#include <stddef.h>
#include <math.h>
-#include <string.h> // for memcpy()
+#include <string.h>
#include "gmem.h"
#include "Error.h"
#include "Object.h"
#include "Array.h"
#include "Page.h"
#include "GfxState.h"
-#include "cmyk.h"
//------------------------------------------------------------------------
+static inline GfxColorComp clip01(GfxColorComp x) {
+ return (x < 0) ? 0 : (x > gfxColorComp1) ? gfxColorComp1 : x;
+}
+
static inline double clip01(double x) {
- return (x < 0) ? 0 : ((x > 1) ? 1 : x);
+ return (x < 0) ? 0 : (x > 1) ? 1 : x;
}
//------------------------------------------------------------------------
+static struct {
+ char *name;
+ GfxBlendMode mode;
+} gfxBlendModeNames[] = {
+ { "Normal", gfxBlendNormal },
+ { "Compatible", gfxBlendNormal },
+ { "Multiply", gfxBlendMultiply },
+ { "Screen", gfxBlendScreen },
+ { "Overlay", gfxBlendOverlay },
+ { "Darken", gfxBlendDarken },
+ { "Lighten", gfxBlendLighten },
+ { "ColorDodge", gfxBlendColorDodge },
+ { "ColorBurn", gfxBlendColorBurn },
+ { "HardLight", gfxBlendHardLight },
+ { "SoftLight", gfxBlendSoftLight },
+ { "Difference", gfxBlendDifference },
+ { "Exclusion", gfxBlendExclusion },
+ { "Hue", gfxBlendHue },
+ { "Saturation", gfxBlendSaturation },
+ { "Color", gfxBlendColor },
+ { "Luminosity", gfxBlendLuminosity }
+};
+
+#define nGfxBlendModeNames \
+ ((int)((sizeof(gfxBlendModeNames) / sizeof(char *))))
+
+//------------------------------------------------------------------------
+
+// NB: This must match the GfxColorSpaceMode enum defined in
+// GfxState.h
static char *gfxColorSpaceModeNames[] = {
"DeviceGray",
"CalGray",
return new GfxDeviceGrayColorSpace();
}
-void GfxDeviceGrayColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxDeviceGrayColorSpace::getGray(GfxColor *color, GfxGray *gray) {
*gray = clip01(color->c[0]);
}
void GfxDeviceGrayColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
cmyk->c = cmyk->m = cmyk->y = 0;
- cmyk->k = clip01(1 - color->c[0]);
+ cmyk->k = clip01(gfxColorComp1 - color->c[0]);
}
//------------------------------------------------------------------------
return cs;
}
-void GfxCalGrayColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxCalGrayColorSpace::getGray(GfxColor *color, GfxGray *gray) {
*gray = clip01(color->c[0]);
}
void GfxCalGrayColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
cmyk->c = cmyk->m = cmyk->y = 0;
- cmyk->k = clip01(1 - color->c[0]);
+ cmyk->k = clip01(gfxColorComp1 - color->c[0]);
}
//------------------------------------------------------------------------
return new GfxDeviceRGBColorSpace();
}
-void GfxDeviceRGBColorSpace::getGray(GfxColor *color, double *gray) {
- *gray = clip01(0.299 * color->c[0] +
- 0.587 * color->c[1] +
- 0.114 * color->c[2]);
+void GfxDeviceRGBColorSpace::getGray(GfxColor *color, GfxGray *gray) {
+ *gray = clip01((GfxColorComp)(0.3 * color->c[0] +
+ 0.59 * color->c[1] +
+ 0.11 * color->c[2] + 0.5));
}
void GfxDeviceRGBColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
}
void GfxDeviceRGBColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
- double c, m, y, k;
+ GfxColorComp c, m, y, k;
- c = clip01(1 - color->c[0]);
- m = clip01(1 - color->c[1]);
- y = clip01(1 - color->c[2]);
+ c = clip01(gfxColorComp1 - color->c[0]);
+ m = clip01(gfxColorComp1 - color->c[1]);
+ y = clip01(gfxColorComp1 - color->c[2]);
k = c;
if (m < k) {
k = m;
return cs;
}
-void GfxCalRGBColorSpace::getGray(GfxColor *color, double *gray) {
- *gray = clip01(0.299 * color->c[0] +
- 0.587 * color->c[1] +
- 0.114 * color->c[2]);
+void GfxCalRGBColorSpace::getGray(GfxColor *color, GfxGray *gray) {
+ *gray = clip01((GfxColorComp)(0.299 * color->c[0] +
+ 0.587 * color->c[1] +
+ 0.114 * color->c[2] + 0.5));
}
void GfxCalRGBColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
}
void GfxCalRGBColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
- double c, m, y, k;
+ GfxColorComp c, m, y, k;
- c = clip01(1 - color->c[0]);
- m = clip01(1 - color->c[1]);
- y = clip01(1 - color->c[2]);
+ c = clip01(gfxColorComp1 - color->c[0]);
+ m = clip01(gfxColorComp1 - color->c[1]);
+ y = clip01(gfxColorComp1 - color->c[2]);
k = c;
if (m < k) {
k = m;
return new GfxDeviceCMYKColorSpace();
}
-void GfxDeviceCMYKColorSpace::getGray(GfxColor *color, double *gray) {
- *gray = clip01(1 - color->c[3]
- - 0.299 * color->c[0]
- - 0.587 * color->c[1]
- - 0.114 * color->c[2]);
-}
-
-/*void GfxDeviceCMYKColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
- double c,m,y,k,white;
- c = color->c[0];
- m = color->c[1];
- y = color->c[2];
- k = color->c[3];
- white = 1.0 - k;
- rgb->r = white - (c*white);
- rgb->g = white - (m*white);
- rgb->b = white - (y*white);
-}*/
-/*void GfxDeviceCMYKColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
- double c, m, y, aw, ac, am, ay, ar, ag, ab;
-
- c = clip01(color->c[0] + color->c[3]);
- m = clip01(color->c[1] + color->c[3]);
- y = clip01(color->c[2] + color->c[3]);
- aw = (1-c) * (1-m) * (1-y);
- ac = c * (1-m) * (1-y);
- am = (1-c) * m * (1-y);
- ay = (1-c) * (1-m) * y;
- ar = (1-c) * m * y;
- ag = c * (1-m) * y;
- ab = c * m * (1-y);
- rgb->r = clip01(aw + 0.9137*am + 0.9961*ay + 0.9882*ar);
- rgb->g = clip01(aw + 0.6196*ac + ay + 0.5176*ag);
- rgb->b = clip01(aw + 0.7804*ac + 0.5412*am + 0.0667*ar + 0.2118*ag + 0.4863*ab);
-}*/
+void GfxDeviceCMYKColorSpace::getGray(GfxColor *color, GfxGray *gray) {
+ *gray = clip01((GfxColorComp)(gfxColorComp1 - color->c[3]
+ - 0.3 * color->c[0]
+ - 0.59 * color->c[1]
+ - 0.11 * color->c[2] + 0.5));
+}
+
void GfxDeviceCMYKColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
- unsigned char r,g,b;
- float c = color->c[0];
- float m = color->c[1];
- float y = color->c[2];
- float k = color->c[3];
- convert_cmyk2rgb(c,m,y,k, &r,&g,&b);
- rgb->r = r/255.0;
- rgb->g = g/255.0;
- rgb->b = b/255.0;
+ double c, m, y, k, c1, m1, y1, k1, r, g, b, x;
+
+ c = colToDbl(color->c[0]);
+ m = colToDbl(color->c[1]);
+ y = colToDbl(color->c[2]);
+ k = colToDbl(color->c[3]);
+ c1 = 1 - c;
+ m1 = 1 - m;
+ y1 = 1 - y;
+ k1 = 1 - k;
+ // this is a matrix multiplication, unrolled for performance
+ // C M Y K
+ x = c1 * m1 * y1 * k1; // 0 0 0 0
+ r = g = b = x;
+ x = c1 * m1 * y1 * k; // 0 0 0 1
+ r += 0.1373 * x;
+ g += 0.1216 * x;
+ b += 0.1255 * x;
+ x = c1 * m1 * y * k1; // 0 0 1 0
+ r += x;
+ g += 0.9490 * x;
+ x = c1 * m1 * y * k; // 0 0 1 1
+ r += 0.1098 * x;
+ g += 0.1020 * x;
+ x = c1 * m * y1 * k1; // 0 1 0 0
+ r += 0.9255 * x;
+ b += 0.5490 * x;
+ x = c1 * m * y1 * k; // 0 1 0 1
+ r += 0.1412 * x;
+ x = c1 * m * y * k1; // 0 1 1 0
+ r += 0.9294 * x;
+ g += 0.1098 * x;
+ b += 0.1412 * x;
+ x = c1 * m * y * k; // 0 1 1 1
+ r += 0.1333 * x;
+ x = c * m1 * y1 * k1; // 1 0 0 0
+ g += 0.6784 * x;
+ b += 0.9373 * x;
+ x = c * m1 * y1 * k; // 1 0 0 1
+ g += 0.0588 * x;
+ b += 0.1412 * x;
+ x = c * m1 * y * k1; // 1 0 1 0
+ g += 0.6510 * x;
+ b += 0.3137 * x;
+ x = c * m1 * y * k; // 1 0 1 1
+ g += 0.0745 * x;
+ x = c * m * y1 * k1; // 1 1 0 0
+ r += 0.1804 * x;
+ g += 0.1922 * x;
+ b += 0.5725 * x;
+ x = c * m * y1 * k; // 1 1 0 1
+ b += 0.0078 * x;
+ x = c * m * y * k1; // 1 1 1 0
+ r += 0.2118 * x;
+ g += 0.2119 * x;
+ b += 0.2235 * x;
+ rgb->r = clip01(dblToCol(r));
+ rgb->g = clip01(dblToCol(g));
+ rgb->b = clip01(dblToCol(b));
}
void GfxDeviceCMYKColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
return cs;
}
-void GfxLabColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxLabColorSpace::getGray(GfxColor *color, GfxGray *gray) {
GfxRGB rgb;
getRGB(color, &rgb);
- *gray = clip01(0.299 * rgb.r +
- 0.587 * rgb.g +
- 0.114 * rgb.b);
+ *gray = clip01((GfxColorComp)(0.299 * rgb.r +
+ 0.587 * rgb.g +
+ 0.114 * rgb.b + 0.5));
}
void GfxLabColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
double r, g, b;
// convert L*a*b* to CIE 1931 XYZ color space
- t1 = (color->c[0] + 16) / 116;
- t2 = t1 + color->c[1] / 500;
+ t1 = (colToDbl(color->c[0]) + 16) / 116;
+ t2 = t1 + colToDbl(color->c[1]) / 500;
if (t2 >= (6.0 / 29.0)) {
X = t2 * t2 * t2;
} else {
Y = (108.0 / 841.0) * (t1 - (4.0 / 29.0));
}
Y *= whiteY;
- t2 = t1 - color->c[2] / 200;
+ t2 = t1 - colToDbl(color->c[2]) / 200;
if (t2 >= (6.0 / 29.0)) {
Z = t2 * t2 * t2;
} else {
r = xyzrgb[0][0] * X + xyzrgb[0][1] * Y + xyzrgb[0][2] * Z;
g = xyzrgb[1][0] * X + xyzrgb[1][1] * Y + xyzrgb[1][2] * Z;
b = xyzrgb[2][0] * X + xyzrgb[2][1] * Y + xyzrgb[2][2] * Z;
- rgb->r = pow(clip01(r * kr), 0.5);
- rgb->g = pow(clip01(g * kg), 0.5);
- rgb->b = pow(clip01(b * kb), 0.5);
+ rgb->r = dblToCol(pow(clip01(r * kr), 0.5));
+ rgb->g = dblToCol(pow(clip01(g * kg), 0.5));
+ rgb->b = dblToCol(pow(clip01(b * kb), 0.5));
}
void GfxLabColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
GfxRGB rgb;
- double c, m, y, k;
+ GfxColorComp c, m, y, k;
getRGB(color, &rgb);
- c = clip01(1 - rgb.r);
- m = clip01(1 - rgb.g);
- y = clip01(1 - rgb.b);
+ c = clip01(gfxColorComp1 - rgb.r);
+ m = clip01(gfxColorComp1 - rgb.g);
+ y = clip01(gfxColorComp1 - rgb.b);
k = c;
if (m < k) {
k = m;
}
nCompsA = obj2.getInt();
obj2.free();
+ if (nCompsA > gfxColorMaxComps) {
+ error(-1, "ICCBased color space with too many (%d > %d) components",
+ nCompsA, gfxColorMaxComps);
+ nCompsA = gfxColorMaxComps;
+ }
if (dict->lookup("Alternate", &obj2)->isNull() ||
!(altA = GfxColorSpace::parse(&obj2))) {
switch (nCompsA) {
return cs;
}
-void GfxICCBasedColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxICCBasedColorSpace::getGray(GfxColor *color, GfxGray *gray) {
alt->getGray(color, gray);
}
int indexHighA) {
base = baseA;
indexHigh = indexHighA;
- lookup = (Guchar *)gmalloc((indexHigh + 1) * base->getNComps() *
- sizeof(Guchar));
+ lookup = (Guchar *)gmallocn((indexHigh + 1) * base->getNComps(),
+ sizeof(Guchar));
}
GfxIndexedColorSpace::~GfxIndexedColorSpace() {
n = base->getNComps();
base->getDefaultRanges(low, range, indexHigh);
- p = &lookup[(int)(color->c[0] + 0.5) * n];
+ p = &lookup[(int)(colToDbl(color->c[0]) + 0.5) * n];
for (i = 0; i < n; ++i) {
- baseColor->c[i] = low[i] + (p[i] / 255.0) * range[i];
+ baseColor->c[i] = dblToCol(low[i] + (p[i] / 255.0) * range[i]);
}
return baseColor;
}
-void GfxIndexedColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxIndexedColorSpace::getGray(GfxColor *color, GfxGray *gray) {
GfxColor color2;
base->getGray(mapColorToBase(color, &color2), gray);
return NULL;
}
-void GfxSeparationColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxSeparationColorSpace::getGray(GfxColor *color, GfxGray *gray) {
+ double x;
+ double c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ x = colToDbl(color->c[0]);
+ func->transform(&x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getGray(&color2, gray);
}
void GfxSeparationColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ double x;
+ double c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ x = colToDbl(color->c[0]);
+ func->transform(&x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getRGB(&color2, rgb);
}
void GfxSeparationColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ double x;
+ double c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ x = colToDbl(color->c[0]);
+ func->transform(&x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getCMYK(&color2, cmyk);
}
}
nCompsA = obj1.arrayGetLength();
if (nCompsA > gfxColorMaxComps) {
- error(-1, "DeviceN color space with more than %d > %d components",
+ error(-1, "DeviceN color space with too many (%d > %d) components",
nCompsA, gfxColorMaxComps);
nCompsA = gfxColorMaxComps;
}
return NULL;
}
-void GfxDeviceNColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxDeviceNColorSpace::getGray(GfxColor *color, GfxGray *gray) {
+ double x[gfxColorMaxComps], c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ for (i = 0; i < nComps; ++i) {
+ x[i] = colToDbl(color->c[i]);
+ }
+ func->transform(x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getGray(&color2, gray);
}
void GfxDeviceNColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ double x[gfxColorMaxComps], c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ for (i = 0; i < nComps; ++i) {
+ x[i] = colToDbl(color->c[i]);
+ }
+ func->transform(x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getRGB(&color2, rgb);
}
void GfxDeviceNColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ double x[gfxColorMaxComps], c[gfxColorMaxComps];
GfxColor color2;
+ int i;
- func->transform(color->c, color2.c);
+ for (i = 0; i < nComps; ++i) {
+ x[i] = colToDbl(color->c[i]);
+ }
+ func->transform(x, c);
+ for (i = 0; i < alt->getNComps(); ++i) {
+ color2.c[i] = dblToCol(c[i]);
+ }
alt->getCMYK(&color2, cmyk);
}
return cs;
}
-void GfxPatternColorSpace::getGray(GfxColor *color, double *gray) {
+void GfxPatternColorSpace::getGray(GfxColor *color, GfxGray *gray) {
*gray = 0;
}
case 3:
shading = GfxRadialShading::parse(dict);
break;
+ case 4:
+ if (obj->isStream()) {
+ shading = GfxGouraudTriangleShading::parse(4, dict, obj->getStream());
+ } else {
+ error(-1, "Invalid Type 4 shading object");
+ goto err1;
+ }
+ break;
+ case 5:
+ if (obj->isStream()) {
+ shading = GfxGouraudTriangleShading::parse(5, dict, obj->getStream());
+ } else {
+ error(-1, "Invalid Type 5 shading object");
+ goto err1;
+ }
+ break;
+ case 6:
+ if (obj->isStream()) {
+ shading = GfxPatchMeshShading::parse(6, dict, obj->getStream());
+ } else {
+ error(-1, "Invalid Type 6 shading object");
+ goto err1;
+ }
+ break;
+ case 7:
+ if (obj->isStream()) {
+ shading = GfxPatchMeshShading::parse(7, dict, obj->getStream());
+ } else {
+ error(-1, "Invalid Type 7 shading object");
+ goto err1;
+ }
+ break;
default:
error(-1, "Unimplemented shading type %d", typeA);
goto err1;
if (obj1.arrayGetLength() == colorSpace->getNComps()) {
hasBackground = gTrue;
for (i = 0; i < colorSpace->getNComps(); ++i) {
- background.c[i] = obj1.arrayGet(i, &obj2)->getNum();
+ background.c[i] = dblToCol(obj1.arrayGet(i, &obj2)->getNum());
obj2.free();
}
} else {
}
void GfxFunctionShading::getColor(double x, double y, GfxColor *color) {
- double in[2];
+ double in[2], out[gfxColorMaxComps];
int i;
+ // NB: there can be one function with n outputs or n functions with
+ // one output each (where n = number of color components)
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ out[i] = 0;
+ }
in[0] = x;
in[1] = y;
for (i = 0; i < nFuncs; ++i) {
- funcs[i]->transform(in, &color->c[i]);
+ funcs[i]->transform(in, &out[i]);
+ }
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ color->c[i] = dblToCol(out[i]);
}
}
}
void GfxAxialShading::getColor(double t, GfxColor *color) {
+ double out[gfxColorMaxComps];
int i;
// NB: there can be one function with n outputs or n functions with
// one output each (where n = number of color components)
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ out[i] = 0;
+ }
for (i = 0; i < nFuncs; ++i) {
- funcs[i]->transform(&t, &color->c[i]);
+ funcs[i]->transform(&t, &out[i]);
+ }
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ color->c[i] = dblToCol(out[i]);
}
}
}
void GfxRadialShading::getColor(double t, GfxColor *color) {
+ double out[gfxColorMaxComps];
int i;
// NB: there can be one function with n outputs or n functions with
// one output each (where n = number of color components)
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ out[i] = 0;
+ }
for (i = 0; i < nFuncs; ++i) {
- funcs[i]->transform(&t, &color->c[i]);
+ funcs[i]->transform(&t, &out[i]);
+ }
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ color->c[i] = dblToCol(out[i]);
}
}
//------------------------------------------------------------------------
+// GfxShadingBitBuf
+//------------------------------------------------------------------------
+
+class GfxShadingBitBuf {
+public:
+
+ GfxShadingBitBuf(Stream *strA);
+ ~GfxShadingBitBuf();
+ GBool getBits(int n, Guint *val);
+ void flushBits();
+
+private:
+
+ Stream *str;
+ int bitBuf;
+ int nBits;
+};
+
+GfxShadingBitBuf::GfxShadingBitBuf(Stream *strA) {
+ str = strA;
+ str->reset();
+ bitBuf = 0;
+ nBits = 0;
+}
+
+GfxShadingBitBuf::~GfxShadingBitBuf() {
+ str->close();
+}
+
+GBool GfxShadingBitBuf::getBits(int n, Guint *val) {
+ int x;
+
+ if (nBits >= n) {
+ x = (bitBuf >> (nBits - n)) & ((1 << n) - 1);
+ nBits -= n;
+ } else {
+ x = 0;
+ if (nBits > 0) {
+ x = bitBuf & ((1 << nBits) - 1);
+ n -= nBits;
+ nBits = 0;
+ }
+ while (n > 0) {
+ if ((bitBuf = str->getChar()) == EOF) {
+ nBits = 0;
+ return gFalse;
+ }
+ if (n >= 8) {
+ x = (x << 8) | bitBuf;
+ n -= 8;
+ } else {
+ x = (x << n) | (bitBuf >> (8 - n));
+ nBits = 8 - n;
+ n = 0;
+ }
+ }
+ }
+ *val = x;
+ return gTrue;
+}
+
+void GfxShadingBitBuf::flushBits() {
+ bitBuf = 0;
+ nBits = 0;
+}
+
+//------------------------------------------------------------------------
+// GfxGouraudTriangleShading
+//------------------------------------------------------------------------
+
+GfxGouraudTriangleShading::GfxGouraudTriangleShading(
+ int typeA,
+ GfxGouraudVertex *verticesA, int nVerticesA,
+ int (*trianglesA)[3], int nTrianglesA,
+ Function **funcsA, int nFuncsA):
+ GfxShading(typeA)
+{
+ int i;
+
+ vertices = verticesA;
+ nVertices = nVerticesA;
+ triangles = trianglesA;
+ nTriangles = nTrianglesA;
+ nFuncs = nFuncsA;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = funcsA[i];
+ }
+}
+
+GfxGouraudTriangleShading::GfxGouraudTriangleShading(
+ GfxGouraudTriangleShading *shading):
+ GfxShading(shading)
+{
+ int i;
+
+ nVertices = shading->nVertices;
+ vertices = (GfxGouraudVertex *)gmallocn(nVertices, sizeof(GfxGouraudVertex));
+ memcpy(vertices, shading->vertices, nVertices * sizeof(GfxGouraudVertex));
+ nTriangles = shading->nTriangles;
+ triangles = (int (*)[3])gmallocn(nTriangles * 3, sizeof(int));
+ memcpy(triangles, shading->triangles, nTriangles * 3 * sizeof(int));
+ nFuncs = shading->nFuncs;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = shading->funcs[i]->copy();
+ }
+}
+
+GfxGouraudTriangleShading::~GfxGouraudTriangleShading() {
+ int i;
+
+ gfree(vertices);
+ gfree(triangles);
+ for (i = 0; i < nFuncs; ++i) {
+ delete funcs[i];
+ }
+}
+
+GfxGouraudTriangleShading *GfxGouraudTriangleShading::parse(int typeA,
+ Dict *dict,
+ Stream *str) {
+ GfxGouraudTriangleShading *shading;
+ Function *funcsA[gfxColorMaxComps];
+ int nFuncsA;
+ int coordBits, compBits, flagBits, vertsPerRow, nRows;
+ double xMin, xMax, yMin, yMax;
+ double cMin[gfxColorMaxComps], cMax[gfxColorMaxComps];
+ double xMul, yMul;
+ double cMul[gfxColorMaxComps];
+ GfxGouraudVertex *verticesA;
+ int (*trianglesA)[3];
+ int nComps, nVerticesA, nTrianglesA, vertSize, triSize;
+ Guint x, y, flag;
+ Guint c[gfxColorMaxComps];
+ GfxShadingBitBuf *bitBuf;
+ Object obj1, obj2;
+ int i, j, k, state;
+
+ if (dict->lookup("BitsPerCoordinate", &obj1)->isInt()) {
+ coordBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerCoordinate in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ if (dict->lookup("BitsPerComponent", &obj1)->isInt()) {
+ compBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerComponent in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ flagBits = vertsPerRow = 0; // make gcc happy
+ if (typeA == 4) {
+ if (dict->lookup("BitsPerFlag", &obj1)->isInt()) {
+ flagBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerFlag in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ } else {
+ if (dict->lookup("VerticesPerRow", &obj1)->isInt()) {
+ vertsPerRow = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid VerticesPerRow in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ }
+ if (dict->lookup("Decode", &obj1)->isArray() &&
+ obj1.arrayGetLength() >= 6) {
+ xMin = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ xMax = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ xMul = (xMax - xMin) / (pow(2.0, coordBits) - 1);
+ yMin = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ yMax = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ yMul = (yMax - yMin) / (pow(2.0, coordBits) - 1);
+ for (i = 0; 5 + 2*i < obj1.arrayGetLength() && i < gfxColorMaxComps; ++i) {
+ cMin[i] = obj1.arrayGet(4 + 2*i, &obj2)->getNum();
+ obj2.free();
+ cMax[i] = obj1.arrayGet(5 + 2*i, &obj2)->getNum();
+ obj2.free();
+ cMul[i] = (cMax[i] - cMin[i]) / (double)((1 << compBits) - 1);
+ }
+ nComps = i;
+ } else {
+ error(-1, "Missing or invalid Decode array in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+
+ if (!dict->lookup("Function", &obj1)->isNull()) {
+ if (obj1.isArray()) {
+ nFuncsA = obj1.arrayGetLength();
+ if (nFuncsA > gfxColorMaxComps) {
+ error(-1, "Invalid Function array in shading dictionary");
+ goto err1;
+ }
+ for (i = 0; i < nFuncsA; ++i) {
+ obj1.arrayGet(i, &obj2);
+ if (!(funcsA[i] = Function::parse(&obj2))) {
+ obj1.free();
+ obj2.free();
+ goto err1;
+ }
+ obj2.free();
+ }
+ } else {
+ nFuncsA = 1;
+ if (!(funcsA[0] = Function::parse(&obj1))) {
+ obj1.free();
+ goto err1;
+ }
+ }
+ } else {
+ nFuncsA = 0;
+ }
+ obj1.free();
+
+ nVerticesA = nTrianglesA = 0;
+ verticesA = NULL;
+ trianglesA = NULL;
+ vertSize = triSize = 0;
+ state = 0;
+ flag = 0; // make gcc happy
+ bitBuf = new GfxShadingBitBuf(str);
+ while (1) {
+ if (typeA == 4) {
+ if (!bitBuf->getBits(flagBits, &flag)) {
+ break;
+ }
+ }
+ if (!bitBuf->getBits(coordBits, &x) ||
+ !bitBuf->getBits(coordBits, &y)) {
+ break;
+ }
+ for (i = 0; i < nComps; ++i) {
+ if (!bitBuf->getBits(compBits, &c[i])) {
+ break;
+ }
+ }
+ if (i < nComps) {
+ break;
+ }
+ if (nVerticesA == vertSize) {
+ vertSize = (vertSize == 0) ? 16 : 2 * vertSize;
+ verticesA = (GfxGouraudVertex *)
+ greallocn(verticesA, vertSize, sizeof(GfxGouraudVertex));
+ }
+ verticesA[nVerticesA].x = xMin + xMul * (double)x;
+ verticesA[nVerticesA].y = yMin + yMul * (double)y;
+ for (i = 0; i < nComps; ++i) {
+ verticesA[nVerticesA].color.c[i] =
+ dblToCol(cMin[i] + cMul[i] * (double)c[i]);
+ }
+ ++nVerticesA;
+ bitBuf->flushBits();
+ if (typeA == 4) {
+ if (state == 0 || state == 1) {
+ ++state;
+ } else if (state == 2 || flag > 0) {
+ if (nTrianglesA == triSize) {
+ triSize = (triSize == 0) ? 16 : 2 * triSize;
+ trianglesA = (int (*)[3])
+ greallocn(trianglesA, triSize * 3, sizeof(int));
+ }
+ if (state == 2) {
+ trianglesA[nTrianglesA][0] = nVerticesA - 3;
+ trianglesA[nTrianglesA][1] = nVerticesA - 2;
+ trianglesA[nTrianglesA][2] = nVerticesA - 1;
+ ++state;
+ } else if (flag == 1) {
+ trianglesA[nTrianglesA][0] = trianglesA[nTrianglesA - 1][1];
+ trianglesA[nTrianglesA][1] = trianglesA[nTrianglesA - 1][2];
+ trianglesA[nTrianglesA][2] = nVerticesA - 1;
+ } else { // flag == 2
+ trianglesA[nTrianglesA][0] = trianglesA[nTrianglesA - 1][0];
+ trianglesA[nTrianglesA][1] = trianglesA[nTrianglesA - 1][2];
+ trianglesA[nTrianglesA][2] = nVerticesA - 1;
+ }
+ ++nTrianglesA;
+ } else { // state == 3 && flag == 0
+ state = 1;
+ }
+ }
+ }
+ delete bitBuf;
+ if (typeA == 5) {
+ nRows = nVerticesA / vertsPerRow;
+ nTrianglesA = (nRows - 1) * 2 * (vertsPerRow - 1);
+ trianglesA = (int (*)[3])gmallocn(nTrianglesA * 3, sizeof(int));
+ k = 0;
+ for (i = 0; i < nRows - 1; ++i) {
+ for (j = 0; j < vertsPerRow - 1; ++j) {
+ trianglesA[k][0] = i * vertsPerRow + j;
+ trianglesA[k][1] = i * vertsPerRow + j+1;
+ trianglesA[k][2] = (i+1) * vertsPerRow + j;
+ ++k;
+ trianglesA[k][0] = i * vertsPerRow + j+1;
+ trianglesA[k][1] = (i+1) * vertsPerRow + j;
+ trianglesA[k][2] = (i+1) * vertsPerRow + j+1;
+ ++k;
+ }
+ }
+ }
+
+ shading = new GfxGouraudTriangleShading(typeA, verticesA, nVerticesA,
+ trianglesA, nTrianglesA,
+ funcsA, nFuncsA);
+ if (!shading->init(dict)) {
+ delete shading;
+ return NULL;
+ }
+ return shading;
+
+ err2:
+ obj1.free();
+ err1:
+ return NULL;
+}
+
+GfxShading *GfxGouraudTriangleShading::copy() {
+ return new GfxGouraudTriangleShading(this);
+}
+
+void GfxGouraudTriangleShading::getTriangle(
+ int i,
+ double *x0, double *y0, GfxColor *color0,
+ double *x1, double *y1, GfxColor *color1,
+ double *x2, double *y2, GfxColor *color2) {
+ double in;
+ double out[gfxColorMaxComps];
+ int v, j;
+
+ v = triangles[i][0];
+ *x0 = vertices[v].x;
+ *y0 = vertices[v].y;
+ if (nFuncs > 0) {
+ in = colToDbl(vertices[v].color.c[0]);
+ for (j = 0; j < nFuncs; ++j) {
+ funcs[j]->transform(&in, &out[j]);
+ }
+ for (j = 0; j < gfxColorMaxComps; ++j) {
+ color0->c[j] = dblToCol(out[j]);
+ }
+ } else {
+ *color0 = vertices[v].color;
+ }
+ v = triangles[i][1];
+ *x1 = vertices[v].x;
+ *y1 = vertices[v].y;
+ if (nFuncs > 0) {
+ in = colToDbl(vertices[v].color.c[0]);
+ for (j = 0; j < nFuncs; ++j) {
+ funcs[j]->transform(&in, &out[j]);
+ }
+ for (j = 0; j < gfxColorMaxComps; ++j) {
+ color1->c[j] = dblToCol(out[j]);
+ }
+ } else {
+ *color1 = vertices[v].color;
+ }
+ v = triangles[i][2];
+ *x2 = vertices[v].x;
+ *y2 = vertices[v].y;
+ if (nFuncs > 0) {
+ in = colToDbl(vertices[v].color.c[0]);
+ for (j = 0; j < nFuncs; ++j) {
+ funcs[j]->transform(&in, &out[j]);
+ }
+ for (j = 0; j < gfxColorMaxComps; ++j) {
+ color2->c[j] = dblToCol(out[j]);
+ }
+ } else {
+ *color2 = vertices[v].color;
+ }
+}
+
+//------------------------------------------------------------------------
+// GfxPatchMeshShading
+//------------------------------------------------------------------------
+
+GfxPatchMeshShading::GfxPatchMeshShading(int typeA,
+ GfxPatch *patchesA, int nPatchesA,
+ Function **funcsA, int nFuncsA):
+ GfxShading(typeA)
+{
+ int i;
+
+ patches = patchesA;
+ nPatches = nPatchesA;
+ nFuncs = nFuncsA;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = funcsA[i];
+ }
+}
+
+GfxPatchMeshShading::GfxPatchMeshShading(GfxPatchMeshShading *shading):
+ GfxShading(shading)
+{
+ int i;
+
+ nPatches = shading->nPatches;
+ patches = (GfxPatch *)gmallocn(nPatches, sizeof(GfxPatch));
+ memcpy(patches, shading->patches, nPatches * sizeof(GfxPatch));
+ nFuncs = shading->nFuncs;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = shading->funcs[i]->copy();
+ }
+}
+
+GfxPatchMeshShading::~GfxPatchMeshShading() {
+ int i;
+
+ gfree(patches);
+ for (i = 0; i < nFuncs; ++i) {
+ delete funcs[i];
+ }
+}
+
+GfxPatchMeshShading *GfxPatchMeshShading::parse(int typeA, Dict *dict,
+ Stream *str) {
+ GfxPatchMeshShading *shading;
+ Function *funcsA[gfxColorMaxComps];
+ int nFuncsA;
+ int coordBits, compBits, flagBits;
+ double xMin, xMax, yMin, yMax;
+ double cMin[gfxColorMaxComps], cMax[gfxColorMaxComps];
+ double xMul, yMul;
+ double cMul[gfxColorMaxComps];
+ GfxPatch *patchesA, *p;
+ int nComps, nPatchesA, patchesSize, nPts, nColors;
+ Guint flag;
+ double x[16], y[16];
+ Guint xi, yi;
+ GfxColorComp c[4][gfxColorMaxComps];
+ Guint ci[4];
+ GfxShadingBitBuf *bitBuf;
+ Object obj1, obj2;
+ int i, j;
+
+ if (dict->lookup("BitsPerCoordinate", &obj1)->isInt()) {
+ coordBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerCoordinate in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ if (dict->lookup("BitsPerComponent", &obj1)->isInt()) {
+ compBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerComponent in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ if (dict->lookup("BitsPerFlag", &obj1)->isInt()) {
+ flagBits = obj1.getInt();
+ } else {
+ error(-1, "Missing or invalid BitsPerFlag in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+ if (dict->lookup("Decode", &obj1)->isArray() &&
+ obj1.arrayGetLength() >= 6) {
+ xMin = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ xMax = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ xMul = (xMax - xMin) / (pow(2.0, coordBits) - 1);
+ yMin = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ yMax = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ yMul = (yMax - yMin) / (pow(2.0, coordBits) - 1);
+ for (i = 0; 5 + 2*i < obj1.arrayGetLength() && i < gfxColorMaxComps; ++i) {
+ cMin[i] = obj1.arrayGet(4 + 2*i, &obj2)->getNum();
+ obj2.free();
+ cMax[i] = obj1.arrayGet(5 + 2*i, &obj2)->getNum();
+ obj2.free();
+ cMul[i] = (cMax[i] - cMin[i]) / (double)((1 << compBits) - 1);
+ }
+ nComps = i;
+ } else {
+ error(-1, "Missing or invalid Decode array in shading dictionary");
+ goto err2;
+ }
+ obj1.free();
+
+ if (!dict->lookup("Function", &obj1)->isNull()) {
+ if (obj1.isArray()) {
+ nFuncsA = obj1.arrayGetLength();
+ if (nFuncsA > gfxColorMaxComps) {
+ error(-1, "Invalid Function array in shading dictionary");
+ goto err1;
+ }
+ for (i = 0; i < nFuncsA; ++i) {
+ obj1.arrayGet(i, &obj2);
+ if (!(funcsA[i] = Function::parse(&obj2))) {
+ obj1.free();
+ obj2.free();
+ goto err1;
+ }
+ obj2.free();
+ }
+ } else {
+ nFuncsA = 1;
+ if (!(funcsA[0] = Function::parse(&obj1))) {
+ obj1.free();
+ goto err1;
+ }
+ }
+ } else {
+ nFuncsA = 0;
+ }
+ obj1.free();
+
+ nPatchesA = 0;
+ patchesA = NULL;
+ patchesSize = 0;
+ bitBuf = new GfxShadingBitBuf(str);
+ while (1) {
+ if (!bitBuf->getBits(flagBits, &flag)) {
+ break;
+ }
+ if (typeA == 6) {
+ switch (flag) {
+ case 0: nPts = 12; nColors = 4; break;
+ case 1:
+ case 2:
+ case 3:
+ default: nPts = 8; nColors = 2; break;
+ }
+ } else {
+ switch (flag) {
+ case 0: nPts = 16; nColors = 4; break;
+ case 1:
+ case 2:
+ case 3:
+ default: nPts = 12; nColors = 2; break;
+ }
+ }
+ for (i = 0; i < nPts; ++i) {
+ if (!bitBuf->getBits(coordBits, &xi) ||
+ !bitBuf->getBits(coordBits, &yi)) {
+ break;
+ }
+ x[i] = xMin + xMul * (double)xi;
+ y[i] = yMin + yMul * (double)yi;
+ }
+ if (i < nPts) {
+ break;
+ }
+ for (i = 0; i < nColors; ++i) {
+ for (j = 0; j < nComps; ++j) {
+ if (!bitBuf->getBits(compBits, &ci[j])) {
+ break;
+ }
+ c[i][j] = dblToCol(cMin[j] + cMul[j] * (double)ci[j]);
+ }
+ if (j < nComps) {
+ break;
+ }
+ }
+ if (i < nColors) {
+ break;
+ }
+ if (nPatchesA == patchesSize) {
+ patchesSize = (patchesSize == 0) ? 16 : 2 * patchesSize;
+ patchesA = (GfxPatch *)greallocn(patchesA,
+ patchesSize, sizeof(GfxPatch));
+ }
+ p = &patchesA[nPatchesA];
+ if (typeA == 6) {
+ switch (flag) {
+ case 0:
+ p->x[0][0] = x[0];
+ p->y[0][0] = y[0];
+ p->x[0][1] = x[1];
+ p->y[0][1] = y[1];
+ p->x[0][2] = x[2];
+ p->y[0][2] = y[2];
+ p->x[0][3] = x[3];
+ p->y[0][3] = y[3];
+ p->x[1][3] = x[4];
+ p->y[1][3] = y[4];
+ p->x[2][3] = x[5];
+ p->y[2][3] = y[5];
+ p->x[3][3] = x[6];
+ p->y[3][3] = y[6];
+ p->x[3][2] = x[7];
+ p->y[3][2] = y[7];
+ p->x[3][1] = x[8];
+ p->y[3][1] = y[8];
+ p->x[3][0] = x[9];
+ p->y[3][0] = y[9];
+ p->x[2][0] = x[10];
+ p->y[2][0] = y[10];
+ p->x[1][0] = x[11];
+ p->y[1][0] = y[11];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = c[0][j];
+ p->color[0][1].c[j] = c[1][j];
+ p->color[1][1].c[j] = c[2][j];
+ p->color[1][0].c[j] = c[3][j];
+ }
+ break;
+ case 1:
+ p->x[0][0] = patchesA[nPatchesA-1].x[0][3];
+ p->y[0][0] = patchesA[nPatchesA-1].y[0][3];
+ p->x[0][1] = patchesA[nPatchesA-1].x[1][3];
+ p->y[0][1] = patchesA[nPatchesA-1].y[1][3];
+ p->x[0][2] = patchesA[nPatchesA-1].x[2][3];
+ p->y[0][2] = patchesA[nPatchesA-1].y[2][3];
+ p->x[0][3] = patchesA[nPatchesA-1].x[3][3];
+ p->y[0][3] = patchesA[nPatchesA-1].y[3][3];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = patchesA[nPatchesA-1].color[0][1].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[1][1].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ case 2:
+ p->x[0][0] = patchesA[nPatchesA-1].x[3][3];
+ p->y[0][0] = patchesA[nPatchesA-1].y[3][3];
+ p->x[0][1] = patchesA[nPatchesA-1].x[3][2];
+ p->y[0][1] = patchesA[nPatchesA-1].y[3][2];
+ p->x[0][2] = patchesA[nPatchesA-1].x[3][1];
+ p->y[0][2] = patchesA[nPatchesA-1].y[3][1];
+ p->x[0][3] = patchesA[nPatchesA-1].x[3][0];
+ p->y[0][3] = patchesA[nPatchesA-1].y[3][0];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = patchesA[nPatchesA-1].color[1][1].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[1][0].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ case 3:
+ p->x[0][0] = patchesA[nPatchesA-1].x[3][0];
+ p->y[0][0] = patchesA[nPatchesA-1].y[3][0];
+ p->x[0][1] = patchesA[nPatchesA-1].x[2][0];
+ p->y[0][1] = patchesA[nPatchesA-1].y[2][0];
+ p->x[0][2] = patchesA[nPatchesA-1].x[1][0];
+ p->y[0][2] = patchesA[nPatchesA-1].y[1][0];
+ p->x[0][3] = patchesA[nPatchesA-1].x[0][0];
+ p->y[0][3] = patchesA[nPatchesA-1].y[0][0];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[1][0].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[0][0].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ }
+ } else {
+ switch (flag) {
+ case 0:
+ p->x[0][0] = x[0];
+ p->y[0][0] = y[0];
+ p->x[0][1] = x[1];
+ p->y[0][1] = y[1];
+ p->x[0][2] = x[2];
+ p->y[0][2] = y[2];
+ p->x[0][3] = x[3];
+ p->y[0][3] = y[3];
+ p->x[1][3] = x[4];
+ p->y[1][3] = y[4];
+ p->x[2][3] = x[5];
+ p->y[2][3] = y[5];
+ p->x[3][3] = x[6];
+ p->y[3][3] = y[6];
+ p->x[3][2] = x[7];
+ p->y[3][2] = y[7];
+ p->x[3][1] = x[8];
+ p->y[3][1] = y[8];
+ p->x[3][0] = x[9];
+ p->y[3][0] = y[9];
+ p->x[2][0] = x[10];
+ p->y[2][0] = y[10];
+ p->x[1][0] = x[11];
+ p->y[1][0] = y[11];
+ p->x[1][1] = x[12];
+ p->y[1][1] = y[12];
+ p->x[1][2] = x[13];
+ p->y[1][2] = y[13];
+ p->x[2][2] = x[14];
+ p->y[2][2] = y[14];
+ p->x[2][1] = x[15];
+ p->y[2][1] = y[15];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = c[0][j];
+ p->color[0][1].c[j] = c[1][j];
+ p->color[1][1].c[j] = c[2][j];
+ p->color[1][0].c[j] = c[3][j];
+ }
+ break;
+ case 1:
+ p->x[0][0] = patchesA[nPatchesA-1].x[0][3];
+ p->y[0][0] = patchesA[nPatchesA-1].y[0][3];
+ p->x[0][1] = patchesA[nPatchesA-1].x[1][3];
+ p->y[0][1] = patchesA[nPatchesA-1].y[1][3];
+ p->x[0][2] = patchesA[nPatchesA-1].x[2][3];
+ p->y[0][2] = patchesA[nPatchesA-1].y[2][3];
+ p->x[0][3] = patchesA[nPatchesA-1].x[3][3];
+ p->y[0][3] = patchesA[nPatchesA-1].y[3][3];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ p->x[1][1] = x[8];
+ p->y[1][1] = y[8];
+ p->x[1][2] = x[9];
+ p->y[1][2] = y[9];
+ p->x[2][2] = x[10];
+ p->y[2][2] = y[10];
+ p->x[2][1] = x[11];
+ p->y[2][1] = y[11];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = patchesA[nPatchesA-1].color[0][1].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[1][1].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ case 2:
+ p->x[0][0] = patchesA[nPatchesA-1].x[3][3];
+ p->y[0][0] = patchesA[nPatchesA-1].y[3][3];
+ p->x[0][1] = patchesA[nPatchesA-1].x[3][2];
+ p->y[0][1] = patchesA[nPatchesA-1].y[3][2];
+ p->x[0][2] = patchesA[nPatchesA-1].x[3][1];
+ p->y[0][2] = patchesA[nPatchesA-1].y[3][1];
+ p->x[0][3] = patchesA[nPatchesA-1].x[3][0];
+ p->y[0][3] = patchesA[nPatchesA-1].y[3][0];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ p->x[1][1] = x[8];
+ p->y[1][1] = y[8];
+ p->x[1][2] = x[9];
+ p->y[1][2] = y[9];
+ p->x[2][2] = x[10];
+ p->y[2][2] = y[10];
+ p->x[2][1] = x[11];
+ p->y[2][1] = y[11];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = patchesA[nPatchesA-1].color[1][1].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[1][0].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ case 3:
+ p->x[0][0] = patchesA[nPatchesA-1].x[3][0];
+ p->y[0][0] = patchesA[nPatchesA-1].y[3][0];
+ p->x[0][1] = patchesA[nPatchesA-1].x[2][0];
+ p->y[0][1] = patchesA[nPatchesA-1].y[2][0];
+ p->x[0][2] = patchesA[nPatchesA-1].x[1][0];
+ p->y[0][2] = patchesA[nPatchesA-1].y[1][0];
+ p->x[0][3] = patchesA[nPatchesA-1].x[0][0];
+ p->y[0][3] = patchesA[nPatchesA-1].y[0][0];
+ p->x[1][3] = x[0];
+ p->y[1][3] = y[0];
+ p->x[2][3] = x[1];
+ p->y[2][3] = y[1];
+ p->x[3][3] = x[2];
+ p->y[3][3] = y[2];
+ p->x[3][2] = x[3];
+ p->y[3][2] = y[3];
+ p->x[3][1] = x[4];
+ p->y[3][1] = y[4];
+ p->x[3][0] = x[5];
+ p->y[3][0] = y[5];
+ p->x[2][0] = x[6];
+ p->y[2][0] = y[6];
+ p->x[1][0] = x[7];
+ p->y[1][0] = y[7];
+ p->x[1][1] = x[8];
+ p->y[1][1] = y[8];
+ p->x[1][2] = x[9];
+ p->y[1][2] = y[9];
+ p->x[2][2] = x[10];
+ p->y[2][2] = y[10];
+ p->x[2][1] = x[11];
+ p->y[2][1] = y[11];
+ for (j = 0; j < nComps; ++j) {
+ p->color[0][0].c[j] = patchesA[nPatchesA-1].color[1][0].c[j];
+ p->color[0][1].c[j] = patchesA[nPatchesA-1].color[0][0].c[j];
+ p->color[1][1].c[j] = c[0][j];
+ p->color[1][0].c[j] = c[1][j];
+ }
+ break;
+ }
+ }
+ ++nPatchesA;
+ bitBuf->flushBits();
+ }
+ delete bitBuf;
+
+ if (typeA == 6) {
+ for (i = 0; i < nPatchesA; ++i) {
+ p = &patchesA[i];
+ p->x[1][1] = (-4 * p->x[0][0]
+ +6 * (p->x[0][1] + p->x[1][0])
+ -2 * (p->x[0][3] + p->x[3][0])
+ +3 * (p->x[3][1] + p->x[1][3])
+ - p->x[3][3]) / 9;
+ p->y[1][1] = (-4 * p->y[0][0]
+ +6 * (p->y[0][1] + p->y[1][0])
+ -2 * (p->y[0][3] + p->y[3][0])
+ +3 * (p->y[3][1] + p->y[1][3])
+ - p->y[3][3]) / 9;
+ p->x[1][2] = (-4 * p->x[0][3]
+ +6 * (p->x[0][2] + p->x[1][3])
+ -2 * (p->x[0][0] + p->x[3][3])
+ +3 * (p->x[3][2] + p->x[1][0])
+ - p->x[3][0]) / 9;
+ p->y[1][2] = (-4 * p->y[0][3]
+ +6 * (p->y[0][2] + p->y[1][3])
+ -2 * (p->y[0][0] + p->y[3][3])
+ +3 * (p->y[3][2] + p->y[1][0])
+ - p->y[3][0]) / 9;
+ p->x[2][1] = (-4 * p->x[3][0]
+ +6 * (p->x[3][1] + p->x[2][0])
+ -2 * (p->x[3][3] + p->x[0][0])
+ +3 * (p->x[0][1] + p->x[2][3])
+ - p->x[0][3]) / 9;
+ p->y[2][1] = (-4 * p->y[3][0]
+ +6 * (p->y[3][1] + p->y[2][0])
+ -2 * (p->y[3][3] + p->y[0][0])
+ +3 * (p->y[0][1] + p->y[2][3])
+ - p->y[0][3]) / 9;
+ p->x[2][2] = (-4 * p->x[3][3]
+ +6 * (p->x[3][2] + p->x[2][3])
+ -2 * (p->x[3][0] + p->x[0][3])
+ +3 * (p->x[0][2] + p->x[2][0])
+ - p->x[0][0]) / 9;
+ p->y[2][2] = (-4 * p->y[3][3]
+ +6 * (p->y[3][2] + p->y[2][3])
+ -2 * (p->y[3][0] + p->y[0][3])
+ +3 * (p->y[0][2] + p->y[2][0])
+ - p->y[0][0]) / 9;
+ }
+ }
+
+ shading = new GfxPatchMeshShading(typeA, patchesA, nPatchesA,
+ funcsA, nFuncsA);
+ if (!shading->init(dict)) {
+ delete shading;
+ return NULL;
+ }
+ return shading;
+
+ err2:
+ obj1.free();
+ err1:
+ return NULL;
+}
+
+GfxShading *GfxPatchMeshShading::copy() {
+ return new GfxPatchMeshShading(this);
+}
+
+//------------------------------------------------------------------------
// GfxImageColorMap
//------------------------------------------------------------------------
double x[gfxColorMaxComps];
double y[gfxColorMaxComps];
int i, j, k;
- int maxPixelForAlloc;
ok = gTrue;
// bits per component and color space
bits = bitsA;
maxPixel = (1 << bits) - 1;
- maxPixelForAlloc = (1 << (bits>8?bits:8));
colorSpace = colorSpaceA;
// get decode map
// Optimization: for Indexed and Separation color spaces (which have
// only one component), we store color values in the lookup table
// rather than component values.
+ for (k = 0; k < gfxColorMaxComps; ++k) {
+ lookup[k] = NULL;
+ }
colorSpace2 = NULL;
nComps2 = 0;
if (colorSpace->getMode() == csIndexed) {
colorSpace2 = indexedCS->getBase();
indexHigh = indexedCS->getIndexHigh();
nComps2 = colorSpace2->getNComps();
- lookup = (double *)gmalloc((maxPixelForAlloc + 1) * nComps2 * sizeof(double));
lookup2 = indexedCS->getLookup();
colorSpace2->getDefaultRanges(x, y, indexHigh);
- for (i = 0; i <= maxPixel; ++i) {
- j = (int)(decodeLow[0] + (i * decodeRange[0]) / maxPixel + 0.5);
- if (j < 0) {
- j = 0;
- } else if (j > indexHigh) {
- j = indexHigh;
- }
- for (k = 0; k < nComps2; ++k) {
- lookup[i*nComps2 + k] = x[k] + (lookup2[j*nComps2 + k] / 255.0) * y[k];
+ for (k = 0; k < nComps2; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(maxPixel + 1,
+ sizeof(GfxColorComp));
+ for (i = 0; i <= maxPixel; ++i) {
+ j = (int)(decodeLow[0] + (i * decodeRange[0]) / maxPixel + 0.5);
+ if (j < 0) {
+ j = 0;
+ } else if (j > indexHigh) {
+ j = indexHigh;
+ }
+ lookup[k][i] =
+ dblToCol(x[k] + (lookup2[j*nComps2 + k] / 255.0) * y[k]);
}
}
} else if (colorSpace->getMode() == csSeparation) {
sepCS = (GfxSeparationColorSpace *)colorSpace;
colorSpace2 = sepCS->getAlt();
nComps2 = colorSpace2->getNComps();
- lookup = (double *)gmalloc((maxPixelForAlloc + 1) * nComps2 * sizeof(double));
sepFunc = sepCS->getFunc();
- for (i = 0; i <= maxPixel; ++i) {
- x[0] = decodeLow[0] + (i * decodeRange[0]) / maxPixel;
- sepFunc->transform(x, y);
- for (k = 0; k < nComps2; ++k) {
- lookup[i*nComps2 + k] = y[k];
+ for (k = 0; k < nComps2; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(maxPixel + 1,
+ sizeof(GfxColorComp));
+ for (i = 0; i <= maxPixel; ++i) {
+ x[0] = decodeLow[0] + (i * decodeRange[0]) / maxPixel;
+ sepFunc->transform(x, y);
+ lookup[k][i] = dblToCol(y[k]);
}
}
} else {
- lookup = (double *)gmalloc((maxPixelForAlloc + 1) * nComps * sizeof(double));
- for (i = 0; i <= maxPixel; ++i) {
- for (k = 0; k < nComps; ++k) {
- lookup[i*nComps + k] = decodeLow[k] +
- (i * decodeRange[k]) / maxPixel;
+ for (k = 0; k < nComps; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(maxPixel + 1,
+ sizeof(GfxColorComp));
+ for (i = 0; i <= maxPixel; ++i) {
+ lookup[k][i] = dblToCol(decodeLow[k] +
+ (i * decodeRange[k]) / maxPixel);
}
}
}
}
GfxImageColorMap::GfxImageColorMap(GfxImageColorMap *colorMap) {
- int n, i;
+ int n, i, k;
colorSpace = colorMap->colorSpace->copy();
bits = colorMap->bits;
nComps = colorMap->nComps;
nComps2 = colorMap->nComps2;
colorSpace2 = NULL;
- lookup = NULL;
+ for (k = 0; k < gfxColorMaxComps; ++k) {
+ lookup[k] = NULL;
+ }
n = 1 << bits;
if (colorSpace->getMode() == csIndexed) {
colorSpace2 = ((GfxIndexedColorSpace *)colorSpace)->getBase();
- n = n * nComps2 * sizeof(double);
+ for (k = 0; k < nComps2; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(n, sizeof(GfxColorComp));
+ memcpy(lookup[k], colorMap->lookup[k], n * sizeof(GfxColorComp));
+ }
} else if (colorSpace->getMode() == csSeparation) {
colorSpace2 = ((GfxSeparationColorSpace *)colorSpace)->getAlt();
- n = n * nComps2 * sizeof(double);
+ for (k = 0; k < nComps2; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(n, sizeof(GfxColorComp));
+ memcpy(lookup[k], colorMap->lookup[k], n * sizeof(GfxColorComp));
+ }
} else {
- n = n * nComps * sizeof(double);
+ for (k = 0; k < nComps; ++k) {
+ lookup[k] = (GfxColorComp *)gmallocn(n, sizeof(GfxColorComp));
+ memcpy(lookup[k], colorMap->lookup[k], n * sizeof(GfxColorComp));
+ }
}
- lookup = (double *)gmalloc(n);
- memcpy(lookup, colorMap->lookup, n);
for (i = 0; i < nComps; ++i) {
decodeLow[i] = colorMap->decodeLow[i];
decodeRange[i] = colorMap->decodeRange[i];
}
GfxImageColorMap::~GfxImageColorMap() {
+ int i;
+
delete colorSpace;
- gfree(lookup);
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ gfree(lookup[i]);
+ }
}
-void GfxImageColorMap::getGray(Guchar *x, double *gray) {
+void GfxImageColorMap::getGray(Guchar *x, GfxGray *gray) {
GfxColor color;
- double *p;
int i;
if (colorSpace2) {
- p = &lookup[x[0] * nComps2];
for (i = 0; i < nComps2; ++i) {
- color.c[i] = *p++;
+ color.c[i] = lookup[i][x[0]];
}
colorSpace2->getGray(&color, gray);
} else {
for (i = 0; i < nComps; ++i) {
- color.c[i] = lookup[x[i] * nComps + i];
+ color.c[i] = lookup[i][x[i]];
}
colorSpace->getGray(&color, gray);
}
void GfxImageColorMap::getRGB(Guchar *x, GfxRGB *rgb) {
GfxColor color;
- double *p;
int i;
if (colorSpace2) {
- p = &lookup[x[0] * nComps2];
for (i = 0; i < nComps2; ++i) {
- color.c[i] = *p++;
+ color.c[i] = lookup[i][x[0]];
}
colorSpace2->getRGB(&color, rgb);
} else {
for (i = 0; i < nComps; ++i) {
- color.c[i] = lookup[x[i] * nComps + i];
+ color.c[i] = lookup[i][x[i]];
}
colorSpace->getRGB(&color, rgb);
}
void GfxImageColorMap::getCMYK(Guchar *x, GfxCMYK *cmyk) {
GfxColor color;
- double *p;
int i;
if (colorSpace2) {
- p = &lookup[x[0] * nComps2];
for (i = 0; i < nComps2; ++i) {
- color.c[i] = *p++;
+ color.c[i] = lookup[i][x[0]];
}
colorSpace2->getCMYK(&color, cmyk);
} else {
for (i = 0; i < nComps; ++i) {
- color.c[i] = lookup[x[i] * nComps + i];
+ color.c[i] = lookup[i][x[i]];
}
colorSpace->getCMYK(&color, cmyk);
}
maxPixel = (1 << bits) - 1;
for (i = 0; i < nComps; ++i) {
- color->c[i] = decodeLow[i] + (x[i] * decodeRange[i]) / maxPixel;
+ color->c[i] = dblToCol(decodeLow[i] + (x[i] * decodeRange[i]) / maxPixel);
}
}
GfxSubpath::GfxSubpath(double x1, double y1) {
size = 16;
- x = (double *)gmalloc(size * sizeof(double));
- y = (double *)gmalloc(size * sizeof(double));
- curve = (GBool *)gmalloc(size * sizeof(GBool));
+ x = (double *)gmallocn(size, sizeof(double));
+ y = (double *)gmallocn(size, sizeof(double));
+ curve = (GBool *)gmallocn(size, sizeof(GBool));
n = 1;
x[0] = x1;
y[0] = y1;
GfxSubpath::GfxSubpath(GfxSubpath *subpath) {
size = subpath->size;
n = subpath->n;
- x = (double *)gmalloc(size * sizeof(double));
- y = (double *)gmalloc(size * sizeof(double));
- curve = (GBool *)gmalloc(size * sizeof(GBool));
+ x = (double *)gmallocn(size, sizeof(double));
+ y = (double *)gmallocn(size, sizeof(double));
+ curve = (GBool *)gmallocn(size, sizeof(GBool));
memcpy(x, subpath->x, n * sizeof(double));
memcpy(y, subpath->y, n * sizeof(double));
memcpy(curve, subpath->curve, n * sizeof(GBool));
void GfxSubpath::lineTo(double x1, double y1) {
if (n >= size) {
size += 16;
- x = (double *)grealloc(x, size * sizeof(double));
- y = (double *)grealloc(y, size * sizeof(double));
- curve = (GBool *)grealloc(curve, size * sizeof(GBool));
+ x = (double *)greallocn(x, size, sizeof(double));
+ y = (double *)greallocn(y, size, sizeof(double));
+ curve = (GBool *)greallocn(curve, size, sizeof(GBool));
}
x[n] = x1;
y[n] = y1;
double x3, double y3) {
if (n+3 > size) {
size += 16;
- x = (double *)grealloc(x, size * sizeof(double));
- y = (double *)grealloc(y, size * sizeof(double));
- curve = (GBool *)grealloc(curve, size * sizeof(GBool));
+ x = (double *)greallocn(x, size, sizeof(double));
+ y = (double *)greallocn(y, size, sizeof(double));
+ curve = (GBool *)greallocn(curve, size, sizeof(GBool));
}
x[n] = x1;
y[n] = y1;
size = 16;
n = 0;
firstX = firstY = 0;
- subpaths = (GfxSubpath **)gmalloc(size * sizeof(GfxSubpath *));
+ subpaths = (GfxSubpath **)gmallocn(size, sizeof(GfxSubpath *));
}
GfxPath::~GfxPath() {
firstY = firstY1;
size = size1;
n = n1;
- subpaths = (GfxSubpath **)gmalloc(size * sizeof(GfxSubpath *));
+ subpaths = (GfxSubpath **)gmallocn(size, sizeof(GfxSubpath *));
for (i = 0; i < n; ++i)
subpaths[i] = subpaths1[i]->copy();
}
if (n >= size) {
size += 16;
subpaths = (GfxSubpath **)
- grealloc(subpaths, size * sizeof(GfxSubpath *));
+ greallocn(subpaths, size, sizeof(GfxSubpath *));
}
subpaths[n] = new GfxSubpath(firstX, firstY);
++n;
if (n >= size) {
size += 16;
subpaths = (GfxSubpath **)
- grealloc(subpaths, size * sizeof(GfxSubpath *));
+ greallocn(subpaths, size, sizeof(GfxSubpath *));
}
subpaths[n] = new GfxSubpath(firstX, firstY);
++n;
if (n >= size) {
size += 16;
subpaths = (GfxSubpath **)
- grealloc(subpaths, size * sizeof(GfxSubpath *));
+ greallocn(subpaths, size, sizeof(GfxSubpath *));
}
subpaths[n] = new GfxSubpath(firstX, firstY);
++n;
if (n + path->n > size) {
size = n + path->n;
subpaths = (GfxSubpath **)
- grealloc(subpaths, size * sizeof(GfxSubpath *));
+ greallocn(subpaths, size, sizeof(GfxSubpath *));
}
for (i = 0; i < path->n; ++i) {
subpaths[n++] = path->subpaths[i]->copy();
//------------------------------------------------------------------------
GfxState::GfxState(double hDPI, double vDPI, PDFRectangle *pageBox,
- int rotate, GBool upsideDown) {
+ int rotateA, GBool upsideDown) {
double kx, ky;
+ rotate = rotateA;
px1 = pageBox->x1;
py1 = pageBox->y1;
px2 = pageBox->x2;
strokeColor.c[0] = 0;
fillPattern = NULL;
strokePattern = NULL;
+ blendMode = gfxBlendNormal;
fillOpacity = 1;
strokeOpacity = 1;
+ fillOverprint = gFalse;
+ strokeOverprint = gFalse;
lineWidth = 1;
lineDash = NULL;
strokePattern = state->strokePattern->copy();
}
if (lineDashLength > 0) {
- lineDash = (double *)gmalloc(lineDashLength * sizeof(double));
+ lineDash = (double *)gmallocn(lineDashLength, sizeof(double));
memcpy(lineDash, state->lineDash, lineDashLength * sizeof(double));
}
saved = NULL;
return oldState;
}
+
+GBool GfxState::parseBlendMode(Object *obj, GfxBlendMode *mode) {
+ Object obj2;
+ int i, j;
+
+ if (obj->isName()) {
+ for (i = 0; i < nGfxBlendModeNames; ++i) {
+ if (!strcmp(obj->getName(), gfxBlendModeNames[i].name)) {
+ *mode = gfxBlendModeNames[i].mode;
+ return gTrue;
+ }
+ }
+ return gFalse;
+ } else if (obj->isArray()) {
+ for (i = 0; i < obj->arrayGetLength(); ++i) {
+ obj->arrayGet(i, &obj2);
+ if (!obj2.isName()) {
+ obj2.free();
+ return gFalse;
+ }
+ for (j = 0; j < nGfxBlendModeNames; ++j) {
+ if (!strcmp(obj2.getName(), gfxBlendModeNames[j].name)) {
+ obj2.free();
+ *mode = gfxBlendModeNames[j].mode;
+ return gTrue;
+ }
+ }
+ obj2.free();
+ }
+ *mode = gfxBlendNormal;
+ return gTrue;
+ } else {
+ return gFalse;
+ }
+}
git.asbjorn.biz / swftools.git / commitdiff