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/*
* ===========================================
* Java Pdf Extraction Decoding Access Library
* ===========================================
*
* Project Info: http://www.idrsolutions.com
* Help section for developers at http://www.idrsolutions.com/support/
*
* (C) Copyright 1997-2015 IDRsolutions and Contributors.
*
* This file is part of JPedal/JPDF2HTML5
*
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* ---------------
* TTGraphicsState.java
* ---------------
*/
package org.jpedal.fonts.tt.hinting;
import java.io.Serializable;
/**
* holds the graphics state variables
*/
public class TTGraphicsState implements Cloneable, Serializable {
/**
* Preset vectors -
*
* Vectors are stored as two F2Dot14 numbers stored in an int, with the x component taking up the high 16 bits and
* the y component taking up the bottom 16. The hypotenuse must be 1 in length. (0x4000 in F2Dot14)
*/
public static final int x_axis=0x40000000;
public static final int y_axis=0x00004000;
/**
* Preset round states -
*
* The spec defines a way of interpreting an item from the stack to form a round state consisting of period, phase
* and threshold for use in the SROUND instruction. This format is used instead of storing each aspect of the round
* state individually.
*/
public static final int hg =0x68; //Half Grid
public static final int g =0x48; //Grid
public static final int dg =0x08; //Double Grid
public static final int dtg=0x44; //Down to Grid
public static final int utg=0x40; //Up to Grid
public static final int off=-1; //None
//Controls whether MIRP will flip CVT entries to match the actual distance
public boolean autoFlip=true;
//The maximum difference between the measured distance and the cvt entry if the entry is to be used for MIRP
public int controlValueTableCutIn =68;
//Lowest number in relative numbering system used by DELTA instructions
public int deltaBase=9;
//Determines the magnitude of movements by DELTA instructions
public int deltaShift=3;
//Vector which defines the direction of movement (for almost all instructions)
public int freedomVector=x_axis;
//Vector which defines the direction of measurement (usually)
public int projectionVector=x_axis;
//Vector which defines the direction of measurement when dealing with points original positions in GC, MD, MDRP and MIRP
public int dualProjectionVector=x_axis;
//Allows you to disable instructions entirely for glyph programs.
public int instructControl;
//Scan conversion not implemented - using java for anti aliased rendering instead
// public boolean scanControl=false;
//Used by some functions to repeat actions. It's always reset to 1 after it's used.
public int loop=1;
//Sets the minimum distance to which a value will be rounded in MIRP and MDRP
public int minimumDistance=1;
//Contains the components required to round variables
public int roundState=g;
//Grid period for rounding - 1 usually, sqrt(2)/2 for 45 degrees
public double gridPeriod=1.0;
//Reference points
public int rp0;
public int rp1;
public int rp2;
//The cutIn is the difference below which a distance will be replaced with the widthValue in MDRP and MIRP
public int singleWidthCutIn;
public int singleWidthValue;
//Zone pointers
public int zp0=TTVM.GLYPH_ZONE;
public int zp1=TTVM.GLYPH_ZONE;
public int zp2=TTVM.GLYPH_ZONE;
/**
* Create a copy of this object.
* @return Copy reference
* @throws CloneNotSupportedException
*/
@Override
public Object clone() throws CloneNotSupportedException {
return super.clone();
}
/**
* Rounds a double according to the round state variable.
* @param n Number to round
* @return Rounded number
*/
public double round(double n) {
if (roundState == off) {
return n;
}
final boolean isPositive = n > 0;
//Get period
int p = (roundState >> 6) & 3;
final double period;
if (p==0) {
period = gridPeriod / 2;
} else if (p==1) {
period = gridPeriod;
} else {
period = gridPeriod * 2;
}
//Get phase
p = (roundState >> 4) & 3;
final double phase;
if (p==0) {
phase = 0;
} else if (p==1) {
phase = period / 4;
} else if (p==2) {
phase = period / 2;
} else {
phase = (3 * period) / 4;
}
//Get threshold
p = roundState & 15;
//special case - use largest number smaller than period
if (p==0) {
double result = phase;
while (result < n) {
result += period;
}
return result;
}
final double threshold = ((p-4) * period) / 8;
//Round
n -= phase;
double lower = 0;
if (n > 0) {
n += threshold;
while (lower+period <= n) {
lower += period;
}
} else {
n -= threshold;
while (lower-period >= n) {
lower -= period;
}
}
n = lower;
n += phase;
//Make sure number doesn't flip from pos to neg/neg to pos
if (isPositive && n < 0) {
n = phase % period;
}
if (!isPositive && n > 0) {
n = (phase - (10 * period)) % period;
}
return n;
}
/**
* Rounds a F26Dot6 number according to the round state variable.
* @param f26dot6 Number to round
* @return Rounded number
*/
public int round(final int f26dot6) {
double d = TTVM.getDoubleFromF26Dot6(f26dot6);
d = round(d);
return TTVM.storeDoubleAsF26Dot6(d);
}
/**
* Takes an F26Dot6 distance along the projection vector and calculates the shift along the freedom vector IN ACTUAL
* SPACE required.
* @param distance Move required along PV
* @return F26Dot6 shifts needed in x and y
*/
public int[] getFVMoveforPVDistance(final int distance) {
if (distance == 0) {
return new int[]{0, 0};
}
final int[] fv = getVectorComponents(freedomVector);
fv[0] = TTVM.storeDoubleAsF26Dot6(TTVM.getDoubleFromF2Dot14(fv[0]));
fv[1] = TTVM.storeDoubleAsF26Dot6(TTVM.getDoubleFromF2Dot14(fv[1]));
final double fvWorth = TTVM.getDoubleFromF26Dot6(getCoordsOnVector(projectionVector, fv[0], fv[1]));
if (fvWorth != 0) {
final double mul = TTVM.getDoubleFromF26Dot6(distance);
fv[0] = (int)((fv[0]*mul)/fvWorth);
fv[1] = (int)((fv[1]*mul)/fvWorth);
} else {
fv[0] = 0;
fv[1] = 0;
}
return fv;
}
/**
* Get the F2Dot14 components of a vector.
* @param vector vector to get
* @return array of x and y components
*/
static int[] getVectorComponents(final int vector) {
return new int[]{(vector >> 16), ((vector << 16) >> 16)};
}
/**
* Create a vector from two F2Dot14 numbers.
* @param x x component
* @param y y component
* @return newly created vector
*/
static int createVector(final int x, final int y) {
return ((x & 0xFFFF) << 16) + (y & 0xFFFF);
}
/**
* Get the coordinates of a point on a vector.
* @param vector Vector to measure against
* @param x F26Dot6 x coordinate
* @param y F26Dot6 y coordinate
* @return F26Dot6 coordinate on vector
*/
static int getCoordsOnVector(final int vector, final int x, final int y) {
final int[] pv = getVectorComponents(vector);
// double xProj = TTVM.getDoubleFromF2Dot14(pv[0]) * TTVM.getDoubleFromF26Dot6(x);
// double yProj = TTVM.getDoubleFromF2Dot14(pv[1]) * TTVM.getDoubleFromF26Dot6(y);
// return TTVM.storeDoubleAsF26Dot6(xProj + yProj);
final long xProj = (long)pv[0] * (long)x;
final long yProj = (long)pv[1] * (long)y;
long bigResult = xProj + yProj;
final boolean roundUp = (bigResult & 0x3FFF) >= 0x7F;
bigResult >>= 14;
if (roundUp) {
bigResult++;
}
return (int)bigResult;
}
/**
* Resets various variables for each glyph.
*/
public void resetForGlyph() {
zp0 = TTVM.GLYPH_ZONE;
zp1 = TTVM.GLYPH_ZONE;
zp2 = TTVM.GLYPH_ZONE;
projectionVector = x_axis;
dualProjectionVector = x_axis;
freedomVector = x_axis;
roundState = g;
loop = 1;
controlValueTableCutIn=68;
}
//
}