/* * * (C) Copyright IBM Corp. 1998-2005 - All Rights Reserved * */ #include "LETypes.h" #include "GlyphPositionAdjustments.h" #include "LEGlyphStorage.h" #include "LEFontInstance.h" U_NAMESPACE_BEGIN #define CHECK_ALLOCATE_ARRAY(array, type, size) \ if (array == NULL) { \ array = (type *) new type[size]; \ } GlyphPositionAdjustments::GlyphPositionAdjustments(le_int32 glyphCount) : fGlyphCount(glyphCount), fEntryExitPoints(NULL), fAdjustments(NULL) { fAdjustments = (Adjustment *) new Adjustment[glyphCount]; } GlyphPositionAdjustments::~GlyphPositionAdjustments() { delete[] fEntryExitPoints; delete[] fAdjustments; } const LEPoint *GlyphPositionAdjustments::getEntryPoint(le_int32 index, LEPoint &entryPoint) const { if (fEntryExitPoints == NULL) { return NULL; } return fEntryExitPoints[index].getEntryPoint(entryPoint); } const LEPoint *GlyphPositionAdjustments::getExitPoint(le_int32 index, LEPoint &exitPoint)const { if (fEntryExitPoints == NULL) { return NULL; } return fEntryExitPoints[index].getExitPoint(exitPoint); } void GlyphPositionAdjustments::setEntryPoint(le_int32 index, LEPoint &newEntryPoint, le_bool baselineIsLogicalEnd) { CHECK_ALLOCATE_ARRAY(fEntryExitPoints, EntryExitPoint, fGlyphCount); fEntryExitPoints[index].setEntryPoint(newEntryPoint, baselineIsLogicalEnd); } void GlyphPositionAdjustments::setExitPoint(le_int32 index, LEPoint &newExitPoint, le_bool baselineIsLogicalEnd) { CHECK_ALLOCATE_ARRAY(fEntryExitPoints, EntryExitPoint, fGlyphCount); fEntryExitPoints[index].setExitPoint(newExitPoint, baselineIsLogicalEnd); } void GlyphPositionAdjustments::setCursiveGlyph(le_int32 index, le_bool baselineIsLogicalEnd) { CHECK_ALLOCATE_ARRAY(fEntryExitPoints, EntryExitPoint, fGlyphCount); fEntryExitPoints[index].setCursiveGlyph(baselineIsLogicalEnd); } void GlyphPositionAdjustments::applyCursiveAdjustments(LEGlyphStorage &glyphStorage, le_bool rightToLeft, const LEFontInstance *fontInstance) { if (! hasCursiveGlyphs()) { return; } le_int32 start = 0, end = fGlyphCount, dir = 1; le_int32 firstExitPoint = -1, lastExitPoint = -1; LEPoint entryAnchor, exitAnchor, pixels; LEGlyphID lastExitGlyphID = 0; float baselineAdjustment = 0; // This removes a possible warning about // using exitAnchor before it's been initialized. exitAnchor.fX = exitAnchor.fY = 0; if (rightToLeft) { start = fGlyphCount - 1; end = -1; dir = -1; } for (le_int32 i = start; i != end; i += dir) { LEGlyphID glyphID = glyphStorage[i]; if (isCursiveGlyph(i)) { if (lastExitPoint >= 0 && getEntryPoint(i, entryAnchor) != NULL) { float anchorDiffX = exitAnchor.fX - entryAnchor.fX; float anchorDiffY = exitAnchor.fY - entryAnchor.fY; baselineAdjustment += anchorDiffY; adjustYPlacement(i, baselineAdjustment); if (rightToLeft) { LEPoint secondAdvance; fontInstance->getGlyphAdvance(glyphID, pixels); fontInstance->pixelsToUnits(pixels, secondAdvance); adjustXAdvance(i, -(anchorDiffX + secondAdvance.fX)); } else { LEPoint firstAdvance; fontInstance->getGlyphAdvance(lastExitGlyphID, pixels); fontInstance->pixelsToUnits(pixels, firstAdvance); adjustXAdvance(lastExitPoint, anchorDiffX - firstAdvance.fX); } } lastExitPoint = i; if (getExitPoint(i, exitAnchor) != NULL) { if (firstExitPoint < 0) { firstExitPoint = i; } lastExitGlyphID = glyphID; } else { if (baselineIsLogicalEnd(i) && firstExitPoint >= 0 && lastExitPoint >= 0) { le_int32 limit = lastExitPoint + dir; for (le_int32 j = firstExitPoint; j != limit; j += dir) { if (isCursiveGlyph(j)) { adjustYPlacement(j, -baselineAdjustment); } } } firstExitPoint = lastExitPoint = -1; baselineAdjustment = 0; } } } } LEPoint *GlyphPositionAdjustments::EntryExitPoint::getEntryPoint(LEPoint &entryPoint) const { if (fFlags & EEF_HAS_ENTRY_POINT) { entryPoint = fEntryPoint; return &entryPoint; } return NULL; } LEPoint *GlyphPositionAdjustments::EntryExitPoint::getExitPoint(LEPoint &exitPoint) const { if (fFlags & EEF_HAS_EXIT_POINT) { exitPoint = fExitPoint; return &exitPoint; } return NULL; } U_NAMESPACE_END