source/layout/GlyphPositionAdjustments.cpp - external/github.com/unicode-org/icu - Git at Google

 /*
  *
  * (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
	/*
	*
	* (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