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skia / third_party / poppler / 223a4bf3a679f666b6c963a8787cf5b5ac75c4b6 / . / poppler / SplashOutputDev.cc
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//========================================================================
//
// SplashOutputDev.cc
//
// Copyright 2003 Glyph & Cog, LLC
//
//========================================================================
#include <config.h>
#ifdef USE_GCC_PRAGMAS
#pragma implementation
#endif
#include <string.h>
#include <math.h>
#include "goo/gfile.h"
#include "GlobalParams.h"
#include "Error.h"
#include "Object.h"
#include "GfxFont.h"
#include "Link.h"
#include "CharCodeToUnicode.h"
#include "FontEncodingTables.h"
#include "fofi/FoFiTrueType.h"
#include "splash/SplashBitmap.h"
#include "splash/SplashGlyphBitmap.h"
#include "splash/SplashPattern.h"
#include "splash/SplashScreen.h"
#include "splash/SplashPath.h"
#include "splash/SplashState.h"
#include "splash/SplashErrorCodes.h"
#include "splash/SplashFontEngine.h"
#include "splash/SplashFont.h"
#include "splash/SplashFontFile.h"
#include "splash/SplashFontFileID.h"
#include "splash/Splash.h"
#include "SplashOutputDev.h"
//------------------------------------------------------------------------
// Blend functions
//------------------------------------------------------------------------
static void splashOutBlendMultiply(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
// note: floor(x / 255) = x >> 8 (for 16-bit x)
blend[i] = (dest[i] * src[i]) >> 8;
}
}
static void splashOutBlendScreen(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
// note: floor(x / 255) = x >> 8 (for 16-bit x)
blend[i] = dest[i] + src[i] - ((dest[i] * src[i]) >> 8);
}
}
static void splashOutBlendOverlay(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
//~ not sure if this is right
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
// note: floor(x / 255) = x >> 8 (for 16-bit x)
blend[i] = dest[i] < 0x80 ? ((dest[i] * src[i]) >> 8)
: dest[i] + src[i] - ((dest[i] * src[i]) >> 8);
}
}
static void splashOutBlendDarken(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
blend[i] = dest[i] < src[i] ? dest[i] : src[i];
}
}
static void splashOutBlendLighten(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
blend[i] = dest[i] > src[i] ? dest[i] : src[i];
}
}
static void splashOutBlendColorDodge(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend,
SplashColorMode cm) {
int i, x;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
x = dest[i] + src[i];
blend[i] = x <= 255 ? x : 255;
}
}
static void splashOutBlendColorBurn(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i, x;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
x = dest[i] - (255 - src[i]);
blend[i] = x >= 0 ? x : 0;
}
}
static void splashOutBlendHardLight(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
//~ not sure if this is right
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
// note: floor(x / 255) = x >> 8 (for 16-bit x)
blend[i] = src[i] < 0x80
? ((dest[i] * (src[i] * 2)) >> 8)
: 0xff - (((0xff - dest[i]) * (0x1ff - src[i] * 2)) >> 8);
}
}
static void splashOutBlendSoftLight(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i, x;
//~ not sure if this is right
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
if (src[i] < 0x80) {
x = dest[i] - (0x80 - src[i]);
blend[i] = x >= 0 ? x : 0;
} else {
x = dest[i] + (src[i] - 0x80);
blend[i] = x <= 255 ? x : 255;
}
}
}
static void splashOutBlendDifference(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend,
SplashColorMode cm) {
int i;
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
blend[i] = dest[i] < src[i] ? src[i] - dest[i] : dest[i] - src[i];
}
}
static void splashOutBlendExclusion(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int i;
//~ not sure what this is supposed to do
for (i = 0; i < splashColorModeNComps[cm]; ++i) {
blend[i] = dest[i] < src[i] ? src[i] - dest[i] : dest[i] - src[i];
}
}
static void cvtRGBToHSV(Guchar r, Guchar g, Guchar b, int *h, int *s, int *v) {
int cmax, cmid, cmin, x;
if (r >= g) {
if (g >= b) { x = 0; cmax = r; cmid = g; cmin = b; }
else if (b >= r) { x = 4; cmax = b; cmid = r; cmin = g; }
else { x = 5; cmax = r; cmid = b; cmin = g; }
} else {
if (r >= b) { x = 1; cmax = g; cmid = r; cmin = b; }
else if (g >= b) { x = 2; cmax = g; cmid = b; cmin = r; }
else { x = 3; cmax = b; cmid = g; cmin = r; }
}
if (cmax == cmin) {
*h = *s = 0;
} else {
*h = x * 60;
if (x & 1) {
*h += ((cmax - cmid) * 60) / (cmax - cmin);
} else {
*h += ((cmid - cmin) * 60) / (cmax - cmin);
}
*s = (255 * (cmax - cmin)) / cmax;
}
*v = cmax;
}
static void cvtHSVToRGB(int h, int s, int v, Guchar *r, Guchar *g, Guchar *b) {
int x, f, cmax, cmid, cmin;
if (s == 0) {
*r = *g = *b = v;
} else {
x = h / 60;
f = h % 60;
cmax = v;
if (x & 1) {
cmid = (v * 255 - ((s * f) / 60)) >> 8;
} else {
cmid = (v * (255 - ((s * (60 - f)) / 60))) >> 8;
}
// note: floor(x / 255) = x >> 8 (for 16-bit x)
cmin = (v * (255 - s)) >> 8;
switch (x) {
case 0: *r = cmax; *g = cmid; *b = cmin; break;
case 1: *g = cmax; *r = cmid; *b = cmin; break;
case 2: *g = cmax; *b = cmid; *r = cmin; break;
case 3: *b = cmax; *g = cmid; *r = cmin; break;
case 4: *b = cmax; *r = cmid; *g = cmin; break;
case 5: *r = cmax; *b = cmid; *g = cmin; break;
}
}
}
static void splashOutBlendHue(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int hs, ss, vs, hd, sd, vd;
#if SPLASH_CMYK
Guchar r, g, b;
#endif
switch (cm) {
case splashModeMono1:
case splashModeMono8:
blend[0] = dest[0];
break;
case splashModeRGB8:
cvtRGBToHSV(src[0], src[1], src[2], &hs, &ss, &vs);
cvtRGBToHSV(dest[0], dest[1], dest[2], &hd, &sd, &vd);
cvtHSVToRGB(hs, sd, vd, &blend[0], &blend[1], &blend[2]);
break;
case splashModeBGR8:
cvtRGBToHSV(src[2], src[1], src[0], &hs, &ss, &vs);
cvtRGBToHSV(dest[2], dest[1], dest[0], &hd, &sd, &vd);
cvtHSVToRGB(hs, sd, vd, &blend[2], &blend[1], &blend[0]);
break;
#if SPLASH_CMYK
case splashModeCMYK8:
//~ (0xff - ...) should be clipped
cvtRGBToHSV(0xff - (src[0] + src[3]),
0xff - (src[1] + src[3]),
0xff - (src[2] + src[3]), &hs, &ss, &vs);
cvtRGBToHSV(0xff - (dest[0] + dest[3]),
0xff - (dest[1] + dest[3]),
0xff - (dest[2] + dest[3]), &hd, &sd, &vd);
cvtHSVToRGB(hs, sd, vd, &r, &g, &b);
//~ should do black generation
blend[0] = 0xff - r;
blend[0] = 0xff - g;
blend[0] = 0xff - b;
blend[3] = 0;
break;
#endif
default:
//~ unimplemented
break;
}
}
static void splashOutBlendSaturation(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend,
SplashColorMode cm) {
int hs, ss, vs, hd, sd, vd;
#if SPLASH_CMYK
Guchar r, g, b;
#endif
switch (cm) {
case splashModeMono1:
case splashModeMono8:
blend[0] = dest[0];
break;
case splashModeRGB8:
cvtRGBToHSV(src[0], src[1], src[2], &hs, &ss, &vs);
cvtRGBToHSV(dest[0], dest[1], dest[2], &hd, &sd, &vd);
cvtHSVToRGB(hd, ss, vd, &blend[0], &blend[1], &blend[2]);
break;
case splashModeBGR8:
cvtRGBToHSV(src[2], src[1], src[0], &hs, &ss, &vs);
cvtRGBToHSV(dest[2], dest[1], dest[0], &hd, &sd, &vd);
cvtHSVToRGB(hd, ss, vd, &blend[2], &blend[1], &blend[0]);
break;
#if SPLASH_CMYK
case splashModeCMYK8:
//~ (0xff - ...) should be clipped
cvtRGBToHSV(0xff - (src[0] + src[3]),
0xff - (src[1] + src[3]),
0xff - (src[2] + src[3]), &hs, &ss, &vs);
cvtRGBToHSV(0xff - (dest[0] + dest[3]),
0xff - (dest[1] + dest[3]),
0xff - (dest[2] + dest[3]), &hd, &sd, &vd);
cvtHSVToRGB(hd, ss, vd, &r, &g, &b);
//~ should do black generation
blend[0] = 0xff - r;
blend[0] = 0xff - g;
blend[0] = 0xff - b;
blend[3] = 0;
break;
#endif
default:
//~ unimplemented
break;
}
}
static void splashOutBlendColor(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend, SplashColorMode cm) {
int hs, ss, vs, hd, sd, vd;
#if SPLASH_CMYK
Guchar r, g, b;
#endif
switch (cm) {
case splashModeMono1:
case splashModeMono8:
blend[0] = dest[0];
break;
case splashModeRGB8:
cvtRGBToHSV(src[0], src[1], src[2], &hs, &ss, &vs);
cvtRGBToHSV(dest[0], dest[1], dest[2], &hd, &sd, &vd);
cvtHSVToRGB(hs, ss, vd, &blend[0], &blend[1], &blend[2]);
break;
case splashModeBGR8:
cvtRGBToHSV(src[2], src[1], src[0], &hs, &ss, &vs);
cvtRGBToHSV(dest[2], dest[1], dest[0], &hd, &sd, &vd);
cvtHSVToRGB(hs, ss, vd, &blend[2], &blend[1], &blend[0]);
break;
#if SPLASH_CMYK
case splashModeCMYK8:
//~ (0xff - ...) should be clipped
cvtRGBToHSV(0xff - (src[0] + src[3]),
0xff - (src[1] + src[3]),
0xff - (src[2] + src[3]), &hs, &ss, &vs);
cvtRGBToHSV(0xff - (dest[0] + dest[3]),
0xff - (dest[1] + dest[3]),
0xff - (dest[2] + dest[3]), &hd, &sd, &vd);
cvtHSVToRGB(hs, ss, vd, &r, &g, &b);
//~ should do black generation
blend[0] = 0xff - r;
blend[0] = 0xff - g;
blend[0] = 0xff - b;
blend[3] = 0;
break;
#endif
default:
//~ unimplemented
break;
}
}
static void splashOutBlendLuminosity(SplashColorPtr src, SplashColorPtr dest,
SplashColorPtr blend,
SplashColorMode cm) {
int hs, ss, vs, hd, sd, vd;
#if SPLASH_CMYK
Guchar r, g, b;
#endif
switch (cm) {
case splashModeMono1:
case splashModeMono8:
blend[0] = dest[0];
break;
case splashModeRGB8:
cvtRGBToHSV(src[0], src[1], src[2], &hs, &ss, &vs);
cvtRGBToHSV(dest[0], dest[1], dest[2], &hd, &sd, &vd);
cvtHSVToRGB(hd, sd, vs, &blend[0], &blend[1], &blend[2]);
break;
case splashModeBGR8:
cvtRGBToHSV(src[2], src[1], src[0], &hs, &ss, &vs);
cvtRGBToHSV(dest[2], dest[1], dest[0], &hd, &sd, &vd);
cvtHSVToRGB(hd, sd, vs, &blend[2], &blend[1], &blend[0]);
break;
#if SPLASH_CMYK
case splashModeCMYK8:
//~ (0xff - ...) should be clipped
cvtRGBToHSV(0xff - (src[0] + src[3]),
0xff - (src[1] + src[3]),
0xff - (src[2] + src[3]), &hs, &ss, &vs);
cvtRGBToHSV(0xff - (dest[0] + dest[3]),
0xff - (dest[1] + dest[3]),
0xff - (dest[2] + dest[3]), &hd, &sd, &vd);
cvtHSVToRGB(hd, sd, vs, &r, &g, &b);
//~ should do black generation
blend[0] = 0xff - r;
blend[0] = 0xff - g;
blend[0] = 0xff - b;
blend[3] = 0;
break;
#endif
default:
//~ unimplemented
break;
}
}
// NB: This must match the GfxBlendMode enum defined in GfxState.h.
SplashBlendFunc splashOutBlendFuncs[] = {
NULL,
&splashOutBlendMultiply,
&splashOutBlendScreen,
&splashOutBlendOverlay,
&splashOutBlendDarken,
&splashOutBlendLighten,
&splashOutBlendColorDodge,
&splashOutBlendColorBurn,
&splashOutBlendHardLight,
&splashOutBlendSoftLight,
&splashOutBlendDifference,
&splashOutBlendExclusion,
&splashOutBlendHue,
&splashOutBlendSaturation,
&splashOutBlendColor,
&splashOutBlendLuminosity
};
//------------------------------------------------------------------------
// SplashOutFontFileID
//------------------------------------------------------------------------
class SplashOutFontFileID: public SplashFontFileID {
public:
SplashOutFontFileID(Ref *rA) { r = *rA; }
~SplashOutFontFileID() {}
GBool matches(SplashFontFileID *id) {
return ((SplashOutFontFileID *)id)->r.num == r.num &&
((SplashOutFontFileID *)id)->r.gen == r.gen;
}
private:
Ref r;
};
//------------------------------------------------------------------------
// T3FontCache
//------------------------------------------------------------------------
struct T3FontCacheTag {
Gushort code;
Gushort mru; // valid bit (0x8000) and MRU index
};
class T3FontCache {
public:
T3FontCache(Ref *fontID, double m11A, double m12A,
double m21A, double m22A,
int glyphXA, int glyphYA, int glyphWA, int glyphHA,
GBool aa);
~T3FontCache();
GBool matches(Ref *idA, double m11A, double m12A,
double m21A, double m22A)
{ return fontID.num == idA->num && fontID.gen == idA->gen &&
m11 == m11A && m12 == m12A && m21 == m21A && m22 == m22A; }
Ref fontID; // PDF font ID
double m11, m12, m21, m22; // transform matrix
int glyphX, glyphY; // pixel offset of glyph bitmaps
int glyphW, glyphH; // size of glyph bitmaps, in pixels
int glyphSize; // size of glyph bitmaps, in bytes
int cacheSets; // number of sets in cache
int cacheAssoc; // cache associativity (glyphs per set)
Guchar *cacheData; // glyph pixmap cache
T3FontCacheTag *cacheTags; // cache tags, i.e., char codes
};
T3FontCache::T3FontCache(Ref *fontIDA, double m11A, double m12A,
double m21A, double m22A,
int glyphXA, int glyphYA, int glyphWA, int glyphHA,
GBool aa) {
int i;
fontID = *fontIDA;
m11 = m11A;
m12 = m12A;
m21 = m21A;
m22 = m22A;
glyphX = glyphXA;
glyphY = glyphYA;
glyphW = glyphWA;
glyphH = glyphHA;
if (aa) {
glyphSize = glyphW * glyphH;
} else {
glyphSize = ((glyphW + 7) >> 3) * glyphH;
}
cacheAssoc = 8;
if (glyphSize <= 256) {
cacheSets = 8;
} else if (glyphSize <= 512) {
cacheSets = 4;
} else if (glyphSize <= 1024) {
cacheSets = 2;
} else {
cacheSets = 1;
}
cacheData = (Guchar *)gmallocn(cacheSets * cacheAssoc, glyphSize);
cacheTags = (T3FontCacheTag *)gmallocn(cacheSets * cacheAssoc,
sizeof(T3FontCacheTag));
for (i = 0; i < cacheSets * cacheAssoc; ++i) {
cacheTags[i].mru = i & (cacheAssoc - 1);
}
}
T3FontCache::~T3FontCache() {
gfree(cacheData);
gfree(cacheTags);
}
struct T3GlyphStack {
Gushort code; // character code
double x, y; // position to draw the glyph
//----- cache info
T3FontCache *cache; // font cache for the current font
T3FontCacheTag *cacheTag; // pointer to cache tag for the glyph
Guchar *cacheData; // pointer to cache data for the glyph
//----- saved state
SplashBitmap *origBitmap;
Splash *origSplash;
double origCTM4, origCTM5;
T3GlyphStack *next; // next object on stack
};
//------------------------------------------------------------------------
// SplashOutputDev
//------------------------------------------------------------------------
SplashOutputDev::SplashOutputDev(SplashColorMode colorModeA,
int bitmapRowPadA,
GBool reverseVideoA,
SplashColorPtr paperColorA,
GBool bitmapTopDownA,
GBool allowAntialiasA) {
colorMode = colorModeA;
bitmapRowPad = bitmapRowPadA;
bitmapTopDown = bitmapTopDownA;
allowAntialias = allowAntialiasA;
reverseVideo = reverseVideoA;
splashColorCopy(paperColor, paperColorA);
xref = NULL;
bitmap = new SplashBitmap(1, 1, bitmapRowPad, colorMode, bitmapTopDown);
splash = new Splash(bitmap);
splash->clear(paperColor);
fontEngine = NULL;
nT3Fonts = 0;
t3GlyphStack = NULL;
font = NULL;
needFontUpdate = gFalse;
textClipPath = NULL;
}
SplashOutputDev::~SplashOutputDev() {
int i;
for (i = 0; i < nT3Fonts; ++i) {
delete t3FontCache[i];
}
if (fontEngine) {
delete fontEngine;
}
if (splash) {
delete splash;
}
if (bitmap) {
delete bitmap;
}
}
void SplashOutputDev::startDoc(XRef *xrefA) {
int i;
xref = xrefA;
if (fontEngine) {
delete fontEngine;
}
fontEngine = new SplashFontEngine(
#if HAVE_T1LIB_H
globalParams->getEnableT1lib(),
#endif
#if HAVE_FREETYPE_FREETYPE_H || HAVE_FREETYPE_H
globalParams->getEnableFreeType(),
#endif
allowAntialias &&
globalParams->getAntialias() &&
colorMode != splashModeMono1);
for (i = 0; i < nT3Fonts; ++i) {
delete t3FontCache[i];
}
nT3Fonts = 0;
}
void SplashOutputDev::startPage(int pageNum, GfxState *state) {
int w, h;
SplashColor color;
w = state ? (int)(state->getPageWidth() + 0.5) : 1;
h = state ? (int)(state->getPageHeight() + 0.5) : 1;
if (splash) {
delete splash;
}
if (!bitmap || w != bitmap->getWidth() || h != bitmap->getHeight()) {
if (bitmap) {
delete bitmap;
}
bitmap = new SplashBitmap(w, h, bitmapRowPad, colorMode, bitmapTopDown);
}
splash = new Splash(bitmap);
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
color[0] = 0;
break;
case splashModeRGB8:
case splashModeBGR8:
case splashModeRGB8Qt:
color[0] = color[1] = color[2] = 0;
break;
case splashModeAMono8:
color[0] = 0xff;
color[1] = 0;
break;
case splashModeARGB8:
color[0] = 255;
color[1] = color[2] = color[3] = 0;
break;
case splashModeBGRA8:
color[0] = color[1] = color[2] = 0;
color[3] = 255;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
color[0] = color[1] = color[2] = color[3] = 0;
break;
case splashModeACMYK8:
color[0] = 255;
color[1] = color[2] = color[3] = color[4] = 0;
break;
#endif
}
splash->setStrokePattern(new SplashSolidColor(color));
splash->setFillPattern(new SplashSolidColor(color));
splash->setLineCap(splashLineCapButt);
splash->setLineJoin(splashLineJoinMiter);
splash->setLineDash(NULL, 0, 0);
splash->setMiterLimit(10);
splash->setFlatness(1);
splash->clear(paperColor);
}
void SplashOutputDev::endPage() {
}
void SplashOutputDev::drawLink(Link *link, Catalog *catalog) {
double x1, y1, x2, y2;
LinkBorderStyle *borderStyle;
double r, g, b;
GfxRGB rgb;
GfxGray gray;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
double *dash;
int dashLength;
SplashCoord dashList[20];
SplashPath *path;
int x, y, i;
link->getRect(&x1, &y1, &x2, &y2);
borderStyle = link->getBorderStyle();
if (borderStyle->getWidth() > 0) {
borderStyle->getColor(&r, &g, &b);
rgb.r = dblToCol(r);
rgb.g = dblToCol(g);
rgb.b = dblToCol(b);
gray = dblToCol(0.299 * r + 0.587 * g + 0.114 * b);
if (gray > gfxColorComp1) {
gray = gfxColorComp1;
}
#if SPLASH_CMYK
cmyk.c = gfxColorComp1 - rgb.r;
cmyk.m = gfxColorComp1 - rgb.g;
cmyk.y = gfxColorComp1 - rgb.b;
cmyk.k = 0;
splash->setStrokePattern(getColor(gray, &rgb, &cmyk));
#else
splash->setStrokePattern(getColor(gray, &rgb));
#endif
splash->setLineWidth((SplashCoord)borderStyle->getWidth());
borderStyle->getDash(&dash, &dashLength);
if (borderStyle->getType() == linkBorderDashed && dashLength > 0) {
if (dashLength > 20) {
dashLength = 20;
}
for (i = 0; i < dashLength; ++i) {
dashList[i] = (SplashCoord)dash[i];
}
splash->setLineDash(dashList, dashLength, 0);
}
path = new SplashPath();
if (borderStyle->getType() == linkBorderUnderlined) {
cvtUserToDev(x1, y1, &x, &y);
path->moveTo((SplashCoord)x, (SplashCoord)y);
cvtUserToDev(x2, y1, &x, &y);
path->lineTo((SplashCoord)x, (SplashCoord)y);
} else {
cvtUserToDev(x1, y1, &x, &y);
path->moveTo((SplashCoord)x, (SplashCoord)y);
cvtUserToDev(x2, y1, &x, &y);
path->lineTo((SplashCoord)x, (SplashCoord)y);
cvtUserToDev(x2, y2, &x, &y);
path->lineTo((SplashCoord)x, (SplashCoord)y);
cvtUserToDev(x1, y2, &x, &y);
path->lineTo((SplashCoord)x, (SplashCoord)y);
path->close();
}
splash->stroke(path);
delete path;
}
}
void SplashOutputDev::saveState(GfxState *state) {
splash->saveState();
}
void SplashOutputDev::restoreState(GfxState *state) {
splash->restoreState();
needFontUpdate = gTrue;
}
void SplashOutputDev::updateAll(GfxState *state) {
updateLineDash(state);
updateLineJoin(state);
updateLineCap(state);
updateLineWidth(state);
updateFlatness(state);
updateMiterLimit(state);
updateFillColor(state);
updateStrokeColor(state);
needFontUpdate = gTrue;
}
void SplashOutputDev::updateCTM(GfxState *state, double m11, double m12,
double m21, double m22,
double m31, double m32) {
updateLineDash(state);
updateLineJoin(state);
updateLineCap(state);
updateLineWidth(state);
}
void SplashOutputDev::updateLineDash(GfxState *state) {
double *dashPattern;
int dashLength;
double dashStart;
SplashCoord dash[20];
SplashCoord phase;
int i;
state->getLineDash(&dashPattern, &dashLength, &dashStart);
if (dashLength > 20) {
dashLength = 20;
}
for (i = 0; i < dashLength; ++i) {
dash[i] = (SplashCoord)state->transformWidth(dashPattern[i]);
if (dash[i] < 1) {
dash[i] = 1;
}
}
phase = (SplashCoord)state->transformWidth(dashStart);
splash->setLineDash(dash, dashLength, phase);
}
void SplashOutputDev::updateFlatness(GfxState *state) {
splash->setFlatness(state->getFlatness());
}
void SplashOutputDev::updateLineJoin(GfxState *state) {
splash->setLineJoin(state->getLineJoin());
}
void SplashOutputDev::updateLineCap(GfxState *state) {
splash->setLineCap(state->getLineCap());
}
void SplashOutputDev::updateMiterLimit(GfxState *state) {
splash->setMiterLimit(state->getMiterLimit());
}
void SplashOutputDev::updateLineWidth(GfxState *state) {
splash->setLineWidth(state->getTransformedLineWidth());
}
void SplashOutputDev::updateFillColor(GfxState *state) {
GfxGray gray;
GfxRGB rgb;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
state->getFillGray(&gray);
state->getFillRGB(&rgb);
#if SPLASH_CMYK
state->getFillCMYK(&cmyk);
splash->setFillPattern(getColor(gray, &rgb, &cmyk));
#else
splash->setFillPattern(getColor(gray, &rgb));
#endif
}
void SplashOutputDev::updateStrokeColor(GfxState *state) {
GfxGray gray;
GfxRGB rgb;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
state->getStrokeGray(&gray);
state->getStrokeRGB(&rgb);
#if SPLASH_CMYK
state->getStrokeCMYK(&cmyk);
splash->setStrokePattern(getColor(gray, &rgb, &cmyk));
#else
splash->setStrokePattern(getColor(gray, &rgb));
#endif
}
#if SPLASH_CMYK
SplashPattern *SplashOutputDev::getColor(GfxGray gray, GfxRGB *rgb,
GfxCMYK *cmyk) {
#else
SplashPattern *SplashOutputDev::getColor(GfxGray gray, GfxRGB *rgb) {
#endif
SplashPattern *pattern;
SplashColor color0, color1;
GfxColorComp r, g, b;
if (reverseVideo) {
gray = gfxColorComp1 - gray;
r = gfxColorComp1 - rgb->r;
g = gfxColorComp1 - rgb->g;
b = gfxColorComp1 - rgb->b;
} else {
r = rgb->r;
g = rgb->g;
b = rgb->b;
}
pattern = NULL; // make gcc happy
switch (colorMode) {
case splashModeMono1:
color0[0] = 0;
color1[0] = 1;
pattern = new SplashHalftone(color0, color1,
splash->getScreen()->copy(),
(SplashCoord)colToDbl(gray));
break;
case splashModeMono8:
color1[0] = colToByte(gray);
pattern = new SplashSolidColor(color1);
break;
case splashModeAMono8:
color1[0] = 255;
color1[1] = colToByte(gray);
pattern = new SplashSolidColor(color1);
break;
case splashModeRGB8:
case splashModeRGB8Qt:
color1[0] = colToByte(r);
color1[1] = colToByte(g);
color1[2] = colToByte(b);
pattern = new SplashSolidColor(color1);
break;
case splashModeBGR8:
color1[2] = colToByte(r);
color1[1] = colToByte(g);
color1[0] = colToByte(b);
pattern = new SplashSolidColor(color1);
break;
case splashModeARGB8:
color1[0] = 255;
color1[1] = colToByte(r);
color1[2] = colToByte(g);
color1[3] = colToByte(b);
pattern = new SplashSolidColor(color1);
break;
case splashModeBGRA8:
color1[3] = 255;
color1[2] = colToByte(r);
color1[1] = colToByte(g);
color1[0] = colToByte(b);
pattern = new SplashSolidColor(color1);
break;
#if SPLASH_CMYK
case splashModeCMYK8:
color1[0] = colToByte(cmyk->c);
color1[1] = colToByte(cmyk->m);
color1[2] = colToByte(cmyk->y);
color1[3] = colToByte(cmyk->k);
pattern = new SplashSolidColor(color1);
break;
case splashModeACMYK8:
color1[0] = 255;
color1[1] = colToByte(cmyk->c);
color1[2] = colToByte(cmyk->m);
color1[3] = colToByte(cmyk->y);
color1[4] = colToByte(cmyk->k);
pattern = new SplashSolidColor(color1);
break;
#endif
}
return pattern;
}
void SplashOutputDev::updateBlendMode(GfxState *state) {
splash->setBlendFunc(splashOutBlendFuncs[state->getBlendMode()]);
}
void SplashOutputDev::updateFillOpacity(GfxState *state) {
splash->setFillAlpha((SplashCoord)state->getFillOpacity());
}
void SplashOutputDev::updateStrokeOpacity(GfxState *state) {
splash->setStrokeAlpha((SplashCoord)state->getStrokeOpacity());
}
void SplashOutputDev::updateFont(GfxState *state) {
GfxFont *gfxFont;
GfxFontType fontType;
SplashOutFontFileID *id;
SplashFontFile *fontFile;
SplashFontSrc *fontsrc;
FoFiTrueType *ff;
Ref embRef;
Object refObj, strObj;
GooString *fileName, *substName;
char *tmpBuf;
int tmpBufLen;
Gushort *codeToGID;
DisplayFontParam *dfp;
CharCodeToUnicode *ctu;
double m11, m12, m21, m22, w1, w2;
SplashCoord mat[4];
char *name;
Unicode uBuf[8];
int c, substIdx, n, code, cmap;
int faceIndex = 0;
needFontUpdate = gFalse;
font = NULL;
fileName = NULL;
tmpBuf = NULL;
substIdx = -1;
dfp = NULL;
if (!(gfxFont = state->getFont())) {
goto err1;
}
fontType = gfxFont->getType();
if (fontType == fontType3) {
goto err1;
}
// check the font file cache
id = new SplashOutFontFileID(gfxFont->getID());
if ((fontFile = fontEngine->getFontFile(id))) {
delete id;
} else {
// if there is an embedded font, write it to disk
if (gfxFont->getEmbeddedFontID(&embRef)) {
tmpBuf = gfxFont->readEmbFontFile(xref, &tmpBufLen);
if (! tmpBuf)
goto err2;
// if there is an external font file, use it
} else if (!(fileName = gfxFont->getExtFontFile())) {
// look for a display font mapping or a substitute font
dfp = NULL;
if (gfxFont->getName()) {
dfp = globalParams->getDisplayFont(gfxFont);
}
if (!dfp) {
error(-1, "Couldn't find a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
switch (dfp->kind) {
case displayFontT1:
fileName = dfp->t1.fileName;
fontType = gfxFont->isCIDFont() ? fontCIDType0 : fontType1;
break;
case displayFontTT:
fileName = dfp->tt.fileName;
fontType = gfxFont->isCIDFont() ? fontCIDType2 : fontTrueType;
faceIndex = dfp->tt.faceIndex;
break;
}
}
fontsrc = new SplashFontSrc;
if (fileName)
fontsrc->setFile(fileName, gFalse);
else
fontsrc->setBuf(tmpBuf, tmpBufLen, gFalse);
// load the font file
switch (fontType) {
case fontType1:
fontFile = fontEngine->loadType1Font(id, fontsrc,
((Gfx8BitFont *)gfxFont)->getEncoding());
if (! fontFile) {
error(-1, "Couldn't create a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
break;
case fontType1C:
fontFile = fontEngine->loadType1CFont(id, fontsrc,
((Gfx8BitFont *)gfxFont)->getEncoding());
if (! fontFile) {
error(-1, "Couldn't create a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
break;
case fontTrueType:
if (fileName)
ff = FoFiTrueType::load(fileName->getCString());
else
ff = new FoFiTrueType(tmpBuf, tmpBufLen, gFalse);
if (ff) {
codeToGID = ((Gfx8BitFont *)gfxFont)->getCodeToGIDMap(ff);
n = 256;
delete ff;
} else {
codeToGID = NULL;
n = 0;
}
if (!(fontFile = fontEngine->loadTrueTypeFont(
id,
fontsrc,
codeToGID, n))) {
error(-1, "Couldn't create a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
break;
case fontCIDType0:
case fontCIDType0C:
fontFile = fontEngine->loadCIDFont(id, fontsrc);
if (! fontFile) {
error(-1, "Couldn't create a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
break;
case fontCIDType2:
codeToGID = NULL;
n = 0;
if (dfp) {
// create a CID-to-GID mapping, via Unicode
if ((ctu = ((GfxCIDFont *)gfxFont)->getToUnicode())) {
if (fileName)
ff = FoFiTrueType::load(fileName->getCString());
else
ff = new FoFiTrueType(tmpBuf, tmpBufLen, gFalse);
if (ff) {
// look for a Unicode cmap
for (cmap = 0; cmap < ff->getNumCmaps(); ++cmap) {
if ((ff->getCmapPlatform(cmap) == 3 &&
ff->getCmapEncoding(cmap) == 1) ||
ff->getCmapPlatform(cmap) == 0) {
break;
}
}
if (cmap < ff->getNumCmaps()) {
// map CID -> Unicode -> GID
n = ctu->getLength();
codeToGID = (Gushort *)gmallocn(n, sizeof(Gushort));
for (code = 0; code < n; ++code) {
if (ctu->mapToUnicode(code, uBuf, 8) > 0) {
codeToGID[code] = ff->mapCodeToGID(cmap, uBuf[0]);
} else {
codeToGID[code] = 0;
}
}
}
delete ff;
}
ctu->decRefCnt();
} else {
error(-1, "Couldn't find a mapping to Unicode for font '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
}
} else {
if (((GfxCIDFont *)gfxFont)->getCIDToGID()) {
n = ((GfxCIDFont *)gfxFont)->getCIDToGIDLen();
if (n) {
codeToGID = (Gushort *)gmallocn(n, sizeof(Gushort));
memcpy(codeToGID, ((GfxCIDFont *)gfxFont)->getCIDToGID(),
n * sizeof(Gushort));
} else {
if (fileName)
ff = FoFiTrueType::load(fileName->getCString());
else
ff = new FoFiTrueType(tmpBuf, tmpBufLen, gFalse);
if (! ff)
goto err2;
codeToGID = ((GfxCIDFont *)gfxFont)->getCodeToGIDMap(ff, &n);
delete ff;
}
}
}
if (!(fontFile = fontEngine->loadTrueTypeFont(
id,
fontsrc,
codeToGID,
n,
faceIndex))) {
error(-1, "Couldn't create a font for '%s'",
gfxFont->getName() ? gfxFont->getName()->getCString()
: "(unnamed)");
goto err2;
}
break;
default:
// this shouldn't happen
goto err2;
}
}
// get the font matrix
state->getFontTransMat(&m11, &m12, &m21, &m22);
m11 *= state->getHorizScaling();
m12 *= state->getHorizScaling();
// create the scaled font
mat[0] = m11; mat[1] = -m12;
mat[2] = m21; mat[3] = -m22;
if (fabs(mat[0] * mat[3] - mat[1] * mat[2]) < 0.01) {
// avoid a singular (or close-to-singular) matrix
mat[0] = 0.01; mat[1] = 0;
mat[2] = 0; mat[3] = 0.01;
}
font = fontEngine->getFont(fontFile, mat);
return;
err2:
delete id;
err1:
return;
}
void SplashOutputDev::stroke(GfxState *state) {
SplashPath *path;
path = convertPath(state, state->getPath());
splash->stroke(path);
delete path;
}
void SplashOutputDev::fill(GfxState *state) {
SplashPath *path;
path = convertPath(state, state->getPath());
splash->fill(path, gFalse);
delete path;
}
void SplashOutputDev::eoFill(GfxState *state) {
SplashPath *path;
path = convertPath(state, state->getPath());
splash->fill(path, gTrue);
delete path;
}
void SplashOutputDev::clip(GfxState *state) {
SplashPath *path;
path = convertPath(state, state->getPath());
splash->clipToPath(path, gFalse);
delete path;
}
void SplashOutputDev::eoClip(GfxState *state) {
SplashPath *path;
path = convertPath(state, state->getPath());
splash->clipToPath(path, gTrue);
delete path;
}
SplashPath *SplashOutputDev::convertPath(GfxState *state, GfxPath *path) {
SplashPath *sPath;
GfxSubpath *subpath;
double x1, y1, x2, y2, x3, y3;
int i, j;
sPath = new SplashPath();
for (i = 0; i < path->getNumSubpaths(); ++i) {
subpath = path->getSubpath(i);
if (subpath->getNumPoints() > 0) {
state->transform(subpath->getX(0), subpath->getY(0), &x1, &y1);
sPath->moveTo((SplashCoord)x1, (SplashCoord)y1);
j = 1;
while (j < subpath->getNumPoints()) {
if (subpath->getCurve(j)) {
state->transform(subpath->getX(j), subpath->getY(j), &x1, &y1);
state->transform(subpath->getX(j+1), subpath->getY(j+1), &x2, &y2);
state->transform(subpath->getX(j+2), subpath->getY(j+2), &x3, &y3);
sPath->curveTo((SplashCoord)x1, (SplashCoord)y1,
(SplashCoord)x2, (SplashCoord)y2,
(SplashCoord)x3, (SplashCoord)y3);
j += 3;
} else {
state->transform(subpath->getX(j), subpath->getY(j), &x1, &y1);
sPath->lineTo((SplashCoord)x1, (SplashCoord)y1);
++j;
}
}
if (subpath->isClosed()) {
sPath->close();
}
}
}
return sPath;
}
void SplashOutputDev::drawChar(GfxState *state, double x, double y,
double dx, double dy,
double originX, double originY,
CharCode code, int nBytes,
Unicode *u, int uLen) {
double x1, y1;
SplashPath *path;
int render;
if (needFontUpdate) {
updateFont(state);
}
if (!font) {
return;
}
// check for invisible text -- this is used by Acrobat Capture
render = state->getRender();
if (render == 3) {
return;
}
x -= originX;
y -= originY;
state->transform(x, y, &x1, &y1);
// fill
if (!(render & 1)) {
splash->fillChar((SplashCoord)x1, (SplashCoord)y1, code, font);
}
// stroke
if ((render & 3) == 1 || (render & 3) == 2) {
if ((path = font->getGlyphPath(code))) {
path->offset((SplashCoord)x1, (SplashCoord)y1);
splash->stroke(path);
delete path;
}
}
// clip
if (render & 4) {
path = font->getGlyphPath(code);
path->offset((SplashCoord)x1, (SplashCoord)y1);
if (textClipPath) {
textClipPath->append(path);
delete path;
} else {
textClipPath = path;
}
}
}
GBool SplashOutputDev::beginType3Char(GfxState *state, double x, double y,
double dx, double dy,
CharCode code, Unicode *u, int uLen) {
GfxFont *gfxFont;
Ref *fontID;
double *ctm, *bbox;
T3FontCache *t3Font;
T3GlyphStack *t3gs;
double x1, y1, xMin, yMin, xMax, yMax, xt, yt;
int i, j;
if (!(gfxFont = state->getFont())) {
return gFalse;
}
fontID = gfxFont->getID();
ctm = state->getCTM();
state->transform(0, 0, &xt, &yt);
// is it the first (MRU) font in the cache?
if (!(nT3Fonts > 0 &&
t3FontCache[0]->matches(fontID, ctm[0], ctm[1], ctm[2], ctm[3]))) {
// is the font elsewhere in the cache?
for (i = 1; i < nT3Fonts; ++i) {
if (t3FontCache[i]->matches(fontID, ctm[0], ctm[1], ctm[2], ctm[3])) {
t3Font = t3FontCache[i];
for (j = i; j > 0; --j) {
t3FontCache[j] = t3FontCache[j - 1];
}
t3FontCache[0] = t3Font;
break;
}
}
if (i >= nT3Fonts) {
// create new entry in the font cache
if (nT3Fonts == splashOutT3FontCacheSize) {
delete t3FontCache[nT3Fonts - 1];
--nT3Fonts;
}
for (j = nT3Fonts; j > 0; --j) {
t3FontCache[j] = t3FontCache[j - 1];
}
++nT3Fonts;
bbox = gfxFont->getFontBBox();
if (bbox[0] == 0 && bbox[1] == 0 && bbox[2] == 0 && bbox[3] == 0) {
// broken bounding box -- just take a guess
xMin = xt - 5;
xMax = xMin + 30;
yMax = yt + 15;
yMin = yMax - 45;
} else {
state->transform(bbox[0], bbox[1], &x1, &y1);
xMin = xMax = x1;
yMin = yMax = y1;
state->transform(bbox[0], bbox[3], &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
state->transform(bbox[2], bbox[1], &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
state->transform(bbox[2], bbox[3], &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
}
t3FontCache[0] = new T3FontCache(fontID, ctm[0], ctm[1], ctm[2], ctm[3],
(int)floor(xMin - xt),
(int)floor(yMin - yt),
(int)ceil(xMax) - (int)floor(xMin) + 3,
(int)ceil(yMax) - (int)floor(yMin) + 3,
colorMode != splashModeMono1);
}
}
t3Font = t3FontCache[0];
// is the glyph in the cache?
i = (code & (t3Font->cacheSets - 1)) * t3Font->cacheAssoc;
for (j = 0; j < t3Font->cacheAssoc; ++j) {
if ((t3Font->cacheTags[i+j].mru & 0x8000) &&
t3Font->cacheTags[i+j].code == code) {
drawType3Glyph(t3Font, &t3Font->cacheTags[i+j],
t3Font->cacheData + (i+j) * t3Font->glyphSize,
xt, yt);
return gTrue;
}
}
// push a new Type 3 glyph record
t3gs = new T3GlyphStack();
t3gs->next = t3GlyphStack;
t3GlyphStack = t3gs;
t3GlyphStack->code = code;
t3GlyphStack->x = xt;
t3GlyphStack->y = yt;
t3GlyphStack->cache = t3Font;
t3GlyphStack->cacheTag = NULL;
t3GlyphStack->cacheData = NULL;
return gFalse;
}
void SplashOutputDev::endType3Char(GfxState *state) {
T3GlyphStack *t3gs;
double *ctm;
if (t3GlyphStack->cacheTag) {
memcpy(t3GlyphStack->cacheData, bitmap->getDataPtr(),
t3GlyphStack->cache->glyphSize);
delete bitmap;
delete splash;
bitmap = t3GlyphStack->origBitmap;
splash = t3GlyphStack->origSplash;
ctm = state->getCTM();
state->setCTM(ctm[0], ctm[1], ctm[2], ctm[3],
t3GlyphStack->origCTM4, t3GlyphStack->origCTM5);
drawType3Glyph(t3GlyphStack->cache,
t3GlyphStack->cacheTag, t3GlyphStack->cacheData,
t3GlyphStack->x, t3GlyphStack->y);
}
t3gs = t3GlyphStack;
t3GlyphStack = t3gs->next;
delete t3gs;
}
void SplashOutputDev::type3D0(GfxState *state, double wx, double wy) {
}
void SplashOutputDev::type3D1(GfxState *state, double wx, double wy,
double llx, double lly, double urx, double ury) {
double *ctm;
T3FontCache *t3Font;
SplashColor color;
double xt, yt, xMin, xMax, yMin, yMax, x1, y1;
int i, j;
t3Font = t3GlyphStack->cache;
// check for a valid bbox
state->transform(0, 0, &xt, &yt);
state->transform(llx, lly, &x1, &y1);
xMin = xMax = x1;
yMin = yMax = y1;
state->transform(llx, ury, &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
state->transform(urx, lly, &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
state->transform(urx, ury, &x1, &y1);
if (x1 < xMin) {
xMin = x1;
} else if (x1 > xMax) {
xMax = x1;
}
if (y1 < yMin) {
yMin = y1;
} else if (y1 > yMax) {
yMax = y1;
}
if (xMin - xt < t3Font->glyphX ||
yMin - yt < t3Font->glyphY ||
xMax - xt > t3Font->glyphX + t3Font->glyphW ||
yMax - yt > t3Font->glyphY + t3Font->glyphH) {
error(-1, "Bad bounding box in Type 3 glyph");
return;
}
// allocate a cache entry
i = (t3GlyphStack->code & (t3Font->cacheSets - 1)) * t3Font->cacheAssoc;
for (j = 0; j < t3Font->cacheAssoc; ++j) {
if ((t3Font->cacheTags[i+j].mru & 0x7fff) == t3Font->cacheAssoc - 1) {
t3Font->cacheTags[i+j].mru = 0x8000;
t3Font->cacheTags[i+j].code = t3GlyphStack->code;
t3GlyphStack->cacheTag = &t3Font->cacheTags[i+j];
t3GlyphStack->cacheData = t3Font->cacheData + (i+j) * t3Font->glyphSize;
} else {
++t3Font->cacheTags[i+j].mru;
}
}
// save state
t3GlyphStack->origBitmap = bitmap;
t3GlyphStack->origSplash = splash;
ctm = state->getCTM();
t3GlyphStack->origCTM4 = ctm[4];
t3GlyphStack->origCTM5 = ctm[5];
// create the temporary bitmap
if (colorMode == splashModeMono1) {
bitmap = new SplashBitmap(t3Font->glyphW, t3Font->glyphH, 1,
splashModeMono1);
splash = new Splash(bitmap);
color[0] = 0;
splash->clear(color);
color[0] = 1;
} else {
bitmap = new SplashBitmap(t3Font->glyphW, t3Font->glyphH, 1,
splashModeMono8);
splash = new Splash(bitmap);
color[0] = 0x00;
splash->clear(color);
color[0] = 0xff;
}
splash->setFillPattern(new SplashSolidColor(color));
splash->setStrokePattern(new SplashSolidColor(color));
//~ this should copy other state from t3GlyphStack->origSplash?
state->setCTM(ctm[0], ctm[1], ctm[2], ctm[3],
-t3Font->glyphX, -t3Font->glyphY);
}
void SplashOutputDev::drawType3Glyph(T3FontCache *t3Font,
T3FontCacheTag *tag, Guchar *data,
double x, double y) {
SplashGlyphBitmap glyph;
glyph.x = -t3Font->glyphX;
glyph.y = -t3Font->glyphY;
glyph.w = t3Font->glyphW;
glyph.h = t3Font->glyphH;
glyph.aa = colorMode != splashModeMono1;
glyph.data = data;
glyph.freeData = gFalse;
splash->fillGlyph((SplashCoord)x, (SplashCoord)y, &glyph);
}
void SplashOutputDev::endTextObject(GfxState *state) {
if (textClipPath) {
splash->clipToPath(textClipPath, gFalse);
delete textClipPath;
textClipPath = NULL;
}
}
struct SplashOutImageMaskData {
ImageStream *imgStr;
GBool invert;
int width, height, y;
};
GBool SplashOutputDev::imageMaskSrc(void *data, SplashColorPtr line) {
SplashOutImageMaskData *imgMaskData = (SplashOutImageMaskData *)data;
Guchar *p;
SplashColorPtr q;
int x;
if (imgMaskData->y == imgMaskData->height) {
return gFalse;
}
for (x = 0, p = imgMaskData->imgStr->getLine(), q = line;
x < imgMaskData->width;
++x) {
*q++ = *p++ ^ imgMaskData->invert;
}
++imgMaskData->y;
return gTrue;
}
void SplashOutputDev::drawImageMask(GfxState *state, Object *ref, Stream *str,
int width, int height, GBool invert,
GBool inlineImg) {
double *ctm;
SplashCoord mat[6];
SplashOutImageMaskData imgMaskData;
ctm = state->getCTM();
mat[0] = ctm[0];
mat[1] = ctm[1];
mat[2] = -ctm[2];
mat[3] = -ctm[3];
mat[4] = ctm[2] + ctm[4];
mat[5] = ctm[3] + ctm[5];
imgMaskData.imgStr = new ImageStream(str, width, 1, 1);
imgMaskData.imgStr->reset();
imgMaskData.invert = invert ? 0 : 1;
imgMaskData.width = width;
imgMaskData.height = height;
imgMaskData.y = 0;
splash->fillImageMask(&imageMaskSrc, &imgMaskData, width, height, mat);
if (inlineImg) {
while (imgMaskData.y < height) {
imgMaskData.imgStr->getLine();
++imgMaskData.y;
}
}
delete imgMaskData.imgStr;
str->close();
}
struct SplashOutImageData {
ImageStream *imgStr;
GfxImageColorMap *colorMap;
SplashColorPtr lookup;
int *maskColors;
SplashColorMode colorMode;
int width, height, y;
};
GBool SplashOutputDev::imageSrc(void *data, SplashColorPtr line) {
SplashOutImageData *imgData = (SplashOutImageData *)data;
Guchar *p;
SplashColorPtr q, col;
GfxRGB rgb;
GfxGray gray;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
int nComps, x;
if (imgData->y == imgData->height) {
return gFalse;
}
nComps = imgData->colorMap->getNumPixelComps();
if (imgData->lookup) {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, ++p) {
*q++ = imgData->lookup[*p];
}
break;
case splashModeRGB8:
case splashModeBGR8:
case splashModeRGB8Qt:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, ++p) {
col = &imgData->lookup[3 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
}
break;
#if SPLASH_CMYK
case splashModeCMYK8:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, ++p) {
col = &imgData->lookup[4 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
*q++ = col[3];
}
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
} else {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
imgData->colorMap->getGray(p, &gray);
*q++ = colToByte(gray);
}
break;
case splashModeRGB8:
case splashModeRGB8Qt:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
imgData->colorMap->getRGB(p, &rgb);
*q++ = colToByte(rgb.r);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.b);
}
break;
case splashModeBGR8:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
imgData->colorMap->getRGB(p, &rgb);
*q++ = colToByte(rgb.b);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.r);
}
break;
#if SPLASH_CMYK
case splashModeCMYK8:
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
imgData->colorMap->getCMYK(p, &cmyk);
*q++ = colToByte(cmyk.c);
*q++ = colToByte(cmyk.m);
*q++ = colToByte(cmyk.y);
*q++ = colToByte(cmyk.k);
}
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
}
++imgData->y;
return gTrue;
}
GBool SplashOutputDev::alphaImageSrc(void *data, SplashColorPtr line) {
SplashOutImageData *imgData = (SplashOutImageData *)data;
Guchar *p;
SplashColorPtr q, col;
GfxRGB rgb;
GfxGray gray;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
Guchar alpha;
int nComps, x, i;
if (imgData->y == imgData->height) {
return gFalse;
}
nComps = imgData->colorMap->getNumPixelComps();
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
alpha = 0;
for (i = 0; i < nComps; ++i) {
if (p[i] < imgData->maskColors[2*i] ||
p[i] > imgData->maskColors[2*i+1]) {
alpha = 0xff;
break;
}
}
if (imgData->lookup) {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
*q++ = alpha;
*q++ = imgData->lookup[*p];
break;
case splashModeRGB8:
case splashModeRGB8Qt:
*q++ = alpha;
col = &imgData->lookup[3 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
break;
case splashModeBGR8:
col = &imgData->lookup[3 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
*q++ = alpha;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
*q++ = alpha;
col = &imgData->lookup[4 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
*q++ = col[3];
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
} else {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
imgData->colorMap->getGray(p, &gray);
*q++ = alpha;
*q++ = colToByte(gray);
break;
case splashModeRGB8:
case splashModeRGB8Qt:
imgData->colorMap->getRGB(p, &rgb);
*q++ = alpha;
*q++ = colToByte(rgb.r);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.b);
break;
case splashModeBGR8:
imgData->colorMap->getRGB(p, &rgb);
*q++ = colToByte(rgb.b);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.r);
*q++ = alpha;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
imgData->colorMap->getCMYK(p, &cmyk);
*q++ = alpha;
*q++ = colToByte(cmyk.c);
*q++ = colToByte(cmyk.m);
*q++ = colToByte(cmyk.y);
*q++ = colToByte(cmyk.k);
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
}
}
++imgData->y;
return gTrue;
}
void SplashOutputDev::drawImage(GfxState *state, Object *ref, Stream *str,
int width, int height,
GfxImageColorMap *colorMap,
int *maskColors, GBool inlineImg) {
double *ctm;
SplashCoord mat[6];
SplashOutImageData imgData;
SplashColorMode srcMode;
SplashImageSource src;
GfxGray gray;
GfxRGB rgb;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
Guchar pix;
int n, i;
ctm = state->getCTM();
mat[0] = ctm[0];
mat[1] = ctm[1];
mat[2] = -ctm[2];
mat[3] = -ctm[3];
mat[4] = ctm[2] + ctm[4];
mat[5] = ctm[3] + ctm[5];
imgData.imgStr = new ImageStream(str, width,
colorMap->getNumPixelComps(),
colorMap->getBits());
imgData.imgStr->reset();
imgData.colorMap = colorMap;
imgData.maskColors = maskColors;
imgData.colorMode = colorMode;
imgData.width = width;
imgData.height = height;
imgData.y = 0;
// special case for one-channel (monochrome/gray/separation) images:
// build a lookup table here
imgData.lookup = NULL;
if (colorMap->getNumPixelComps() == 1) {
n = 1 << colorMap->getBits();
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
imgData.lookup = (SplashColorPtr)gmalloc(n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getGray(&pix, &gray);
imgData.lookup[i] = colToByte(gray);
}
break;
case splashModeRGB8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.r);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.b);
}
break;
case splashModeBGR8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.b);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.r);
}
break;
#if SPLASH_CMYK
case splashModeCMYK8:
imgData.lookup = (SplashColorPtr)gmalloc(4 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getCMYK(&pix, &cmyk);
imgData.lookup[4*i] = colToByte(cmyk.c);
imgData.lookup[4*i+1] = colToByte(cmyk.m);
imgData.lookup[4*i+2] = colToByte(cmyk.y);
imgData.lookup[4*i+3] = colToByte(cmyk.k);
}
break;
#endif
default:
//~ unimplemented
break;
}
}
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
srcMode = maskColors ? splashModeAMono8 : splashModeMono8;
break;
case splashModeRGB8:
srcMode = maskColors ? splashModeARGB8 : splashModeRGB8;
break;
case splashModeBGR8:
srcMode = maskColors ? splashModeBGRA8 : splashModeBGR8;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
srcMode = maskColors ? splashModeACMYK8 : splashModeCMYK8;
break;
#endif
default:
//~ unimplemented
srcMode = splashModeRGB8;
break;
}
src = maskColors ? &alphaImageSrc : &imageSrc;
splash->drawImage(src, &imgData, srcMode, width, height, mat);
if (inlineImg) {
while (imgData.y < height) {
imgData.imgStr->getLine();
++imgData.y;
}
}
gfree(imgData.lookup);
delete imgData.imgStr;
str->close();
}
struct SplashOutMaskedImageData {
ImageStream *imgStr;
GfxImageColorMap *colorMap;
SplashBitmap *mask;
SplashColorPtr lookup;
SplashColorMode colorMode;
int width, height, y;
};
GBool SplashOutputDev::maskedImageSrc(void *data, SplashColorPtr line) {
SplashOutMaskedImageData *imgData = (SplashOutMaskedImageData *)data;
Guchar *p;
SplashColor maskColor;
SplashColorPtr q, col;
GfxRGB rgb;
GfxGray gray;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
Guchar alpha;
int nComps, x;
if (imgData->y == imgData->height) {
return gFalse;
}
nComps = imgData->colorMap->getNumPixelComps();
for (x = 0, p = imgData->imgStr->getLine(), q = line;
x < imgData->width;
++x, p += nComps) {
imgData->mask->getPixel(x, imgData->y, maskColor);
alpha = maskColor[0] ? 0xff : 0x00;
if (imgData->lookup) {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
*q++ = alpha;
*q++ = imgData->lookup[*p];
break;
case splashModeRGB8:
case splashModeRGB8Qt:
*q++ = alpha;
col = &imgData->lookup[3 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
break;
case splashModeBGR8:
col = &imgData->lookup[3 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
*q++ = alpha;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
*q++ = alpha;
col = &imgData->lookup[4 * *p];
*q++ = col[0];
*q++ = col[1];
*q++ = col[2];
*q++ = col[3];
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
} else {
switch (imgData->colorMode) {
case splashModeMono1:
case splashModeMono8:
imgData->colorMap->getGray(p, &gray);
*q++ = alpha;
*q++ = colToByte(gray);
break;
case splashModeRGB8:
case splashModeRGB8Qt:
imgData->colorMap->getRGB(p, &rgb);
*q++ = alpha;
*q++ = colToByte(rgb.r);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.b);
break;
case splashModeBGR8:
imgData->colorMap->getRGB(p, &rgb);
*q++ = colToByte(rgb.b);
*q++ = colToByte(rgb.g);
*q++ = colToByte(rgb.r);
*q++ = alpha;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
imgData->colorMap->getCMYK(p, &cmyk);
*q++ = alpha;
*q++ = colToByte(cmyk.c);
*q++ = colToByte(cmyk.m);
*q++ = colToByte(cmyk.y);
*q++ = colToByte(cmyk.k);
break;
#endif
case splashModeAMono8:
case splashModeARGB8:
case splashModeBGRA8:
#if SPLASH_CMYK
case splashModeACMYK8:
#endif
//~ unimplemented
break;
}
}
}
++imgData->y;
return gTrue;
}
void SplashOutputDev::drawMaskedImage(GfxState *state, Object *ref,
Stream *str, int width, int height,
GfxImageColorMap *colorMap,
Stream *maskStr, int maskWidth,
int maskHeight, GBool maskInvert) {
double *ctm;
SplashCoord mat[6];
SplashOutMaskedImageData imgData;
SplashOutImageMaskData imgMaskData;
SplashColorMode srcMode;
SplashBitmap *maskBitmap;
Splash *maskSplash;
SplashColor maskColor;
GfxGray gray;
GfxRGB rgb;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
Guchar pix;
int n, i;
//----- scale the mask image to the same size as the source image
mat[0] = (SplashCoord)width;
mat[1] = 0;
mat[2] = 0;
mat[3] = (SplashCoord)height;
mat[4] = 0;
mat[5] = 0;
imgMaskData.imgStr = new ImageStream(maskStr, maskWidth, 1, 1);
imgMaskData.imgStr->reset();
imgMaskData.invert = maskInvert ? 0 : 1;
imgMaskData.width = maskWidth;
imgMaskData.height = maskHeight;
imgMaskData.y = 0;
maskBitmap = new SplashBitmap(width, height, 1, splashModeMono1);
maskSplash = new Splash(maskBitmap);
maskColor[0] = 0;
maskSplash->clear(maskColor);
maskColor[0] = 1;
maskSplash->setFillPattern(new SplashSolidColor(maskColor));
maskSplash->fillImageMask(&imageMaskSrc, &imgMaskData,
maskWidth, maskHeight, mat);
delete imgMaskData.imgStr;
maskStr->close();
delete maskSplash;
//----- draw the source image
ctm = state->getCTM();
mat[0] = ctm[0];
mat[1] = ctm[1];
mat[2] = -ctm[2];
mat[3] = -ctm[3];
mat[4] = ctm[2] + ctm[4];
mat[5] = ctm[3] + ctm[5];
imgData.imgStr = new ImageStream(str, width,
colorMap->getNumPixelComps(),
colorMap->getBits());
imgData.imgStr->reset();
imgData.colorMap = colorMap;
imgData.mask = maskBitmap;
imgData.colorMode = colorMode;
imgData.width = width;
imgData.height = height;
imgData.y = 0;
// special case for one-channel (monochrome/gray/separation) images:
// build a lookup table here
imgData.lookup = NULL;
if (colorMap->getNumPixelComps() == 1) {
n = 1 << colorMap->getBits();
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
imgData.lookup = (SplashColorPtr)gmalloc(n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getGray(&pix, &gray);
imgData.lookup[i] = colToByte(gray);
}
break;
case splashModeRGB8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.r);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.b);
}
break;
case splashModeBGR8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.b);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.r);
}
break;
#if SPLASH_CMYK
case splashModeCMYK8:
imgData.lookup = (SplashColorPtr)gmalloc(4 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getCMYK(&pix, &cmyk);
imgData.lookup[4*i] = colToByte(cmyk.c);
imgData.lookup[4*i+1] = colToByte(cmyk.m);
imgData.lookup[4*i+2] = colToByte(cmyk.y);
imgData.lookup[4*i+3] = colToByte(cmyk.k);
}
break;
#endif
default:
//~ unimplemented
break;
}
}
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
srcMode = splashModeAMono8;
break;
case splashModeRGB8:
srcMode = splashModeARGB8;
break;
case splashModeBGR8:
srcMode = splashModeBGRA8;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
srcMode = splashModeACMYK8;
break;
#endif
default:
//~ unimplemented
srcMode = splashModeARGB8;
break;
}
splash->drawImage(&maskedImageSrc, &imgData, srcMode, width, height, mat);
delete maskBitmap;
gfree(imgData.lookup);
delete imgData.imgStr;
str->close();
}
void SplashOutputDev::drawSoftMaskedImage(GfxState *state, Object *ref,
Stream *str, int width, int height,
GfxImageColorMap *colorMap,
Stream *maskStr,
int maskWidth, int maskHeight,
GfxImageColorMap *maskColorMap) {
double *ctm;
SplashCoord mat[6];
SplashOutImageData imgData;
SplashOutImageData imgMaskData;
SplashColorMode srcMode;
SplashBitmap *maskBitmap;
Splash *maskSplash;
SplashColor maskColor;
GfxGray gray;
GfxRGB rgb;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
Guchar pix;
int n, i;
ctm = state->getCTM();
mat[0] = ctm[0];
mat[1] = ctm[1];
mat[2] = -ctm[2];
mat[3] = -ctm[3];
mat[4] = ctm[2] + ctm[4];
mat[5] = ctm[3] + ctm[5];
//----- set up the soft mask
imgMaskData.imgStr = new ImageStream(maskStr, maskWidth,
maskColorMap->getNumPixelComps(),
maskColorMap->getBits());
imgMaskData.imgStr->reset();
imgMaskData.colorMap = maskColorMap;
imgMaskData.maskColors = NULL;
imgMaskData.colorMode = splashModeMono8;
imgMaskData.width = maskWidth;
imgMaskData.height = maskHeight;
imgMaskData.y = 0;
n = 1 << maskColorMap->getBits();
imgMaskData.lookup = (SplashColorPtr)gmalloc(n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
maskColorMap->getGray(&pix, &gray);
imgMaskData.lookup[i] = colToByte(gray);
}
maskBitmap = new SplashBitmap(bitmap->getWidth(), bitmap->getHeight(),
1, splashModeMono8);
maskSplash = new Splash(maskBitmap);
maskColor[0] = 0;
maskSplash->clear(maskColor);
maskSplash->drawImage(&imageSrc, &imgMaskData,
splashModeMono8, maskWidth, maskHeight, mat);
delete imgMaskData.imgStr;
maskStr->close();
gfree(imgMaskData.lookup);
delete maskSplash;
splash->setSoftMask(maskBitmap);
//----- draw the source image
imgData.imgStr = new ImageStream(str, width,
colorMap->getNumPixelComps(),
colorMap->getBits());
imgData.imgStr->reset();
imgData.colorMap = colorMap;
imgData.maskColors = NULL;
imgData.colorMode = colorMode;
imgData.width = width;
imgData.height = height;
imgData.y = 0;
// special case for one-channel (monochrome/gray/separation) images:
// build a lookup table here
imgData.lookup = NULL;
if (colorMap->getNumPixelComps() == 1) {
n = 1 << colorMap->getBits();
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
imgData.lookup = (SplashColorPtr)gmalloc(n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getGray(&pix, &gray);
imgData.lookup[i] = colToByte(gray);
}
break;
case splashModeRGB8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.r);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.b);
}
break;
case splashModeBGR8:
imgData.lookup = (SplashColorPtr)gmalloc(3 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getRGB(&pix, &rgb);
imgData.lookup[3*i] = colToByte(rgb.b);
imgData.lookup[3*i+1] = colToByte(rgb.g);
imgData.lookup[3*i+2] = colToByte(rgb.r);
}
break;
#if SPLASH_CMYK
case splashModeCMYK8:
imgData.lookup = (SplashColorPtr)gmalloc(4 * n);
for (i = 0; i < n; ++i) {
pix = (Guchar)i;
colorMap->getCMYK(&pix, &cmyk);
imgData.lookup[4*i] = colToByte(cmyk.c);
imgData.lookup[4*i+1] = colToByte(cmyk.m);
imgData.lookup[4*i+2] = colToByte(cmyk.y);
imgData.lookup[4*i+3] = colToByte(cmyk.k);
}
break;
#endif
default:
//~ unimplemented
break;
}
}
switch (colorMode) {
case splashModeMono1:
case splashModeMono8:
srcMode = splashModeMono8;
break;
case splashModeRGB8:
srcMode = splashModeRGB8;
break;
case splashModeBGR8:
srcMode = splashModeBGR8;
break;
#if SPLASH_CMYK
case splashModeCMYK8:
srcMode = splashModeCMYK8;
break;
#endif
default:
//~ unimplemented
srcMode = splashModeRGB8;
break;
}
splash->drawImage(&imageSrc, &imgData, srcMode, width, height, mat);
splash->setSoftMask(NULL);
gfree(imgData.lookup);
delete imgData.imgStr;
str->close();
}
void SplashOutputDev::setPaperColor(SplashColorPtr paperColorA) {
splashColorCopy(paperColor, paperColorA);
}
int SplashOutputDev::getBitmapWidth() {
return bitmap->getWidth();
}
int SplashOutputDev::getBitmapHeight() {
return bitmap->getHeight();
}
SplashBitmap *SplashOutputDev::takeBitmap() {
SplashBitmap *ret;
ret = bitmap;
bitmap = new SplashBitmap(1, 1, bitmapRowPad, colorMode, bitmapTopDown);
return ret;
}
void SplashOutputDev::getModRegion(int *xMin, int *yMin,
int *xMax, int *yMax) {
splash->getModRegion(xMin, yMin, xMax, yMax);
}
void SplashOutputDev::clearModRegion() {
splash->clearModRegion();
}
void SplashOutputDev::setFillColor(int r, int g, int b) {
GfxRGB rgb;
GfxGray gray;
#if SPLASH_CMYK
GfxCMYK cmyk;
#endif
rgb.r = byteToCol(r);
rgb.g = byteToCol(g);
rgb.b = byteToCol(b);
gray = (GfxColorComp)(0.299 * rgb.r + 0.587 * rgb.g + 0.114 * rgb.g + 0.5);
if (gray > gfxColorComp1) {
gray = gfxColorComp1;
}
#if SPLASH_CMYK
cmyk.c = gfxColorComp1 - rgb.r;
cmyk.m = gfxColorComp1 - rgb.g;
cmyk.y = gfxColorComp1 - rgb.b;
cmyk.k = 0;
splash->setFillPattern(getColor(gray, &rgb, &cmyk));
#else
splash->setFillPattern(getColor(gray, &rgb));
#endif
}