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|
/*
* Copyright (c) 1994 Paul Vojta. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*
* NOTE:
* xdvi is based on prior work as noted in the modification history, below.
*/
/*
* DVI previewer for X.
*
* Eric Cooper, CMU, September 1985.
*
* Code derived from dvi-imagen.c.
*
* Modification history:
* 1/1986 Modified for X.10 --Bob Scheifler, MIT LCS.
* 7/1988 Modified for X.11 --Mark Eichin, MIT
* 12/1988 Added 'R' option, toolkit, magnifying glass
* --Paul Vojta, UC Berkeley.
* 2/1989 Added tpic support --Jeffrey Lee, U of Toronto
* 4/1989 Modified for System V --Donald Richardson, Clarkson Univ.
* 3/1990 Added VMS support --Scott Allendorf, U of Iowa
* 7/1990 Added reflection mode --Michael Pak, Hebrew U of Jerusalem
* 1/1992 Added greyscale code --Till Brychcy, Techn. Univ. Muenchen
* and Lee Hetherington, MIT
* 4/1994 Added DPS support, bounding box
* --Ricardo Telichevesky
* and Luis Miguel Silveira, MIT RLE.
*/
#include <config.h>
#include <kdebug.h>
#include <klocale.h>
#include <math.h>
#include <tqbitmap.h>
#include <tqfile.h>
#include <tqimage.h>
#include <tqpainter.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "fontpool.h"
#include "glyph.h"
#include "xdvi.h"
#include "TeXFontDefinition.h"
#include "TeXFont_PK.h"
//#define DEBUG_PK
#define PK_PRE 247
#define PK_ID 89
#define PK_MAGIC (PK_PRE << 8) + PK_ID
extern void oops(TQString message);
TeXFont_PK::TeXFont_PK(TeXFontDefinition *tqparent)
: TeXFont(tqparent)
{
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::TeXFont_PK( tqparent=" << tqparent << ")" << endl;
#endif
for(unsigned int i=0; i<TeXFontDefinition::max_num_of_chars_in_font; i++)
characterBitmaps[i] = 0;
file = fopen(TQFile::encodeName(tqparent->filename), "r");
if (file == 0)
kdError(4300) << i18n("Cannot open font file %1.").tqarg(tqparent->filename) << endl;
#ifdef DEBUG_PK
else
kdDebug(4300) << "TeXFont_PK::TeXFont_PK(): file opened successfully" << endl;
#endif
read_PK_index();
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::TeXFont_PK() ended" << endl;
#endif
}
TeXFont_PK::~TeXFont_PK()
{
//@@@ Release bitmaps
if (file != 0) {
fclose(file);
file = 0;
}
}
glyph* TeXFont_PK::getGlyph(TQ_UINT16 ch, bool generateCharacterPixmap, const TQColor& color)
{
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::getGlyph( ch=" << ch << ", generateCharacterPixmap=" << generateCharacterPixmap << " )" << endl;
#endif
// Paranoia checks
if (ch >= TeXFontDefinition::max_num_of_chars_in_font) {
kdError(4300) << "TeXFont_PK::getGlyph(): Argument is too big." << endl;
return glyphtable;
}
// This is the address of the glyph that will be returned.
struct glyph *g = glyphtable+ch;
// Check if the glyph is loaded. If not, load it now.
if (characterBitmaps[ch] == 0) {
// If the character is not defined in the PK file, mark the
// character as missing, and print an error message
if (g->addr == 0) {
kdError(4300) << i18n("TexFont_PK::operator[]: Character %1 not defined in font %2").tqarg(ch).tqarg(tqparent->filename) << endl;
g->addr = -1;
return g;
}
// If the character has already been marked as missing, just
// return a pointer to the glyph (which will then be empty)
if (g->addr == -1)
return g;
// Otherwise, try to load the character
fseek(file, g->addr, 0);
read_PK_char(ch);
// Check if the character could be loaded. If not, mark the
// character as 'missing', and return a pointer.
if (characterBitmaps[ch]->bits == 0) {
g->addr = -1;
return g;
}
}
// At this point, g points to a properly loaded character. Generate
// a smoothly scaled TQPixmap if the user asks for it.
if ((generateCharacterPixmap == true) &&
((g->shrunkenCharacter.isNull()) || (color != g->color)) &&
(characterBitmaps[ch]->w != 0)) {
g->color = color;
double shrinkFactor = 1200 / tqparent->displayResolution_in_dpi;
// All is fine? Then we rescale the bitmap in order to produce the
// required pixmap. Rescaling a character, however, is an art
// that requires some explanation...
//
// If we would just divide the size of the character and the
// coordinates by the shrink factor, then the result would look
// quite ugly: due to the ineviatable rounding errors in the
// integer arithmetic, the characters would be displaced by up to
// a pixel. That doesn't sound much, but on low-resolution
// devices, such as a notebook screen, the effect would be a
// "dancing line" of characters, which looks really bad.
// Calculate the coordinates of the hot point in the shrunken
// bitmap. For simplicity, let us consider the x-coordinate
// first. In principle, the hot point should have an x-coordinate
// of (g->x/shrinkFactor). That, however, will generally NOT be an
// integral number. The cure is to translate the source image
// somewhat, so that the x-coordinate of the hot point falls onto
// the round-up of this number, i.e.
g->x2 = (int)ceil(g->x/shrinkFactor);
// Translating and scaling then means that the pixel in the scaled
// image which covers the range [x,x+1) corresponds to the range
// [x*shrinkFactor+srcXTrans, (x+1)*shrinkFactor+srcXTrans), where
// srcXTrans is the following NEGATIVE number
double srcXTrans = shrinkFactor * (g->x/shrinkFactor - ceil(g->x/shrinkFactor));
// How big will the shrunken bitmap then become? If shrunk_width
// denotes that width of the scaled image, and
// characterBitmaps[ch]->w the width of the orininal image, we
// need to make sure that the following inequality holds:
//
// shrunk_width*shrinkFactor+srcXTrans >= characterBitmaps[ch]->w
//
// in other words,
int shrunk_width = (int)ceil( (characterBitmaps[ch]->w - srcXTrans)/shrinkFactor );
// Now do the same for the y-coordinate
g->y2 = (int)ceil(g->y/shrinkFactor);
double srcYTrans = shrinkFactor * (g->y/shrinkFactor - ceil(g->y/shrinkFactor ));
int shrunk_height = (int)ceil( (characterBitmaps[ch]->h - srcYTrans)/shrinkFactor );
// Turn the image into 8 bit
TQByteArray translated(characterBitmaps[ch]->w * characterBitmaps[ch]->h);
TQ_UINT8 *data = (TQ_UINT8 *)translated.data();
for(int x=0; x<characterBitmaps[ch]->w; x++)
for(int y=0; y<characterBitmaps[ch]->h; y++) {
TQ_UINT8 bit = *(characterBitmaps[ch]->bits + characterBitmaps[ch]->bytes_wide*y + (x >> 3));
bit = bit >> (x & 7);
bit = bit & 1;
data[characterBitmaps[ch]->w*y + x] = bit;
}
// Now shrink the image. We shrink the X-direction first
TQByteArray xshrunk(shrunk_width*characterBitmaps[ch]->h);
TQ_UINT8 *xdata = (TQ_UINT8 *)xshrunk.data();
// Do the shrinking. The pixel (x,y) that we want to calculate
// corresponds to the line segment from
//
// [shrinkFactor*x+srcXTrans, shrinkFactor*(x+1)+srcXTrans)
//
// The trouble is, these numbers are in general no integers.
for(int y=0; y<characterBitmaps[ch]->h; y++)
for(int x=0; x<shrunk_width; x++) {
TQ_UINT32 value = 0;
double destStartX = shrinkFactor*x+srcXTrans;
double destEndX = shrinkFactor*(x+1)+srcXTrans;
for(int srcX=(int)ceil(destStartX); srcX<floor(destEndX); srcX++)
if ((srcX >= 0) && (srcX < characterBitmaps[ch]->w))
value += data[characterBitmaps[ch]->w*y + srcX] * 255;
if (destStartX >= 0.0)
value += (TQ_UINT32) (255.0*(ceil(destStartX)-destStartX) * data[characterBitmaps[ch]->w*y + (int)floor(destStartX)]);
if (floor(destEndX) < characterBitmaps[ch]->w)
value += (TQ_UINT32) (255.0*(destEndX-floor(destEndX)) * data[characterBitmaps[ch]->w*y + (int)floor(destEndX)]);
xdata[shrunk_width*y + x] = (int)(value/shrinkFactor + 0.5);
}
// Now shrink the Y-direction
TQByteArray xyshrunk(shrunk_width*shrunk_height);
TQ_UINT8 *xydata = (TQ_UINT8 *)xyshrunk.data();
for(int x=0; x<shrunk_width; x++)
for(int y=0; y<shrunk_height; y++) {
TQ_UINT32 value = 0;
double destStartY = shrinkFactor*y+srcYTrans;
double destEndY = shrinkFactor*(y+1)+srcYTrans;
for(int srcY=(int)ceil(destStartY); srcY<floor(destEndY); srcY++)
if ((srcY >= 0) && (srcY < characterBitmaps[ch]->h))
value += xdata[shrunk_width*srcY + x];
if (destStartY >= 0.0)
value += (TQ_UINT32) ((ceil(destStartY)-destStartY) * xdata[shrunk_width*(int)floor(destStartY) + x]);
if (floor(destEndY) < characterBitmaps[ch]->h)
value += (TQ_UINT32) ((destEndY-floor(destEndY)) * xdata[shrunk_width*(int)floor(destEndY) + x]);
xydata[shrunk_width*y + x] = (int)(value/shrinkFactor);
}
TQImage im32(shrunk_width, shrunk_height, 32);
im32.setAlphaBuffer(true);
// Do TQPixmaps fully support the alpha channel? If yes, we use
// that. Otherwise, use other routines as a fallback
if (tqparent->font_pool->TQPixmapSupportsAlpha) {
// If the alpha channel is properly supported, we set the
// character glyph to a colored rectangle, and define the
// character outline only using the alpha channel. That ensures
// good quality rendering for overlapping characters.
im32.fill(tqRgb(color.red(), color.green(), color.blue()));
for(TQ_UINT16 y=0; y<shrunk_height; y++) {
TQ_UINT8 *destScanLine = (TQ_UINT8 *)im32.scanLine(y);
for(TQ_UINT16 col=0; col<shrunk_width; col++)
destScanLine[4*col+3] = xydata[shrunk_width*y + col];
}
} else {
// If the alpha channel is not supported... QT seems to turn the
// alpha channel into a crude bitmap which is used to tqmask the
// resulting TQPixmap. In this case, we define the character
// outline using the image data, and use the alpha channel only
// to store "maximally opaque" or "completely transparent"
// values. When characters are rendered, overlapping characters
// are no longer correctly drawn, but quality is still
// sufficient for most purposes. One notable exception is output
// from the gftodvi program, which will be partially unreadable.
TQ_UINT16 rInv = 0xFF - color.red();
TQ_UINT16 gInv = 0xFF - color.green();
TQ_UINT16 bInv = 0xFF - color.blue();
TQ_UINT8 *srcScanLine = xydata;
for(TQ_UINT16 y=0; y<shrunk_height; y++) {
unsigned int *destScanLine = (unsigned int *)im32.scanLine(y);
for(TQ_UINT16 col=0; col<shrunk_width; col++) {
TQ_UINT16 data = *srcScanLine;
// The value stored in "data" now has the following meaning:
// data = 0 -> white; data = 0xff -> use "color"
*destScanLine = tqRgba(0xFF - (rInv*data + 0x7F) / 0xFF,
0xFF - (gInv*data + 0x7F) / 0xFF,
0xFF - (bInv*data + 0x7F) / 0xFF,
(data > 0x03) ? 0xff : 0x00);
destScanLine++;
srcScanLine++;
}
}
}
g->shrunkenCharacter.convertFromImage(im32,0);
g->shrunkenCharacter.setOptimization(TQPixmap::BestOptim);
}
return g;
}
#define ADD(a, b) ((TQ_UINT32 *) (((char *) a) + b))
#define SUB(a, b) ((TQ_UINT32 *) (((char *) a) - b))
// This table is used for changing the bit order in a byte. The
// expression bitflp[byte] takes a byte in big endian and gives the
// little endian equivalent of that.
static const uchar bitflip[256] = {
0, 128, 64, 192, 32, 160, 96, 224, 16, 144, 80, 208, 48, 176, 112, 240,
8, 136, 72, 200, 40, 168, 104, 232, 24, 152, 88, 216, 56, 184, 120, 248,
4, 132, 68, 196, 36, 164, 100, 228, 20, 148, 84, 212, 52, 180, 116, 244,
12, 140, 76, 204, 44, 172, 108, 236, 28, 156, 92, 220, 60, 188, 124, 252,
2, 130, 66, 194, 34, 162, 98, 226, 18, 146, 82, 210, 50, 178, 114, 242,
10, 138, 74, 202, 42, 170, 106, 234, 26, 154, 90, 218, 58, 186, 122, 250,
6, 134, 70, 198, 38, 166, 102, 230, 22, 150, 86, 214, 54, 182, 118, 246,
14, 142, 78, 206, 46, 174, 110, 238, 30, 158, 94, 222, 62, 190, 126, 254,
1, 129, 65, 193, 33, 161, 97, 225, 17, 145, 81, 209, 49, 177, 113, 241,
9, 137, 73, 201, 41, 169, 105, 233, 25, 153, 89, 217, 57, 185, 121, 249,
5, 133, 69, 197, 37, 165, 101, 229, 21, 149, 85, 213, 53, 181, 117, 245,
13, 141, 77, 205, 45, 173, 109, 237, 29, 157, 93, 221, 61, 189, 125, 253,
3, 131, 67, 195, 35, 163, 99, 227, 19, 147, 83, 211, 51, 179, 115, 243,
11, 139, 75, 203, 43, 171, 107, 235, 27, 155, 91, 219, 59, 187, 123, 251,
7, 135, 71, 199, 39, 167, 103, 231, 23, 151, 87, 215, 55, 183, 119, 247,
15, 143, 79, 207, 47, 175, 111, 239, 31, 159, 95, 223, 63, 191, 127, 255
};
static TQ_UINT32 bit_masks[33] = {
0x0, 0x1, 0x3, 0x7,
0xf, 0x1f, 0x3f, 0x7f,
0xff, 0x1ff, 0x3ff, 0x7ff,
0xfff, 0x1fff, 0x3fff, 0x7fff,
0xffff, 0x1ffff, 0x3ffff, 0x7ffff,
0xfffff, 0x1fffff, 0x3fffff, 0x7fffff,
0xffffff, 0x1ffffff, 0x3ffffff, 0x7ffffff,
0xfffffff, 0x1fffffff, 0x3fffffff, 0x7fffffff,
0xffffffff
};
#define PK_ID 89
#define PK_CMD_START 240
#define PK_X1 240
#define PK_X2 241
#define PK_X3 242
#define PK_X4 243
#define PK_Y 244
#define PK_POST 245
#define PK_NOOP 246
#define PK_PRE 247
int TeXFont_PK::PK_get_nyb(FILE *fp)
{
#ifdef DEBUG_PK
kdDebug(4300) << "PK_get_nyb" << endl;
#endif
unsigned temp;
if (PK_bitpos < 0) {
PK_input_byte = one(fp);
PK_bitpos = 4;
}
temp = PK_input_byte >> PK_bitpos;
PK_bitpos -= 4;
return (temp & 0xf);
}
int TeXFont_PK::PK_packed_num(FILE *fp)
{
#ifdef DEBUG_PK
kdDebug(4300) << "PK_packed_num" << endl;
#endif
int i,j;
if ((i = PK_get_nyb(fp)) == 0) {
do {
j = PK_get_nyb(fp);
++i;
}
while (j == 0);
while (i > 0) {
j = (j << 4) | PK_get_nyb(fp);
--i;
}
return (j - 15 + ((13 - PK_dyn_f) << 4) + PK_dyn_f);
}
else {
if (i <= PK_dyn_f) return i;
if (i < 14)
return (((i - PK_dyn_f - 1) << 4) + PK_get_nyb(fp)
+ PK_dyn_f + 1);
if (i == 14) PK_repeat_count = PK_packed_num(fp);
else PK_repeat_count = 1;
return PK_packed_num(fp);
}
}
void TeXFont_PK::PK_skip_specials()
{
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::PK_skip_specials() called" << endl;
#endif
int i,j;
register FILE *fp = file;
#ifdef DEBUG_PK
if (fp == 0)
kdDebug(4300) << "TeXFont_PK::PK_skip_specials(): file == 0" << endl;
#endif
do {
PK_flag_byte = one(fp);
if (PK_flag_byte >= PK_CMD_START) {
switch (PK_flag_byte) {
case PK_X1 :
case PK_X2 :
case PK_X3 :
case PK_X4 :
i = 0;
for (j = PK_CMD_START; j <= PK_flag_byte; ++j)
i = (i << 8) | one(fp);
while (i--) (void) one(fp);
break;
case PK_Y :
(void) four(fp);
case PK_POST :
case PK_NOOP :
break;
default :
oops(i18n("Unexpected %1 in PK file %2").tqarg(PK_flag_byte).tqarg(tqparent->filename) );
break;
}
}
}
while (PK_flag_byte != PK_POST && PK_flag_byte >= PK_CMD_START);
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::PK_skip_specials() ended" << endl;
#endif
}
void TeXFont_PK::read_PK_char(unsigned int ch)
{
#ifdef DEBUG_PK
kdDebug(4300) << "read_PK_char" << endl;
#endif
int i, j;
int n;
int row_bit_pos;
bool paint_switch;
TQ_UINT32 *cp;
register struct glyph *g;
register FILE *fp = file;
long fpwidth;
TQ_UINT32 word = 0;
int word_weight, bytes_wide;
int rows_left, h_bit, count;
g = glyphtable + ch;
PK_flag_byte = g->x2;
PK_dyn_f = PK_flag_byte >> 4;
paint_switch = ((PK_flag_byte & 8) != 0);
PK_flag_byte &= 0x7;
if (PK_flag_byte == 7)
n = 4;
else
if (PK_flag_byte > 3)
n = 2;
else
n = 1;
#ifdef DEBUG_PK
kdDebug(4300) << "loading pk char " << ch << ", char type " << n << endl;
#endif
if (characterBitmaps[ch] == 0)
characterBitmaps[ch] = new bitmap();
/*
* now read rest of character preamble
*/
if (n != 4)
fpwidth = num(fp, 3);
else {
fpwidth = sfour(fp);
(void) four(fp); /* horizontal escapement */
}
(void) num(fp, n); /* vertical escapement */
{
unsigned long w, h;
w = num(fp, n);
h = num(fp, n);
if (w > 0x7fff || h > 0x7fff)
oops(i18n("The character %1 is too large in file %2").tqarg(ch).tqarg(tqparent->filename));
characterBitmaps[ch]->w = w;
characterBitmaps[ch]->h = h;
}
g->x = snum(fp, n);
g->y = snum(fp, n);
g->dvi_advance_in_units_of_design_size_by_2e20 = fpwidth;
{
/* width must be multiple of 16 bits for raster_op */
characterBitmaps[ch]->bytes_wide = ROUNDUP((int) characterBitmaps[ch]->w, 32) * 4;
register unsigned int size = characterBitmaps[ch]->bytes_wide * characterBitmaps[ch]->h;
characterBitmaps[ch]->bits = new char[size != 0 ? size : 1];
}
cp = (TQ_UINT32 *) characterBitmaps[ch]->bits;
/*
* read character data into *cp
*/
bytes_wide = ROUNDUP((int) characterBitmaps[ch]->w, 32) * 4;
PK_bitpos = -1;
// The routines which read the character depend on the bit
// ordering. In principle, the bit order should be detected at
// compile time and the proper routing chosen. For the moment, as
// autoconf is somewhat complicated for the author, we prefer a
// simpler -even if somewhat slower approach and detect the ordering
// at runtime. That should of course be changed in the future.
int wordSize;
bool bigEndian;
qSysInfo (&wordSize, &bigEndian);
if (bigEndian) {
// Routine for big Endian machines. Applies e.g. to Motorola and
// (Ultra-)Sparc processors.
#ifdef DEBUG_PK
kdDebug(4300) << "big Endian byte ordering" << endl;
#endif
if (PK_dyn_f == 14) { /* get raster by bits */
memset(characterBitmaps[ch]->bits, 0, (int) characterBitmaps[ch]->h * bytes_wide);
for (i = 0; i < (int) characterBitmaps[ch]->h; i++) { /* get all rows */
cp = ADD(characterBitmaps[ch]->bits, i * bytes_wide);
row_bit_pos = 32;
for (j = 0; j < (int) characterBitmaps[ch]->w; j++) { /* get one row */
if (--PK_bitpos < 0) {
word = one(fp);
PK_bitpos = 7;
}
if (--row_bit_pos < 0) {
cp++;
row_bit_pos = 32 - 1;
}
if (word & (1 << PK_bitpos))
*cp |= 1 << row_bit_pos;
}
}
} else { /* get packed raster */
rows_left = characterBitmaps[ch]->h;
h_bit = characterBitmaps[ch]->w;
PK_repeat_count = 0;
word_weight = 32;
word = 0;
while (rows_left > 0) {
count = PK_packed_num(fp);
while (count > 0) {
if (count < word_weight && count < h_bit) {
h_bit -= count;
word_weight -= count;
if (paint_switch)
word |= bit_masks[count] << word_weight;
count = 0;
} else
if (count >= h_bit && h_bit <= word_weight) {
if (paint_switch)
word |= bit_masks[h_bit] << (word_weight - h_bit);
*cp++ = word;
/* "output" row(s) */
for (i = PK_repeat_count * bytes_wide / 4; i > 0; --i) {
*cp = *SUB(cp, bytes_wide);
++cp;
}
rows_left -= PK_repeat_count + 1;
PK_repeat_count = 0;
word = 0;
word_weight = 32;
count -= h_bit;
h_bit = characterBitmaps[ch]->w;
} else {
if (paint_switch)
word |= bit_masks[word_weight];
*cp++ = word;
word = 0;
count -= word_weight;
h_bit -= word_weight;
word_weight = 32;
}
}
paint_switch = 1 - paint_switch;
}
if (cp != ((TQ_UINT32 *) (characterBitmaps[ch]->bits + bytes_wide * characterBitmaps[ch]->h)))
oops(i18n("Wrong number of bits stored: char. %1, font %2").tqarg(ch).tqarg(tqparent->filename));
if (rows_left != 0 || h_bit != characterBitmaps[ch]->w)
oops(i18n("Bad pk file (%1), too many bits").tqarg(tqparent->filename));
}
// The data in the bitmap is now in the processor's bit order,
// that is, big endian. Since XWindows needs little endian, we
// need to change the bit order now.
register unsigned char* bitmapData = (unsigned char*) characterBitmaps[ch]->bits;
register unsigned char* endOfData = bitmapData + characterBitmaps[ch]->bytes_wide*characterBitmaps[ch]->h;
while(bitmapData < endOfData) {
*bitmapData = bitflip[*bitmapData];
bitmapData++;
}
} else {
// Routines for small Endian start here. This applies e.g. to
// Intel and Alpha processors.
#ifdef DEBUG_PK
kdDebug(4300) << "small Endian byte ordering" << endl;
#endif
if (PK_dyn_f == 14) { /* get raster by bits */
memset(characterBitmaps[ch]->bits, 0, (int) characterBitmaps[ch]->h * bytes_wide);
for (i = 0; i < (int) characterBitmaps[ch]->h; i++) { /* get all rows */
cp = ADD(characterBitmaps[ch]->bits, i * bytes_wide);
row_bit_pos = -1;
for (j = 0; j < (int) characterBitmaps[ch]->w; j++) { /* get one row */
if (--PK_bitpos < 0) {
word = one(fp);
PK_bitpos = 7;
}
if (++row_bit_pos >= 32) {
cp++;
row_bit_pos = 0;
}
if (word & (1 << PK_bitpos))
*cp |= 1 << row_bit_pos;
}
}
} else { /* get packed raster */
rows_left = characterBitmaps[ch]->h;
h_bit = characterBitmaps[ch]->w;
PK_repeat_count = 0;
word_weight = 32;
word = 0;
while (rows_left > 0) {
count = PK_packed_num(fp);
while (count > 0) {
if (count < word_weight && count < h_bit) {
if (paint_switch)
word |= bit_masks[count] << (32 - word_weight);
h_bit -= count;
word_weight -= count;
count = 0;
} else
if (count >= h_bit && h_bit <= word_weight) {
if (paint_switch)
word |= bit_masks[h_bit] << (32 - word_weight);
*cp++ = word;
/* "output" row(s) */
for (i = PK_repeat_count * bytes_wide / 4; i > 0; --i) {
*cp = *SUB(cp, bytes_wide);
++cp;
}
rows_left -= PK_repeat_count + 1;
PK_repeat_count = 0;
word = 0;
word_weight = 32;
count -= h_bit;
h_bit = characterBitmaps[ch]->w;
} else {
if (paint_switch)
word |= bit_masks[word_weight] << (32 - word_weight);
*cp++ = word;
word = 0;
count -= word_weight;
h_bit -= word_weight;
word_weight = 32;
}
}
paint_switch = 1 - paint_switch;
}
if (cp != ((TQ_UINT32 *) (characterBitmaps[ch]->bits + bytes_wide * characterBitmaps[ch]->h)))
oops(i18n("Wrong number of bits stored: char. %1, font %2").tqarg(ch).tqarg(tqparent->filename));
if (rows_left != 0 || h_bit != characterBitmaps[ch]->w)
oops(i18n("Bad pk file (%1), too many bits").tqarg(tqparent->filename));
}
} // endif: big or small Endian?
}
void TeXFont_PK::read_PK_index()
{
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::read_PK_index() called" << endl;
#endif
if (file == 0) {
kdError(4300) << "TeXFont_PK::read_PK_index(): file == 0" << endl;
return;
}
int magic = two(file);
if (magic != PK_MAGIC) {
kdError(4300) << "TeXFont_PK::read_PK_index(): file is not a PK file" << endl;
return;
}
fseek(file, (long) one(file), SEEK_CUR); /* skip comment */
(void) four(file); /* skip design size */
checksum = four(file);
int hppp = sfour(file);
int vppp = sfour(file);
if (hppp != vppp)
kdWarning(4300) << i18n("Font has non-square aspect ratio ") << vppp << ":" << hppp << endl;
// Read glyph directory (really a whole pass over the file).
for (;;) {
int bytes_left, flag_low_bits;
unsigned int ch;
PK_skip_specials();
if (PK_flag_byte == PK_POST)
break;
flag_low_bits = PK_flag_byte & 0x7;
if (flag_low_bits == 7) {
bytes_left = four(file);
ch = four(file);
} else
if (flag_low_bits > 3) {
bytes_left = ((flag_low_bits - 4) << 16) + two(file);
ch = one(file);
} else {
bytes_left = (flag_low_bits << 8) + one(file);
ch = one(file);
}
glyphtable[ch].addr = ftell(file);
glyphtable[ch].x2 = PK_flag_byte;
fseek(file, (long) bytes_left, SEEK_CUR);
#ifdef DEBUG_PK
kdDebug(4300) << "Scanning pk char " << ch << "at " << glyphtable[ch].addr << endl;
#endif
}
#ifdef DEBUG_PK
kdDebug(4300) << "TeXFont_PK::read_PK_index() called" << endl;
#endif
}
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