rMapRes.mnMapOfsY = aOrigin.Y();
296 	}
297 	else
298 	{
299 		BigInt aX( rMapRes.mnMapOfsX );
300 		aX *= BigInt( aScaleX.GetDenominator() );
301 		if ( rMapRes.mnMapOfsX >= 0 )
302 		{
303 			if ( aScaleX.GetNumerator() >= 0 )
304 				aX += BigInt( aScaleX.GetNumerator()/2 );
305 			else
306 				aX -= BigInt( (aScaleX.GetNumerator()+1)/2 );
307 		}
308 		else
309 		{
310 			if ( aScaleX.GetNumerator() >= 0 )
311 				aX -= BigInt( (aScaleX.GetNumerator()-1)/2 );
312 			else
313 				aX += BigInt( aScaleX.GetNumerator()/2 );
314 		}
315 		aX /= BigInt( aScaleX.GetNumerator() );
316 		rMapRes.mnMapOfsX = (long)aX + aOrigin.X();
317 		BigInt aY( rMapRes.mnMapOfsY );
318 		aY *= BigInt( aScaleY.GetDenominator() );
319 		if( rMapRes.mnMapOfsY >= 0 )
320 		{
321 			if ( aScaleY.GetNumerator() >= 0 )
322 				aY += BigInt( aScaleY.GetNumerator()/2 );
323 			else
324 				aY -= BigInt( (aScaleY.GetNumerator()+1)/2 );
325 		}
326 		else
327 		{
328 			if ( aScaleY.GetNumerator() >= 0 )
329 				aY -= BigInt( (aScaleY.GetNumerator()-1)/2 );
330 			else
331 				aY += BigInt( aScaleY.GetNumerator()/2 );
332 		}
333 		aY /= BigInt( aScaleY.GetNumerator() );
334 		rMapRes.mnMapOfsY = (long)aY + aOrigin.Y();
335 	}
336 
337 	// Scaling Faktor laut MapMode einberechnen
338 	// aTemp? = rMapRes.mnMapSc? * aScale?
339 	Fraction aTempX = ImplMakeFraction( rMapRes.mnMapScNumX,
340 										aScaleX.GetNumerator(),
341 										rMapRes.mnMapScDenomX,
342 										aScaleX.GetDenominator() );
343 	Fraction aTempY = ImplMakeFraction( rMapRes.mnMapScNumY,
344 										aScaleY.GetNumerator(),
345 										rMapRes.mnMapScDenomY,
346 										aScaleY.GetDenominator() );
347 	rMapRes.mnMapScNumX   = aTempX.GetNumerator();
348 	rMapRes.mnMapScDenomX = aTempX.GetDenominator();
349 	rMapRes.mnMapScNumY   = aTempY.GetNumerator();
350 	rMapRes.mnMapScDenomY = aTempY.GetDenominator();
351 
352 	// hack: 0/n ungef"ahr 1/max
353 	if ( !rMapRes.mnMapScNumX )
354 	{
355 		rMapRes.mnMapScNumX = 1;
356 		rMapRes.mnMapScDenomX = LONG_MAX;
357 	}
358 	if ( !rMapRes.mnMapScNumY )
359 	{
360 		rMapRes.mnMapScNumY = 1;
361 		rMapRes.mnMapScDenomY = LONG_MAX;
362 	}
363 }
364 
365 // -----------------------------------------------------------------------
366 
367 inline void ImplCalcMapResolution( const MapMode& rMapMode,
368 								   long nDPIX, long nDPIY,
369 								   ImplMapRes& rMapRes,
370 								   ImplThresholdRes& rThresRes )
371 {
372 	ImplCalcMapResolution( rMapMode, nDPIX, nDPIY, rMapRes );
373 	ImplCalcBigIntThreshold( nDPIX, nDPIY, rMapRes, rThresRes );
374 }
375 
376 // -----------------------------------------------------------------------
377 
378 static long ImplLogicToPixel( long n, long nDPI, long nMapNum, long nMapDenom,
379 							  long nThres )
380 {
381     // To "use" it...
382     (void) nThres;
383 #ifdef USE_64BIT_INTS
384 #if (SAL_TYPES_SIZEOFLONG < 8)
385     if( (+n < nThres) && (-n < nThres) )
386     {
387        n *= nMapNum * nDPI;
388        if( nMapDenom != 1 )
389        {
390           n = (2 * n) / nMapDenom;
391           if( n < 0 ) --n; else ++n;
392           n /= 2;
393        }
394     }
395     else
396 #endif
397     {
398        sal_Int64 n64 = n;
399        n64 *= nMapNum;
400        n64 *= nDPI;
401        if( nMapDenom == 1 )
402           n = (long)n64;
403        else
404        {
405           n = (long)(2 * n64 / nMapDenom);
406           if( n < 0 ) --n; else ++n;
407           n /= 2;
408        }
409     }
410     return n;
411 #else // USE_64BIT_INTS
412 	if ( Abs( n ) < nThres )
413 	{
414 		n *= nDPI * nMapNum;
415 		n += n >= 0 ? nMapDenom/2 : -((nMapDenom-1)/2);
416                 return (n / nMapDenom);
417 	}
418 	else
419 	{
420 		BigInt aTemp( n );
421 		aTemp *= BigInt( nDPI );
422 		aTemp *= BigInt( nMapNum );
423 
424 		if ( aTemp.IsNeg() )
425 		{
426 			BigInt aMapScDenom2( (nMapDenom-1)/2 );
427 			aTemp -= aMapScDenom2;
428 		}
429 		else
430 		{
431 			BigInt aMapScDenom2( nMapDenom/2 );
432 			aTemp += aMapScDenom2;
433 		}
434 
435 		aTemp /= BigInt( nMapDenom );
436 		return (long)aTemp;
437 	}
438 #endif
439 }
440 
441 // -----------------------------------------------------------------------
442 
443 static long ImplPixelToLogic( long n, long nDPI, long nMapNum, long nMapDenom,
444 							  long nThres )
445 {
446     // To "use" it...
447    (void) nThres;
448 #ifdef USE_64BIT_INTS
449 #if (SAL_TYPES_SIZEOFLONG < 8)
450     if( (+n < nThres) && (-n < nThres) )
451         n = (2 * n * nMapDenom) / (nDPI * nMapNum);
452     else
453 #endif
454     {
455         sal_Int64 n64 = n;
456         n64 *= nMapDenom;
457         long nDenom  = nDPI * nMapNum;
458         n = (long)(2 * n64 / nDenom);
459     }
460     if( n < 0 ) --n; else ++n;
461     return (n / 2);
462 #else // USE_64BIT_INTS
463 	if ( Abs( n ) < nThres )
464 	{
465 		long nDenom  = nDPI * nMapNum;
466 		long nNum    = n * nMapDenom;
467 		if( (nNum ^ nDenom) >= 0 )
468 			nNum += nDenom/2;
469 		else
470 			nNum -= nDenom/2;
471 		return (nNum / nDenom);
472 	}
473 	else
474 	{
475 		BigInt aDenom( nDPI );
476 		aDenom *= BigInt( nMapNum );
477 
478 		BigInt aNum( n );
479 		aNum *= BigInt( nMapDenom );
480 
481 		BigInt aDenom2( aDenom );
482 		if ( aNum.IsNeg() )
483 		{
484 			if ( aDenom.IsNeg() )
485 			{
486 				aDenom2 /= BigInt(2);
487 				aNum += aDenom2;
488 			}
489 			else
490 			{
491 				aDenom2 -= 1;
492 				aDenom2 /= BigInt(2);
493 				aNum -= aDenom2;
494 			}
495 		}
496 		else
497 		{
498 			if ( aDenom.IsNeg() )
499 			{
500 				aDenom2 += 1;
501 				aDenom2 /= BigInt(2);
502 				aNum -= aDenom2;
503 			}
504 			else
505 			{
506 				aDenom2 /= BigInt(2);
507 				aNum += aDenom2;
508 			}
509 		}
510 
511 		aNum  /= aDenom;
512 		return (long)aNum;
513 	}
514 #endif
515 }
516 
517 // -----------------------------------------------------------------------
518 
519 long OutputDevice::ImplLogicXToDevicePixel( long nX ) const
520 {
521 	if ( !mbMap )
522 		return nX+mnOutOffX;
523 
524 	return ImplLogicToPixel( nX + maMapRes.mnMapOfsX, mnDPIX,
525 							 maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
526 							 maThresRes.mnThresLogToPixX )+mnOutOffX+mnOutOffOrigX;
527 }
528 
529 // -----------------------------------------------------------------------
530 
531 long OutputDevice::ImplLogicYToDevicePixel( long nY ) const
532 {
533 	if ( !mbMap )
534 		return nY+mnOutOffY;
535 
536 	return ImplLogicToPixel( nY + maMapRes.mnMapOfsY, mnDPIY,
537 							 maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
538 							 maThresRes.mnThresLogToPixY )+mnOutOffY+mnOutOffOrigY;
539 }
540 
541 // -----------------------------------------------------------------------
542 
543 long OutputDevice::ImplLogicWidthToDevicePixel( long nWidth ) const
544 {
545 	if ( !mbMap )
546 		return nWidth;
547 
548 	return ImplLogicToPixel( nWidth, mnDPIX,
549 							 maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
550 							 maThresRes.mnThresLogToPixX );
551 }
552 
553 float OutputDevice::ImplFloatLogicWidthToDevicePixel( float fLogicWidth) const
554 {
555 	if( !mbMap)
556 		return fLogicWidth;
557 	// TODO: consolidate the calculation into one multiplication
558 	float fPixelWidth = (fLogicWidth * mnDPIX * maMapRes.mnMapScNumX) / maMapRes.mnMapScDenomX;
559 	return fPixelWidth;
560 }
561 
562 // -----------------------------------------------------------------------
563 
564 long OutputDevice::ImplLogicHeightToDevicePixel( long nHeight ) const
565 {
566 	if ( !mbMap )
567 		return nHeight;
568 
569 	return ImplLogicToPixel( nHeight, mnDPIY,
570 							 maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
571 							 maThresRes.mnThresLogToPixY );
572 }
573 
574 float OutputDevice::ImplFloatLogicHeightToDevicePixel( float fLogicHeight) const
575 {
576 	if( !mbMap)
577 		return fLogicHeight;
578 	float fPixelHeight = (fLogicHeight * mnDPIY * maMapRes.mnMapScNumY) / maMapRes.mnMapScDenomY;
579 	return fPixelHeight;
580 }
581 
582 // -----------------------------------------------------------------------
583 
584 long OutputDevice::ImplDevicePixelToLogicWidth( long nWidth ) const
585 {
586 	if ( !mbMap )
587 		return nWidth;
588 
589 	return ImplPixelToLogic( nWidth, mnDPIX,
590 							 maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
591 							 maThresRes.mnThresPixToLogX );
592 }
593 
594 float OutputDevice::ImplFloatDevicePixelToLogicWidth( float fPixelWidth) const
595 {
596 	if( !mbMap)
597 		return fPixelWidth;
598 	float fLogicHeight = (fPixelWidth * maMapRes.mnMapScDenomX) / (mnDPIX * maMapRes.mnMapScNumX);
599 	return fLogicHeight;
600 }
601 
602 // -----------------------------------------------------------------------
603 
604 long OutputDevice::ImplDevicePixelToLogicHeight( long nHeight ) const
605 {
606 	if ( !mbMap )
607 		return nHeight;
608 
609 	return ImplPixelToLogic( nHeight, mnDPIY,
610 							 maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
611 							 maThresRes.mnThresPixToLogY );
612 }
613 
614 float OutputDevice::ImplFloatDevicePixelToLogicHeight( float fPixelHeight) const
615 {
616 	if( !mbMap)
617 		return fPixelHeight;
618 	float fLogicHeight = (fPixelHeight * maMapRes.mnMapScDenomY) / (mnDPIY * maMapRes.mnMapScNumY);
619 	return fLogicHeight;
620 }
621 
622 
623 // -----------------------------------------------------------------------
624 
625 Point OutputDevice::ImplLogicToDevicePixel( const Point& rLogicPt ) const
626 {
627 	if ( !mbMap )
628 		return Point( rLogicPt.X()+mnOutOffX, rLogicPt.Y()+mnOutOffY );
629 
630 	return Point( ImplLogicToPixel( rLogicPt.X() + maMapRes.mnMapOfsX, mnDPIX,
631 									maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
632 									maThresRes.mnThresLogToPixX )+mnOutOffX+mnOutOffOrigX,
633 				  ImplLogicToPixel( rLogicPt.Y() + maMapRes.mnMapOfsY, mnDPIY,
634 									maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
635 									maThresRes.mnThresLogToPixY )+mnOutOffY+mnOutOffOrigY );
636 }
637 
638 // -----------------------------------------------------------------------
639 
640 Size OutputDevice::ImplLogicToDevicePixel( const Size& rLogicSize ) const
641 {
642 	if ( !mbMap )
643 		return rLogicSize;
644 
645 	return Size( ImplLogicToPixel( rLogicSize.Width(), mnDPIX,
646 								   maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
647 								   maThresRes.mnThresLogToPixX ),
648 				 ImplLogicToPixel( rLogicSize.Height(), mnDPIY,
649 								   maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
650 								   maThresRes.mnThresLogToPixY ) );
651 }
652 
653 // -----------------------------------------------------------------------
654 
655 Rectangle OutputDevice::ImplLogicToDevicePixel( const Rectangle& rLogicRect ) const
656 {
657 	if ( rLogicRect.IsEmpty() )
658 		return rLogicRect;
659 
660 	if ( !mbMap )
661 	{
662 		return Rectangle( rLogicRect.Left()+mnOutOffX, rLogicRect.Top()+mnOutOffY,
663 						  rLogicRect.Right()+mnOutOffX, rLogicRect.Bottom()+mnOutOffY );
664 	}
665 
666 	return Rectangle( ImplLogicToPixel( rLogicRect.Left()+maMapRes.mnMapOfsX, mnDPIX,
667 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
668 										maThresRes.mnThresLogToPixX )+mnOutOffX+mnOutOffOrigX,
669 					  ImplLogicToPixel( rLogicRect.Top()+maMapRes.mnMapOfsY, mnDPIY,
670 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
671 										maThresRes.mnThresLogToPixY )+mnOutOffY+mnOutOffOrigY,
672 					  ImplLogicToPixel( rLogicRect.Right()+maMapRes.mnMapOfsX, mnDPIX,
673 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
674 										maThresRes.mnThresLogToPixX )+mnOutOffX+mnOutOffOrigX,
675 					  ImplLogicToPixel( rLogicRect.Bottom()+maMapRes.mnMapOfsY, mnDPIY,
676 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
677 										maThresRes.mnThresLogToPixY )+mnOutOffY+mnOutOffOrigY );
678 }
679 
680 // -----------------------------------------------------------------------
681 
682 Polygon OutputDevice::ImplLogicToDevicePixel( const Polygon& rLogicPoly ) const
683 {
684 	if ( !mbMap && !mnOutOffX && !mnOutOffY )
685 		return rLogicPoly;
686 
687 	sal_uInt16	i;
688 	sal_uInt16	nPoints = rLogicPoly.GetSize();
689 	Polygon aPoly( rLogicPoly );
690 
691 	// Pointer auf das Point-Array holen (Daten werden kopiert)
692 	const Point* pPointAry = aPoly.GetConstPointAry();
693 
694 	if ( mbMap )
695 	{
696 		for ( i = 0; i < nPoints; i++ )
697 		{
698 			const Point* pPt = &(pPointAry[i]);
699             Point aPt;
700 			aPt.X() = ImplLogicToPixel( pPt->X()+maMapRes.mnMapOfsX, mnDPIX,
701                                         maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
702                                         maThresRes.mnThresLogToPixX )+mnOutOffX+mnOutOffOrigX;
703 			aPt.Y() = ImplLogicToPixel( pPt->Y()+maMapRes.mnMapOfsY, mnDPIY,
704                                         maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
705                                         maThresRes.mnThresLogToPixY )+mnOutOffY+mnOutOffOrigY;
706             aPoly[i] = aPt;
707 		}
708 	}
709 	else
710 	{
711 		for ( i = 0; i < nPoints; i++ )
712 		{
713 			Point aPt = pPointAry[i];
714 			aPt.X() += mnOutOffX;
715 			aPt.Y() += mnOutOffY;
716             aPoly[i] = aPt;
717 		}
718 	}
719 
720 	return aPoly;
721 }
722 
723 // -----------------------------------------------------------------------
724 
725 PolyPolygon OutputDevice::ImplLogicToDevicePixel( const PolyPolygon& rLogicPolyPoly ) const
726 {
727 	if ( !mbMap && !mnOutOffX && !mnOutOffY )
728 		return rLogicPolyPoly;
729 
730 	PolyPolygon aPolyPoly( rLogicPolyPoly );
731 	sal_uInt16		nPoly = aPolyPoly.Count();
732 	for( sal_uInt16 i = 0; i < nPoly; i++ )
733 	{
734 		Polygon& rPoly = aPolyPoly[i];
735 		rPoly = ImplLogicToDevicePixel( rPoly );
736 	}
737 	return aPolyPoly;
738 }
739 
740 // -----------------------------------------------------------------------
741 
742 LineInfo OutputDevice::ImplLogicToDevicePixel( const LineInfo& rLineInfo ) const
743 {
744 	LineInfo aInfo( rLineInfo );
745 
746 	if( aInfo.GetStyle() == LINE_DASH )
747 	{
748 		if( aInfo.GetDotCount() && aInfo.GetDotLen() )
749 			aInfo.SetDotLen( Max( ImplLogicWidthToDevicePixel( aInfo.GetDotLen() ), 1L ) );
750 		else
751 			aInfo.SetDotCount( 0 );
752 
753 		if( aInfo.GetDashCount() && aInfo.GetDashLen() )
754 			aInfo.SetDashLen( Max( ImplLogicWidthToDevicePixel( aInfo.GetDashLen() ), 1L ) );
755 		else
756 			aInfo.SetDashCount( 0 );
757 
758 		aInfo.SetDistance( ImplLogicWidthToDevicePixel( aInfo.GetDistance() ) );
759 
760 		if( ( !aInfo.GetDashCount() && !aInfo.GetDotCount() ) || !aInfo.GetDistance() )
761 			aInfo.SetStyle( LINE_SOLID );
762 	}
763 
764 	aInfo.SetWidth( ImplLogicWidthToDevicePixel( aInfo.GetWidth() ) );
765 
766 	return aInfo;
767 }
768 
769 // -----------------------------------------------------------------------
770 
771 Rectangle OutputDevice::ImplDevicePixelToLogic( const Rectangle& rPixelRect ) const
772 {
773 	if ( rPixelRect.IsEmpty() )
774 		return rPixelRect;
775 
776 	if ( !mbMap )
777 	{
778 		return Rectangle( rPixelRect.Left()-mnOutOffX, rPixelRect.Top()-mnOutOffY,
779 						  rPixelRect.Right()-mnOutOffX, rPixelRect.Bottom()-mnOutOffY );
780 	}
781 
782 	return Rectangle( ImplPixelToLogic( rPixelRect.Left()-mnOutOffX-mnOutOffOrigX, mnDPIX,
783 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
784 										maThresRes.mnThresPixToLogX )-maMapRes.mnMapOfsX,
785 					  ImplPixelToLogic( rPixelRect.Top()-mnOutOffY-mnOutOffOrigY, mnDPIY,
786 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
787 										maThresRes.mnThresPixToLogY )-maMapRes.mnMapOfsY,
788 					  ImplPixelToLogic( rPixelRect.Right()-mnOutOffX-mnOutOffOrigX, mnDPIX,
789 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
790 										maThresRes.mnThresPixToLogX )-maMapRes.mnMapOfsX,
791 					  ImplPixelToLogic( rPixelRect.Bottom()-mnOutOffY-mnOutOffOrigY, mnDPIY,
792 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
793 										maThresRes.mnThresPixToLogY )-maMapRes.mnMapOfsY );
794 }
795 
796 // -----------------------------------------------------------------------
797 
798 Region OutputDevice::ImplPixelToDevicePixel( const Region& rRegion ) const
799 {
800 	if ( !mnOutOffX && !mnOutOffY )
801 		return rRegion;
802 
803 	Region aRegion( rRegion );
804 	aRegion.Move( mnOutOffX+mnOutOffOrigX, mnOutOffY+mnOutOffOrigY );
805 	return aRegion;
806 }
807 
808 // -----------------------------------------------------------------------
809 
810 void OutputDevice::EnableMapMode( sal_Bool bEnable )
811 {
812     mbMap = (bEnable != 0);
813 
814     if( mpAlphaVDev )
815         mpAlphaVDev->EnableMapMode( bEnable );
816 }
817 
818 // -----------------------------------------------------------------------
819 
820 void OutputDevice::SetMapMode()
821 {
822 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
823 
824 	if ( mpMetaFile )
825 		mpMetaFile->AddAction( new MetaMapModeAction( MapMode() ) );
826 
827 	if ( mbMap || !maMapMode.IsDefault() )
828 	{
829 		mbMap		= sal_False;
830 		maMapMode	= MapMode();
831 
832 		// create new objects (clip region werden nicht neu skaliert)
833 		mbNewFont	= sal_True;
834 		mbInitFont	= sal_True;
835 		if ( GetOutDevType() == OUTDEV_WINDOW )
836 		{
837 			if ( ((Window*)this)->mpWindowImpl->mpCursor )
838 				((Window*)this)->mpWindowImpl->mpCursor->ImplNew();
839 		}
840 
841         // #106426# Adapt logical offset when changing mapmode
842         mnOutOffLogicX = mnOutOffOrigX; // no mapping -> equal offsets
843         mnOutOffLogicY = mnOutOffOrigY;
844 
845 		// #i75163#
846 		ImplInvalidateViewTransform();
847 	}
848 
849     if( mpAlphaVDev )
850         mpAlphaVDev->SetMapMode();
851 }
852 
853 // -----------------------------------------------------------------------
854 
855 void OutputDevice::SetMapMode( const MapMode& rNewMapMode )
856 {
857 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
858 
859 	sal_Bool bRelMap = (rNewMapMode.GetMapUnit() == MAP_RELATIVE);
860 
861 	if ( mpMetaFile )
862 	{
863 		mpMetaFile->AddAction( new MetaMapModeAction( rNewMapMode ) );
864 #ifdef DBG_UTIL
865 		if ( GetOutDevType() != OUTDEV_PRINTER )
866 			DBG_ASSERTWARNING( bRelMap, "Please record only relative MapModes!" );
867 #endif
868 	}
869 
870 	// Ist der MapMode der gleiche wie vorher, dann mache nichts
871 	if ( maMapMode == rNewMapMode )
872 		return;
873 
874     if( mpAlphaVDev )
875         mpAlphaVDev->SetMapMode( rNewMapMode );
876 
877 	// Ist Default-MapMode, dann bereche nichts
878 	sal_Bool bOldMap = mbMap;
879 	mbMap = !rNewMapMode.IsDefault();
880 	if ( mbMap )
881 	{
882 		// Falls nur der Orign umgesetzt wird, dann scaliere nichts neu
883 		if ( (rNewMapMode.GetMapUnit() == maMapMode.GetMapUnit()) &&
884 			 (rNewMapMode.GetScaleX()  == maMapMode.GetScaleX())  &&
885 			 (rNewMapMode.GetScaleY()  == maMapMode.GetScaleY())  &&
886 			 (bOldMap				   == mbMap) )
887 		{
888 			// Offset setzen
889 			Point aOrigin = rNewMapMode.GetOrigin();
890 			maMapRes.mnMapOfsX = aOrigin.X();
891 			maMapRes.mnMapOfsY = aOrigin.Y();
892 			maMapMode = rNewMapMode;
893 
894 			// #i75163#
895 			ImplInvalidateViewTransform();
896 
897 			return;
898 		}
899 		if ( !bOldMap && bRelMap )
900 		{
901 			maMapRes.mnMapScNumX	= 1;
902 			maMapRes.mnMapScNumY	= 1;
903 			maMapRes.mnMapScDenomX	= mnDPIX;
904 			maMapRes.mnMapScDenomY	= mnDPIY;
905 			maMapRes.mnMapOfsX		= 0;
906 			maMapRes.mnMapOfsY		= 0;
907 		}
908 
909 		// Neue MapMode-Aufloesung berechnen
910 		ImplCalcMapResolution( rNewMapMode, mnDPIX, mnDPIY, maMapRes, maThresRes );
911 	}
912 
913 	// Neuen MapMode setzen
914 	if ( bRelMap )
915 	{
916 		Point aOrigin( maMapRes.mnMapOfsX, maMapRes.mnMapOfsY );
917 		// aScale? = maMapMode.GetScale?() * rNewMapMode.GetScale?()
918 		Fraction aScaleX = ImplMakeFraction( maMapMode.GetScaleX().GetNumerator(),
919 											 rNewMapMode.GetScaleX().GetNumerator(),
920 											 maMapMode.GetScaleX().GetDenominator(),
921 											 rNewMapMode.GetScaleX().GetDenominator() );
922 		Fraction aScaleY = ImplMakeFraction( maMapMode.GetScaleY().GetNumerator(),
923 											 rNewMapMode.GetScaleY().GetNumerator(),
924 											 maMapMode.GetScaleY().GetDenominator(),
925 											 rNewMapMode.GetScaleY().GetDenominator() );
926 		maMapMode.SetOrigin( aOrigin );
927 		maMapMode.SetScaleX( aScaleX );
928 		maMapMode.SetScaleY( aScaleY );
929 	}
930 	else
931 		maMapMode = rNewMapMode;
932 
933 	// create new objects (clip region werden nicht neu skaliert)
934 	mbNewFont	= sal_True;
935 	mbInitFont	= sal_True;
936 	if ( GetOutDevType() == OUTDEV_WINDOW )
937 	{
938 		if ( ((Window*)this)->mpWindowImpl->mpCursor )
939 			((Window*)this)->mpWindowImpl->mpCursor->ImplNew();
940 	}
941 
942     // #106426# Adapt logical offset when changing mapmode
943 	mnOutOffLogicX = ImplPixelToLogic( mnOutOffOrigX, mnDPIX,
944                                        maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
945                                        maThresRes.mnThresPixToLogX );
946 	mnOutOffLogicY = ImplPixelToLogic( mnOutOffOrigY, mnDPIY,
947                                        maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
948                                        maThresRes.mnThresPixToLogY );
949 
950 	// #i75163#
951 	ImplInvalidateViewTransform();
952 }
953 
954 // -----------------------------------------------------------------------
955 
956 void OutputDevice::SetRelativeMapMode( const MapMode& rNewMapMode )
957 {
958 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
959 
960 	// Ist der MapMode der gleiche wie vorher, dann mache nichts
961 	if ( maMapMode == rNewMapMode )
962 		return;
963 
964 	MapUnit eOld = maMapMode.GetMapUnit();
965 	MapUnit eNew = rNewMapMode.GetMapUnit();
966 
967 	// a?F = rNewMapMode.GetScale?() / maMapMode.GetScale?()
968 	Fraction aXF = ImplMakeFraction( rNewMapMode.GetScaleX().GetNumerator(),
969 									 maMapMode.GetScaleX().GetDenominator(),
970 									 rNewMapMode.GetScaleX().GetDenominator(),
971 									 maMapMode.GetScaleX().GetNumerator() );
972 	Fraction aYF = ImplMakeFraction( rNewMapMode.GetScaleY().GetNumerator(),
973 									 maMapMode.GetScaleY().GetDenominator(),
974 									 rNewMapMode.GetScaleY().GetDenominator(),
975 									 maMapMode.GetScaleY().GetNumerator() );
976 
977 	Point aPt( LogicToLogic( Point(), NULL, &rNewMapMode ) );
978 	if ( eNew != eOld )
979 	{
980 		if ( eOld > MAP_PIXEL )
981 		{
982 			DBG_ERRORFILE( "Not implemented MapUnit" );
983 		}
984 		else if ( eNew > MAP_PIXEL )
985 		{
986 			DBG_ERRORFILE( "Not implemented MapUnit" );
987 		}
988 		else
989 		{
990 			Fraction aF( aImplNumeratorAry[eNew] * aImplDenominatorAry[eOld],
991 						 aImplNumeratorAry[eOld] * aImplDenominatorAry[eNew] );
992 
993 			// a?F =  a?F * aF
994 			aXF = ImplMakeFraction( aXF.GetNumerator(),   aF.GetNumerator(),
995 									aXF.GetDenominator(), aF.GetDenominator() );
996 			aYF = ImplMakeFraction( aYF.GetNumerator(),   aF.GetNumerator(),
997 									aYF.GetDenominator(), aF.GetDenominator() );
998 			if ( eOld == MAP_PIXEL )
999 			{
1000 				aXF *= Fraction( mnDPIX, 1 );
1001 				aYF *= Fraction( mnDPIY, 1 );
1002 			}
1003 			else if ( eNew == MAP_PIXEL )
1004 			{
1005 				aXF *= Fraction( 1, mnDPIX );
1006 				aYF *= Fraction( 1, mnDPIY );
1007 			}
1008 		}
1009 	}
1010 
1011 	MapMode aNewMapMode( MAP_RELATIVE, Point( -aPt.X(), -aPt.Y() ), aXF, aYF );
1012 	SetMapMode( aNewMapMode );
1013 
1014 	if ( eNew != eOld )
1015 		maMapMode = rNewMapMode;
1016 
1017     // #106426# Adapt logical offset when changing mapmode
1018 	mnOutOffLogicX = ImplPixelToLogic( mnOutOffOrigX, mnDPIX,
1019                                        maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1020                                        maThresRes.mnThresPixToLogX );
1021 	mnOutOffLogicY = ImplPixelToLogic( mnOutOffOrigY, mnDPIY,
1022                                        maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1023                                        maThresRes.mnThresPixToLogY );
1024 
1025     if( mpAlphaVDev )
1026         mpAlphaVDev->SetRelativeMapMode( rNewMapMode );
1027 }
1028 
1029 // -----------------------------------------------------------------------
1030 
1031 // #i75163#
1032 basegfx::B2DHomMatrix OutputDevice::GetViewTransformation() const
1033 {
1034     if(mbMap)
1035     {
1036         // #i82615#
1037         if(!mpOutDevData)
1038         {
1039     		const_cast< OutputDevice* >(this)->ImplInitOutDevData();
1040         }
1041 
1042 		if(!mpOutDevData->mpViewTransform)
1043 		{
1044 			mpOutDevData->mpViewTransform = new basegfx::B2DHomMatrix;
1045 
1046 			const double fScaleFactorX((double)mnDPIX * (double)maMapRes.mnMapScNumX / (double)maMapRes.mnMapScDenomX);
1047 			const double fScaleFactorY((double)mnDPIY * (double)maMapRes.mnMapScNumY / (double)maMapRes.mnMapScDenomY);
1048 			const double fZeroPointX(((double)maMapRes.mnMapOfsX * fScaleFactorX) + (double)mnOutOffOrigX);
1049 			const double fZeroPointY(((double)maMapRes.mnMapOfsY * fScaleFactorY) + (double)mnOutOffOrigY);
1050 
1051 			mpOutDevData->mpViewTransform->set(0, 0, fScaleFactorX);
1052 			mpOutDevData->mpViewTransform->set(1, 1, fScaleFactorY);
1053 			mpOutDevData->mpViewTransform->set(0, 2, fZeroPointX);
1054 			mpOutDevData->mpViewTransform->set(1, 2, fZeroPointY);
1055 		}
1056 
1057 		return *mpOutDevData->mpViewTransform;
1058     }
1059 	else
1060 	{
1061 		return basegfx::B2DHomMatrix();
1062 	}
1063 }
1064 
1065 // -----------------------------------------------------------------------
1066 
1067 // #i75163#
1068 basegfx::B2DHomMatrix OutputDevice::GetInverseViewTransformation() const
1069 {
1070     if(mbMap)
1071     {
1072         // #i82615#
1073         if(!mpOutDevData)
1074         {
1075     		const_cast< OutputDevice* >(this)->ImplInitOutDevData();
1076         }
1077 
1078         if(!mpOutDevData->mpInverseViewTransform)
1079 		{
1080 			GetViewTransformation();
1081 			mpOutDevData->mpInverseViewTransform = new basegfx::B2DHomMatrix(*mpOutDevData->mpViewTransform);
1082 			mpOutDevData->mpInverseViewTransform->invert();
1083 		}
1084 
1085 		return *mpOutDevData->mpInverseViewTransform;
1086 	}
1087 	else
1088 	{
1089 		return basegfx::B2DHomMatrix();
1090 	}
1091 }
1092 
1093 // -----------------------------------------------------------------------
1094 
1095 // #i75163#
1096 basegfx::B2DHomMatrix OutputDevice::GetViewTransformation( const MapMode& rMapMode ) const
1097 {
1098     // #i82615#
1099 	ImplMapRes			aMapRes;
1100 	ImplThresholdRes	aThresRes;
1101 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1102 
1103 	basegfx::B2DHomMatrix aTransform;
1104 
1105 	const double fScaleFactorX((double)mnDPIX * (double)aMapRes.mnMapScNumX / (double)aMapRes.mnMapScDenomX);
1106 	const double fScaleFactorY((double)mnDPIY * (double)aMapRes.mnMapScNumY / (double)aMapRes.mnMapScDenomY);
1107 	const double fZeroPointX(((double)aMapRes.mnMapOfsX * fScaleFactorX) + (double)mnOutOffOrigX);
1108 	const double fZeroPointY(((double)aMapRes.mnMapOfsY * fScaleFactorY) + (double)mnOutOffOrigY);
1109 
1110 	aTransform.set(0, 0, fScaleFactorX);
1111 	aTransform.set(1, 1, fScaleFactorY);
1112 	aTransform.set(0, 2, fZeroPointX);
1113 	aTransform.set(1, 2, fZeroPointY);
1114 
1115 	return aTransform;
1116 }
1117 
1118 // -----------------------------------------------------------------------
1119 
1120 // #i75163#
1121 basegfx::B2DHomMatrix OutputDevice::GetInverseViewTransformation( const MapMode& rMapMode ) const
1122 {
1123     basegfx::B2DHomMatrix aMatrix( GetViewTransformation( rMapMode ) );
1124     aMatrix.invert();
1125     return aMatrix;
1126 }
1127 
1128 // -----------------------------------------------------------------------
1129 
1130 basegfx::B2DHomMatrix OutputDevice::ImplGetDeviceTransformation() const
1131 {
1132 	basegfx::B2DHomMatrix aTransformation = GetViewTransformation();
1133 	// TODO: is it worth to cache the transformed result?
1134 	if( mnOutOffX || mnOutOffY )
1135 		aTransformation.translate( mnOutOffX, mnOutOffY );
1136 	return aTransformation;
1137 }
1138 
1139 // -----------------------------------------------------------------------
1140 
1141 Point OutputDevice::LogicToPixel( const Point& rLogicPt ) const
1142 {
1143 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1144 
1145 	if ( !mbMap )
1146 		return rLogicPt;
1147 
1148 	return Point( ImplLogicToPixel( rLogicPt.X() + maMapRes.mnMapOfsX, mnDPIX,
1149 									maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1150 									maThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1151 				  ImplLogicToPixel( rLogicPt.Y() + maMapRes.mnMapOfsY, mnDPIY,
1152 									maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1153 									maThresRes.mnThresLogToPixY )+mnOutOffOrigY );
1154 }
1155 
1156 // -----------------------------------------------------------------------
1157 
1158 Size OutputDevice::LogicToPixel( const Size& rLogicSize ) const
1159 {
1160 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1161 
1162 	if ( !mbMap )
1163 		return rLogicSize;
1164 
1165 	return Size( ImplLogicToPixel( rLogicSize.Width(), mnDPIX,
1166 								   maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1167 								   maThresRes.mnThresLogToPixX ),
1168 				 ImplLogicToPixel( rLogicSize.Height(), mnDPIY,
1169 								   maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1170 								   maThresRes.mnThresLogToPixY ) );
1171 }
1172 
1173 // -----------------------------------------------------------------------
1174 
1175 Rectangle OutputDevice::LogicToPixel( const Rectangle& rLogicRect ) const
1176 {
1177 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1178 
1179 	if ( !mbMap || rLogicRect.IsEmpty() )
1180 		return rLogicRect;
1181 
1182 	return Rectangle( ImplLogicToPixel( rLogicRect.Left() + maMapRes.mnMapOfsX, mnDPIX,
1183 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1184 										maThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1185 					  ImplLogicToPixel( rLogicRect.Top() + maMapRes.mnMapOfsY, mnDPIY,
1186 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1187 										maThresRes.mnThresLogToPixY )+mnOutOffOrigY,
1188 					  ImplLogicToPixel( rLogicRect.Right() + maMapRes.mnMapOfsX, mnDPIX,
1189 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1190 										maThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1191 					  ImplLogicToPixel( rLogicRect.Bottom() + maMapRes.mnMapOfsY, mnDPIY,
1192 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1193 										maThresRes.mnThresLogToPixY )+mnOutOffOrigY );
1194 }
1195 
1196 // -----------------------------------------------------------------------
1197 
1198 Polygon OutputDevice::LogicToPixel( const Polygon& rLogicPoly ) const
1199 {
1200 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1201 	DBG_CHKOBJ( &rLogicPoly, Polygon, NULL );
1202 
1203 	if ( !mbMap )
1204 		return rLogicPoly;
1205 
1206 	sal_uInt16	i;
1207 	sal_uInt16	nPoints = rLogicPoly.GetSize();
1208 	Polygon aPoly( rLogicPoly );
1209 
1210 	// Pointer auf das Point-Array holen (Daten werden kopiert)
1211 	const Point* pPointAry = aPoly.GetConstPointAry();
1212 
1213     for ( i = 0; i < nPoints; i++ )
1214     {
1215         const Point* pPt = &(pPointAry[i]);
1216         Point aPt;
1217         aPt.X() = ImplLogicToPixel( pPt->X() + maMapRes.mnMapOfsX, mnDPIX,
1218                                     maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1219                                     maThresRes.mnThresLogToPixX )+mnOutOffOrigX;
1220         aPt.Y() = ImplLogicToPixel( pPt->Y() + maMapRes.mnMapOfsY, mnDPIY,
1221                                     maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1222                                     maThresRes.mnThresLogToPixY )+mnOutOffOrigY;
1223         aPoly[i] = aPt;
1224     }
1225 
1226 	return aPoly;
1227 }
1228 
1229 // -----------------------------------------------------------------------
1230 
1231 PolyPolygon OutputDevice::LogicToPixel( const PolyPolygon& rLogicPolyPoly ) const
1232 {
1233 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1234 	DBG_CHKOBJ( &rLogicPolyPoly, PolyPolygon, NULL );
1235 
1236 	if ( !mbMap )
1237 		return rLogicPolyPoly;
1238 
1239 	PolyPolygon aPolyPoly( rLogicPolyPoly );
1240 	sal_uInt16		nPoly = aPolyPoly.Count();
1241 	for( sal_uInt16 i = 0; i < nPoly; i++ )
1242 	{
1243 		Polygon& rPoly = aPolyPoly[i];
1244 		rPoly = LogicToPixel( rPoly );
1245 	}
1246 	return aPolyPoly;
1247 }
1248 
1249 // -----------------------------------------------------------------------
1250 
1251 basegfx::B2DPolygon OutputDevice::LogicToPixel( const basegfx::B2DPolygon& rLogicPoly ) const
1252 {
1253     basegfx::B2DPolygon aTransformedPoly = rLogicPoly;
1254     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetViewTransformation();
1255     aTransformedPoly.transform( rTransformationMatrix );
1256     return aTransformedPoly;
1257 }
1258 
1259 // -----------------------------------------------------------------------
1260 
1261 basegfx::B2DPolyPolygon OutputDevice::LogicToPixel( const basegfx::B2DPolyPolygon& rLogicPolyPoly ) const
1262 {
1263     basegfx::B2DPolyPolygon aTransformedPoly = rLogicPolyPoly;
1264     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetViewTransformation();
1265     aTransformedPoly.transform( rTransformationMatrix );
1266     return aTransformedPoly;
1267 }
1268 
1269 // -----------------------------------------------------------------------
1270 
1271 Region OutputDevice::LogicToPixel( const Region& rLogicRegion ) const
1272 {
1273 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1274 
1275 	if(!mbMap || rLogicRegion.IsNull() || rLogicRegion.IsEmpty())
1276     {
1277 		return rLogicRegion;
1278     }
1279 
1280 	Region aRegion;
1281 
1282     if(rLogicRegion.getB2DPolyPolygon())
1283     {
1284         aRegion = Region(LogicToPixel(*rLogicRegion.getB2DPolyPolygon()));
1285     }
1286     else if(rLogicRegion.getPolyPolygon())
1287     {
1288         aRegion = Region(LogicToPixel(*rLogicRegion.getPolyPolygon()));
1289     }
1290     else if(rLogicRegion.getRegionBand())
1291     {
1292         RectangleVector aRectangles;
1293         rLogicRegion.GetRegionRectangles(aRectangles);
1294         const RectangleVector& rRectangles(aRectangles); // needed to make the '!=' work
1295 
1296         // make reverse run to fill new region bottom-up, this will speed it up due to the used data structuring
1297         for(RectangleVector::const_reverse_iterator aRectIter(rRectangles.rbegin()); aRectIter != rRectangles.rend(); aRectIter++)
1298         {
1299             aRegion.Union(LogicToPixel(*aRectIter));
1300         }
1301 
1302         //long nX(0);
1303 		//long nY(0);
1304 		//long nWidth(0);
1305 		//long nHeight(0);
1306 		//ImplRegionInfo aInfo;
1307 		//aRegion.ImplBeginAddRect();
1308         //bool bRegionRect(rLogicRegion.ImplGetFirstRect(aInfo, nX, nY, nWidth, nHeight));
1309         //
1310         //while(bRegionRect)
1311 		//{
1312 		//	const Rectangle aRect(Point(nX, nY), Size(nWidth, nHeight));
1313 		//	aRegion.ImplAddRect(LogicToPixel(aRect));
1314 		//	bRegionRect = rLogicRegion.ImplGetNextRect(aInfo, nX, nY, nWidth, nHeight);
1315 		//}
1316         //
1317         //aRegion.ImplEndAddRect();
1318     }
1319 
1320 	return aRegion;
1321 }
1322 
1323 // -----------------------------------------------------------------------
1324 
1325 Point OutputDevice::LogicToPixel( const Point& rLogicPt,
1326 								  const MapMode& rMapMode ) const
1327 {
1328 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1329 
1330 	if ( rMapMode.IsDefault() )
1331 		return rLogicPt;
1332 
1333 	// MapMode-Aufloesung berechnen und Umrechnen
1334 	ImplMapRes			aMapRes;
1335 	ImplThresholdRes	aThresRes;
1336 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1337 
1338 	return Point( ImplLogicToPixel( rLogicPt.X() + aMapRes.mnMapOfsX, mnDPIX,
1339 									aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1340 									aThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1341 				  ImplLogicToPixel( rLogicPt.Y() + aMapRes.mnMapOfsY, mnDPIY,
1342 									aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1343 									aThresRes.mnThresLogToPixY )+mnOutOffOrigY );
1344 }
1345 
1346 // -----------------------------------------------------------------------
1347 
1348 Size OutputDevice::LogicToPixel( const Size& rLogicSize,
1349 								 const MapMode& rMapMode ) const
1350 {
1351 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1352 
1353 	if ( rMapMode.IsDefault() )
1354 		return rLogicSize;
1355 
1356 	// MapMode-Aufloesung berechnen und Umrechnen
1357 	ImplMapRes			aMapRes;
1358 	ImplThresholdRes	aThresRes;
1359 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1360 
1361 	return Size( ImplLogicToPixel( rLogicSize.Width(), mnDPIX,
1362 								   aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1363 								   aThresRes.mnThresLogToPixX ),
1364 				 ImplLogicToPixel( rLogicSize.Height(), mnDPIY,
1365 								   aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1366 								   aThresRes.mnThresLogToPixY ) );
1367 }
1368 
1369 // -----------------------------------------------------------------------
1370 
1371 Rectangle OutputDevice::LogicToPixel( const Rectangle& rLogicRect,
1372 									  const MapMode& rMapMode ) const
1373 {
1374 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1375 
1376 	if ( rMapMode.IsDefault() || rLogicRect.IsEmpty() )
1377 		return rLogicRect;
1378 
1379 	// MapMode-Aufloesung berechnen und Umrechnen
1380 	ImplMapRes			aMapRes;
1381 	ImplThresholdRes	aThresRes;
1382 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1383 
1384 	return Rectangle( ImplLogicToPixel( rLogicRect.Left() + aMapRes.mnMapOfsX, mnDPIX,
1385 										aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1386 										aThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1387 					  ImplLogicToPixel( rLogicRect.Top() + aMapRes.mnMapOfsY, mnDPIY,
1388 										aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1389 										aThresRes.mnThresLogToPixY )+mnOutOffOrigY,
1390 					  ImplLogicToPixel( rLogicRect.Right() + aMapRes.mnMapOfsX, mnDPIX,
1391 										aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1392 										aThresRes.mnThresLogToPixX )+mnOutOffOrigX,
1393 					  ImplLogicToPixel( rLogicRect.Bottom() + aMapRes.mnMapOfsY, mnDPIY,
1394 										aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1395 										aThresRes.mnThresLogToPixY )+mnOutOffOrigY );
1396 }
1397 
1398 // -----------------------------------------------------------------------
1399 
1400 Polygon OutputDevice::LogicToPixel( const Polygon& rLogicPoly,
1401 									const MapMode& rMapMode ) const
1402 {
1403 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1404 	DBG_CHKOBJ( &rLogicPoly, Polygon, NULL );
1405 
1406 	if ( rMapMode.IsDefault() )
1407 		return rLogicPoly;
1408 
1409 	// MapMode-Aufloesung berechnen und Umrechnen
1410 	ImplMapRes			aMapRes;
1411 	ImplThresholdRes	aThresRes;
1412 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1413 
1414 	sal_uInt16	i;
1415 	sal_uInt16	nPoints = rLogicPoly.GetSize();
1416 	Polygon aPoly( rLogicPoly );
1417 
1418 	// Pointer auf das Point-Array holen (Daten werden kopiert)
1419 	const Point* pPointAry = aPoly.GetConstPointAry();
1420 
1421     for ( i = 0; i < nPoints; i++ )
1422     {
1423         const Point* pPt = &(pPointAry[i]);
1424         Point aPt;
1425         aPt.X() = ImplLogicToPixel( pPt->X() + aMapRes.mnMapOfsX, mnDPIX,
1426                                     aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1427                                     aThresRes.mnThresLogToPixX )+mnOutOffOrigX;
1428         aPt.Y() = ImplLogicToPixel( pPt->Y() + aMapRes.mnMapOfsY, mnDPIY,
1429                                     aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1430                                     aThresRes.mnThresLogToPixY )+mnOutOffOrigY;
1431         aPoly[i] = aPt;
1432     }
1433 
1434 	return aPoly;
1435 }
1436 
1437 // -----------------------------------------------------------------------
1438 
1439 PolyPolygon OutputDevice::LogicToPixel( const PolyPolygon& rLogicPolyPoly,
1440 										const MapMode& rMapMode ) const
1441 {
1442 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1443 	DBG_CHKOBJ( &rLogicPolyPoly, PolyPolygon, NULL );
1444 
1445 	if ( rMapMode.IsDefault() )
1446 		return rLogicPolyPoly;
1447 
1448 	PolyPolygon aPolyPoly( rLogicPolyPoly );
1449 	sal_uInt16		nPoly = aPolyPoly.Count();
1450 	for( sal_uInt16 i = 0; i < nPoly; i++ )
1451 	{
1452 		Polygon& rPoly = aPolyPoly[i];
1453 		rPoly = LogicToPixel( rPoly, rMapMode );
1454 	}
1455 	return aPolyPoly;
1456 }
1457 
1458 // -----------------------------------------------------------------------
1459 
1460 basegfx::B2DPolyPolygon OutputDevice::LogicToPixel( const basegfx::B2DPolyPolygon& rLogicPolyPoly,
1461                                                     const MapMode& rMapMode ) const
1462 {
1463     basegfx::B2DPolyPolygon aTransformedPoly = rLogicPolyPoly;
1464     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetViewTransformation( rMapMode );
1465     aTransformedPoly.transform( rTransformationMatrix );
1466     return aTransformedPoly;
1467 }
1468 
1469 // -----------------------------------------------------------------------
1470 
1471 basegfx::B2DPolygon OutputDevice::LogicToPixel( const basegfx::B2DPolygon& rLogicPoly,
1472                                                 const MapMode& rMapMode ) const
1473 {
1474     basegfx::B2DPolygon aTransformedPoly = rLogicPoly;
1475     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetViewTransformation( rMapMode );
1476     aTransformedPoly.transform( rTransformationMatrix );
1477     return aTransformedPoly;
1478 }
1479 
1480 // -----------------------------------------------------------------------
1481 
1482 Region OutputDevice::LogicToPixel( const Region& rLogicRegion, const MapMode& rMapMode ) const
1483 {
1484 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1485 
1486 	if(rMapMode.IsDefault() || rLogicRegion.IsNull() || rLogicRegion.IsEmpty())
1487     {
1488 		return rLogicRegion;
1489     }
1490 
1491 	Region aRegion;
1492 
1493     if(rLogicRegion.getB2DPolyPolygon())
1494     {
1495         aRegion = Region(LogicToPixel(*rLogicRegion.getB2DPolyPolygon(), rMapMode));
1496     }
1497     else if(rLogicRegion.getPolyPolygon())
1498     {
1499         aRegion = Region(LogicToPixel(*rLogicRegion.getPolyPolygon(), rMapMode));
1500     }
1501     else if(rLogicRegion.getRegionBand())
1502     {
1503         RectangleVector aRectangles;
1504         rLogicRegion.GetRegionRectangles(aRectangles);
1505         const RectangleVector& rRectangles(aRectangles); // needed to make the '!=' work
1506 
1507         // make reverse run to fill new region bottom-up, this will speed it up due to the used data structuring
1508         for(RectangleVector::const_reverse_iterator aRectIter(rRectangles.rbegin()); aRectIter != rRectangles.rend(); aRectIter++)
1509         {
1510             aRegion.Union(LogicToPixel(*aRectIter, rMapMode));
1511         }
1512 
1513 		//long nX(0);
1514 		//long nY(0);
1515 		//long nWidth(0);
1516 		//long nHeight(0);
1517 		//ImplRegionInfo aInfo;
1518 		//aRegion.ImplBeginAddRect();
1519 		//bool bRegionRect(rLogicRegion.ImplGetFirstRect(aInfo, nX, nY, nWidth, nHeight));
1520         //
1521 		//while(bRegionRect)
1522 		//{
1523 		//	const Rectangle aRect(Point(nX, nY), Size(nWidth, nHeight));
1524 		//	aRegion.ImplAddRect(LogicToPixel(aRect, rMapMode));
1525 		//	bRegionRect = rLogicRegion.ImplGetNextRect(aInfo, nX, nY, nWidth, nHeight);
1526 		//}
1527         //
1528         //aRegion.ImplEndAddRect();
1529     }
1530 
1531 	return aRegion;
1532 }
1533 
1534 // -----------------------------------------------------------------------
1535 
1536 Point OutputDevice::PixelToLogic( const Point& rDevicePt ) const
1537 {
1538 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1539 
1540 	if ( !mbMap )
1541 		return rDevicePt;
1542 
1543 	return Point( ImplPixelToLogic( rDevicePt.X(), mnDPIX,
1544 									maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1545 									maThresRes.mnThresPixToLogX ) - maMapRes.mnMapOfsX - mnOutOffLogicX,
1546 				  ImplPixelToLogic( rDevicePt.Y(), mnDPIY,
1547 									maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1548 									maThresRes.mnThresPixToLogY ) - maMapRes.mnMapOfsY - mnOutOffLogicY );
1549 }
1550 
1551 // -----------------------------------------------------------------------
1552 
1553 Size OutputDevice::PixelToLogic( const Size& rDeviceSize ) const
1554 {
1555 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1556 
1557 	if ( !mbMap )
1558 		return rDeviceSize;
1559 
1560 	return Size( ImplPixelToLogic( rDeviceSize.Width(), mnDPIX,
1561 								   maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1562 								   maThresRes.mnThresPixToLogX ),
1563 				 ImplPixelToLogic( rDeviceSize.Height(), mnDPIY,
1564 								   maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1565 								   maThresRes.mnThresPixToLogY ) );
1566 }
1567 
1568 // -----------------------------------------------------------------------
1569 
1570 Rectangle OutputDevice::PixelToLogic( const Rectangle& rDeviceRect ) const
1571 {
1572 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1573 
1574 	if ( !mbMap || rDeviceRect.IsEmpty() )
1575 		return rDeviceRect;
1576 
1577 	return Rectangle( ImplPixelToLogic( rDeviceRect.Left(), mnDPIX,
1578 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1579 										maThresRes.mnThresPixToLogX ) - maMapRes.mnMapOfsX - mnOutOffLogicX,
1580 					  ImplPixelToLogic( rDeviceRect.Top(), mnDPIY,
1581 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1582 										maThresRes.mnThresPixToLogY ) - maMapRes.mnMapOfsY - mnOutOffLogicY,
1583 					  ImplPixelToLogic( rDeviceRect.Right(), mnDPIX,
1584 										maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1585 										maThresRes.mnThresPixToLogX ) - maMapRes.mnMapOfsX - mnOutOffLogicX,
1586 					  ImplPixelToLogic( rDeviceRect.Bottom(), mnDPIY,
1587 										maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1588 										maThresRes.mnThresPixToLogY ) - maMapRes.mnMapOfsY - mnOutOffLogicY );
1589 }
1590 
1591 // -----------------------------------------------------------------------
1592 
1593 Polygon OutputDevice::PixelToLogic( const Polygon& rDevicePoly ) const
1594 {
1595 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1596 	DBG_CHKOBJ( &rDevicePoly, Polygon, NULL );
1597 
1598 	if ( !mbMap )
1599 		return rDevicePoly;
1600 
1601 	sal_uInt16	i;
1602 	sal_uInt16	nPoints = rDevicePoly.GetSize();
1603 	Polygon aPoly( rDevicePoly );
1604 
1605 	// Pointer auf das Point-Array holen (Daten werden kopiert)
1606 	const Point* pPointAry = aPoly.GetConstPointAry();
1607 
1608     for ( i = 0; i < nPoints; i++ )
1609     {
1610         const Point* pPt = &(pPointAry[i]);
1611         Point aPt;
1612         aPt.X() = ImplPixelToLogic( pPt->X(), mnDPIX,
1613                                     maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
1614                                     maThresRes.mnThresPixToLogX ) - maMapRes.mnMapOfsX - mnOutOffLogicX;
1615         aPt.Y() = ImplPixelToLogic( pPt->Y(), mnDPIY,
1616                                     maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
1617                                     maThresRes.mnThresPixToLogY ) - maMapRes.mnMapOfsY - mnOutOffLogicY;
1618         aPoly[i] = aPt;
1619     }
1620 
1621 	return aPoly;
1622 }
1623 
1624 // -----------------------------------------------------------------------
1625 
1626 PolyPolygon OutputDevice::PixelToLogic( const PolyPolygon& rDevicePolyPoly ) const
1627 {
1628 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1629 	DBG_CHKOBJ( &rDevicePolyPoly, PolyPolygon, NULL );
1630 
1631 	if ( !mbMap )
1632 		return rDevicePolyPoly;
1633 
1634 	PolyPolygon aPolyPoly( rDevicePolyPoly );
1635 	sal_uInt16		nPoly = aPolyPoly.Count();
1636 	for( sal_uInt16 i = 0; i < nPoly; i++ )
1637 	{
1638 		Polygon& rPoly = aPolyPoly[i];
1639 		rPoly = PixelToLogic( rPoly );
1640 	}
1641 	return aPolyPoly;
1642 }
1643 
1644 // -----------------------------------------------------------------------
1645 
1646 basegfx::B2DPolygon OutputDevice::PixelToLogic( const basegfx::B2DPolygon& rPixelPoly ) const
1647 {
1648     basegfx::B2DPolygon aTransformedPoly = rPixelPoly;
1649     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetInverseViewTransformation();
1650     aTransformedPoly.transform( rTransformationMatrix );
1651     return aTransformedPoly;
1652 }
1653 
1654 // -----------------------------------------------------------------------
1655 
1656 basegfx::B2DPolyPolygon OutputDevice::PixelToLogic( const basegfx::B2DPolyPolygon& rPixelPolyPoly ) const
1657 {
1658     basegfx::B2DPolyPolygon aTransformedPoly = rPixelPolyPoly;
1659     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetInverseViewTransformation();
1660     aTransformedPoly.transform( rTransformationMatrix );
1661     return aTransformedPoly;
1662 }
1663 
1664 // -----------------------------------------------------------------------
1665 
1666 Region OutputDevice::PixelToLogic( const Region& rDeviceRegion ) const
1667 {
1668 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1669 
1670 	if(!mbMap || rDeviceRegion.IsNull() || rDeviceRegion.IsEmpty())
1671     {
1672 		return rDeviceRegion;
1673     }
1674 
1675 	Region aRegion;
1676 
1677     if(rDeviceRegion.getB2DPolyPolygon())
1678     {
1679         aRegion = Region(PixelToLogic(*rDeviceRegion.getB2DPolyPolygon()));
1680     }
1681     else if(rDeviceRegion.getPolyPolygon())
1682     {
1683 	    aRegion = Region(PixelToLogic(*rDeviceRegion.getPolyPolygon()));
1684     }
1685     else if(rDeviceRegion.getRegionBand())
1686     {
1687         RectangleVector aRectangles;
1688         rDeviceRegion.GetRegionRectangles(aRectangles);
1689         const RectangleVector& rRectangles(aRectangles); // needed to make the '!=' work
1690 
1691         // make reverse run to fill new region bottom-up, this will speed it up due to the used data structuring
1692         for(RectangleVector::const_reverse_iterator aRectIter(rRectangles.rbegin()); aRectIter != rRectangles.rend(); aRectIter++)
1693         {
1694             aRegion.Union(PixelToLogic(*aRectIter));
1695         }
1696 
1697 		//long nX(0);
1698 		//long nY(0);
1699 		//long nWidth(0);
1700 		//long nHeight(0);
1701 		//ImplRegionInfo aInfo;
1702 		//aRegion.ImplBeginAddRect();
1703 		//bool bRegionRect(rDeviceRegion.ImplGetFirstRect(aInfo, nX, nY, nWidth, nHeight));
1704         //
1705 		//while(bRegionRect)
1706 		//{
1707 		//	const Rectangle aRect(Point(nX, nY), Size(nWidth, nHeight));
1708 		//	aRegion.ImplAddRect(PixelToLogic(aRect));
1709 		//	bRegionRect = rDeviceRegion.ImplGetNextRect(aInfo, nX, nY, nWidth, nHeight);
1710 		//}
1711         //
1712         //aRegion.ImplEndAddRect();
1713     }
1714 
1715 	return aRegion;
1716 }
1717 
1718 // -----------------------------------------------------------------------
1719 
1720 Point OutputDevice::PixelToLogic( const Point& rDevicePt,
1721 								  const MapMode& rMapMode ) const
1722 {
1723 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1724 
1725 	// Ist Default-MapMode, dann bereche nichts
1726 	if ( rMapMode.IsDefault() )
1727 		return rDevicePt;
1728 
1729 	// MapMode-Aufloesung berechnen und Umrechnen
1730 	ImplMapRes			aMapRes;
1731 	ImplThresholdRes	aThresRes;
1732 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1733 
1734 	return Point( ImplPixelToLogic( rDevicePt.X(), mnDPIX,
1735 									aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1736 									aThresRes.mnThresPixToLogX ) - aMapRes.mnMapOfsX - mnOutOffLogicX,
1737 				  ImplPixelToLogic( rDevicePt.Y(), mnDPIY,
1738 									aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1739 									aThresRes.mnThresPixToLogY ) - aMapRes.mnMapOfsY - mnOutOffLogicY );
1740 }
1741 
1742 // -----------------------------------------------------------------------
1743 
1744 Size OutputDevice::PixelToLogic( const Size& rDeviceSize,
1745 								 const MapMode& rMapMode ) const
1746 {
1747 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1748 
1749 	// Ist Default-MapMode, dann bereche nichts
1750 	if ( rMapMode.IsDefault() )
1751 		return rDeviceSize;
1752 
1753 	// MapMode-Aufloesung berechnen und Umrechnen
1754 	ImplMapRes			aMapRes;
1755 	ImplThresholdRes	aThresRes;
1756 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1757 
1758 	return Size( ImplPixelToLogic( rDeviceSize.Width(), mnDPIX,
1759 								   aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1760 								   aThresRes.mnThresPixToLogX ),
1761 				 ImplPixelToLogic( rDeviceSize.Height(), mnDPIY,
1762 								   aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1763 								   aThresRes.mnThresPixToLogY ) );
1764 }
1765 
1766 // -----------------------------------------------------------------------
1767 
1768 Rectangle OutputDevice::PixelToLogic( const Rectangle& rDeviceRect,
1769 									  const MapMode& rMapMode ) const
1770 {
1771 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1772 
1773 	// Ist Default-MapMode, dann bereche nichts
1774 	if ( rMapMode.IsDefault() || rDeviceRect.IsEmpty() )
1775 		return rDeviceRect;
1776 
1777 	// MapMode-Aufloesung berechnen und Umrechnen
1778 	ImplMapRes			aMapRes;
1779 	ImplThresholdRes	aThresRes;
1780 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1781 
1782 	return Rectangle( ImplPixelToLogic( rDeviceRect.Left(), mnDPIX,
1783 										aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1784 										aThresRes.mnThresPixToLogX ) - aMapRes.mnMapOfsX - mnOutOffLogicX,
1785 					  ImplPixelToLogic( rDeviceRect.Top(), mnDPIY,
1786 										aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1787 										aThresRes.mnThresPixToLogY ) - aMapRes.mnMapOfsY - mnOutOffLogicY,
1788 					  ImplPixelToLogic( rDeviceRect.Right(), mnDPIX,
1789 										aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1790 										aThresRes.mnThresPixToLogX ) - aMapRes.mnMapOfsX - mnOutOffLogicX,
1791 					  ImplPixelToLogic( rDeviceRect.Bottom(), mnDPIY,
1792 										aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1793 										aThresRes.mnThresPixToLogY ) - aMapRes.mnMapOfsY - mnOutOffLogicY );
1794 }
1795 
1796 // -----------------------------------------------------------------------
1797 
1798 Polygon OutputDevice::PixelToLogic( const Polygon& rDevicePoly,
1799 									const MapMode& rMapMode ) const
1800 {
1801 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1802 	DBG_CHKOBJ( &rDevicePoly, Polygon, NULL );
1803 
1804 	// Ist Default-MapMode, dann bereche nichts
1805 	if ( rMapMode.IsDefault() )
1806 		return rDevicePoly;
1807 
1808 	// MapMode-Aufloesung berechnen und Umrechnen
1809 	ImplMapRes			aMapRes;
1810 	ImplThresholdRes	aThresRes;
1811 	ImplCalcMapResolution( rMapMode, mnDPIX, mnDPIY, aMapRes, aThresRes );
1812 
1813 	sal_uInt16	i;
1814 	sal_uInt16	nPoints = rDevicePoly.GetSize();
1815 	Polygon aPoly( rDevicePoly );
1816 
1817 	// Pointer auf das Point-Array holen (Daten werden kopiert)
1818 	const Point* pPointAry = aPoly.GetConstPointAry();
1819 
1820     for ( i = 0; i < nPoints; i++ )
1821     {
1822         const Point* pPt = &(pPointAry[i]);
1823         Point aPt;
1824         aPt.X() = ImplPixelToLogic( pPt->X(), mnDPIX,
1825                                     aMapRes.mnMapScNumX, aMapRes.mnMapScDenomX,
1826                                     aThresRes.mnThresPixToLogX ) - aMapRes.mnMapOfsX - mnOutOffLogicX;
1827         aPt.Y() = ImplPixelToLogic( pPt->Y(), mnDPIY,
1828                                     aMapRes.mnMapScNumY, aMapRes.mnMapScDenomY,
1829                                     aThresRes.mnThresPixToLogY ) - aMapRes.mnMapOfsY - mnOutOffLogicY;
1830         aPoly[i] = aPt;
1831     }
1832 
1833 	return aPoly;
1834 }
1835 
1836 // -----------------------------------------------------------------------
1837 
1838 PolyPolygon OutputDevice::PixelToLogic( const PolyPolygon& rDevicePolyPoly,
1839 										const MapMode& rMapMode ) const
1840 {
1841 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1842 	DBG_CHKOBJ( &rDevicePolyPoly, PolyPolygon, NULL );
1843 
1844 	if ( rMapMode.IsDefault() )
1845 		return rDevicePolyPoly;
1846 
1847 	PolyPolygon aPolyPoly( rDevicePolyPoly );
1848 	sal_uInt16		nPoly = aPolyPoly.Count();
1849 	for( sal_uInt16 i = 0; i < nPoly; i++ )
1850 	{
1851 		Polygon& rPoly = aPolyPoly[i];
1852 		rPoly = PixelToLogic( rPoly, rMapMode );
1853 	}
1854 	return aPolyPoly;
1855 }
1856 
1857 // -----------------------------------------------------------------------
1858 
1859 basegfx::B2DPolygon OutputDevice::PixelToLogic( const basegfx::B2DPolygon& rPixelPoly,
1860                                                 const MapMode& rMapMode ) const
1861 {
1862     basegfx::B2DPolygon aTransformedPoly = rPixelPoly;
1863     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetInverseViewTransformation( rMapMode );
1864     aTransformedPoly.transform( rTransformationMatrix );
1865     return aTransformedPoly;
1866 }
1867 
1868 // -----------------------------------------------------------------------
1869 
1870 basegfx::B2DPolyPolygon OutputDevice::PixelToLogic( const basegfx::B2DPolyPolygon& rPixelPolyPoly,
1871                                                     const MapMode& rMapMode ) const
1872 {
1873     basegfx::B2DPolyPolygon aTransformedPoly = rPixelPolyPoly;
1874     const ::basegfx::B2DHomMatrix& rTransformationMatrix = GetInverseViewTransformation( rMapMode );
1875     aTransformedPoly.transform( rTransformationMatrix );
1876     return aTransformedPoly;
1877 }
1878 
1879 // -----------------------------------------------------------------------
1880 
1881 Region OutputDevice::PixelToLogic( const Region& rDeviceRegion, const MapMode& rMapMode ) const
1882 {
1883 	DBG_CHKTHIS( OutputDevice, ImplDbgCheckOutputDevice );
1884 
1885 	if(rMapMode.IsDefault() || rDeviceRegion.IsNull() || rDeviceRegion.IsEmpty())
1886     {
1887 		return rDeviceRegion;
1888     }
1889 
1890 	Region aRegion;
1891 
1892     if(rDeviceRegion.getB2DPolyPolygon())
1893     {
1894         aRegion = Region(PixelToLogic(*rDeviceRegion.getB2DPolyPolygon(), rMapMode));
1895     }
1896     else if(rDeviceRegion.getPolyPolygon())
1897     {
1898 	    aRegion = Region(PixelToLogic(*rDeviceRegion.getPolyPolygon(), rMapMode));
1899     }
1900     else if(rDeviceRegion.getRegionBand())
1901     {
1902         RectangleVector aRectangles;
1903         rDeviceRegion.GetRegionRectangles(aRectangles);
1904         const RectangleVector& rRectangles(aRectangles); // needed to make the '!=' work
1905 
1906         // make reverse run to fill new region bottom-up, this will speed it up due to the used data structuring
1907         for(RectangleVector::const_reverse_iterator aRectIter(rRectangles.rbegin()); aRectIter != rRectangles.rend(); aRectIter++)
1908         {
1909             aRegion.Union(PixelToLogic(*aRectIter, rMapMode));
1910         }
1911 
1912 		//long nX(0);
1913 		//long nY(0);
1914 		//long nWidth(0);
1915 		//long nHeight(0);
1916 		//ImplRegionInfo aInfo;
1917 		//aRegion.ImplBeginAddRect();
1918 		//bool bRegionRect(rDeviceRegion.ImplGetFirstRect(aInfo, nX, nY, nWidth, nHeight));
1919         //
1920 		//while(bRegionRect)
1921 		//{
1922 		//	const Rectangle aRect(Point(nX, nY), Size(nWidth, nHeight));
1923 		//	aRegion.ImplAddRect(PixelToLogic(aRect, rMapMode));
1924 		//	bRegionRect = rDeviceRegion.ImplGetNextRect(aInfo, nX, nY, nWidth, nHeight);
1925 		//}
1926         //
1927         //aRegion.ImplEndAddRect();
1928     }
1929 
1930 	return aRegion;
1931 }
1932 
1933 // -----------------------------------------------------------------------
1934 
1935 #define ENTER0( rSource, pMapModeSource, pMapModeDest ) 				\
1936 	if ( !pMapModeSource )												\
1937 		pMapModeSource = &maMapMode;									\
1938 	if ( !pMapModeDest )												\
1939 		pMapModeDest = &maMapMode;										\
1940 	if ( *pMapModeSource == *pMapModeDest ) 							\
1941 		return rSource
1942 
1943 // -----------------------------------------------------------------------
1944 
1945 #define ENTER1( rSource, pMapModeSource, pMapModeDest ) 				\
1946 	ENTER0( rSource, pMapModeSource, pMapModeDest );					\
1947 																		\
1948 	ImplMapRes aMapResSource;											\
1949 	ImplMapRes aMapResDest; 											\
1950 																		\
1951 	if ( !mbMap || pMapModeSource != &maMapMode )						\
1952 	{																	\
1953 		if ( pMapModeSource->GetMapUnit() == MAP_RELATIVE ) 			\
1954 			aMapResSource = maMapRes;									\
1955 		ImplCalcMapResolution( *pMapModeSource, 						\
1956 							   mnDPIX, mnDPIY, aMapResSource ); 		\
1957 	}																	\
1958 	else																\
1959 		aMapResSource = maMapRes;										\
1960 	if ( !mbMap || pMapModeDest != &maMapMode ) 						\
1961 	{																	\
1962 		if ( pMapModeDest->GetMapUnit() == MAP_RELATIVE )				\
1963 			aMapResDest = maMapRes; 									\
1964 		ImplCalcMapResolution( *pMapModeDest,							\
1965 							   mnDPIX, mnDPIY, aMapResDest );			\
1966 	}																	\
1967 	else																\
1968 		aMapResDest = maMapRes
1969 
1970 // -----------------------------------------------------------------------
1971 
1972 #define ENTER2( eUnitSource, eUnitDest )								\
1973 	DBG_ASSERT( eUnitSource != MAP_SYSFONT								\
1974 				&& eUnitSource != MAP_APPFONT							\
1975 				&& eUnitSource != MAP_RELATIVE, 						\
1976 				"Source MapUnit nicht erlaubt" );                       \
1977 	DBG_ASSERT( eUnitDest != MAP_SYSFONT								\
1978 				&& eUnitDest != MAP_APPFONT 							\
1979 				&& eUnitDest != MAP_RELATIVE,							\
1980 				"Destination MapUnit nicht erlaubt" );                  \
1981 	DBG_ASSERTWARNING( eUnitSource != MAP_PIXEL,						\
1982 					   "MAP_PIXEL mit 72dpi angenaehert" );             \
1983 	DBG_ASSERTWARNING( eUnitDest != MAP_PIXEL,							\
1984 					   "MAP_PIXEL mit 72dpi angenaehert" )
1985 
1986 // -----------------------------------------------------------------------
1987 
1988 #define ENTER3( eUnitSource, eUnitDest )								\
1989 	long nNumerator 	 = 1;		\
1990 	long nDenominator	 = 1;		\
1991 	DBG_ASSERT( eUnitSource < s_ImplArySize, "Invalid source map unit");	\
1992 	DBG_ASSERT( eUnitDest < s_ImplArySize, "Invalid destination map unit");	\
1993 	if( (eUnitSource < s_ImplArySize) && (eUnitDest < s_ImplArySize) )	\
1994 	{	\
1995 		nNumerator 	 = aImplNumeratorAry[eUnitSource] * 			\
1996 						   aImplDenominatorAry[eUnitDest];				\
1997 		nDenominator	 = aImplNumeratorAry[eUnitDest] *				\
1998 						   aImplDenominatorAry[eUnitSource];			\
1999 	} \
2000 	if ( eUnitSource == MAP_PIXEL ) 									\
2001 		nDenominator *= 72; 											\
2002 	else if( eUnitDest == MAP_PIXEL )									\
2003 		nNumerator *= 72
2004 
2005 // -----------------------------------------------------------------------
2006 
2007 #define ENTER4( rMapModeSource, rMapModeDest )							\
2008 	ImplMapRes aMapResSource;											\
2009 	ImplMapRes aMapResDest; 											\
2010 																		\
2011 	ImplCalcMapResolution( rMapModeSource, 72, 72, aMapResSource ); 	\
2012 	ImplCalcMapResolution( rMapModeDest, 72, 72, aMapResDest )
2013 
2014 // -----------------------------------------------------------------------
2015 
2016 // return (n1 * n2 * n3) / (n4 * n5)
2017 static long fn5( const long n1,
2018 				 const long n2,
2019 				 const long n3,
2020 				 const long n4,
2021 				 const long n5 )
2022 {
2023 	if ( n1 == 0 || n2 == 0 || n3 == 0 || n4 == 0 || n5 == 0 )
2024 		return 0;
2025 	if ( LONG_MAX / Abs(n2) < Abs(n3) )
2026 	{
2027 		// a6 wird "ubersprungen
2028 		BigInt a7 = n2;
2029 		a7 *= n3;
2030 		a7 *= n1;
2031 
2032 		if ( LONG_MAX / Abs(n4) < Abs(n5) )
2033 		{
2034 			BigInt a8 = n4;
2035 			a8 *= n5;
2036 
2037 			BigInt a9 = a8;
2038 			a9 /= 2;
2039 			if ( a7.IsNeg() )
2040 				a7 -= a9;
2041 			else
2042 				a7 += a9;
2043 
2044 			a7 /= a8;
2045 		} // of if
2046 		else
2047 		{
2048 			long n8 = n4 * n5;
2049 
2050 			if ( a7.IsNeg() )
2051 				a7 -= n8 / 2;
2052 			else
2053 				a7 += n8 / 2;
2054 
2055 			a7 /= n8;
2056 		} // of else
2057 		return (long)a7;
2058 	} // of if
2059 	else
2060 	{
2061 		long n6 = n2 * n3;
2062 
2063 		if ( LONG_MAX / Abs(n1) < Abs(n6) )
2064 		{
2065 			BigInt a7 = n1;
2066 			a7 *= n6;
2067 
2068 			if ( LONG_MAX / Abs(n4) < Abs(n5) )
2069 			{
2070 				BigInt a8 = n4;
2071 				a8 *= n5;
2072 
2073 				BigInt a9 = a8;
2074 				a9 /= 2;
2075 				if ( a7.IsNeg() )
2076 					a7 -= a9;
2077 				else
2078 					a7 += a9;
2079 
2080 				a7 /= a8;
2081 			} // of if
2082 			else
2083 			{
2084 				long n8 = n4 * n5;
2085 
2086 				if ( a7.IsNeg() )
2087 					a7 -= n8 / 2;
2088 				else
2089 					a7 += n8 / 2;
2090 
2091 				a7 /= n8;
2092 			} // of else
2093 			return (long)a7;
2094 		} // of if
2095 		else
2096 		{
2097 			long n7 = n1 * n6;
2098 
2099 			if ( LONG_MAX / Abs(n4) < Abs(n5) )
2100 			{
2101 				BigInt a7 = n7;
2102 				BigInt a8 = n4;
2103 				a8 *= n5;
2104 
2105 				BigInt a9 = a8;
2106 				a9 /= 2;
2107 				if ( a7.IsNeg() )
2108 					a7 -= a9;
2109 				else
2110 					a7 += a9;
2111 
2112 				a7 /= a8;
2113 				return (long)a7;
2114 			} // of if
2115 			else
2116 			{
2117 				const long n8 = n4 * n5;
2118 				const long n8_2 = n8 / 2;
2119 
2120 				if( n7 < 0 )
2121 				{
2122 					if( ( n7 - LONG_MIN ) >= n8_2 )
2123 						n7 -= n8_2;
2124 				}
2125 				else if( ( LONG_MAX - n7 ) >= n8_2 )
2126 					n7 += n8_2;
2127 
2128 				return n7 / n8;
2129 			} // of else
2130 		} // of else
2131 	} // of else
2132 }
2133 
2134 // -----------------------------------------------------------------------
2135 
2136 // return (n1 * n2) / n3
2137 static long fn3( const long n1, const long n2, const long n3 )
2138 {
2139 	if ( n1 == 0 || n2 == 0 || n3 == 0 )
2140 		return 0;
2141 	if ( LONG_MAX / Abs(n1) < Abs(n2) )
2142 	{
2143 		BigInt a4 = n1;
2144 		a4 *= n2;
2145 
2146 		if ( a4.IsNeg() )
2147 			a4 -= n3 / 2;
2148 		else
2149 			a4 += n3 / 2;
2150 
2151 		a4 /= n3;
2152 		return (long)a4;
2153 	} // of if
2154 	else
2155 	{
2156 		long		n4 = n1 * n2;
2157 		const long	n3_2 = n3 / 2;
2158 
2159 		if( n4 < 0 )
2160 		{
2161 			if( ( n4 - LONG_MIN ) >= n3_2 )
2162 				n4 -= n3_2;
2163 		}
2164 		else if( ( LONG_MAX - n4 ) >= n3_2 )
2165 			n4 += n3_2;
2166 
2167 		return n4 / n3;
2168 	} // of else
2169 }
2170 
2171 // -----------------------------------------------------------------------
2172 
2173 Point OutputDevice::LogicToLogic( const Point& rPtSource,
2174 								  const MapMode* pMapModeSource,
2175 								  const MapMode* pMapModeDest ) const
2176 {
2177 	ENTER1( rPtSource, pMapModeSource, pMapModeDest );
2178 
2179 	return Point( fn5( rPtSource.X() + aMapResSource.mnMapOfsX,
2180 					   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2181 					   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2182 				  aMapResDest.mnMapOfsX,
2183 				  fn5( rPtSource.Y() + aMapResSource.mnMapOfsY,
2184 					   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2185 					   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2186 				  aMapResDest.mnMapOfsY );
2187 }
2188 
2189 // -----------------------------------------------------------------------
2190 
2191 Size OutputDevice::LogicToLogic( const Size& rSzSource,
2192 								 const MapMode* pMapModeSource,
2193 								 const MapMode* pMapModeDest ) const
2194 {
2195 	ENTER1( rSzSource, pMapModeSource, pMapModeDest );
2196 
2197 	return Size( fn5( rSzSource.Width(),
2198 					  aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2199 					  aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ),
2200 				 fn5( rSzSource.Height(),
2201 					  aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2202 					  aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) );
2203 }
2204 
2205 // -----------------------------------------------------------------------
2206 
2207 Rectangle OutputDevice::LogicToLogic( const Rectangle& rRectSource,
2208 									  const MapMode* pMapModeSource,
2209 									  const MapMode* pMapModeDest ) const
2210 {
2211 	ENTER1( rRectSource, pMapModeSource, pMapModeDest );
2212 
2213 	return Rectangle( fn5( rRectSource.Left() + aMapResSource.mnMapOfsX,
2214 						   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2215 						   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2216 					  aMapResDest.mnMapOfsX,
2217 					  fn5( rRectSource.Top() + aMapResSource.mnMapOfsY,
2218 						   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2219 						   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2220 					  aMapResDest.mnMapOfsY,
2221 					  fn5( rRectSource.Right() + aMapResSource.mnMapOfsX,
2222 						   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2223 						   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2224 					  aMapResDest.mnMapOfsX,
2225 					  fn5( rRectSource.Bottom() + aMapResSource.mnMapOfsY,
2226 						   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2227 						   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2228 					  aMapResDest.mnMapOfsY );
2229 }
2230 
2231 // -----------------------------------------------------------------------
2232 
2233 long* OutputDevice::LogicToLogic( long* pX, sal_uInt16 nCount,
2234 								  const MapMode* pMapModeSource,
2235 								  const MapMode* pMapModeDest ) const
2236 {
2237 	ENTER1( pX, pMapModeSource, pMapModeDest );
2238 
2239 	for( ; nCount; nCount--, pX++ )
2240 	{
2241 		*pX = fn5( *pX,
2242 				   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2243 				   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX );
2244 	}
2245 
2246 	return NULL;
2247 }
2248 
2249 // -----------------------------------------------------------------------
2250 
2251 Point OutputDevice::LogicToLogic( const Point& rPtSource,
2252 								  const MapMode& rMapModeSource,
2253 								  const MapMode& rMapModeDest )
2254 {
2255 	if ( rMapModeSource == rMapModeDest )
2256 		return rPtSource;
2257 
2258 	MapUnit eUnitSource = rMapModeSource.GetMapUnit();
2259 	MapUnit eUnitDest	= rMapModeDest.GetMapUnit();
2260 	ENTER2( eUnitSource, eUnitDest );
2261 
2262 	if ( rMapModeSource.mpImplMapMode->mbSimple &&
2263 		 rMapModeDest.mpImplMapMode->mbSimple )
2264 	{
2265 		ENTER3( eUnitSource, eUnitDest );
2266 
2267 		return Point( fn3( rPtSource.X(), nNumerator, nDenominator ),
2268 					  fn3( rPtSource.Y(), nNumerator, nDenominator ) );
2269 	}
2270 	else
2271 	{
2272 		ENTER4( rMapModeSource, rMapModeDest );
2273 
2274 		return Point( fn5( rPtSource.X() + aMapResSource.mnMapOfsX,
2275 						   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2276 						   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2277 					  aMapResDest.mnMapOfsX,
2278 					  fn5( rPtSource.Y() + aMapResSource.mnMapOfsY,
2279 						   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2280 						   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2281 					  aMapResDest.mnMapOfsY );
2282 	}
2283 }
2284 
2285 // -----------------------------------------------------------------------
2286 
2287 Size OutputDevice::LogicToLogic( const Size& rSzSource,
2288 								 const MapMode& rMapModeSource,
2289 								 const MapMode& rMapModeDest )
2290 {
2291 	if ( rMapModeSource == rMapModeDest )
2292 		return rSzSource;
2293 
2294 	MapUnit eUnitSource = rMapModeSource.GetMapUnit();
2295 	MapUnit eUnitDest	= rMapModeDest.GetMapUnit();
2296 	ENTER2( eUnitSource, eUnitDest );
2297 
2298 	if ( rMapModeSource.mpImplMapMode->mbSimple &&
2299 		 rMapModeDest.mpImplMapMode->mbSimple )
2300 	{
2301 		ENTER3( eUnitSource, eUnitDest );
2302 
2303 		return Size( fn3( rSzSource.Width(),  nNumerator, nDenominator ),
2304 					 fn3( rSzSource.Height(), nNumerator, nDenominator ) );
2305 	}
2306 	else
2307 	{
2308 		ENTER4( rMapModeSource, rMapModeDest );
2309 
2310 		return Size( fn5( rSzSource.Width(),
2311 						  aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2312 						  aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ),
2313 					 fn5( rSzSource.Height(),
2314 						  aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2315 						  aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) );
2316 	}
2317 }
2318 
2319 // -----------------------------------------------------------------------
2320 
2321 basegfx::B2DPolygon OutputDevice::LogicToLogic( const basegfx::B2DPolygon& rPolySource,
2322                                                 const MapMode& rMapModeSource,
2323                                                 const MapMode& rMapModeDest )
2324 {
2325 	if ( rMapModeSource == rMapModeDest )
2326 		return rPolySource;
2327 
2328 	MapUnit eUnitSource = rMapModeSource.GetMapUnit();
2329 	MapUnit eUnitDest	= rMapModeDest.GetMapUnit();
2330 	ENTER2( eUnitSource, eUnitDest );
2331 
2332     basegfx::B2DHomMatrix aTransform;
2333 
2334 	if ( rMapModeSource.mpImplMapMode->mbSimple &&
2335 		 rMapModeDest.mpImplMapMode->mbSimple )
2336 	{
2337 		ENTER3( eUnitSource, eUnitDest );
2338 
2339 		const double fScaleFactor((double)nNumerator / (double)nDenominator);
2340 		aTransform.set(0, 0, fScaleFactor);
2341 		aTransform.set(1, 1, fScaleFactor);
2342 	}
2343 	else
2344 	{
2345 		ENTER4( rMapModeSource, rMapModeDest );
2346 
2347 		const double fScaleFactorX(  (double(aMapResSource.mnMapScNumX) *  double(aMapResDest.mnMapScDenomX))
2348 		                           / (double(aMapResSource.mnMapScDenomX) * double(aMapResDest.mnMapScNumX)) );
2349 		const double fScaleFactorY(  (double(aMapResSource.mnMapScNumY) *  double(aMapResDest.mnMapScDenomY))
2350 		                           / (double(aMapResSource.mnMapScDenomY) * double(aMapResDest.mnMapScNumY)) );
2351 		const double fZeroPointX(double(aMapResSource.mnMapOfsX) * fScaleFactorX - double(aMapResDest.mnMapOfsX));
2352 		const double fZeroPointY(double(aMapResSource.mnMapOfsY) * fScaleFactorY - double(aMapResDest.mnMapOfsY));
2353 
2354 		aTransform.set(0, 0, fScaleFactorX);
2355 		aTransform.set(1, 1, fScaleFactorY);
2356 		aTransform.set(0, 2, fZeroPointX);
2357 		aTransform.set(1, 2, fZeroPointY);
2358 	}
2359 	basegfx::B2DPolygon aPoly( rPolySource );
2360 	aPoly.transform( aTransform );
2361 	return aPoly;
2362 }
2363 
2364 // -----------------------------------------------------------------------
2365 
2366 basegfx::B2DPolyPolygon OutputDevice::LogicToLogic( const basegfx::B2DPolyPolygon& rPolySource,
2367                                                     const MapMode& rMapModeSource,
2368                                                     const MapMode& rMapModeDest )
2369 {
2370 	if ( rMapModeSource == rMapModeDest )
2371 		return rPolySource;
2372 
2373 	MapUnit eUnitSource = rMapModeSource.GetMapUnit();
2374 	MapUnit eUnitDest	= rMapModeDest.GetMapUnit();
2375 	ENTER2( eUnitSource, eUnitDest );
2376 
2377     basegfx::B2DHomMatrix aTransform;
2378 
2379 	if ( rMapModeSource.mpImplMapMode->mbSimple &&
2380 		 rMapModeDest.mpImplMapMode->mbSimple )
2381 	{
2382 		ENTER3( eUnitSource, eUnitDest );
2383 
2384 		const double fScaleFactor((double)nNumerator / (double)nDenominator);
2385 		aTransform.set(0, 0, fScaleFactor);
2386 		aTransform.set(1, 1, fScaleFactor);
2387 	}
2388 	else
2389 	{
2390 		ENTER4( rMapModeSource, rMapModeDest );
2391 
2392 		const double fScaleFactorX(  (double(aMapResSource.mnMapScNumX) *  double(aMapResDest.mnMapScDenomX))
2393 		                           / (double(aMapResSource.mnMapScDenomX) * double(aMapResDest.mnMapScNumX)) );
2394 		const double fScaleFactorY(  (double(aMapResSource.mnMapScNumY) *  double(aMapResDest.mnMapScDenomY))
2395 		                           / (double(aMapResSource.mnMapScDenomY) * double(aMapResDest.mnMapScNumY)) );
2396 		const double fZeroPointX(double(aMapResSource.mnMapOfsX) * fScaleFactorX - double(aMapResDest.mnMapOfsX));
2397 		const double fZeroPointY(double(aMapResSource.mnMapOfsY) * fScaleFactorY - double(aMapResDest.mnMapOfsY));
2398 
2399 		aTransform.set(0, 0, fScaleFactorX);
2400 		aTransform.set(1, 1, fScaleFactorY);
2401 		aTransform.set(0, 2, fZeroPointX);
2402 		aTransform.set(1, 2, fZeroPointY);
2403 	}
2404 	basegfx::B2DPolyPolygon aPoly( rPolySource );
2405 	aPoly.transform( aTransform );
2406 	return aPoly;
2407 }
2408 
2409 // -----------------------------------------------------------------------
2410 
2411 Rectangle OutputDevice::LogicToLogic( const Rectangle& rRectSource,
2412 									  const MapMode& rMapModeSource,
2413 									  const MapMode& rMapModeDest )
2414 {
2415 	if ( rMapModeSource == rMapModeDest )
2416 		return rRectSource;
2417 
2418 	MapUnit eUnitSource = rMapModeSource.GetMapUnit();
2419 	MapUnit eUnitDest	= rMapModeDest.GetMapUnit();
2420 	ENTER2( eUnitSource, eUnitDest );
2421 
2422 	if ( rMapModeSource.mpImplMapMode->mbSimple &&
2423 		 rMapModeDest.mpImplMapMode->mbSimple )
2424 	{
2425 		ENTER3( eUnitSource, eUnitDest );
2426 
2427 		return Rectangle( fn3( rRectSource.Left(), nNumerator, nDenominator ),
2428 						  fn3( rRectSource.Top(), nNumerator, nDenominator ),
2429 						  fn3( rRectSource.Right(), nNumerator, nDenominator ),
2430 						  fn3( rRectSource.Bottom(), nNumerator, nDenominator ) );
2431 	}
2432 	else
2433 	{
2434 		ENTER4( rMapModeSource, rMapModeDest );
2435 
2436 		return Rectangle( fn5( rRectSource.Left() + aMapResSource.mnMapOfsX,
2437 							   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2438 							   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2439 						  aMapResDest.mnMapOfsX,
2440 						  fn5( rRectSource.Top() + aMapResSource.mnMapOfsY,
2441 							   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2442 							   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2443 						  aMapResDest.mnMapOfsY,
2444 						  fn5( rRectSource.Right() + aMapResSource.mnMapOfsX,
2445 							   aMapResSource.mnMapScNumX, aMapResDest.mnMapScDenomX,
2446 							   aMapResSource.mnMapScDenomX, aMapResDest.mnMapScNumX ) -
2447 						  aMapResDest.mnMapOfsX,
2448 						  fn5( rRectSource.Bottom() + aMapResSource.mnMapOfsY,
2449 							   aMapResSource.mnMapScNumY, aMapResDest.mnMapScDenomY,
2450 							   aMapResSource.mnMapScDenomY, aMapResDest.mnMapScNumY ) -
2451 						  aMapResDest.mnMapOfsY );
2452 	}
2453 }
2454 
2455 // -----------------------------------------------------------------------
2456 
2457 long OutputDevice::LogicToLogic( long nLongSource,
2458 								 MapUnit eUnitSource, MapUnit eUnitDest )
2459 {
2460 	if ( eUnitSource == eUnitDest )
2461 		return nLongSource;
2462 
2463 	ENTER2( eUnitSource, eUnitDest );
2464 	ENTER3( eUnitSource, eUnitDest );
2465 
2466 	return fn3( nLongSource, nNumerator, nDenominator );
2467 }
2468 
2469 // -----------------------------------------------------------------------
2470 
2471 void OutputDevice::SetPixelOffset( const Size& rOffset )
2472 {
2473     mnOutOffOrigX  = rOffset.Width();
2474     mnOutOffOrigY  = rOffset.Height();
2475 
2476 	mnOutOffLogicX = ImplPixelToLogic( mnOutOffOrigX, mnDPIX,
2477                                        maMapRes.mnMapScNumX, maMapRes.mnMapScDenomX,
2478                                        maThresRes.mnThresPixToLogX );
2479 	mnOutOffLogicY = ImplPixelToLogic( mnOutOffOrigY, mnDPIY,
2480                                        maMapRes.mnMapScNumY, maMapRes.mnMapScDenomY,
2481                                        maThresRes.mnThresPixToLogY );
2482 
2483     if( mpAlphaVDev )
2484         mpAlphaVDev->SetPixelOffset( rOffset );
2485 }
2486 
2487 // -----------------------------------------------------------------------
2488 
2489 Size OutputDevice::GetPixelOffset() const
2490 {
2491     return Size(mnOutOffOrigX, mnOutOffOrigY);
2492 }
2493 
2494 // -----------------------------------------------------------------------
2495 
2496 long Window::ImplLogicUnitToPixelX( long nX, MapUnit eUnit )
2497 {
2498 	if ( eUnit != MAP_PIXEL )
2499 	{
2500 		ImplFrameData* pFrameData = mpWindowImpl->mpFrameData;
2501 
2502 		// Map-Einheit verschieden, dann neu berechnen
2503 		if ( pFrameData->meMapUnit != eUnit )
2504 		{
2505 			pFrameData->meMapUnit = eUnit;
2506 			ImplCalcMapResolution( MapMode( eUnit ), mnDPIX, mnDPIY,
2507 								   pFrameData->maMapUnitRes );
2508 		}
2509 
2510 		// Es wird kein BigInt gebraucht, da diese Funktion nur zur Umrechnung
2511 		// von Fensterposition benutzt wird
2512 		nX	= nX * mnDPIX * pFrameData->maMapUnitRes.mnMapScNumX;
2513 		nX += nX >= 0 ?  (pFrameData->maMapUnitRes.mnMapScDenomX/2) :
2514 						-((pFrameData->maMapUnitRes.mnMapScDenomX-1)/2);
2515 		nX /= pFrameData->maMapUnitRes.mnMapScDenomX;
2516 	}
2517 
2518 	return nX;
2519 }
2520 
2521 // -----------------------------------------------------------------------
2522 
2523 long Window::ImplLogicUnitToPixelY( long nY, MapUnit eUnit )
2524 {
2525 	if ( eUnit != MAP_PIXEL )
2526 	{
2527 		ImplFrameData* pFrameData = mpWindowImpl->mpFrameData;
2528 
2529 		// Map-Einheit verschieden, dann neu berechnen
2530 		if ( pFrameData->meMapUnit != eUnit )
2531 		{
2532 			pFrameData->meMapUnit = eUnit;
2533 			ImplCalcMapResolution( MapMode( eUnit ), mnDPIX, mnDPIY,
2534 								   pFrameData->maMapUnitRes );
2535 		}
2536 
2537 		// Es wird kein BigInt gebraucht, da diese Funktion nur zur Umrechnung
2538 		// von Fensterposition benutzt wird
2539 		nY	= nY * mnDPIY * pFrameData->maMapUnitRes.mnMapScNumY;
2540 		nY += nY >= 0 ?  (pFrameData->maMapUnitRes.mnMapScDenomY/2) :
2541 						-((pFrameData->maMapUnitRes.mnMapScDenomY-1)/2);
2542 		nY /= pFrameData->maMapUnitRes.mnMapScDenomY;
2543 	}
2544 
2545 	return nY;
2546 }
2547