1 /************************************************************** 2 * 3 * Licensed to the Apache Software Foundation (ASF) under one 4 * or more contributor license agreements. See the NOTICE file 5 * distributed with this work for additional information 6 * regarding copyright ownership. The ASF licenses this file 7 * to you under the Apache License, Version 2.0 (the 8 * "License"); you may not use this file except in compliance 9 * with the License. You may obtain a copy of the License at 10 * 11 * http://www.apache.org/licenses/LICENSE-2.0 12 * 13 * Unless required by applicable law or agreed to in writing, 14 * software distributed under the License is distributed on an 15 * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY 16 * KIND, either express or implied. See the License for the 17 * specific language governing permissions and limitations 18 * under the License. 19 * 20 *************************************************************/ 21 22 23 24 // MARKER(update_precomp.py): autogen include statement, do not remove 25 #include "precompiled_sdext.hxx" 26 27 #include "pdfiprocessor.hxx" 28 #include "xmlemitter.hxx" 29 #include "pdfihelper.hxx" 30 #include "imagecontainer.hxx" 31 #include "genericelements.hxx" 32 #include "style.hxx" 33 #include "treevisiting.hxx" 34 35 #include <rtl/string.hxx> 36 #include <rtl/strbuf.hxx> 37 38 #include <comphelper/sequence.hxx> 39 #include <basegfx/polygon/b2dpolypolygontools.hxx> 40 #include <basegfx/polygon/b2dpolygonclipper.hxx> 41 #include <basegfx/polygon/b2dpolygontools.hxx> 42 #include <basegfx/tools/canvastools.hxx> 43 #include <basegfx/matrix/b2dhommatrix.hxx> 44 #include <basegfx/range/b2irange.hxx> 45 #include <basegfx/range/b2drectangle.hxx> 46 #include <basegfx/matrix/b2dhommatrixtools.hxx> 47 48 #include <com/sun/star/rendering/XVolatileBitmap.hpp> 49 #include <com/sun/star/geometry/RealSize2D.hpp> 50 #include <com/sun/star/geometry/RealPoint2D.hpp> 51 #include <com/sun/star/geometry/RealRectangle2D.hpp> 52 53 54 using namespace com::sun::star; 55 56 57 namespace pdfi 58 { 59 60 PDFIProcessor::PDFIProcessor( const uno::Reference< task::XStatusIndicator >& xStat , 61 com::sun::star::uno::Reference< com::sun::star::uno::XComponentContext > xContext) : 62 63 m_xContext(xContext), 64 fYPrevTextPosition(-10000.0), 65 fPrevTextHeight(0.0), 66 fXPrevTextPosition(0.0), 67 fPrevTextWidth(0.0), 68 m_pElFactory( new ElementFactory() ), 69 m_pDocument( m_pElFactory->createDocumentElement() ), 70 m_pCurPage(0), 71 m_pCurElement(0), 72 m_nNextFontId( 1 ), 73 m_aIdToFont(), 74 m_aFontToId(), 75 m_aGCStack(), 76 m_nNextGCId( 1 ), 77 m_aIdToGC(), 78 m_aGCToId(), 79 m_aImages(), 80 m_eTextDirection( LrTb ), 81 m_nPages(0), 82 m_nNextZOrder( 1 ), 83 m_fWordSpace(0.0), 84 m_bIsWhiteSpaceInLine( false ), 85 m_xStatusIndicator( xStat ), 86 m_bHaveTextOnDocLevel(false), 87 m_bMirrorMapperTried(false) 88 { 89 FontAttributes aDefFont; 90 aDefFont.familyName = USTR("Helvetica"); 91 aDefFont.isBold = false; 92 aDefFont.isItalic = false; 93 aDefFont.size = 10*PDFI_OUTDEV_RESOLUTION/72; 94 m_aIdToFont[ 0 ] = aDefFont; 95 m_aFontToId[ aDefFont ] = 0; 96 97 GraphicsContext aDefGC; 98 m_aGCStack.push_back( aDefGC ); 99 m_aIdToGC[ 0 ] = aDefGC; 100 m_aGCToId[ aDefGC ] = 0; 101 } 102 103 void PDFIProcessor::enableToplevelText() 104 { 105 m_bHaveTextOnDocLevel = true; 106 } 107 108 void PDFIProcessor::setPageNum( sal_Int32 nPages ) 109 { 110 m_nPages = nPages; 111 } 112 113 114 void PDFIProcessor::pushState() 115 { 116 m_aGCStack.push_back( m_aGCStack.back() ); 117 } 118 119 void PDFIProcessor::popState() 120 { 121 m_aGCStack.pop_back(); 122 } 123 124 void PDFIProcessor::setFlatness( double value ) 125 { 126 getCurrentContext().Flatness = value; 127 } 128 129 void PDFIProcessor::setTransformation( const geometry::AffineMatrix2D& rMatrix ) 130 { 131 basegfx::unotools::homMatrixFromAffineMatrix( 132 getCurrentContext().Transformation, 133 rMatrix ); 134 } 135 136 void PDFIProcessor::setLineDash( const uno::Sequence<double>& dashes, 137 double /*start*/ ) 138 { 139 // TODO(F2): factor in start offset 140 GraphicsContext& rContext( getCurrentContext() ); 141 comphelper::sequenceToContainer(rContext.DashArray,dashes); 142 } 143 144 void PDFIProcessor::setLineJoin(sal_Int8 nJoin) 145 { 146 getCurrentContext().LineJoin = nJoin; 147 } 148 149 void PDFIProcessor::setLineCap(sal_Int8 nCap) 150 { 151 getCurrentContext().LineCap = nCap; 152 } 153 154 void PDFIProcessor::setMiterLimit(double) 155 { 156 OSL_TRACE("PDFIProcessor::setMiterLimit(): not supported by ODF"); 157 } 158 159 void PDFIProcessor::setLineWidth(double nWidth) 160 { 161 getCurrentContext().LineWidth = nWidth; 162 } 163 164 void PDFIProcessor::setFillColor( const rendering::ARGBColor& rColor ) 165 { 166 getCurrentContext().FillColor = rColor; 167 } 168 169 void PDFIProcessor::setStrokeColor( const rendering::ARGBColor& rColor ) 170 { 171 getCurrentContext().LineColor = rColor; 172 } 173 174 void PDFIProcessor::setBlendMode(sal_Int8) 175 { 176 OSL_TRACE("PDFIProcessor::setBlendMode(): not supported by ODF"); 177 } 178 179 void PDFIProcessor::setFont( const FontAttributes& i_rFont ) 180 { 181 FontAttributes aChangedFont( i_rFont ); 182 GraphicsContext& rGC=getCurrentContext(); 183 // for text render modes, please see PDF reference manual 184 aChangedFont.isOutline = ( (rGC.TextRenderMode == 1) || (rGC. TextRenderMode == 2) ); 185 FontToIdMap::const_iterator it = m_aFontToId.find( aChangedFont ); 186 if( it != m_aFontToId.end() ) 187 rGC.FontId = it->second; 188 else 189 { 190 m_aFontToId[ aChangedFont ] = m_nNextFontId; 191 m_aIdToFont[ m_nNextFontId ] = aChangedFont; 192 rGC.FontId = m_nNextFontId; 193 m_nNextFontId++; 194 } 195 } 196 197 void PDFIProcessor::setTextRenderMode( sal_Int32 i_nMode ) 198 { 199 GraphicsContext& rGC=getCurrentContext(); 200 rGC.TextRenderMode = i_nMode; 201 IdToFontMap::iterator it = m_aIdToFont.find( rGC.FontId ); 202 if( it != m_aIdToFont.end() ) 203 setFont( it->second ); 204 } 205 206 sal_Int32 PDFIProcessor::getFontId( const FontAttributes& rAttr ) const 207 { 208 const sal_Int32 nCurFont = getCurrentContext().FontId; 209 const_cast<PDFIProcessor*>(this)->setFont( rAttr ); 210 const sal_Int32 nFont = getCurrentContext().FontId; 211 const_cast<PDFIProcessor*>(this)->getCurrentContext().FontId = nCurFont; 212 213 return nFont; 214 } 215 216 // line diagnose block - start 217 void PDFIProcessor::processGlyphLine() 218 { 219 if( m_GlyphsList.size()<1 ) 220 return; 221 222 double fPreAvarageSpaceValue= 0.0; 223 double fAvarageDiffCharSpaceValue= 0.0; 224 double fMinPreSpaceValue= 0.0; 225 double fMaxPreSpaceValue= 0.0; 226 double fNullSpaceBreakerAvaregeSpaceValue = 0.0; 227 228 unsigned int nSpaceCount( 0 ); 229 unsigned int nDiffSpaceCount( 0 ); 230 unsigned int nNullSpaceBreakerCount=0; 231 bool preSpaceNull(true); 232 233 for ( unsigned int i=0; i<m_GlyphsList.size()-1; i++ ) // i=1 because the first glyph doesn't have a prevGlyphSpace value 234 { 235 if( m_GlyphsList[i].getPrevGlyphsSpace()>0.0 ) 236 { 237 if( fMinPreSpaceValue>m_GlyphsList[i].getPrevGlyphsSpace() ) 238 fMinPreSpaceValue=m_GlyphsList[i].getPrevGlyphsSpace(); 239 240 if( fMaxPreSpaceValue<m_GlyphsList[i].getPrevGlyphsSpace() ) 241 fMaxPreSpaceValue=m_GlyphsList[i].getPrevGlyphsSpace(); 242 243 fPreAvarageSpaceValue+= m_GlyphsList[i].getPrevGlyphsSpace(); 244 nSpaceCount++; 245 } 246 } 247 248 if( nSpaceCount!=0 ) 249 fPreAvarageSpaceValue= fPreAvarageSpaceValue/( nSpaceCount ); 250 251 for ( unsigned int i=0; i<m_GlyphsList.size()-1; i++ ) // i=1 because the first glyph doesn't have a prevGlyphSpace value 252 { 253 if ( m_GlyphsList[i].getPrevGlyphsSpace()==0.0 ) 254 { 255 if ( 256 ( m_GlyphsList[i+1].getPrevGlyphsSpace()>0.0)&& 257 ( fPreAvarageSpaceValue>m_GlyphsList[i+1].getPrevGlyphsSpace()) 258 ) 259 { 260 fNullSpaceBreakerAvaregeSpaceValue+=m_GlyphsList[i+1].getPrevGlyphsSpace(); 261 nNullSpaceBreakerCount++; 262 } 263 } 264 } 265 266 if( ( fNullSpaceBreakerAvaregeSpaceValue!= 0.0 )&& 267 ( fNullSpaceBreakerAvaregeSpaceValue < fPreAvarageSpaceValue ) 268 ) 269 { 270 fPreAvarageSpaceValue = fNullSpaceBreakerAvaregeSpaceValue; 271 } 272 273 for ( unsigned int i=0; i<m_GlyphsList.size()-1; i++ ) // i=1 cose the first Glypth dont have prevGlyphSpace value 274 { 275 if ( ( m_GlyphsList[i].getPrevGlyphsSpace()>0.0 ) 276 ) 277 { 278 if ( 279 ( m_GlyphsList[i].getPrevGlyphsSpace() <= fPreAvarageSpaceValue )&& 280 ( m_GlyphsList[i+1].getPrevGlyphsSpace()<= fPreAvarageSpaceValue ) 281 ) 282 { 283 double temp= m_GlyphsList[i].getPrevGlyphsSpace()-m_GlyphsList[i+1].getPrevGlyphsSpace(); 284 285 if(temp!=0.0) 286 { 287 if( temp< 0.0) 288 temp= temp* -1.0; 289 290 fAvarageDiffCharSpaceValue+=temp; 291 nDiffSpaceCount++; 292 } 293 } 294 } 295 296 } 297 298 if ( 299 ( nNullSpaceBreakerCount>0 ) 300 ) 301 { 302 fNullSpaceBreakerAvaregeSpaceValue=fNullSpaceBreakerAvaregeSpaceValue/nNullSpaceBreakerCount; 303 } 304 305 if ( 306 ( nDiffSpaceCount>0 )&&(fAvarageDiffCharSpaceValue>0) 307 ) 308 { 309 fAvarageDiffCharSpaceValue= fAvarageDiffCharSpaceValue/ nDiffSpaceCount; 310 } 311 312 ParagraphElement* pPara= NULL ; 313 FrameElement* pFrame= NULL ; 314 315 if(m_GlyphsList.size()>0) 316 { 317 pFrame = m_pElFactory->createFrameElement( m_GlyphsList[0].getCurElement(), getGCId( getTransformGlyphContext( m_GlyphsList[0])) ); 318 pFrame->ZOrder = m_nNextZOrder++; 319 pPara = m_pElFactory->createParagraphElement( pFrame ); 320 321 322 323 processGlyph( 0, 324 m_GlyphsList[0], 325 pPara, 326 pFrame, 327 m_bIsWhiteSpaceInLine ); 328 329 330 } 331 332 333 preSpaceNull=false; 334 335 for ( unsigned int i=1; i<m_GlyphsList.size()-1; i++ ) 336 { 337 double fPrevDiffCharSpace= m_GlyphsList[i].getPrevGlyphsSpace()-m_GlyphsList[i-1].getPrevGlyphsSpace(); 338 double fPostDiffCharSpace= m_GlyphsList[i].getPrevGlyphsSpace()-m_GlyphsList[i+1].getPrevGlyphsSpace(); 339 340 341 if( 342 preSpaceNull && (m_GlyphsList[i].getPrevGlyphsSpace()!= 0.0) 343 ) 344 { 345 preSpaceNull=false; 346 if( fNullSpaceBreakerAvaregeSpaceValue > m_GlyphsList[i].getPrevGlyphsSpace() ) 347 { 348 processGlyph( 0, 349 m_GlyphsList[i], 350 pPara, 351 pFrame, 352 m_bIsWhiteSpaceInLine ); 353 354 } 355 else 356 { 357 processGlyph( 1, 358 m_GlyphsList[i], 359 pPara, 360 pFrame, 361 m_bIsWhiteSpaceInLine ); 362 363 } 364 365 } 366 else 367 { 368 if ( 369 ( ( m_GlyphsList[i].getPrevGlyphsSpace()<= fPreAvarageSpaceValue )&& 370 ( fPrevDiffCharSpace<=fAvarageDiffCharSpaceValue )&& 371 ( fPostDiffCharSpace<=fAvarageDiffCharSpaceValue ) 372 ) || 373 ( m_GlyphsList[i].getPrevGlyphsSpace() == 0.0 ) 374 ) 375 { 376 preSpaceNull=true; 377 378 processGlyph( 0, 379 m_GlyphsList[i], 380 pPara, 381 pFrame, 382 m_bIsWhiteSpaceInLine ); 383 384 } 385 else 386 { 387 processGlyph( 1, 388 m_GlyphsList[i], 389 pPara, 390 pFrame, 391 m_bIsWhiteSpaceInLine ); 392 393 } 394 395 } 396 397 } 398 399 if(m_GlyphsList.size()>1) 400 processGlyph( 0, 401 m_GlyphsList[m_GlyphsList.size()-1], 402 pPara, 403 pFrame, 404 m_bIsWhiteSpaceInLine ); 405 406 m_GlyphsList.clear(); 407 } 408 409 void PDFIProcessor::processGlyph( double fPreAvarageSpaceValue, 410 CharGlyph& aGlyph, 411 ParagraphElement* pPara, 412 FrameElement* pFrame, 413 bool bIsWhiteSpaceInLine 414 ) 415 { 416 if( !bIsWhiteSpaceInLine ) 417 { 418 bool flag=( 0 < fPreAvarageSpaceValue ); 419 420 drawCharGlyphs( aGlyph.getGlyph(), 421 aGlyph.getRect(), 422 aGlyph.getFontMatrix(), 423 aGlyph.getGC(), 424 aGlyph.getCurElement(), 425 pPara, 426 pFrame, 427 flag); 428 } 429 else 430 { 431 drawCharGlyphs( aGlyph.getGlyph(), 432 aGlyph.getRect(), 433 aGlyph.getFontMatrix(), 434 aGlyph.getGC(), 435 aGlyph.getCurElement(), 436 pPara, 437 pFrame, 438 false ); 439 } 440 } 441 442 void PDFIProcessor::drawGlyphLine( const rtl::OUString& rGlyphs, 443 const geometry::RealRectangle2D& rRect, 444 const geometry::Matrix2D& rFontMatrix ) 445 { 446 double isFirstLine= fYPrevTextPosition+ fXPrevTextPosition+ fPrevTextHeight+ fPrevTextWidth ; 447 if( 448 ( ( ( fYPrevTextPosition!= rRect.Y1 ) ) || 449 ( ( fXPrevTextPosition > rRect.X2 ) ) || 450 ( ( fXPrevTextPosition+fPrevTextWidth*1.3)<rRect.X1 ) 451 ) && ( isFirstLine> 0.0 ) 452 ) 453 { 454 processGlyphLine(); 455 } 456 457 CharGlyph aGlyph; 458 459 aGlyph.setGlyph ( rGlyphs ); 460 aGlyph.setRect ( rRect ); 461 aGlyph.setFontMatrix ( rFontMatrix ); 462 aGlyph.setGraphicsContext ( getCurrentContext() ); 463 getGCId(getCurrentContext()); 464 aGlyph.setCurElement( m_pCurElement ); 465 466 aGlyph.setYPrevGlyphPosition( fYPrevTextPosition ); 467 aGlyph.setXPrevGlyphPosition( fXPrevTextPosition ); 468 aGlyph.setPrevGlyphHeight ( fPrevTextHeight ); 469 aGlyph.setPrevGlyphWidth ( fPrevTextWidth ); 470 471 m_GlyphsList.push_back( aGlyph ); 472 473 fYPrevTextPosition = rRect.Y1; 474 fXPrevTextPosition = rRect.X2; 475 fPrevTextHeight = rRect.Y2-rRect.Y1; 476 fPrevTextWidth = rRect.X2-rRect.X1; 477 478 if( !m_bIsWhiteSpaceInLine ) 479 { 480 static rtl::OUString tempWhiteSpaceStr( 0x20 ); 481 static rtl::OUString tempWhiteSpaceNonBreakingStr( 0xa0 ); 482 m_bIsWhiteSpaceInLine=(rGlyphs.equals( tempWhiteSpaceStr ) || rGlyphs.equals( tempWhiteSpaceNonBreakingStr )); 483 } 484 } 485 486 GraphicsContext& PDFIProcessor::getTransformGlyphContext( CharGlyph& rGlyph ) 487 { 488 geometry::RealRectangle2D rRect = rGlyph.getRect(); 489 geometry::Matrix2D rFontMatrix = rGlyph.getFontMatrix(); 490 491 rtl::OUString tempStr( 32 ); 492 geometry::RealRectangle2D aRect(rRect); 493 494 basegfx::B2DHomMatrix aFontMatrix; 495 basegfx::unotools::homMatrixFromMatrix( 496 aFontMatrix, 497 rFontMatrix ); 498 499 FontAttributes aFontAttrs = m_aIdToFont[ rGlyph.getGC().FontId ]; 500 501 // add transformation to GC 502 basegfx::B2DHomMatrix aFontTransform(basegfx::tools::createTranslateB2DHomMatrix(-rRect.X1, -rRect.Y1)); 503 aFontTransform *= aFontMatrix; 504 aFontTransform.translate( rRect.X1, rRect.Y1 ); 505 506 507 rGlyph.getGC().Transformation = rGlyph.getGC().Transformation * aFontTransform; 508 getGCId(rGlyph.getGC()); 509 510 return rGlyph.getGC(); 511 } 512 void PDFIProcessor::drawCharGlyphs( rtl::OUString& rGlyphs, 513 geometry::RealRectangle2D& rRect, 514 geometry::Matrix2D& , 515 GraphicsContext aGC, 516 Element* , 517 ParagraphElement* pPara, 518 FrameElement* pFrame, 519 bool bSpaceFlag ) 520 { 521 522 523 rtl::OUString tempStr( 32 ); 524 geometry::RealRectangle2D aRect(rRect); 525 526 ::basegfx::B2DRange aRect2; 527 calcTransformedRectBounds( aRect2, 528 ::basegfx::unotools::b2DRectangleFromRealRectangle2D(aRect), 529 aGC.Transformation ); 530 // check whether there was a previous draw frame 531 532 TextElement* pText = m_pElFactory->createTextElement( pPara, 533 getGCId(aGC), 534 aGC.FontId ); 535 if( bSpaceFlag ) 536 pText->Text.append( tempStr ); 537 538 pText->Text.append( rGlyphs ); 539 540 pText->x = aRect2.getMinX() ; 541 pText->y = aRect2.getMinY() ; 542 pText->w = 0.0; // ToDO P2: 1.1 is a hack for solving of size auto-grow problem 543 pText->h = aRect2.getHeight(); // ToDO P2: 1.1 is a hack for solving of size auto-grow problem 544 545 pPara->updateGeometryWith( pText ); 546 547 if( pFrame ) 548 pFrame->updateGeometryWith( pPara ); 549 550 } 551 void PDFIProcessor::drawGlyphs( const rtl::OUString& rGlyphs, 552 const geometry::RealRectangle2D& rRect, 553 const geometry::Matrix2D& rFontMatrix ) 554 { 555 drawGlyphLine( rGlyphs, rRect, rFontMatrix ); 556 } 557 558 void PDFIProcessor::endText() 559 { 560 TextElement* pText = dynamic_cast<TextElement*>(m_pCurElement); 561 if( pText ) 562 m_pCurElement = pText->Parent; 563 } 564 565 void PDFIProcessor::setupImage(ImageId nImage) 566 { 567 const GraphicsContext& rGC( getCurrentContext() ); 568 569 basegfx::B2DHomMatrix aTrans( rGC.Transformation ); 570 571 // check for rotation, which is the other way around in ODF 572 basegfx::B2DTuple aScale, aTranslation; 573 double fRotate, fShearX; 574 rGC.Transformation.decompose( aScale, aTranslation, fRotate, fShearX ); 575 // TODDO(F4): correcting rotation when fShearX != 0 ? 576 if( fRotate != 0.0 ) 577 { 578 579 // try to create a Transformation that corrects for the wrong rotation 580 aTrans.identity(); 581 aTrans.scale( aScale.getX(), aScale.getY() ); 582 aTrans.rotate( -fRotate ); 583 584 basegfx::B2DRange aRect( 0, 0, 1, 1 ); 585 aRect.transform( aTrans ); 586 587 // TODO(F3) treat translation correctly 588 // the corrections below work for multiples of 90 degree 589 // which is a common case (landscape/portrait/seascape) 590 // we need a general solution here; however this needs to 591 // work in sync with DrawXmlEmitter::fillFrameProps and WriterXmlEmitter::fillFrameProps 592 // admittedly this is a lame workaround and fails for arbitrary rotation 593 double fQuadrant = fmod( fRotate, 2.0*M_PI ) / M_PI_2; 594 int nQuadrant = (int)fQuadrant; 595 if( nQuadrant < 0 ) 596 nQuadrant += 4; 597 if( nQuadrant == 1 ) 598 { 599 aTranslation.setX( aTranslation.getX() + aRect.getHeight() + aRect.getWidth()); 600 aTranslation.setY( aTranslation.getY() + aRect.getHeight() ); 601 } 602 if( nQuadrant == 3 ) 603 aTranslation.setX( aTranslation.getX() - aRect.getHeight() ); 604 605 aTrans.translate( aTranslation.getX(), 606 aTranslation.getY() ); 607 } 608 609 bool bMirrorVertical = aScale.getY() > 0; 610 611 // transform unit rect to determine view box 612 basegfx::B2DRange aRect( 0, 0, 1, 1 ); 613 aRect.transform( aTrans ); 614 615 // TODO(F3): Handle clip 616 const sal_Int32 nGCId = getGCId(rGC); 617 FrameElement* pFrame = m_pElFactory->createFrameElement( m_pCurElement, nGCId ); 618 ImageElement* pImageElement = m_pElFactory->createImageElement( pFrame, nGCId, nImage ); 619 pFrame->x = pImageElement->x = aRect.getMinX(); 620 pFrame->y = pImageElement->y = aRect.getMinY(); 621 pFrame->w = pImageElement->w = aRect.getWidth(); 622 pFrame->h = pImageElement->h = aRect.getHeight(); 623 pFrame->ZOrder = m_nNextZOrder++; 624 625 if( bMirrorVertical ) 626 { 627 pFrame->MirrorVertical = pImageElement->MirrorVertical = true; 628 pFrame->x += aRect.getWidth(); 629 pImageElement->x += aRect.getWidth(); 630 pFrame->y += aRect.getHeight(); 631 pImageElement->y += aRect.getHeight(); 632 } 633 } 634 635 void PDFIProcessor::drawMask(const uno::Sequence<beans::PropertyValue>& xBitmap, 636 bool /*bInvert*/ ) 637 { 638 // TODO(F3): Handle mask and inversion 639 setupImage( m_aImages.addImage(xBitmap) ); 640 } 641 642 void PDFIProcessor::drawImage(const uno::Sequence<beans::PropertyValue>& xBitmap ) 643 { 644 setupImage( m_aImages.addImage(xBitmap) ); 645 } 646 647 void PDFIProcessor::drawColorMaskedImage(const uno::Sequence<beans::PropertyValue>& xBitmap, 648 const uno::Sequence<uno::Any>& /*xMaskColors*/ ) 649 { 650 // TODO(F3): Handle mask colors 651 setupImage( m_aImages.addImage(xBitmap) ); 652 } 653 654 void PDFIProcessor::drawMaskedImage(const uno::Sequence<beans::PropertyValue>& xBitmap, 655 const uno::Sequence<beans::PropertyValue>& /*xMask*/, 656 bool /*bInvertMask*/) 657 { 658 // TODO(F3): Handle mask and inversion 659 setupImage( m_aImages.addImage(xBitmap) ); 660 } 661 662 void PDFIProcessor::drawAlphaMaskedImage(const uno::Sequence<beans::PropertyValue>& xBitmap, 663 const uno::Sequence<beans::PropertyValue>& /*xMask*/) 664 { 665 // TODO(F3): Handle mask 666 667 setupImage( m_aImages.addImage(xBitmap) ); 668 669 } 670 671 void PDFIProcessor::strokePath( const uno::Reference< rendering::XPolyPolygon2D >& rPath ) 672 { 673 basegfx::B2DPolyPolygon aPoly=basegfx::unotools::b2DPolyPolygonFromXPolyPolygon2D(rPath); 674 aPoly.transform(getCurrentContext().Transformation); 675 676 PolyPolyElement* pPoly = m_pElFactory->createPolyPolyElement( 677 m_pCurElement, 678 getGCId(getCurrentContext()), 679 aPoly, 680 PATH_STROKE ); 681 pPoly->updateGeometry(); 682 pPoly->ZOrder = m_nNextZOrder++; 683 } 684 685 void PDFIProcessor::fillPath( const uno::Reference< rendering::XPolyPolygon2D >& rPath ) 686 { 687 basegfx::B2DPolyPolygon aPoly=basegfx::unotools::b2DPolyPolygonFromXPolyPolygon2D(rPath); 688 aPoly.transform(getCurrentContext().Transformation); 689 690 PolyPolyElement* pPoly = m_pElFactory->createPolyPolyElement( 691 m_pCurElement, 692 getGCId(getCurrentContext()), 693 aPoly, 694 PATH_FILL ); 695 pPoly->updateGeometry(); 696 pPoly->ZOrder = m_nNextZOrder++; 697 } 698 699 void PDFIProcessor::eoFillPath( const uno::Reference< rendering::XPolyPolygon2D >& rPath ) 700 { 701 basegfx::B2DPolyPolygon aPoly=basegfx::unotools::b2DPolyPolygonFromXPolyPolygon2D(rPath); 702 aPoly.transform(getCurrentContext().Transformation); 703 704 PolyPolyElement* pPoly = m_pElFactory->createPolyPolyElement( 705 m_pCurElement, 706 getGCId(getCurrentContext()), 707 aPoly, 708 PATH_EOFILL ); 709 pPoly->updateGeometry(); 710 pPoly->ZOrder = m_nNextZOrder++; 711 } 712 713 void PDFIProcessor::intersectClip(const uno::Reference< rendering::XPolyPolygon2D >& rPath) 714 { 715 // TODO(F3): interpret fill mode 716 basegfx::B2DPolyPolygon aNewClip = basegfx::unotools::b2DPolyPolygonFromXPolyPolygon2D(rPath); 717 aNewClip.transform(getCurrentContext().Transformation); 718 basegfx::B2DPolyPolygon aCurClip = getCurrentContext().Clip; 719 720 if( aCurClip.count() ) // #i92985# adapted API from (..., false, false) to (..., true, false) 721 aNewClip = basegfx::tools::clipPolyPolygonOnPolyPolygon( aCurClip, aNewClip, true, false ); 722 723 getCurrentContext().Clip = aNewClip; 724 } 725 726 void PDFIProcessor::intersectEoClip(const uno::Reference< rendering::XPolyPolygon2D >& rPath) 727 { 728 // TODO(F3): interpret fill mode 729 basegfx::B2DPolyPolygon aNewClip = basegfx::unotools::b2DPolyPolygonFromXPolyPolygon2D(rPath); 730 aNewClip.transform(getCurrentContext().Transformation); 731 basegfx::B2DPolyPolygon aCurClip = getCurrentContext().Clip; 732 733 if( aCurClip.count() ) // #i92985# adapted API from (..., false, false) to (..., true, false) 734 aNewClip = basegfx::tools::clipPolyPolygonOnPolyPolygon( aCurClip, aNewClip, true, false ); 735 736 getCurrentContext().Clip = aNewClip; 737 } 738 739 void PDFIProcessor::hyperLink( const geometry::RealRectangle2D& rBounds, 740 const ::rtl::OUString& rURI ) 741 { 742 if( rURI.getLength() ) 743 { 744 HyperlinkElement* pLink = m_pElFactory->createHyperlinkElement( 745 &m_pCurPage->Hyperlinks, 746 rURI ); 747 pLink->x = rBounds.X1; 748 pLink->y = rBounds.Y1; 749 pLink->w = rBounds.X2-rBounds.X1; 750 pLink->h = rBounds.Y2-rBounds.Y1; 751 } 752 } 753 754 const FontAttributes& PDFIProcessor::getFont( sal_Int32 nFontId ) const 755 { 756 IdToFontMap::const_iterator it = m_aIdToFont.find( nFontId ); 757 if( it == m_aIdToFont.end() ) 758 it = m_aIdToFont.find( 0 ); 759 return it->second; 760 } 761 762 sal_Int32 PDFIProcessor::getGCId( const GraphicsContext& rGC ) 763 { 764 sal_Int32 nGCId = 0; 765 GCToIdMap::const_iterator it = m_aGCToId.find( rGC ); 766 if( it != m_aGCToId.end() ) 767 nGCId = it->second; 768 else 769 { 770 m_aGCToId[ rGC ] = m_nNextGCId; 771 m_aIdToGC[ m_nNextGCId ] = rGC; 772 nGCId = m_nNextGCId; 773 m_nNextGCId++; 774 } 775 776 return nGCId; 777 } 778 779 const GraphicsContext& PDFIProcessor::getGraphicsContext( sal_Int32 nGCId ) const 780 { 781 IdToGCMap::const_iterator it = m_aIdToGC.find( nGCId ); 782 if( it == m_aIdToGC.end() ) 783 it = m_aIdToGC.find( 0 ); 784 return it->second; 785 } 786 787 void PDFIProcessor::endPage() 788 { 789 processGlyphLine(); // draw last line 790 if( m_xStatusIndicator.is() 791 && m_pCurPage 792 && m_pCurPage->PageNumber == m_nPages 793 ) 794 m_xStatusIndicator->end(); 795 } 796 797 void PDFIProcessor::startPage( const geometry::RealSize2D& rSize ) 798 { 799 // initial clip is to page bounds 800 getCurrentContext().Clip = basegfx::B2DPolyPolygon( 801 basegfx::tools::createPolygonFromRect( 802 basegfx::B2DRange( 0, 0, rSize.Width, rSize.Height ))); 803 804 sal_Int32 nNextPageNr = m_pCurPage ? m_pCurPage->PageNumber+1 : 1; 805 if( m_xStatusIndicator.is() ) 806 { 807 if( nNextPageNr == 1 ) 808 startIndicator( rtl::OUString( RTL_CONSTASCII_USTRINGPARAM( " " ) ) ); 809 m_xStatusIndicator->setValue( nNextPageNr ); 810 } 811 m_pCurPage = m_pElFactory->createPageElement(m_pDocument.get(), nNextPageNr); 812 m_pCurElement = m_pCurPage; 813 m_pCurPage->w = rSize.Width; 814 m_pCurPage->h = rSize.Height; 815 m_nNextZOrder = 1; 816 817 818 } 819 820 void PDFIProcessor::emit( XmlEmitter& rEmitter, 821 const TreeVisitorFactory& rVisitorFactory ) 822 { 823 #if OSL_DEBUG_LEVEL > 1 824 m_pDocument->emitStructure( 0 ); 825 #endif 826 827 ElementTreeVisitorSharedPtr optimizingVisitor( 828 rVisitorFactory.createOptimizingVisitor(*this)); 829 // FIXME: localization 830 startIndicator( rtl::OUString( RTL_CONSTASCII_USTRINGPARAM( " " ) ) ); 831 m_pDocument->visitedBy( *optimizingVisitor, std::list<Element*>::iterator()); 832 833 #if OSL_DEBUG_LEVEL > 1 834 m_pDocument->emitStructure( 0 ); 835 #endif 836 837 // get styles 838 StyleContainer aStyles; 839 ElementTreeVisitorSharedPtr finalizingVisitor( 840 rVisitorFactory.createStyleCollectingVisitor(aStyles,*this)); 841 // FIXME: localization 842 843 m_pDocument->visitedBy( *finalizingVisitor, std::list<Element*>::iterator() ); 844 845 EmitContext aContext( rEmitter, aStyles, m_aImages, *this, m_xStatusIndicator, m_xContext ); 846 ElementTreeVisitorSharedPtr aEmittingVisitor( 847 rVisitorFactory.createEmittingVisitor(aContext, *this)); 848 849 PropertyMap aProps; 850 // document prolog 851 #define OASIS_STR "urn:oasis:names:tc:opendocument:xmlns:" 852 aProps[ USTR( "xmlns:office" ) ] = USTR( OASIS_STR "office:1.0" ); 853 aProps[ USTR( "xmlns:style" ) ] = USTR( OASIS_STR "style:1.0" ); 854 aProps[ USTR( "xmlns:text" ) ] = USTR( OASIS_STR "text:1.0" ); 855 aProps[ USTR( "xmlns:svg" ) ] = USTR( OASIS_STR "svg-compatible:1.0" ); 856 aProps[ USTR( "xmlns:table" ) ] = USTR( OASIS_STR "table:1.0" ); 857 aProps[ USTR( "xmlns:draw" ) ] = USTR( OASIS_STR "drawing:1.0" ); 858 aProps[ USTR( "xmlns:fo" ) ] = USTR( OASIS_STR "xsl-fo-compatible:1.0" ); 859 aProps[ USTR( "xmlns:xlink" )] = USTR( "http://www.w3.org/1999/xlink" ); 860 aProps[ USTR( "xmlns:dc" )] = USTR( "http://purl.org/dc/elements/1.1/" ); 861 aProps[ USTR( "xmlns:number" )] = USTR( OASIS_STR "datastyle:1.0" ); 862 aProps[ USTR( "xmlns:presentation" )] = USTR( OASIS_STR "presentation:1.0" ); 863 aProps[ USTR( "xmlns:math" )] = USTR( "http://www.w3.org/1998/Math/MathML" ); 864 aProps[ USTR( "xmlns:form" )] = USTR( OASIS_STR "form:1.0" ); 865 aProps[ USTR( "xmlns:script" )] = USTR( OASIS_STR "script:1.0" ); 866 aProps[ USTR( "xmlns:dom" )] = USTR( "http://www.w3.org/2001/xml-events" ); 867 aProps[ USTR( "xmlns:xforms" )] = USTR( "http://www.w3.org/2002/xforms" ); 868 aProps[ USTR( "xmlns:xsd" )] = USTR( "http://www.w3.org/2001/XMLSchema" ); 869 aProps[ USTR( "xmlns:xsi" )] = USTR( "http://www.w3.org/2001/XMLSchema-instance" ); 870 aProps[ USTR( "office:version" ) ] = USTR( "1.0" ); 871 aProps[ USTR( "office:version" ) ] = USTR( "1.0" ); 872 873 aContext.rEmitter.beginTag( "office:document", aProps ); 874 875 // emit style list 876 aStyles.emit( aContext, *aEmittingVisitor ); 877 878 m_pDocument->visitedBy( *aEmittingVisitor, std::list<Element*>::iterator() ); 879 aContext.rEmitter.endTag( "office:document" ); 880 endIndicator(); 881 } 882 883 void PDFIProcessor::startIndicator( const rtl::OUString& rText, sal_Int32 nElements ) 884 { 885 if( nElements == -1 ) 886 nElements = m_nPages; 887 if( m_xStatusIndicator.is() ) 888 { 889 sal_Int32 nUnicodes = rText.getLength(); 890 rtl::OUStringBuffer aStr( nUnicodes*2 ); 891 const sal_Unicode* pText = rText.getStr(); 892 for( int i = 0; i < nUnicodes; i++ ) 893 { 894 if( nUnicodes-i > 1&& 895 pText[i] == '%' && 896 pText[i+1] == 'd' 897 ) 898 { 899 aStr.append( nElements ); 900 i++; 901 } 902 else 903 aStr.append( pText[i] ); 904 } 905 m_xStatusIndicator->start( aStr.makeStringAndClear(), nElements ); 906 } 907 } 908 909 void PDFIProcessor::endIndicator() 910 { 911 if( m_xStatusIndicator.is() ) 912 m_xStatusIndicator->end(); 913 } 914 915 void PDFIProcessor::sortDocument( bool bDeep ) 916 { 917 for( std::list< Element* >::iterator it = m_pDocument->Children.begin(); 918 it != m_pDocument->Children.end(); ++it ) 919 { 920 if( dynamic_cast<PageElement*>(*it) != NULL ) 921 sortElements( *it, bDeep ); 922 } 923 } 924 925 static bool lr_tb_sort( Element* pLeft, Element* pRight ) 926 { 927 // first: top-bottom sorting 928 929 // Note: allow for 10% overlap on text lines since text lines are usually 930 // of the same order as font height whereas the real paint area 931 // of text is usually smaller 932 double fudge_factor = 1.0; 933 if( dynamic_cast< TextElement* >(pLeft) || dynamic_cast< TextElement* >(pRight) ) 934 fudge_factor = 0.9; 935 936 // if left's lower boundary is above right's upper boundary 937 // then left is smaller 938 if( pLeft->y+pLeft->h*fudge_factor < pRight->y ) 939 return true; 940 // if right's lower boundary is above left's upper boundary 941 // then left is definitely not smaller 942 if( pRight->y+pRight->h*fudge_factor < pLeft->y ) 943 return false; 944 945 // by now we have established that left and right are inside 946 // a "line", that is they have vertical overlap 947 // second: left-right sorting 948 // if left's right boundary is left to right's left boundary 949 // then left is smaller 950 if( pLeft->x+pLeft->w < pRight->x ) 951 return true; 952 // if right's right boundary is left to left's left boundary 953 // then left is definitely not smaller 954 if( pRight->x+pRight->w < pLeft->x ) 955 return false; 956 957 // here we have established vertical and horizontal overlap 958 // so sort left first, top second 959 if( pLeft->x < pRight->x ) 960 return true; 961 if( pRight->x < pLeft->x ) 962 return false; 963 if( pLeft->y < pRight->y ) 964 return true; 965 966 return false; 967 } 968 969 void PDFIProcessor::sortElements( Element* pEle, bool bDeep ) 970 { 971 if( pEle->Children.empty() ) 972 return; 973 974 if( bDeep ) 975 { 976 for( std::list< Element* >::iterator it = pEle->Children.begin(); 977 it != pEle->Children.end(); ++it ) 978 { 979 sortElements( *it, bDeep ); 980 } 981 } 982 // HACK: the stable sort member on std::list that takes a 983 // strict weak ordering requires member templates - which we 984 // do not have on all compilers. so we need to use std::stable_sort 985 // here - which does need random access iterators which the 986 // list iterators are not. 987 // so we need to copy the Element* to an array, stable sort that and 988 // copy them back. 989 std::vector<Element*> aChildren; 990 while( ! pEle->Children.empty() ) 991 { 992 aChildren.push_back( pEle->Children.front() ); 993 pEle->Children.pop_front(); 994 } 995 switch( m_eTextDirection ) 996 { 997 case LrTb: 998 default: 999 std::stable_sort( aChildren.begin(), aChildren.end(), lr_tb_sort ); 1000 break; 1001 } 1002 int nChildren = aChildren.size(); 1003 for( int i = 0; i < nChildren; i++ ) 1004 pEle->Children.push_back( aChildren[i] ); 1005 } 1006 1007 1008 ::basegfx::B2DRange& PDFIProcessor::calcTransformedRectBounds( ::basegfx::B2DRange& outRect, 1009 const ::basegfx::B2DRange& inRect, 1010 const ::basegfx::B2DHomMatrix& transformation ) 1011 { 1012 outRect.reset(); 1013 1014 if( inRect.isEmpty() ) 1015 return outRect; 1016 1017 // transform all four extremal points of the rectangle, 1018 // take bounding rect of those. 1019 1020 // transform left-top point 1021 outRect.expand( transformation * inRect.getMinimum() ); 1022 1023 // transform bottom-right point 1024 outRect.expand( transformation * inRect.getMaximum() ); 1025 1026 ::basegfx::B2DPoint aPoint; 1027 1028 // transform top-right point 1029 aPoint.setX( inRect.getMaxX() ); 1030 aPoint.setY( inRect.getMinY() ); 1031 1032 aPoint *= transformation; 1033 outRect.expand( aPoint ); 1034 1035 // transform bottom-left point 1036 aPoint.setX( inRect.getMinX() ); 1037 aPoint.setY( inRect.getMaxY() ); 1038 1039 aPoint *= transformation; 1040 outRect.expand( aPoint ); 1041 1042 // over and out. 1043 return outRect; 1044 } 1045 1046 // helper method: get a mirrored string 1047 rtl::OUString PDFIProcessor::mirrorString( const rtl::OUString& i_rString ) 1048 { 1049 if( ! m_xMirrorMapper.is() && ! m_bMirrorMapperTried ) 1050 { 1051 m_bMirrorMapperTried = true; 1052 uno::Reference< lang::XMultiComponentFactory > xMSF( m_xContext->getServiceManager(), uno::UNO_SET_THROW ); 1053 uno::Reference < uno::XInterface > xInterface = xMSF->createInstanceWithContext(::rtl::OUString::createFromAscii("com.sun.star.awt.StringMirror"), m_xContext); 1054 m_xMirrorMapper = uno::Reference< util::XStringMapping >( xInterface, uno::UNO_QUERY ); 1055 #if OSL_DEBUG_LEVEL > 1 1056 if( m_xMirrorMapper.is() ) 1057 fprintf( stderr, "using mirror mapper service\n" ); 1058 #endif 1059 } 1060 if( m_xMirrorMapper.is() ) 1061 { 1062 uno::Sequence< rtl::OUString > aSeq( 1 ); 1063 aSeq.getArray()[0] = i_rString; 1064 m_xMirrorMapper->mapStrings( aSeq ); 1065 return aSeq[0]; 1066 } 1067 1068 prepareMirrorMap(); 1069 sal_Int32 nLen = i_rString.getLength(); 1070 rtl::OUStringBuffer aRet( nLen ); 1071 for(int i = nLen - 1; i >= 0; i--) 1072 { 1073 sal_Unicode cChar = i_rString[ i ]; 1074 aRet.append( m_aMirrorMap[cChar] ); 1075 } 1076 return aRet.makeStringAndClear(); 1077 } 1078 1079 void PDFIProcessor::prepareMirrorMap() 1080 { 1081 if( m_aMirrorMap.empty() ) 1082 { 1083 #if OSL_DEBUG_LEVEL > 1 1084 fprintf( stderr, "falling back to static mirror list\n" ); 1085 #endif 1086 1087 m_aMirrorMap.reserve( 0x10000 ); 1088 for( int i = 0; i < 0x10000; i++ ) 1089 m_aMirrorMap.push_back( sal_Unicode(i) ); 1090 1091 m_aMirrorMap[ 0x0028 ] = 0x0029; // LEFT PARENTHESIS 1092 m_aMirrorMap[ 0x0029 ] = 0x0028; // RIGHT PARENTHESIS 1093 m_aMirrorMap[ 0x003C ] = 0x003E; // LESS-THAN SIGN 1094 m_aMirrorMap[ 0x003E ] = 0x003C; // GREATER-THAN SIGN 1095 m_aMirrorMap[ 0x005B ] = 0x005D; // LEFT SQUARE BRACKET 1096 m_aMirrorMap[ 0x005D ] = 0x005B; // RIGHT SQUARE BRACKET 1097 m_aMirrorMap[ 0x007B ] = 0x007D; // LEFT CURLY BRACKET 1098 m_aMirrorMap[ 0x007D ] = 0x007B; // RIGHT CURLY BRACKET 1099 m_aMirrorMap[ 0x00AB ] = 0x00BB; // LEFT-POINTING DOUBLE ANGLE QUOTATION MARK 1100 m_aMirrorMap[ 0x00BB ] = 0x00AB; // RIGHT-POINTING DOUBLE ANGLE QUOTATION MARK 1101 m_aMirrorMap[ 0x0F3A ] = 0x0F3B; // TIBETAN MARK GUG RTAGS GYON 1102 m_aMirrorMap[ 0x0F3B ] = 0x0F3A; // TIBETAN MARK GUG RTAGS GYAS 1103 m_aMirrorMap[ 0x0F3C ] = 0x0F3D; // TIBETAN MARK ANG KHANG GYON 1104 m_aMirrorMap[ 0x0F3D ] = 0x0F3C; // TIBETAN MARK ANG KHANG GYAS 1105 m_aMirrorMap[ 0x169B ] = 0x169C; // OGHAM FEATHER MARK 1106 m_aMirrorMap[ 0x169C ] = 0x169B; // OGHAM REVERSED FEATHER MARK 1107 m_aMirrorMap[ 0x2039 ] = 0x203A; // SINGLE LEFT-POINTING ANGLE QUOTATION MARK 1108 m_aMirrorMap[ 0x203A ] = 0x2039; // SINGLE RIGHT-POINTING ANGLE QUOTATION MARK 1109 m_aMirrorMap[ 0x2045 ] = 0x2046; // LEFT SQUARE BRACKET WITH QUILL 1110 m_aMirrorMap[ 0x2046 ] = 0x2045; // RIGHT SQUARE BRACKET WITH QUILL 1111 m_aMirrorMap[ 0x207D ] = 0x207E; // SUPERSCRIPT LEFT PARENTHESIS 1112 m_aMirrorMap[ 0x207E ] = 0x207D; // SUPERSCRIPT RIGHT PARENTHESIS 1113 m_aMirrorMap[ 0x208D ] = 0x208E; // SUBSCRIPT LEFT PARENTHESIS 1114 m_aMirrorMap[ 0x208E ] = 0x208D; // SUBSCRIPT RIGHT PARENTHESIS 1115 m_aMirrorMap[ 0x2208 ] = 0x220B; // ELEMENT OF 1116 m_aMirrorMap[ 0x2209 ] = 0x220C; // NOT AN ELEMENT OF 1117 m_aMirrorMap[ 0x220A ] = 0x220D; // SMALL ELEMENT OF 1118 m_aMirrorMap[ 0x220B ] = 0x2208; // CONTAINS AS MEMBER 1119 m_aMirrorMap[ 0x220C ] = 0x2209; // DOES NOT CONTAIN AS MEMBER 1120 m_aMirrorMap[ 0x220D ] = 0x220A; // SMALL CONTAINS AS MEMBER 1121 m_aMirrorMap[ 0x2215 ] = 0x29F5; // DIVISION SLASH 1122 m_aMirrorMap[ 0x223C ] = 0x223D; // TILDE OPERATOR 1123 m_aMirrorMap[ 0x223D ] = 0x223C; // REVERSED TILDE 1124 m_aMirrorMap[ 0x2243 ] = 0x22CD; // ASYMPTOTICALLY EQUAL TO 1125 m_aMirrorMap[ 0x2252 ] = 0x2253; // APPROXIMATELY EQUAL TO OR THE IMAGE OF 1126 m_aMirrorMap[ 0x2253 ] = 0x2252; // IMAGE OF OR APPROXIMATELY EQUAL TO 1127 m_aMirrorMap[ 0x2254 ] = 0x2255; // COLON EQUALS 1128 m_aMirrorMap[ 0x2255 ] = 0x2254; // EQUALS COLON 1129 m_aMirrorMap[ 0x2264 ] = 0x2265; // LESS-THAN OR EQUAL TO 1130 m_aMirrorMap[ 0x2265 ] = 0x2264; // GREATER-THAN OR EQUAL TO 1131 m_aMirrorMap[ 0x2266 ] = 0x2267; // LESS-THAN OVER EQUAL TO 1132 m_aMirrorMap[ 0x2267 ] = 0x2266; // GREATER-THAN OVER EQUAL TO 1133 m_aMirrorMap[ 0x2268 ] = 0x2269; // [BEST FIT] LESS-THAN BUT NOT EQUAL TO 1134 m_aMirrorMap[ 0x2269 ] = 0x2268; // [BEST FIT] GREATER-THAN BUT NOT EQUAL TO 1135 m_aMirrorMap[ 0x226A ] = 0x226B; // MUCH LESS-THAN 1136 m_aMirrorMap[ 0x226B ] = 0x226A; // MUCH GREATER-THAN 1137 m_aMirrorMap[ 0x226E ] = 0x226F; // [BEST FIT] NOT LESS-THAN 1138 m_aMirrorMap[ 0x226F ] = 0x226E; // [BEST FIT] NOT GREATER-THAN 1139 m_aMirrorMap[ 0x2270 ] = 0x2271; // [BEST FIT] NEITHER LESS-THAN NOR EQUAL TO 1140 m_aMirrorMap[ 0x2271 ] = 0x2270; // [BEST FIT] NEITHER GREATER-THAN NOR EQUAL TO 1141 m_aMirrorMap[ 0x2272 ] = 0x2273; // [BEST FIT] LESS-THAN OR EQUIVALENT TO 1142 m_aMirrorMap[ 0x2273 ] = 0x2272; // [BEST FIT] GREATER-THAN OR EQUIVALENT TO 1143 m_aMirrorMap[ 0x2274 ] = 0x2275; // [BEST FIT] NEITHER LESS-THAN NOR EQUIVALENT TO 1144 m_aMirrorMap[ 0x2275 ] = 0x2274; // [BEST FIT] NEITHER GREATER-THAN NOR EQUIVALENT TO 1145 m_aMirrorMap[ 0x2276 ] = 0x2277; // LESS-THAN OR GREATER-THAN 1146 m_aMirrorMap[ 0x2277 ] = 0x2276; // GREATER-THAN OR LESS-THAN 1147 m_aMirrorMap[ 0x2278 ] = 0x2279; // [BEST FIT] NEITHER LESS-THAN NOR GREATER-THAN 1148 m_aMirrorMap[ 0x2279 ] = 0x2278; // [BEST FIT] NEITHER GREATER-THAN NOR LESS-THAN 1149 m_aMirrorMap[ 0x227A ] = 0x227B; // PRECEDES 1150 m_aMirrorMap[ 0x227B ] = 0x227A; // SUCCEEDS 1151 m_aMirrorMap[ 0x227C ] = 0x227D; // PRECEDES OR EQUAL TO 1152 m_aMirrorMap[ 0x227D ] = 0x227C; // SUCCEEDS OR EQUAL TO 1153 m_aMirrorMap[ 0x227E ] = 0x227F; // [BEST FIT] PRECEDES OR EQUIVALENT TO 1154 m_aMirrorMap[ 0x227F ] = 0x227E; // [BEST FIT] SUCCEEDS OR EQUIVALENT TO 1155 m_aMirrorMap[ 0x2280 ] = 0x2281; // [BEST FIT] DOES NOT PRECEDE 1156 m_aMirrorMap[ 0x2281 ] = 0x2280; // [BEST FIT] DOES NOT SUCCEED 1157 m_aMirrorMap[ 0x2282 ] = 0x2283; // SUBSET OF 1158 m_aMirrorMap[ 0x2283 ] = 0x2282; // SUPERSET OF 1159 m_aMirrorMap[ 0x2284 ] = 0x2285; // [BEST FIT] NOT A SUBSET OF 1160 m_aMirrorMap[ 0x2285 ] = 0x2284; // [BEST FIT] NOT A SUPERSET OF 1161 m_aMirrorMap[ 0x2286 ] = 0x2287; // SUBSET OF OR EQUAL TO 1162 m_aMirrorMap[ 0x2287 ] = 0x2286; // SUPERSET OF OR EQUAL TO 1163 m_aMirrorMap[ 0x2288 ] = 0x2289; // [BEST FIT] NEITHER A SUBSET OF NOR EQUAL TO 1164 m_aMirrorMap[ 0x2289 ] = 0x2288; // [BEST FIT] NEITHER A SUPERSET OF NOR EQUAL TO 1165 m_aMirrorMap[ 0x228A ] = 0x228B; // [BEST FIT] SUBSET OF WITH NOT EQUAL TO 1166 m_aMirrorMap[ 0x228B ] = 0x228A; // [BEST FIT] SUPERSET OF WITH NOT EQUAL TO 1167 m_aMirrorMap[ 0x228F ] = 0x2290; // SQUARE IMAGE OF 1168 m_aMirrorMap[ 0x2290 ] = 0x228F; // SQUARE ORIGINAL OF 1169 m_aMirrorMap[ 0x2291 ] = 0x2292; // SQUARE IMAGE OF OR EQUAL TO 1170 m_aMirrorMap[ 0x2292 ] = 0x2291; // SQUARE ORIGINAL OF OR EQUAL TO 1171 m_aMirrorMap[ 0x2298 ] = 0x29B8; // CIRCLED DIVISION SLASH 1172 m_aMirrorMap[ 0x22A2 ] = 0x22A3; // RIGHT TACK 1173 m_aMirrorMap[ 0x22A3 ] = 0x22A2; // LEFT TACK 1174 m_aMirrorMap[ 0x22A6 ] = 0x2ADE; // ASSERTION 1175 m_aMirrorMap[ 0x22A8 ] = 0x2AE4; // TRUE 1176 m_aMirrorMap[ 0x22A9 ] = 0x2AE3; // FORCES 1177 m_aMirrorMap[ 0x22AB ] = 0x2AE5; // DOUBLE VERTICAL BAR DOUBLE RIGHT TURNSTILE 1178 m_aMirrorMap[ 0x22B0 ] = 0x22B1; // PRECEDES UNDER RELATION 1179 m_aMirrorMap[ 0x22B1 ] = 0x22B0; // SUCCEEDS UNDER RELATION 1180 m_aMirrorMap[ 0x22B2 ] = 0x22B3; // NORMAL SUBGROUP OF 1181 m_aMirrorMap[ 0x22B3 ] = 0x22B2; // CONTAINS AS NORMAL SUBGROUP 1182 m_aMirrorMap[ 0x22B4 ] = 0x22B5; // NORMAL SUBGROUP OF OR EQUAL TO 1183 m_aMirrorMap[ 0x22B5 ] = 0x22B4; // CONTAINS AS NORMAL SUBGROUP OR EQUAL TO 1184 m_aMirrorMap[ 0x22B6 ] = 0x22B7; // ORIGINAL OF 1185 m_aMirrorMap[ 0x22B7 ] = 0x22B6; // IMAGE OF 1186 m_aMirrorMap[ 0x22C9 ] = 0x22CA; // LEFT NORMAL FACTOR SEMIDIRECT PRODUCT 1187 m_aMirrorMap[ 0x22CA ] = 0x22C9; // RIGHT NORMAL FACTOR SEMIDIRECT PRODUCT 1188 m_aMirrorMap[ 0x22CB ] = 0x22CC; // LEFT SEMIDIRECT PRODUCT 1189 m_aMirrorMap[ 0x22CC ] = 0x22CB; // RIGHT SEMIDIRECT PRODUCT 1190 m_aMirrorMap[ 0x22CD ] = 0x2243; // REVERSED TILDE EQUALS 1191 m_aMirrorMap[ 0x22D0 ] = 0x22D1; // DOUBLE SUBSET 1192 m_aMirrorMap[ 0x22D1 ] = 0x22D0; // DOUBLE SUPERSET 1193 m_aMirrorMap[ 0x22D6 ] = 0x22D7; // LESS-THAN WITH DOT 1194 m_aMirrorMap[ 0x22D7 ] = 0x22D6; // GREATER-THAN WITH DOT 1195 m_aMirrorMap[ 0x22D8 ] = 0x22D9; // VERY MUCH LESS-THAN 1196 m_aMirrorMap[ 0x22D9 ] = 0x22D8; // VERY MUCH GREATER-THAN 1197 m_aMirrorMap[ 0x22DA ] = 0x22DB; // LESS-THAN EQUAL TO OR GREATER-THAN 1198 m_aMirrorMap[ 0x22DB ] = 0x22DA; // GREATER-THAN EQUAL TO OR LESS-THAN 1199 m_aMirrorMap[ 0x22DC ] = 0x22DD; // EQUAL TO OR LESS-THAN 1200 m_aMirrorMap[ 0x22DD ] = 0x22DC; // EQUAL TO OR GREATER-THAN 1201 m_aMirrorMap[ 0x22DE ] = 0x22DF; // EQUAL TO OR PRECEDES 1202 m_aMirrorMap[ 0x22DF ] = 0x22DE; // EQUAL TO OR SUCCEEDS 1203 m_aMirrorMap[ 0x22E0 ] = 0x22E1; // [BEST FIT] DOES NOT PRECEDE OR EQUAL 1204 m_aMirrorMap[ 0x22E1 ] = 0x22E0; // [BEST FIT] DOES NOT SUCCEED OR EQUAL 1205 m_aMirrorMap[ 0x22E2 ] = 0x22E3; // [BEST FIT] NOT SQUARE IMAGE OF OR EQUAL TO 1206 m_aMirrorMap[ 0x22E3 ] = 0x22E2; // [BEST FIT] NOT SQUARE ORIGINAL OF OR EQUAL TO 1207 m_aMirrorMap[ 0x22E4 ] = 0x22E5; // [BEST FIT] SQUARE IMAGE OF OR NOT EQUAL TO 1208 m_aMirrorMap[ 0x22E5 ] = 0x22E4; // [BEST FIT] SQUARE ORIGINAL OF OR NOT EQUAL TO 1209 m_aMirrorMap[ 0x22E6 ] = 0x22E7; // [BEST FIT] LESS-THAN BUT NOT EQUIVALENT TO 1210 m_aMirrorMap[ 0x22E7 ] = 0x22E6; // [BEST FIT] GREATER-THAN BUT NOT EQUIVALENT TO 1211 m_aMirrorMap[ 0x22E8 ] = 0x22E9; // [BEST FIT] PRECEDES BUT NOT EQUIVALENT TO 1212 m_aMirrorMap[ 0x22E9 ] = 0x22E8; // [BEST FIT] SUCCEEDS BUT NOT EQUIVALENT TO 1213 m_aMirrorMap[ 0x22EA ] = 0x22EB; // [BEST FIT] NOT NORMAL SUBGROUP OF 1214 m_aMirrorMap[ 0x22EB ] = 0x22EA; // [BEST FIT] DOES NOT CONTAIN AS NORMAL SUBGROUP 1215 m_aMirrorMap[ 0x22EC ] = 0x22ED; // [BEST FIT] NOT NORMAL SUBGROUP OF OR EQUAL TO 1216 m_aMirrorMap[ 0x22ED ] = 0x22EC; // [BEST FIT] DOES NOT CONTAIN AS NORMAL SUBGROUP OR EQUAL 1217 m_aMirrorMap[ 0x22F0 ] = 0x22F1; // UP RIGHT DIAGONAL ELLIPSIS 1218 m_aMirrorMap[ 0x22F1 ] = 0x22F0; // DOWN RIGHT DIAGONAL ELLIPSIS 1219 m_aMirrorMap[ 0x22F2 ] = 0x22FA; // ELEMENT OF WITH LONG HORIZONTAL STROKE 1220 m_aMirrorMap[ 0x22F3 ] = 0x22FB; // ELEMENT OF WITH VERTICAL BAR AT END OF HORIZONTAL STROKE 1221 m_aMirrorMap[ 0x22F4 ] = 0x22FC; // SMALL ELEMENT OF WITH VERTICAL BAR AT END OF HORIZONTAL STROKE 1222 m_aMirrorMap[ 0x22F6 ] = 0x22FD; // ELEMENT OF WITH OVERBAR 1223 m_aMirrorMap[ 0x22F7 ] = 0x22FE; // SMALL ELEMENT OF WITH OVERBAR 1224 m_aMirrorMap[ 0x22FA ] = 0x22F2; // CONTAINS WITH LONG HORIZONTAL STROKE 1225 m_aMirrorMap[ 0x22FB ] = 0x22F3; // CONTAINS WITH VERTICAL BAR AT END OF HORIZONTAL STROKE 1226 m_aMirrorMap[ 0x22FC ] = 0x22F4; // SMALL CONTAINS WITH VERTICAL BAR AT END OF HORIZONTAL STROKE 1227 m_aMirrorMap[ 0x22FD ] = 0x22F6; // CONTAINS WITH OVERBAR 1228 m_aMirrorMap[ 0x22FE ] = 0x22F7; // SMALL CONTAINS WITH OVERBAR 1229 m_aMirrorMap[ 0x2308 ] = 0x2309; // LEFT CEILING 1230 m_aMirrorMap[ 0x2309 ] = 0x2308; // RIGHT CEILING 1231 m_aMirrorMap[ 0x230A ] = 0x230B; // LEFT FLOOR 1232 m_aMirrorMap[ 0x230B ] = 0x230A; // RIGHT FLOOR 1233 m_aMirrorMap[ 0x2329 ] = 0x232A; // LEFT-POINTING ANGLE BRACKET 1234 m_aMirrorMap[ 0x232A ] = 0x2329; // RIGHT-POINTING ANGLE BRACKET 1235 m_aMirrorMap[ 0x2768 ] = 0x2769; // MEDIUM LEFT PARENTHESIS ORNAMENT 1236 m_aMirrorMap[ 0x2769 ] = 0x2768; // MEDIUM RIGHT PARENTHESIS ORNAMENT 1237 m_aMirrorMap[ 0x276A ] = 0x276B; // MEDIUM FLATTENED LEFT PARENTHESIS ORNAMENT 1238 m_aMirrorMap[ 0x276B ] = 0x276A; // MEDIUM FLATTENED RIGHT PARENTHESIS ORNAMENT 1239 m_aMirrorMap[ 0x276C ] = 0x276D; // MEDIUM LEFT-POINTING ANGLE BRACKET ORNAMENT 1240 m_aMirrorMap[ 0x276D ] = 0x276C; // MEDIUM RIGHT-POINTING ANGLE BRACKET ORNAMENT 1241 m_aMirrorMap[ 0x276E ] = 0x276F; // HEAVY LEFT-POINTING ANGLE QUOTATION MARK ORNAMENT 1242 m_aMirrorMap[ 0x276F ] = 0x276E; // HEAVY RIGHT-POINTING ANGLE QUOTATION MARK ORNAMENT 1243 m_aMirrorMap[ 0x2770 ] = 0x2771; // HEAVY LEFT-POINTING ANGLE BRACKET ORNAMENT 1244 m_aMirrorMap[ 0x2771 ] = 0x2770; // HEAVY RIGHT-POINTING ANGLE BRACKET ORNAMENT 1245 m_aMirrorMap[ 0x2772 ] = 0x2773; // LIGHT LEFT TORTOISE SHELL BRACKET 1246 m_aMirrorMap[ 0x2773 ] = 0x2772; // LIGHT RIGHT TORTOISE SHELL BRACKET 1247 m_aMirrorMap[ 0x2774 ] = 0x2775; // MEDIUM LEFT CURLY BRACKET ORNAMENT 1248 m_aMirrorMap[ 0x2775 ] = 0x2774; // MEDIUM RIGHT CURLY BRACKET ORNAMENT 1249 m_aMirrorMap[ 0x27C3 ] = 0x27C4; // OPEN SUBSET 1250 m_aMirrorMap[ 0x27C4 ] = 0x27C3; // OPEN SUPERSET 1251 m_aMirrorMap[ 0x27C5 ] = 0x27C6; // LEFT S-SHAPED BAG DELIMITER 1252 m_aMirrorMap[ 0x27C6 ] = 0x27C5; // RIGHT S-SHAPED BAG DELIMITER 1253 m_aMirrorMap[ 0x27C8 ] = 0x27C9; // REVERSE SOLIDUS PRECEDING SUBSET 1254 m_aMirrorMap[ 0x27C9 ] = 0x27C8; // SUPERSET PRECEDING SOLIDUS 1255 m_aMirrorMap[ 0x27D5 ] = 0x27D6; // LEFT OUTER JOIN 1256 m_aMirrorMap[ 0x27D6 ] = 0x27D5; // RIGHT OUTER JOIN 1257 m_aMirrorMap[ 0x27DD ] = 0x27DE; // LONG RIGHT TACK 1258 m_aMirrorMap[ 0x27DE ] = 0x27DD; // LONG LEFT TACK 1259 m_aMirrorMap[ 0x27E2 ] = 0x27E3; // WHITE CONCAVE-SIDED DIAMOND WITH LEFTWARDS TICK 1260 m_aMirrorMap[ 0x27E3 ] = 0x27E2; // WHITE CONCAVE-SIDED DIAMOND WITH RIGHTWARDS TICK 1261 m_aMirrorMap[ 0x27E4 ] = 0x27E5; // WHITE SQUARE WITH LEFTWARDS TICK 1262 m_aMirrorMap[ 0x27E5 ] = 0x27E4; // WHITE SQUARE WITH RIGHTWARDS TICK 1263 m_aMirrorMap[ 0x27E6 ] = 0x27E7; // MATHEMATICAL LEFT WHITE SQUARE BRACKET 1264 m_aMirrorMap[ 0x27E7 ] = 0x27E6; // MATHEMATICAL RIGHT WHITE SQUARE BRACKET 1265 m_aMirrorMap[ 0x27E8 ] = 0x27E9; // MATHEMATICAL LEFT ANGLE BRACKET 1266 m_aMirrorMap[ 0x27E9 ] = 0x27E8; // MATHEMATICAL RIGHT ANGLE BRACKET 1267 m_aMirrorMap[ 0x27EA ] = 0x27EB; // MATHEMATICAL LEFT DOUBLE ANGLE BRACKET 1268 m_aMirrorMap[ 0x27EB ] = 0x27EA; // MATHEMATICAL RIGHT DOUBLE ANGLE BRACKET 1269 m_aMirrorMap[ 0x27EC ] = 0x27ED; // MATHEMATICAL LEFT WHITE TORTOISE SHELL BRACKET 1270 m_aMirrorMap[ 0x27ED ] = 0x27EC; // MATHEMATICAL RIGHT WHITE TORTOISE SHELL BRACKET 1271 m_aMirrorMap[ 0x27EE ] = 0x27EF; // MATHEMATICAL LEFT FLATTENED PARENTHESIS 1272 m_aMirrorMap[ 0x27EF ] = 0x27EE; // MATHEMATICAL RIGHT FLATTENED PARENTHESIS 1273 m_aMirrorMap[ 0x2983 ] = 0x2984; // LEFT WHITE CURLY BRACKET 1274 m_aMirrorMap[ 0x2984 ] = 0x2983; // RIGHT WHITE CURLY BRACKET 1275 m_aMirrorMap[ 0x2985 ] = 0x2986; // LEFT WHITE PARENTHESIS 1276 m_aMirrorMap[ 0x2986 ] = 0x2985; // RIGHT WHITE PARENTHESIS 1277 m_aMirrorMap[ 0x2987 ] = 0x2988; // Z NOTATION LEFT IMAGE BRACKET 1278 m_aMirrorMap[ 0x2988 ] = 0x2987; // Z NOTATION RIGHT IMAGE BRACKET 1279 m_aMirrorMap[ 0x2989 ] = 0x298A; // Z NOTATION LEFT BINDING BRACKET 1280 m_aMirrorMap[ 0x298A ] = 0x2989; // Z NOTATION RIGHT BINDING BRACKET 1281 m_aMirrorMap[ 0x298B ] = 0x298C; // LEFT SQUARE BRACKET WITH UNDERBAR 1282 m_aMirrorMap[ 0x298C ] = 0x298B; // RIGHT SQUARE BRACKET WITH UNDERBAR 1283 m_aMirrorMap[ 0x298D ] = 0x2990; // LEFT SQUARE BRACKET WITH TICK IN TOP CORNER 1284 m_aMirrorMap[ 0x298E ] = 0x298F; // RIGHT SQUARE BRACKET WITH TICK IN BOTTOM CORNER 1285 m_aMirrorMap[ 0x298F ] = 0x298E; // LEFT SQUARE BRACKET WITH TICK IN BOTTOM CORNER 1286 m_aMirrorMap[ 0x2990 ] = 0x298D; // RIGHT SQUARE BRACKET WITH TICK IN TOP CORNER 1287 m_aMirrorMap[ 0x2991 ] = 0x2992; // LEFT ANGLE BRACKET WITH DOT 1288 m_aMirrorMap[ 0x2992 ] = 0x2991; // RIGHT ANGLE BRACKET WITH DOT 1289 m_aMirrorMap[ 0x2993 ] = 0x2994; // LEFT ARC LESS-THAN BRACKET 1290 m_aMirrorMap[ 0x2994 ] = 0x2993; // RIGHT ARC GREATER-THAN BRACKET 1291 m_aMirrorMap[ 0x2995 ] = 0x2996; // DOUBLE LEFT ARC GREATER-THAN BRACKET 1292 m_aMirrorMap[ 0x2996 ] = 0x2995; // DOUBLE RIGHT ARC LESS-THAN BRACKET 1293 m_aMirrorMap[ 0x2997 ] = 0x2998; // LEFT BLACK TORTOISE SHELL BRACKET 1294 m_aMirrorMap[ 0x2998 ] = 0x2997; // RIGHT BLACK TORTOISE SHELL BRACKET 1295 m_aMirrorMap[ 0x29B8 ] = 0x2298; // CIRCLED REVERSE SOLIDUS 1296 m_aMirrorMap[ 0x29C0 ] = 0x29C1; // CIRCLED LESS-THAN 1297 m_aMirrorMap[ 0x29C1 ] = 0x29C0; // CIRCLED GREATER-THAN 1298 m_aMirrorMap[ 0x29C4 ] = 0x29C5; // SQUARED RISING DIAGONAL SLASH 1299 m_aMirrorMap[ 0x29C5 ] = 0x29C4; // SQUARED FALLING DIAGONAL SLASH 1300 m_aMirrorMap[ 0x29CF ] = 0x29D0; // LEFT TRIANGLE BESIDE VERTICAL BAR 1301 m_aMirrorMap[ 0x29D0 ] = 0x29CF; // VERTICAL BAR BESIDE RIGHT TRIANGLE 1302 m_aMirrorMap[ 0x29D1 ] = 0x29D2; // BOWTIE WITH LEFT HALF BLACK 1303 m_aMirrorMap[ 0x29D2 ] = 0x29D1; // BOWTIE WITH RIGHT HALF BLACK 1304 m_aMirrorMap[ 0x29D4 ] = 0x29D5; // TIMES WITH LEFT HALF BLACK 1305 m_aMirrorMap[ 0x29D5 ] = 0x29D4; // TIMES WITH RIGHT HALF BLACK 1306 m_aMirrorMap[ 0x29D8 ] = 0x29D9; // LEFT WIGGLY FENCE 1307 m_aMirrorMap[ 0x29D9 ] = 0x29D8; // RIGHT WIGGLY FENCE 1308 m_aMirrorMap[ 0x29DA ] = 0x29DB; // LEFT DOUBLE WIGGLY FENCE 1309 m_aMirrorMap[ 0x29DB ] = 0x29DA; // RIGHT DOUBLE WIGGLY FENCE 1310 m_aMirrorMap[ 0x29F5 ] = 0x2215; // REVERSE SOLIDUS OPERATOR 1311 m_aMirrorMap[ 0x29F8 ] = 0x29F9; // BIG SOLIDUS 1312 m_aMirrorMap[ 0x29F9 ] = 0x29F8; // BIG REVERSE SOLIDUS 1313 m_aMirrorMap[ 0x29FC ] = 0x29FD; // LEFT-POINTING CURVED ANGLE BRACKET 1314 m_aMirrorMap[ 0x29FD ] = 0x29FC; // RIGHT-POINTING CURVED ANGLE BRACKET 1315 m_aMirrorMap[ 0x2A2B ] = 0x2A2C; // MINUS SIGN WITH FALLING DOTS 1316 m_aMirrorMap[ 0x2A2C ] = 0x2A2B; // MINUS SIGN WITH RISING DOTS 1317 m_aMirrorMap[ 0x2A2D ] = 0x2A2E; // PLUS SIGN IN LEFT HALF CIRCLE 1318 m_aMirrorMap[ 0x2A2E ] = 0x2A2D; // PLUS SIGN IN RIGHT HALF CIRCLE 1319 m_aMirrorMap[ 0x2A34 ] = 0x2A35; // MULTIPLICATION SIGN IN LEFT HALF CIRCLE 1320 m_aMirrorMap[ 0x2A35 ] = 0x2A34; // MULTIPLICATION SIGN IN RIGHT HALF CIRCLE 1321 m_aMirrorMap[ 0x2A3C ] = 0x2A3D; // INTERIOR PRODUCT 1322 m_aMirrorMap[ 0x2A3D ] = 0x2A3C; // RIGHTHAND INTERIOR PRODUCT 1323 m_aMirrorMap[ 0x2A64 ] = 0x2A65; // Z NOTATION DOMAIN ANTIRESTRICTION 1324 m_aMirrorMap[ 0x2A65 ] = 0x2A64; // Z NOTATION RANGE ANTIRESTRICTION 1325 m_aMirrorMap[ 0x2A79 ] = 0x2A7A; // LESS-THAN WITH CIRCLE INSIDE 1326 m_aMirrorMap[ 0x2A7A ] = 0x2A79; // GREATER-THAN WITH CIRCLE INSIDE 1327 m_aMirrorMap[ 0x2A7D ] = 0x2A7E; // LESS-THAN OR SLANTED EQUAL TO 1328 m_aMirrorMap[ 0x2A7E ] = 0x2A7D; // GREATER-THAN OR SLANTED EQUAL TO 1329 m_aMirrorMap[ 0x2A7F ] = 0x2A80; // LESS-THAN OR SLANTED EQUAL TO WITH DOT INSIDE 1330 m_aMirrorMap[ 0x2A80 ] = 0x2A7F; // GREATER-THAN OR SLANTED EQUAL TO WITH DOT INSIDE 1331 m_aMirrorMap[ 0x2A81 ] = 0x2A82; // LESS-THAN OR SLANTED EQUAL TO WITH DOT ABOVE 1332 m_aMirrorMap[ 0x2A82 ] = 0x2A81; // GREATER-THAN OR SLANTED EQUAL TO WITH DOT ABOVE 1333 m_aMirrorMap[ 0x2A83 ] = 0x2A84; // LESS-THAN OR SLANTED EQUAL TO WITH DOT ABOVE RIGHT 1334 m_aMirrorMap[ 0x2A84 ] = 0x2A83; // GREATER-THAN OR SLANTED EQUAL TO WITH DOT ABOVE LEFT 1335 m_aMirrorMap[ 0x2A8B ] = 0x2A8C; // LESS-THAN ABOVE DOUBLE-LINE EQUAL ABOVE GREATER-THAN 1336 m_aMirrorMap[ 0x2A8C ] = 0x2A8B; // GREATER-THAN ABOVE DOUBLE-LINE EQUAL ABOVE LESS-THAN 1337 m_aMirrorMap[ 0x2A91 ] = 0x2A92; // LESS-THAN ABOVE GREATER-THAN ABOVE DOUBLE-LINE EQUAL 1338 m_aMirrorMap[ 0x2A92 ] = 0x2A91; // GREATER-THAN ABOVE LESS-THAN ABOVE DOUBLE-LINE EQUAL 1339 m_aMirrorMap[ 0x2A93 ] = 0x2A94; // LESS-THAN ABOVE SLANTED EQUAL ABOVE GREATER-THAN ABOVE SLANTED EQUAL 1340 m_aMirrorMap[ 0x2A94 ] = 0x2A93; // GREATER-THAN ABOVE SLANTED EQUAL ABOVE LESS-THAN ABOVE SLANTED EQUAL 1341 m_aMirrorMap[ 0x2A95 ] = 0x2A96; // SLANTED EQUAL TO OR LESS-THAN 1342 m_aMirrorMap[ 0x2A96 ] = 0x2A95; // SLANTED EQUAL TO OR GREATER-THAN 1343 m_aMirrorMap[ 0x2A97 ] = 0x2A98; // SLANTED EQUAL TO OR LESS-THAN WITH DOT INSIDE 1344 m_aMirrorMap[ 0x2A98 ] = 0x2A97; // SLANTED EQUAL TO OR GREATER-THAN WITH DOT INSIDE 1345 m_aMirrorMap[ 0x2A99 ] = 0x2A9A; // DOUBLE-LINE EQUAL TO OR LESS-THAN 1346 m_aMirrorMap[ 0x2A9A ] = 0x2A99; // DOUBLE-LINE EQUAL TO OR GREATER-THAN 1347 m_aMirrorMap[ 0x2A9B ] = 0x2A9C; // DOUBLE-LINE SLANTED EQUAL TO OR LESS-THAN 1348 m_aMirrorMap[ 0x2A9C ] = 0x2A9B; // DOUBLE-LINE SLANTED EQUAL TO OR GREATER-THAN 1349 m_aMirrorMap[ 0x2AA1 ] = 0x2AA2; // DOUBLE NESTED LESS-THAN 1350 m_aMirrorMap[ 0x2AA2 ] = 0x2AA1; // DOUBLE NESTED GREATER-THAN 1351 m_aMirrorMap[ 0x2AA6 ] = 0x2AA7; // LESS-THAN CLOSED BY CURVE 1352 m_aMirrorMap[ 0x2AA7 ] = 0x2AA6; // GREATER-THAN CLOSED BY CURVE 1353 m_aMirrorMap[ 0x2AA8 ] = 0x2AA9; // LESS-THAN CLOSED BY CURVE ABOVE SLANTED EQUAL 1354 m_aMirrorMap[ 0x2AA9 ] = 0x2AA8; // GREATER-THAN CLOSED BY CURVE ABOVE SLANTED EQUAL 1355 m_aMirrorMap[ 0x2AAA ] = 0x2AAB; // SMALLER THAN 1356 m_aMirrorMap[ 0x2AAB ] = 0x2AAA; // LARGER THAN 1357 m_aMirrorMap[ 0x2AAC ] = 0x2AAD; // SMALLER THAN OR EQUAL TO 1358 m_aMirrorMap[ 0x2AAD ] = 0x2AAC; // LARGER THAN OR EQUAL TO 1359 m_aMirrorMap[ 0x2AAF ] = 0x2AB0; // PRECEDES ABOVE SINGLE-LINE EQUALS SIGN 1360 m_aMirrorMap[ 0x2AB0 ] = 0x2AAF; // SUCCEEDS ABOVE SINGLE-LINE EQUALS SIGN 1361 m_aMirrorMap[ 0x2AB3 ] = 0x2AB4; // PRECEDES ABOVE EQUALS SIGN 1362 m_aMirrorMap[ 0x2AB4 ] = 0x2AB3; // SUCCEEDS ABOVE EQUALS SIGN 1363 m_aMirrorMap[ 0x2ABB ] = 0x2ABC; // DOUBLE PRECEDES 1364 m_aMirrorMap[ 0x2ABC ] = 0x2ABB; // DOUBLE SUCCEEDS 1365 m_aMirrorMap[ 0x2ABD ] = 0x2ABE; // SUBSET WITH DOT 1366 m_aMirrorMap[ 0x2ABE ] = 0x2ABD; // SUPERSET WITH DOT 1367 m_aMirrorMap[ 0x2ABF ] = 0x2AC0; // SUBSET WITH PLUS SIGN BELOW 1368 m_aMirrorMap[ 0x2AC0 ] = 0x2ABF; // SUPERSET WITH PLUS SIGN BELOW 1369 m_aMirrorMap[ 0x2AC1 ] = 0x2AC2; // SUBSET WITH MULTIPLICATION SIGN BELOW 1370 m_aMirrorMap[ 0x2AC2 ] = 0x2AC1; // SUPERSET WITH MULTIPLICATION SIGN BELOW 1371 m_aMirrorMap[ 0x2AC3 ] = 0x2AC4; // SUBSET OF OR EQUAL TO WITH DOT ABOVE 1372 m_aMirrorMap[ 0x2AC4 ] = 0x2AC3; // SUPERSET OF OR EQUAL TO WITH DOT ABOVE 1373 m_aMirrorMap[ 0x2AC5 ] = 0x2AC6; // SUBSET OF ABOVE EQUALS SIGN 1374 m_aMirrorMap[ 0x2AC6 ] = 0x2AC5; // SUPERSET OF ABOVE EQUALS SIGN 1375 m_aMirrorMap[ 0x2ACD ] = 0x2ACE; // SQUARE LEFT OPEN BOX OPERATOR 1376 m_aMirrorMap[ 0x2ACE ] = 0x2ACD; // SQUARE RIGHT OPEN BOX OPERATOR 1377 m_aMirrorMap[ 0x2ACF ] = 0x2AD0; // CLOSED SUBSET 1378 m_aMirrorMap[ 0x2AD0 ] = 0x2ACF; // CLOSED SUPERSET 1379 m_aMirrorMap[ 0x2AD1 ] = 0x2AD2; // CLOSED SUBSET OR EQUAL TO 1380 m_aMirrorMap[ 0x2AD2 ] = 0x2AD1; // CLOSED SUPERSET OR EQUAL TO 1381 m_aMirrorMap[ 0x2AD3 ] = 0x2AD4; // SUBSET ABOVE SUPERSET 1382 m_aMirrorMap[ 0x2AD4 ] = 0x2AD3; // SUPERSET ABOVE SUBSET 1383 m_aMirrorMap[ 0x2AD5 ] = 0x2AD6; // SUBSET ABOVE SUBSET 1384 m_aMirrorMap[ 0x2AD6 ] = 0x2AD5; // SUPERSET ABOVE SUPERSET 1385 m_aMirrorMap[ 0x2ADE ] = 0x22A6; // SHORT LEFT TACK 1386 m_aMirrorMap[ 0x2AE3 ] = 0x22A9; // DOUBLE VERTICAL BAR LEFT TURNSTILE 1387 m_aMirrorMap[ 0x2AE4 ] = 0x22A8; // VERTICAL BAR DOUBLE LEFT TURNSTILE 1388 m_aMirrorMap[ 0x2AE5 ] = 0x22AB; // DOUBLE VERTICAL BAR DOUBLE LEFT TURNSTILE 1389 m_aMirrorMap[ 0x2AEC ] = 0x2AED; // DOUBLE STROKE NOT SIGN 1390 m_aMirrorMap[ 0x2AED ] = 0x2AEC; // REVERSED DOUBLE STROKE NOT SIGN 1391 m_aMirrorMap[ 0x2AF7 ] = 0x2AF8; // TRIPLE NESTED LESS-THAN 1392 m_aMirrorMap[ 0x2AF8 ] = 0x2AF7; // TRIPLE NESTED GREATER-THAN 1393 m_aMirrorMap[ 0x2AF9 ] = 0x2AFA; // DOUBLE-LINE SLANTED LESS-THAN OR EQUAL TO 1394 m_aMirrorMap[ 0x2AFA ] = 0x2AF9; // DOUBLE-LINE SLANTED GREATER-THAN OR EQUAL TO 1395 m_aMirrorMap[ 0x2E02 ] = 0x2E03; // LEFT SUBSTITUTION BRACKET 1396 m_aMirrorMap[ 0x2E03 ] = 0x2E02; // RIGHT SUBSTITUTION BRACKET 1397 m_aMirrorMap[ 0x2E04 ] = 0x2E05; // LEFT DOTTED SUBSTITUTION BRACKET 1398 m_aMirrorMap[ 0x2E05 ] = 0x2E04; // RIGHT DOTTED SUBSTITUTION BRACKET 1399 m_aMirrorMap[ 0x2E09 ] = 0x2E0A; // LEFT TRANSPOSITION BRACKET 1400 m_aMirrorMap[ 0x2E0A ] = 0x2E09; // RIGHT TRANSPOSITION BRACKET 1401 m_aMirrorMap[ 0x2E0C ] = 0x2E0D; // LEFT RAISED OMISSION BRACKET 1402 m_aMirrorMap[ 0x2E0D ] = 0x2E0C; // RIGHT RAISED OMISSION BRACKET 1403 m_aMirrorMap[ 0x2E1C ] = 0x2E1D; // LEFT LOW PARAPHRASE BRACKET 1404 m_aMirrorMap[ 0x2E1D ] = 0x2E1C; // RIGHT LOW PARAPHRASE BRACKET 1405 m_aMirrorMap[ 0x2E20 ] = 0x2E21; // LEFT VERTICAL BAR WITH QUILL 1406 m_aMirrorMap[ 0x2E21 ] = 0x2E20; // RIGHT VERTICAL BAR WITH QUILL 1407 m_aMirrorMap[ 0x2E22 ] = 0x2E23; // TOP LEFT HALF BRACKET 1408 m_aMirrorMap[ 0x2E23 ] = 0x2E22; // TOP RIGHT HALF BRACKET 1409 m_aMirrorMap[ 0x2E24 ] = 0x2E25; // BOTTOM LEFT HALF BRACKET 1410 m_aMirrorMap[ 0x2E25 ] = 0x2E24; // BOTTOM RIGHT HALF BRACKET 1411 m_aMirrorMap[ 0x2E26 ] = 0x2E27; // LEFT SIDEWAYS U BRACKET 1412 m_aMirrorMap[ 0x2E27 ] = 0x2E26; // RIGHT SIDEWAYS U BRACKET 1413 m_aMirrorMap[ 0x2E28 ] = 0x2E29; // LEFT DOUBLE PARENTHESIS 1414 m_aMirrorMap[ 0x2E29 ] = 0x2E28; // RIGHT DOUBLE PARENTHESIS 1415 m_aMirrorMap[ 0x3008 ] = 0x3009; // LEFT ANGLE BRACKET 1416 m_aMirrorMap[ 0x3009 ] = 0x3008; // RIGHT ANGLE BRACKET 1417 m_aMirrorMap[ 0x300A ] = 0x300B; // LEFT DOUBLE ANGLE BRACKET 1418 m_aMirrorMap[ 0x300B ] = 0x300A; // RIGHT DOUBLE ANGLE BRACKET 1419 m_aMirrorMap[ 0x300C ] = 0x300D; // [BEST FIT] LEFT CORNER BRACKET 1420 m_aMirrorMap[ 0x300D ] = 0x300C; // [BEST FIT] RIGHT CORNER BRACKET 1421 m_aMirrorMap[ 0x300E ] = 0x300F; // [BEST FIT] LEFT WHITE CORNER BRACKET 1422 m_aMirrorMap[ 0x300F ] = 0x300E; // [BEST FIT] RIGHT WHITE CORNER BRACKET 1423 m_aMirrorMap[ 0x3010 ] = 0x3011; // LEFT BLACK LENTICULAR BRACKET 1424 m_aMirrorMap[ 0x3011 ] = 0x3010; // RIGHT BLACK LENTICULAR BRACKET 1425 m_aMirrorMap[ 0x3014 ] = 0x3015; // LEFT TORTOISE SHELL BRACKET 1426 m_aMirrorMap[ 0x3015 ] = 0x3014; // RIGHT TORTOISE SHELL BRACKET 1427 m_aMirrorMap[ 0x3016 ] = 0x3017; // LEFT WHITE LENTICULAR BRACKET 1428 m_aMirrorMap[ 0x3017 ] = 0x3016; // RIGHT WHITE LENTICULAR BRACKET 1429 m_aMirrorMap[ 0x3018 ] = 0x3019; // LEFT WHITE TORTOISE SHELL BRACKET 1430 m_aMirrorMap[ 0x3019 ] = 0x3018; // RIGHT WHITE TORTOISE SHELL BRACKET 1431 m_aMirrorMap[ 0x301A ] = 0x301B; // LEFT WHITE SQUARE BRACKET 1432 m_aMirrorMap[ 0x301B ] = 0x301A; // RIGHT WHITE SQUARE BRACKET 1433 m_aMirrorMap[ 0xFE59 ] = 0xFE5A; // SMALL LEFT PARENTHESIS 1434 m_aMirrorMap[ 0xFE5A ] = 0xFE59; // SMALL RIGHT PARENTHESIS 1435 m_aMirrorMap[ 0xFE5B ] = 0xFE5C; // SMALL LEFT CURLY BRACKET 1436 m_aMirrorMap[ 0xFE5C ] = 0xFE5B; // SMALL RIGHT CURLY BRACKET 1437 m_aMirrorMap[ 0xFE5D ] = 0xFE5E; // SMALL LEFT TORTOISE SHELL BRACKET 1438 m_aMirrorMap[ 0xFE5E ] = 0xFE5D; // SMALL RIGHT TORTOISE SHELL BRACKET 1439 m_aMirrorMap[ 0xFE64 ] = 0xFE65; // SMALL LESS-THAN SIGN 1440 m_aMirrorMap[ 0xFE65 ] = 0xFE64; // SMALL GREATER-THAN SIGN 1441 m_aMirrorMap[ 0xFF08 ] = 0xFF09; // FULLWIDTH LEFT PARENTHESIS 1442 m_aMirrorMap[ 0xFF09 ] = 0xFF08; // FULLWIDTH RIGHT PARENTHESIS 1443 m_aMirrorMap[ 0xFF1C ] = 0xFF1E; // FULLWIDTH LESS-THAN SIGN 1444 m_aMirrorMap[ 0xFF1E ] = 0xFF1C; // FULLWIDTH GREATER-THAN SIGN 1445 m_aMirrorMap[ 0xFF3B ] = 0xFF3D; // FULLWIDTH LEFT SQUARE BRACKET 1446 m_aMirrorMap[ 0xFF3D ] = 0xFF3B; // FULLWIDTH RIGHT SQUARE BRACKET 1447 m_aMirrorMap[ 0xFF5B ] = 0xFF5D; // FULLWIDTH LEFT CURLY BRACKET 1448 m_aMirrorMap[ 0xFF5D ] = 0xFF5B; // FULLWIDTH RIGHT CURLY BRACKET 1449 m_aMirrorMap[ 0xFF5F ] = 0xFF60; // FULLWIDTH LEFT WHITE PARENTHESIS 1450 m_aMirrorMap[ 0xFF60 ] = 0xFF5F; // FULLWIDTH RIGHT WHITE PARENTHESIS 1451 m_aMirrorMap[ 0xFF62 ] = 0xFF63; // [BEST FIT] HALFWIDTH LEFT CORNER BRACKET 1452 m_aMirrorMap[ 0xFF63 ] = 0xFF62; // [BEST FIT] HALFWIDTH RIGHT CORNER BRACKET 1453 } 1454 } 1455 1456 } 1457