//
// GfxState.cc
//
-// Copyright 1996 Derek B. Noonburg
+// Copyright 1996-2003 Glyph & Cog, LLC
//
//========================================================================
-#ifdef __GNUC__
+#include <aconf.h>
+
+#ifdef USE_GCC_PRAGMAS
#pragma implementation
#endif
#include "gmem.h"
#include "Error.h"
#include "Object.h"
+#include "Array.h"
+#include "Page.h"
#include "GfxState.h"
-//------------------------------------------------------------------------
-// GfxColor
//------------------------------------------------------------------------
-void GfxColor::setCMYK(double c, double m, double y, double k) {
- if ((r = 1 - (c + k)) < 0)
- r = 0;
- if ((g = 1 - (m + k)) < 0)
- g = 0;
- if ((b = 1 - (y + k)) < 0)
- b = 0;
+static inline double clip01(double x) {
+ return (x < 0) ? 0 : ((x > 1) ? 1 : x);
}
+//------------------------------------------------------------------------
+
+static char *gfxColorSpaceModeNames[] = {
+ "DeviceGray",
+ "CalGray",
+ "DeviceRGB",
+ "CalRGB",
+ "DeviceCMYK",
+ "Lab",
+ "ICCBased",
+ "Indexed",
+ "Separation",
+ "DeviceN",
+ "Pattern"
+};
+
+#define nGfxColorSpaceModes ((sizeof(gfxColorSpaceModeNames) / sizeof(char *)))
+
//------------------------------------------------------------------------
// GfxColorSpace
//------------------------------------------------------------------------
-GfxColorSpace::GfxColorSpace(Object *colorSpace) {
- Object csObj;
- Object obj, obj2;
- char *s;
- int x;
- int i, j;
+GfxColorSpace::GfxColorSpace() {
+}
- ok = gTrue;
- lookup = NULL;
+GfxColorSpace::~GfxColorSpace() {
+}
- // check for Separation, DeviceN, and Pattern colorspaces
- colorSpace->copy(&csObj);
- sepFunc = NULL;
- if (colorSpace->isArray()) {
- colorSpace->arrayGet(0, &obj);
- if (obj.isName("Separation") || obj.isName("DeviceN")) {
- csObj.free();
- colorSpace->arrayGet(2, &csObj);
- sepFunc = new Function(colorSpace->arrayGet(3, &obj2));
- obj2.free();
- if (!sepFunc->isOk()) {
- delete sepFunc;
- sepFunc = NULL;
- }
- } else if (obj.isName("Pattern")) {
- csObj.free();
- colorSpace->arrayGet(1, &csObj);
- }
- obj.free();
- }
-
- // get mode
- indexed = gFalse;
- if (csObj.isName()) {
- setMode(&csObj);
- } else if (csObj.isArray()) {
- csObj.arrayGet(0, &obj);
- if (obj.isName("Indexed") || obj.isName("I")) {
- indexed = gTrue;
- setMode(csObj.arrayGet(1, &obj2));
- obj2.free();
+GfxColorSpace *GfxColorSpace::parse(Object *csObj) {
+ GfxColorSpace *cs;
+ Object obj1;
+
+ cs = NULL;
+ if (csObj->isName()) {
+ if (csObj->isName("DeviceGray") || csObj->isName("G")) {
+ cs = new GfxDeviceGrayColorSpace();
+ } else if (csObj->isName("DeviceRGB") || csObj->isName("RGB")) {
+ cs = new GfxDeviceRGBColorSpace();
+ } else if (csObj->isName("DeviceCMYK") || csObj->isName("CMYK")) {
+ cs = new GfxDeviceCMYKColorSpace();
+ } else if (csObj->isName("Pattern")) {
+ cs = new GfxPatternColorSpace(NULL);
} else {
- setMode(&csObj);
+ error(-1, "Bad color space '%s'", csObj->getName());
}
- obj.free();
+ } else if (csObj->isArray()) {
+ csObj->arrayGet(0, &obj1);
+ if (obj1.isName("DeviceGray") || obj1.isName("G")) {
+ cs = new GfxDeviceGrayColorSpace();
+ } else if (obj1.isName("DeviceRGB") || obj1.isName("RGB")) {
+ cs = new GfxDeviceRGBColorSpace();
+ } else if (obj1.isName("DeviceCMYK") || obj1.isName("CMYK")) {
+ cs = new GfxDeviceCMYKColorSpace();
+ } else if (obj1.isName("CalGray")) {
+ cs = GfxCalGrayColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("CalRGB")) {
+ cs = GfxCalRGBColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("Lab")) {
+ cs = GfxLabColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("ICCBased")) {
+ cs = GfxICCBasedColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("Indexed") || obj1.isName("I")) {
+ cs = GfxIndexedColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("Separation")) {
+ cs = GfxSeparationColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("DeviceN")) {
+ cs = GfxDeviceNColorSpace::parse(csObj->getArray());
+ } else if (obj1.isName("Pattern")) {
+ cs = GfxPatternColorSpace::parse(csObj->getArray());
+ } else {
+ error(-1, "Bad color space");
+ }
+ obj1.free();
} else {
- goto err1;
+ error(-1, "Bad color space - expected name or array");
}
- if (!ok) {
- goto err1;
+ return cs;
+}
+
+void GfxColorSpace::getDefaultRanges(double *decodeLow, double *decodeRange,
+ int maxImgPixel) {
+ int i;
+
+ for (i = 0; i < getNComps(); ++i) {
+ decodeLow[i] = 0;
+ decodeRange[i] = 1;
}
+}
- // get lookup table for indexed colorspace
- if (indexed) {
- csObj.arrayGet(2, &obj);
- if (!obj.isInt())
- goto err2;
- indexHigh = obj.getInt();
- obj.free();
- lookup = (Guchar (*)[4])gmalloc((indexHigh + 1) * 4 * sizeof(Guchar));
- csObj.arrayGet(3, &obj);
- if (obj.isStream()) {
- obj.streamReset();
- for (i = 0; i <= indexHigh; ++i) {
- for (j = 0; j < numComps; ++j) {
- if ((x = obj.streamGetChar()) == EOF)
- goto err2;
- lookup[i][j] = (Guchar)x;
- }
- }
- } else if (obj.isString()) {
- s = obj.getString()->getCString();
- for (i = 0; i <= indexHigh; ++i)
- for (j = 0; j < numComps; ++j)
- lookup[i][j] = (Guchar)*s++;
- } else {
- goto err2;
+int GfxColorSpace::getNumColorSpaceModes() {
+ return nGfxColorSpaceModes;
+}
+
+char *GfxColorSpace::getColorSpaceModeName(int idx) {
+ return gfxColorSpaceModeNames[idx];
+}
+
+//------------------------------------------------------------------------
+// GfxDeviceGrayColorSpace
+//------------------------------------------------------------------------
+
+GfxDeviceGrayColorSpace::GfxDeviceGrayColorSpace() {
+}
+
+GfxDeviceGrayColorSpace::~GfxDeviceGrayColorSpace() {
+}
+
+GfxColorSpace *GfxDeviceGrayColorSpace::copy() {
+ return new GfxDeviceGrayColorSpace();
+}
+
+void GfxDeviceGrayColorSpace::getGray(GfxColor *color, double *gray) {
+ *gray = clip01(color->c[0]);
+}
+
+void GfxDeviceGrayColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ rgb->r = rgb->g = rgb->b = 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]);
+}
+
+//------------------------------------------------------------------------
+// GfxCalGrayColorSpace
+//------------------------------------------------------------------------
+
+GfxCalGrayColorSpace::GfxCalGrayColorSpace() {
+ whiteX = whiteY = whiteZ = 1;
+ blackX = blackY = blackZ = 0;
+ gamma = 1;
+}
+
+GfxCalGrayColorSpace::~GfxCalGrayColorSpace() {
+}
+
+GfxColorSpace *GfxCalGrayColorSpace::copy() {
+ GfxCalGrayColorSpace *cs;
+
+ cs = new GfxCalGrayColorSpace();
+ cs->whiteX = whiteX;
+ cs->whiteY = whiteY;
+ cs->whiteZ = whiteZ;
+ cs->blackX = blackX;
+ cs->blackY = blackY;
+ cs->blackZ = blackZ;
+ cs->gamma = gamma;
+ return cs;
+}
+
+GfxColorSpace *GfxCalGrayColorSpace::parse(Array *arr) {
+ GfxCalGrayColorSpace *cs;
+ Object obj1, obj2, obj3;
+
+ arr->get(1, &obj1);
+ if (!obj1.isDict()) {
+ error(-1, "Bad CalGray color space");
+ obj1.free();
+ return NULL;
+ }
+ cs = new GfxCalGrayColorSpace();
+ if (obj1.dictLookup("WhitePoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->whiteX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->whiteY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->whiteZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("BlackPoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->blackX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->blackY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->blackZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("Gamma", &obj2)->isNum()) {
+ cs->gamma = obj2.getNum();
+ }
+ obj2.free();
+ obj1.free();
+ return cs;
+}
+
+void GfxCalGrayColorSpace::getGray(GfxColor *color, double *gray) {
+ *gray = clip01(color->c[0]);
+}
+
+void GfxCalGrayColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ rgb->r = rgb->g = rgb->b = 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]);
+}
+
+//------------------------------------------------------------------------
+// GfxDeviceRGBColorSpace
+//------------------------------------------------------------------------
+
+GfxDeviceRGBColorSpace::GfxDeviceRGBColorSpace() {
+}
+
+GfxDeviceRGBColorSpace::~GfxDeviceRGBColorSpace() {
+}
+
+GfxColorSpace *GfxDeviceRGBColorSpace::copy() {
+ 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::getRGB(GfxColor *color, GfxRGB *rgb) {
+ rgb->r = clip01(color->c[0]);
+ rgb->g = clip01(color->c[1]);
+ rgb->b = clip01(color->c[2]);
+}
+
+void GfxDeviceRGBColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ double c, m, y, k;
+
+ c = clip01(1 - color->c[0]);
+ m = clip01(1 - color->c[1]);
+ y = clip01(1 - color->c[2]);
+ k = c;
+ if (m < k) {
+ k = m;
+ }
+ if (y < k) {
+ k = y;
+ }
+ cmyk->c = c - k;
+ cmyk->m = m - k;
+ cmyk->y = y - k;
+ cmyk->k = k;
+}
+
+//------------------------------------------------------------------------
+// GfxCalRGBColorSpace
+//------------------------------------------------------------------------
+
+GfxCalRGBColorSpace::GfxCalRGBColorSpace() {
+ whiteX = whiteY = whiteZ = 1;
+ blackX = blackY = blackZ = 0;
+ gammaR = gammaG = gammaB = 1;
+ mat[0] = 1; mat[1] = 0; mat[2] = 0;
+ mat[3] = 0; mat[4] = 1; mat[5] = 0;
+ mat[6] = 0; mat[7] = 0; mat[8] = 1;
+}
+
+GfxCalRGBColorSpace::~GfxCalRGBColorSpace() {
+}
+
+GfxColorSpace *GfxCalRGBColorSpace::copy() {
+ GfxCalRGBColorSpace *cs;
+ int i;
+
+ cs = new GfxCalRGBColorSpace();
+ cs->whiteX = whiteX;
+ cs->whiteY = whiteY;
+ cs->whiteZ = whiteZ;
+ cs->blackX = blackX;
+ cs->blackY = blackY;
+ cs->blackZ = blackZ;
+ cs->gammaR = gammaR;
+ cs->gammaG = gammaG;
+ cs->gammaB = gammaB;
+ for (i = 0; i < 9; ++i) {
+ cs->mat[i] = mat[i];
+ }
+ return cs;
+}
+
+GfxColorSpace *GfxCalRGBColorSpace::parse(Array *arr) {
+ GfxCalRGBColorSpace *cs;
+ Object obj1, obj2, obj3;
+ int i;
+
+ arr->get(1, &obj1);
+ if (!obj1.isDict()) {
+ error(-1, "Bad CalRGB color space");
+ obj1.free();
+ return NULL;
+ }
+ cs = new GfxCalRGBColorSpace();
+ if (obj1.dictLookup("WhitePoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->whiteX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->whiteY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->whiteZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("BlackPoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->blackX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->blackY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->blackZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("Gamma", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->gammaR = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->gammaG = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->gammaB = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("Matrix", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 9) {
+ for (i = 0; i < 9; ++i) {
+ obj2.arrayGet(i, &obj3);
+ cs->mat[i] = obj3.getNum();
+ obj3.free();
}
- obj.free();
}
+ obj2.free();
+ obj1.free();
+ return cs;
+}
- csObj.free();
- return;
+void GfxCalRGBColorSpace::getGray(GfxColor *color, double *gray) {
+ *gray = clip01(0.299 * color->c[0] +
+ 0.587 * color->c[1] +
+ 0.114 * color->c[2]);
+}
- err2:
- obj.free();
- err1:
- csObj.free();
- ok = gFalse;
+void GfxCalRGBColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ rgb->r = clip01(color->c[0]);
+ rgb->g = clip01(color->c[1]);
+ rgb->b = clip01(color->c[2]);
}
-GfxColorSpace::GfxColorSpace(GfxColorMode mode1) {
- sepFunc = NULL;
- mode = mode1;
- indexed = gFalse;
- switch (mode) {
- case colorGray: numComps = 1; break;
- case colorCMYK: numComps = 4; break;
- case colorRGB: numComps = 3; break;
+void GfxCalRGBColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ double c, m, y, k;
+
+ c = clip01(1 - color->c[0]);
+ m = clip01(1 - color->c[1]);
+ y = clip01(1 - color->c[2]);
+ k = c;
+ if (m < k) {
+ k = m;
}
- lookup = NULL;
- ok = gTrue;
+ if (y < k) {
+ k = y;
+ }
+ cmyk->c = c - k;
+ cmyk->m = m - k;
+ cmyk->y = y - k;
+ cmyk->k = k;
}
-GfxColorSpace::~GfxColorSpace() {
- if (sepFunc)
- delete sepFunc;
- gfree(lookup);
+//------------------------------------------------------------------------
+// GfxDeviceCMYKColorSpace
+//------------------------------------------------------------------------
+
+GfxDeviceCMYKColorSpace::GfxDeviceCMYKColorSpace() {
+}
+
+GfxDeviceCMYKColorSpace::~GfxDeviceCMYKColorSpace() {
+}
+
+GfxColorSpace *GfxDeviceCMYKColorSpace::copy() {
+ 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, aw, ac, am, ay, ar, ag, ab;
+
+ /* FIXME ask Derek */
+ if (color->c[0] == 0.0 && color->c[1] == 0 && color->c[2] == 0) {
+ rgb->r = rgb->g = rgb->b = 1 - color->c[3];
+ return;
+ }
+
+ 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::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ cmyk->c = clip01(color->c[0]);
+ cmyk->m = clip01(color->c[1]);
+ cmyk->y = clip01(color->c[2]);
+ cmyk->k = clip01(color->c[3]);
+}
+
+//------------------------------------------------------------------------
+// GfxLabColorSpace
+//------------------------------------------------------------------------
+
+// This is the inverse of MatrixLMN in Example 4.10 from the PostScript
+// Language Reference, Third Edition.
+static double xyzrgb[3][3] = {
+ { 3.240449, -1.537136, -0.498531 },
+ { -0.969265, 1.876011, 0.041556 },
+ { 0.055643, -0.204026, 1.057229 }
+};
+
+GfxLabColorSpace::GfxLabColorSpace() {
+ whiteX = whiteY = whiteZ = 1;
+ blackX = blackY = blackZ = 0;
+ aMin = bMin = -100;
+ aMax = bMax = 100;
+}
+
+GfxLabColorSpace::~GfxLabColorSpace() {
+}
+
+GfxColorSpace *GfxLabColorSpace::copy() {
+ GfxLabColorSpace *cs;
+
+ cs = new GfxLabColorSpace();
+ cs->whiteX = whiteX;
+ cs->whiteY = whiteY;
+ cs->whiteZ = whiteZ;
+ cs->blackX = blackX;
+ cs->blackY = blackY;
+ cs->blackZ = blackZ;
+ cs->aMin = aMin;
+ cs->aMax = aMax;
+ cs->bMin = bMin;
+ cs->bMax = bMax;
+ cs->kr = kr;
+ cs->kg = kg;
+ cs->kb = kb;
+ return cs;
+}
+
+GfxColorSpace *GfxLabColorSpace::parse(Array *arr) {
+ GfxLabColorSpace *cs;
+ Object obj1, obj2, obj3;
+
+ arr->get(1, &obj1);
+ if (!obj1.isDict()) {
+ error(-1, "Bad Lab color space");
+ obj1.free();
+ return NULL;
+ }
+ cs = new GfxLabColorSpace();
+ if (obj1.dictLookup("WhitePoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->whiteX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->whiteY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->whiteZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("BlackPoint", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 3) {
+ obj2.arrayGet(0, &obj3);
+ cs->blackX = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->blackY = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->blackZ = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ if (obj1.dictLookup("Range", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 4) {
+ obj2.arrayGet(0, &obj3);
+ cs->aMin = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(1, &obj3);
+ cs->aMax = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2, &obj3);
+ cs->bMin = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(3, &obj3);
+ cs->bMax = obj3.getNum();
+ obj3.free();
+ }
+ obj2.free();
+ obj1.free();
+
+ cs->kr = 1 / (xyzrgb[0][0] * cs->whiteX +
+ xyzrgb[0][1] * cs->whiteY +
+ xyzrgb[0][2] * cs->whiteZ);
+ cs->kg = 1 / (xyzrgb[1][0] * cs->whiteX +
+ xyzrgb[1][1] * cs->whiteY +
+ xyzrgb[1][2] * cs->whiteZ);
+ cs->kb = 1 / (xyzrgb[2][0] * cs->whiteX +
+ xyzrgb[2][1] * cs->whiteY +
+ xyzrgb[2][2] * cs->whiteZ);
+
+ return cs;
+}
+
+void GfxLabColorSpace::getGray(GfxColor *color, double *gray) {
+ GfxRGB rgb;
+
+ getRGB(color, &rgb);
+ *gray = clip01(0.299 * rgb.r +
+ 0.587 * rgb.g +
+ 0.114 * rgb.b);
}
-GfxColorSpace::GfxColorSpace(GfxColorSpace *colorSpace) {
- int size;
-
- if (colorSpace->sepFunc)
- sepFunc = colorSpace->sepFunc->copy();
- else
- sepFunc = NULL;
- mode = colorSpace->mode;
- indexed = colorSpace->indexed;
- numComps = colorSpace->numComps;
- indexHigh = colorSpace->indexHigh;
- if (indexed) {
- size = (indexHigh + 1) * 4 * sizeof(Guchar);
- lookup = (Guchar (*)[4])gmalloc(size);
- memcpy(lookup, colorSpace->lookup, size);
+void GfxLabColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ double X, Y, Z;
+ double t1, t2;
+ 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;
+ if (t2 >= (6.0 / 29.0)) {
+ X = t2 * t2 * t2;
} else {
- lookup = NULL;
+ X = (108.0 / 841.0) * (t2 - (4.0 / 29.0));
}
- ok = gTrue;
+ X *= whiteX;
+ if (t1 >= (6.0 / 29.0)) {
+ Y = t1 * t1 * t1;
+ } else {
+ Y = (108.0 / 841.0) * (t1 - (4.0 / 29.0));
+ }
+ Y *= whiteY;
+ t2 = t1 - color->c[2] / 200;
+ if (t2 >= (6.0 / 29.0)) {
+ Z = t2 * t2 * t2;
+ } else {
+ Z = (108.0 / 841.0) * (t2 - (4.0 / 29.0));
+ }
+ Z *= whiteZ;
+
+ // convert XYZ to RGB, including gamut mapping and gamma correction
+ 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);
}
-void GfxColorSpace::setMode(Object *colorSpace) {
- Object obj;
+void GfxLabColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ GfxRGB rgb;
+ double c, m, y, k;
+
+ getRGB(color, &rgb);
+ c = clip01(1 - rgb.r);
+ m = clip01(1 - rgb.g);
+ y = clip01(1 - rgb.b);
+ k = c;
+ if (m < k) {
+ k = m;
+ }
+ if (y < k) {
+ k = y;
+ }
+ cmyk->c = c - k;
+ cmyk->m = m - k;
+ cmyk->y = y - k;
+ cmyk->k = k;
+}
- if (colorSpace->isName("DeviceGray") || colorSpace->isName("G")) {
- mode = colorGray;
- numComps = 1;
- } else if (colorSpace->isName("DeviceRGB") || colorSpace->isName("RGB")) {
- mode = colorRGB;
- numComps = 3;
- } else if (colorSpace->isName("DeviceCMYK") || colorSpace->isName("CMYK")) {
- mode = colorCMYK;
- numComps = 4;
- } else if (colorSpace->isArray()) {
- colorSpace->arrayGet(0, &obj);
- if (obj.isName("CalGray")) {
- mode = colorGray;
- numComps = 1;
- } else if (obj.isName("CalRGB")) {
- mode = colorRGB;
- numComps = 3;
- } else if (obj.isName("CalCMYK")) {
- mode = colorCMYK;
- numComps = 4;
- } else {
- ok = gFalse;
- }
- obj.free();
+void GfxLabColorSpace::getDefaultRanges(double *decodeLow, double *decodeRange,
+ int maxImgPixel) {
+ decodeLow[0] = 0;
+ decodeRange[0] = 100;
+ decodeLow[1] = aMin;
+ decodeRange[1] = aMax - aMin;
+ decodeLow[2] = bMin;
+ decodeRange[2] = bMax - bMin;
+}
+
+//------------------------------------------------------------------------
+// GfxICCBasedColorSpace
+//------------------------------------------------------------------------
+
+GfxICCBasedColorSpace::GfxICCBasedColorSpace(int nCompsA, GfxColorSpace *altA,
+ Ref *iccProfileStreamA) {
+ nComps = nCompsA;
+ alt = altA;
+ iccProfileStream = *iccProfileStreamA;
+ rangeMin[0] = rangeMin[1] = rangeMin[2] = rangeMin[3] = 0;
+ rangeMax[0] = rangeMax[1] = rangeMax[2] = rangeMax[3] = 1;
+}
+
+GfxICCBasedColorSpace::~GfxICCBasedColorSpace() {
+ delete alt;
+}
+
+GfxColorSpace *GfxICCBasedColorSpace::copy() {
+ GfxICCBasedColorSpace *cs;
+ int i;
+
+ cs = new GfxICCBasedColorSpace(nComps, alt->copy(), &iccProfileStream);
+ for (i = 0; i < 4; ++i) {
+ cs->rangeMin[i] = rangeMin[i];
+ cs->rangeMax[i] = rangeMax[i];
+ }
+ return cs;
+}
+
+GfxColorSpace *GfxICCBasedColorSpace::parse(Array *arr) {
+ GfxICCBasedColorSpace *cs;
+ Ref iccProfileStreamA;
+ int nCompsA;
+ GfxColorSpace *altA;
+ Dict *dict;
+ Object obj1, obj2, obj3;
+ int i;
+
+ arr->getNF(1, &obj1);
+ if (obj1.isRef()) {
+ iccProfileStreamA = obj1.getRef();
} else {
- ok = gFalse;
+ iccProfileStreamA.num = 0;
+ iccProfileStreamA.gen = 0;
+ }
+ obj1.free();
+ arr->get(1, &obj1);
+ if (!obj1.isStream()) {
+ error(-1, "Bad ICCBased color space (stream)");
+ obj1.free();
+ return NULL;
+ }
+ dict = obj1.streamGetDict();
+ if (!dict->lookup("N", &obj2)->isInt()) {
+ error(-1, "Bad ICCBased color space (N)");
+ obj2.free();
+ obj1.free();
+ return NULL;
+ }
+ nCompsA = obj2.getInt();
+ obj2.free();
+ if (dict->lookup("Alternate", &obj2)->isNull() ||
+ !(altA = GfxColorSpace::parse(&obj2))) {
+ switch (nCompsA) {
+ case 1:
+ altA = new GfxDeviceGrayColorSpace();
+ break;
+ case 3:
+ altA = new GfxDeviceRGBColorSpace();
+ break;
+ case 4:
+ altA = new GfxDeviceCMYKColorSpace();
+ break;
+ default:
+ error(-1, "Bad ICCBased color space - invalid N");
+ obj2.free();
+ obj1.free();
+ return NULL;
+ }
+ }
+ obj2.free();
+ cs = new GfxICCBasedColorSpace(nCompsA, altA, &iccProfileStreamA);
+ if (dict->lookup("Range", &obj2)->isArray() &&
+ obj2.arrayGetLength() == 2 * nCompsA) {
+ for (i = 0; i < nCompsA; ++i) {
+ obj2.arrayGet(2*i, &obj3);
+ cs->rangeMin[i] = obj3.getNum();
+ obj3.free();
+ obj2.arrayGet(2*i+1, &obj3);
+ cs->rangeMax[i] = obj3.getNum();
+ obj3.free();
+ }
+ }
+ obj2.free();
+ obj1.free();
+ return cs;
+}
+
+void GfxICCBasedColorSpace::getGray(GfxColor *color, double *gray) {
+ alt->getGray(color, gray);
+}
+
+void GfxICCBasedColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ alt->getRGB(color, rgb);
+}
+
+void GfxICCBasedColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ alt->getCMYK(color, cmyk);
+}
+
+void GfxICCBasedColorSpace::getDefaultRanges(double *decodeLow,
+ double *decodeRange,
+ int maxImgPixel) {
+ alt->getDefaultRanges(decodeLow, decodeRange, maxImgPixel);
+
+#if 0
+ // this is nominally correct, but some PDF files don't set the
+ // correct ranges in the ICCBased dict
+ int i;
+
+ for (i = 0; i < nComps; ++i) {
+ decodeLow[i] = rangeMin[i];
+ decodeRange[i] = rangeMax[i] - rangeMin[i];
+ }
+#endif
+}
+
+//------------------------------------------------------------------------
+// GfxIndexedColorSpace
+//------------------------------------------------------------------------
+
+GfxIndexedColorSpace::GfxIndexedColorSpace(GfxColorSpace *baseA,
+ int indexHighA) {
+ base = baseA;
+ indexHigh = indexHighA;
+ lookup = (Guchar *)gmalloc((indexHigh + 1) * base->getNComps() *
+ sizeof(Guchar));
+}
+
+GfxIndexedColorSpace::~GfxIndexedColorSpace() {
+ delete base;
+ gfree(lookup);
+}
+
+GfxColorSpace *GfxIndexedColorSpace::copy() {
+ GfxIndexedColorSpace *cs;
+
+ cs = new GfxIndexedColorSpace(base->copy(), indexHigh);
+ memcpy(cs->lookup, lookup,
+ (indexHigh + 1) * base->getNComps() * sizeof(Guchar));
+ return cs;
+}
+
+GfxColorSpace *GfxIndexedColorSpace::parse(Array *arr) {
+ GfxIndexedColorSpace *cs;
+ GfxColorSpace *baseA;
+ int indexHighA;
+ Object obj1;
+ int x;
+ char *s;
+ int n, i, j;
+
+ if (arr->getLength() != 4) {
+ error(-1, "Bad Indexed color space");
+ goto err1;
+ }
+ arr->get(1, &obj1);
+ if (!(baseA = GfxColorSpace::parse(&obj1))) {
+ error(-1, "Bad Indexed color space (base color space)");
+ goto err2;
+ }
+ obj1.free();
+ if (!arr->get(2, &obj1)->isInt()) {
+ error(-1, "Bad Indexed color space (hival)");
+ delete baseA;
+ goto err2;
+ }
+ indexHighA = obj1.getInt();
+ if (indexHighA < 0 || indexHighA > 255) {
+ // the PDF spec requires indexHigh to be in [0,255] -- allowing
+ // values larger than 255 creates a security hole: if nComps *
+ // indexHigh is greater than 2^31, the loop below may overwrite
+ // past the end of the array
+ error(-1, "Bad Indexed color space (invalid indexHigh value)");
+ delete baseA;
+ goto err2;
}
+ obj1.free();
+ cs = new GfxIndexedColorSpace(baseA, indexHighA);
+ arr->get(3, &obj1);
+ n = baseA->getNComps();
+ if (obj1.isStream()) {
+ obj1.streamReset();
+ for (i = 0; i <= indexHighA; ++i) {
+ for (j = 0; j < n; ++j) {
+ if ((x = obj1.streamGetChar()) == EOF) {
+ error(-1, "Bad Indexed color space (lookup table stream too short)");
+ goto err3;
+ }
+ cs->lookup[i*n + j] = (Guchar)x;
+ }
+ }
+ obj1.streamClose();
+ } else if (obj1.isString()) {
+ if (obj1.getString()->getLength() < (indexHighA + 1) * n) {
+ error(-1, "Bad Indexed color space (lookup table string too short)");
+ goto err3;
+ }
+ s = obj1.getString()->getCString();
+ for (i = 0; i <= indexHighA; ++i) {
+ for (j = 0; j < n; ++j) {
+ cs->lookup[i*n + j] = (Guchar)*s++;
+ }
+ }
+ } else {
+ error(-1, "Bad Indexed color space (lookup table)");
+ goto err3;
+ }
+ obj1.free();
+ return cs;
+
+ err3:
+ delete cs;
+ err2:
+ obj1.free();
+ err1:
+ return NULL;
+}
+
+GfxColor *GfxIndexedColorSpace::mapColorToBase(GfxColor *color,
+ GfxColor *baseColor) {
+ Guchar *p;
+ double low[gfxColorMaxComps], range[gfxColorMaxComps];
+ int n, i;
+
+ n = base->getNComps();
+ base->getDefaultRanges(low, range, indexHigh);
+ p = &lookup[(int)(color->c[0] + 0.5) * n];
+ for (i = 0; i < n; ++i) {
+ baseColor->c[i] = low[i] + (p[i] / 255.0) * range[i];
+ }
+ return baseColor;
+}
+
+void GfxIndexedColorSpace::getGray(GfxColor *color, double *gray) {
+ GfxColor color2;
+
+ base->getGray(mapColorToBase(color, &color2), gray);
+}
+
+void GfxIndexedColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ GfxColor color2;
+
+ base->getRGB(mapColorToBase(color, &color2), rgb);
+}
+
+void GfxIndexedColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ GfxColor color2;
+
+ base->getCMYK(mapColorToBase(color, &color2), cmyk);
+}
+
+void GfxIndexedColorSpace::getDefaultRanges(double *decodeLow,
+ double *decodeRange,
+ int maxImgPixel) {
+ decodeLow[0] = 0;
+ decodeRange[0] = maxImgPixel;
+}
+
+//------------------------------------------------------------------------
+// GfxSeparationColorSpace
+//------------------------------------------------------------------------
+
+GfxSeparationColorSpace::GfxSeparationColorSpace(GString *nameA,
+ GfxColorSpace *altA,
+ Function *funcA) {
+ name = nameA;
+ alt = altA;
+ func = funcA;
+}
+
+GfxSeparationColorSpace::~GfxSeparationColorSpace() {
+ delete name;
+ delete alt;
+ delete func;
+}
+
+GfxColorSpace *GfxSeparationColorSpace::copy() {
+ return new GfxSeparationColorSpace(name->copy(), alt->copy(), func->copy());
+}
+
+//~ handle the 'All' and 'None' colorants
+GfxColorSpace *GfxSeparationColorSpace::parse(Array *arr) {
+ GfxSeparationColorSpace *cs;
+ GString *nameA;
+ GfxColorSpace *altA;
+ Function *funcA;
+ Object obj1;
+
+ if (arr->getLength() != 4) {
+ error(-1, "Bad Separation color space");
+ goto err1;
+ }
+ if (!arr->get(1, &obj1)->isName()) {
+ error(-1, "Bad Separation color space (name)");
+ goto err2;
+ }
+ nameA = new GString(obj1.getName());
+ obj1.free();
+ arr->get(2, &obj1);
+ if (!(altA = GfxColorSpace::parse(&obj1))) {
+ error(-1, "Bad Separation color space (alternate color space)");
+ goto err3;
+ }
+ obj1.free();
+ arr->get(3, &obj1);
+ if (!(funcA = Function::parse(&obj1))) {
+ goto err4;
+ }
+ obj1.free();
+ cs = new GfxSeparationColorSpace(nameA, altA, funcA);
+ return cs;
+
+ err4:
+ delete altA;
+ err3:
+ delete nameA;
+ err2:
+ obj1.free();
+ err1:
+ return NULL;
+}
+
+void GfxSeparationColorSpace::getGray(GfxColor *color, double *gray) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getGray(&color2, gray);
+}
+
+void GfxSeparationColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getRGB(&color2, rgb);
+}
+
+void GfxSeparationColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getCMYK(&color2, cmyk);
+}
+
+//------------------------------------------------------------------------
+// GfxDeviceNColorSpace
+//------------------------------------------------------------------------
+
+GfxDeviceNColorSpace::GfxDeviceNColorSpace(int nCompsA,
+ GfxColorSpace *altA,
+ Function *funcA) {
+ nComps = nCompsA;
+ alt = altA;
+ func = funcA;
+}
+
+GfxDeviceNColorSpace::~GfxDeviceNColorSpace() {
+ int i;
+
+ for (i = 0; i < nComps; ++i) {
+ delete names[i];
+ }
+ delete alt;
+ delete func;
+}
+
+GfxColorSpace *GfxDeviceNColorSpace::copy() {
+ GfxDeviceNColorSpace *cs;
+ int i;
+
+ cs = new GfxDeviceNColorSpace(nComps, alt->copy(), func->copy());
+ for (i = 0; i < nComps; ++i) {
+ cs->names[i] = names[i]->copy();
+ }
+ return cs;
+}
+
+//~ handle the 'None' colorant
+GfxColorSpace *GfxDeviceNColorSpace::parse(Array *arr) {
+ GfxDeviceNColorSpace *cs;
+ int nCompsA;
+ GString *namesA[gfxColorMaxComps];
+ GfxColorSpace *altA;
+ Function *funcA;
+ Object obj1, obj2;
+ int i;
+
+ if (arr->getLength() != 4 && arr->getLength() != 5) {
+ error(-1, "Bad DeviceN color space");
+ goto err1;
+ }
+ if (!arr->get(1, &obj1)->isArray()) {
+ error(-1, "Bad DeviceN color space (names)");
+ goto err2;
+ }
+ nCompsA = obj1.arrayGetLength();
+ if (nCompsA > gfxColorMaxComps) {
+ error(-1, "DeviceN color space with more than %d > %d components",
+ nCompsA, gfxColorMaxComps);
+ nCompsA = gfxColorMaxComps;
+ }
+ for (i = 0; i < nCompsA; ++i) {
+ if (!obj1.arrayGet(i, &obj2)->isName()) {
+ error(-1, "Bad DeviceN color space (names)");
+ obj2.free();
+ goto err2;
+ }
+ namesA[i] = new GString(obj2.getName());
+ obj2.free();
+ }
+ obj1.free();
+ arr->get(2, &obj1);
+ if (!(altA = GfxColorSpace::parse(&obj1))) {
+ error(-1, "Bad DeviceN color space (alternate color space)");
+ goto err3;
+ }
+ obj1.free();
+ arr->get(3, &obj1);
+ if (!(funcA = Function::parse(&obj1))) {
+ goto err4;
+ }
+ obj1.free();
+ cs = new GfxDeviceNColorSpace(nCompsA, altA, funcA);
+ for (i = 0; i < nCompsA; ++i) {
+ cs->names[i] = namesA[i];
+ }
+ return cs;
+
+ err4:
+ delete altA;
+ err3:
+ for (i = 0; i < nCompsA; ++i) {
+ delete namesA[i];
+ }
+ err2:
+ obj1.free();
+ err1:
+ return NULL;
+}
+
+void GfxDeviceNColorSpace::getGray(GfxColor *color, double *gray) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getGray(&color2, gray);
+}
+
+void GfxDeviceNColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getRGB(&color2, rgb);
+}
+
+void GfxDeviceNColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ GfxColor color2;
+
+ func->transform(color->c, color2.c);
+ alt->getCMYK(&color2, cmyk);
+}
+
+//------------------------------------------------------------------------
+// GfxPatternColorSpace
+//------------------------------------------------------------------------
+
+GfxPatternColorSpace::GfxPatternColorSpace(GfxColorSpace *underA) {
+ under = underA;
+}
+
+GfxPatternColorSpace::~GfxPatternColorSpace() {
+ if (under) {
+ delete under;
+ }
+}
+
+GfxColorSpace *GfxPatternColorSpace::copy() {
+ return new GfxPatternColorSpace(under ? under->copy() :
+ (GfxColorSpace *)NULL);
+}
+
+GfxColorSpace *GfxPatternColorSpace::parse(Array *arr) {
+ GfxPatternColorSpace *cs;
+ GfxColorSpace *underA;
+ Object obj1;
+
+ if (arr->getLength() != 1 && arr->getLength() != 2) {
+ error(-1, "Bad Pattern color space");
+ return NULL;
+ }
+ underA = NULL;
+ if (arr->getLength() == 2) {
+ arr->get(1, &obj1);
+ if (!(underA = GfxColorSpace::parse(&obj1))) {
+ error(-1, "Bad Pattern color space (underlying color space)");
+ obj1.free();
+ return NULL;
+ }
+ obj1.free();
+ }
+ cs = new GfxPatternColorSpace(underA);
+ return cs;
+}
+
+void GfxPatternColorSpace::getGray(GfxColor *color, double *gray) {
+ *gray = 0;
+}
+
+void GfxPatternColorSpace::getRGB(GfxColor *color, GfxRGB *rgb) {
+ rgb->r = rgb->g = rgb->b = 0;
+}
+
+void GfxPatternColorSpace::getCMYK(GfxColor *color, GfxCMYK *cmyk) {
+ cmyk->c = cmyk->m = cmyk->y = 0;
+ cmyk->k = 1;
+}
+
+//------------------------------------------------------------------------
+// Pattern
+//------------------------------------------------------------------------
+
+GfxPattern::GfxPattern(int typeA) {
+ type = typeA;
+}
+
+GfxPattern::~GfxPattern() {
+}
+
+GfxPattern *GfxPattern::parse(Object *obj) {
+ GfxPattern *pattern;
+ Object obj1;
+
+ if (obj->isDict()) {
+ obj->dictLookup("PatternType", &obj1);
+ } else if (obj->isStream()) {
+ obj->streamGetDict()->lookup("PatternType", &obj1);
+ } else {
+ return NULL;
+ }
+ pattern = NULL;
+ if (obj1.isInt() && obj1.getInt() == 1) {
+ pattern = GfxTilingPattern::parse(obj);
+ } else if (obj1.isInt() && obj1.getInt() == 2) {
+ pattern = GfxShadingPattern::parse(obj);
+ }
+ obj1.free();
+ return pattern;
+}
+
+//------------------------------------------------------------------------
+// GfxTilingPattern
+//------------------------------------------------------------------------
+
+GfxTilingPattern *GfxTilingPattern::parse(Object *patObj) {
+ GfxTilingPattern *pat;
+ Dict *dict;
+ int paintTypeA, tilingTypeA;
+ double bboxA[4], matrixA[6];
+ double xStepA, yStepA;
+ Object resDictA;
+ Object obj1, obj2;
+ int i;
+
+ if (!patObj->isStream()) {
+ return NULL;
+ }
+ dict = patObj->streamGetDict();
+
+ if (dict->lookup("PaintType", &obj1)->isInt()) {
+ paintTypeA = obj1.getInt();
+ } else {
+ paintTypeA = 1;
+ error(-1, "Invalid or missing PaintType in pattern");
+ }
+ obj1.free();
+ if (dict->lookup("TilingType", &obj1)->isInt()) {
+ tilingTypeA = obj1.getInt();
+ } else {
+ tilingTypeA = 1;
+ error(-1, "Invalid or missing TilingType in pattern");
+ }
+ obj1.free();
+ bboxA[0] = bboxA[1] = 0;
+ bboxA[2] = bboxA[3] = 1;
+ if (dict->lookup("BBox", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 4) {
+ for (i = 0; i < 4; ++i) {
+ if (obj1.arrayGet(i, &obj2)->isNum()) {
+ bboxA[i] = obj2.getNum();
+ }
+ obj2.free();
+ }
+ } else {
+ error(-1, "Invalid or missing BBox in pattern");
+ }
+ obj1.free();
+ if (dict->lookup("XStep", &obj1)->isNum()) {
+ xStepA = obj1.getNum();
+ } else {
+ xStepA = 1;
+ error(-1, "Invalid or missing XStep in pattern");
+ }
+ obj1.free();
+ if (dict->lookup("YStep", &obj1)->isNum()) {
+ yStepA = obj1.getNum();
+ } else {
+ yStepA = 1;
+ error(-1, "Invalid or missing YStep in pattern");
+ }
+ obj1.free();
+ if (!dict->lookup("Resources", &resDictA)->isDict()) {
+ resDictA.free();
+ resDictA.initNull();
+ error(-1, "Invalid or missing Resources in pattern");
+ }
+ matrixA[0] = 1; matrixA[1] = 0;
+ matrixA[2] = 0; matrixA[3] = 1;
+ matrixA[4] = 0; matrixA[5] = 0;
+ if (dict->lookup("Matrix", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 6) {
+ for (i = 0; i < 6; ++i) {
+ if (obj1.arrayGet(i, &obj2)->isNum()) {
+ matrixA[i] = obj2.getNum();
+ }
+ obj2.free();
+ }
+ }
+ obj1.free();
+
+ pat = new GfxTilingPattern(paintTypeA, tilingTypeA, bboxA, xStepA, yStepA,
+ &resDictA, matrixA, patObj);
+ resDictA.free();
+ return pat;
+}
+
+GfxTilingPattern::GfxTilingPattern(int paintTypeA, int tilingTypeA,
+ double *bboxA, double xStepA, double yStepA,
+ Object *resDictA, double *matrixA,
+ Object *contentStreamA):
+ GfxPattern(1)
+{
+ int i;
+
+ paintType = paintTypeA;
+ tilingType = tilingTypeA;
+ for (i = 0; i < 4; ++i) {
+ bbox[i] = bboxA[i];
+ }
+ xStep = xStepA;
+ yStep = yStepA;
+ resDictA->copy(&resDict);
+ for (i = 0; i < 6; ++i) {
+ matrix[i] = matrixA[i];
+ }
+ contentStreamA->copy(&contentStream);
+}
+
+GfxTilingPattern::~GfxTilingPattern() {
+ resDict.free();
+ contentStream.free();
+}
+
+GfxPattern *GfxTilingPattern::copy() {
+ return new GfxTilingPattern(paintType, tilingType, bbox, xStep, yStep,
+ &resDict, matrix, &contentStream);
+}
+
+//------------------------------------------------------------------------
+// GfxShadingPattern
+//------------------------------------------------------------------------
+
+GfxShadingPattern *GfxShadingPattern::parse(Object *patObj) {
+ Dict *dict;
+ GfxShading *shadingA;
+ double matrixA[6];
+ Object obj1, obj2;
+ int i;
+
+ if (!patObj->isDict()) {
+ return NULL;
+ }
+ dict = patObj->getDict();
+
+ dict->lookup("Shading", &obj1);
+ shadingA = GfxShading::parse(&obj1);
+ obj1.free();
+ if (!shadingA) {
+ return NULL;
+ }
+
+ matrixA[0] = 1; matrixA[1] = 0;
+ matrixA[2] = 0; matrixA[3] = 1;
+ matrixA[4] = 0; matrixA[5] = 0;
+ if (dict->lookup("Matrix", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 6) {
+ for (i = 0; i < 6; ++i) {
+ if (obj1.arrayGet(i, &obj2)->isNum()) {
+ matrixA[i] = obj2.getNum();
+ }
+ obj2.free();
+ }
+ }
+ obj1.free();
+
+ return new GfxShadingPattern(shadingA, matrixA);
+}
+
+GfxShadingPattern::GfxShadingPattern(GfxShading *shadingA, double *matrixA):
+ GfxPattern(2)
+{
+ int i;
+
+ shading = shadingA;
+ for (i = 0; i < 6; ++i) {
+ matrix[i] = matrixA[i];
+ }
+}
+
+GfxShadingPattern::~GfxShadingPattern() {
+ delete shading;
+}
+
+GfxPattern *GfxShadingPattern::copy() {
+ return new GfxShadingPattern(shading->copy(), matrix);
+}
+
+//------------------------------------------------------------------------
+// GfxShading
+//------------------------------------------------------------------------
+
+GfxShading::GfxShading(int typeA) {
+ type = typeA;
+ colorSpace = NULL;
+}
+
+GfxShading::GfxShading(GfxShading *shading) {
+ int i;
+
+ type = shading->type;
+ colorSpace = shading->colorSpace->copy();
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ background.c[i] = shading->background.c[i];
+ }
+ hasBackground = shading->hasBackground;
+ xMin = shading->xMin;
+ yMin = shading->yMin;
+ xMax = shading->xMax;
+ yMax = shading->yMax;
+ hasBBox = shading->hasBBox;
+}
+
+GfxShading::~GfxShading() {
+ if (colorSpace) {
+ delete colorSpace;
+ }
+}
+
+GfxShading *GfxShading::parse(Object *obj) {
+ GfxShading *shading;
+ Dict *dict;
+ int typeA;
+ Object obj1;
+
+ if (obj->isDict()) {
+ dict = obj->getDict();
+ } else if (obj->isStream()) {
+ dict = obj->streamGetDict();
+ } else {
+ return NULL;
+ }
+
+ if (!dict->lookup("ShadingType", &obj1)->isInt()) {
+ error(-1, "Invalid ShadingType in shading dictionary");
+ obj1.free();
+ return NULL;
+ }
+ typeA = obj1.getInt();
+ obj1.free();
+
+ switch (typeA) {
+ case 1:
+ shading = GfxFunctionShading::parse(dict);
+ break;
+ case 2:
+ shading = GfxAxialShading::parse(dict);
+ break;
+ case 3:
+ shading = GfxRadialShading::parse(dict);
+ break;
+ default:
+ error(-1, "Unimplemented shading type %d", typeA);
+ goto err1;
+ }
+
+ return shading;
+
+ err1:
+ return NULL;
+}
+
+GBool GfxShading::init(Dict *dict) {
+ Object obj1, obj2;
+ int i;
+
+ dict->lookup("ColorSpace", &obj1);
+ if (!(colorSpace = GfxColorSpace::parse(&obj1))) {
+ error(-1, "Bad color space in shading dictionary");
+ obj1.free();
+ return gFalse;
+ }
+ obj1.free();
+
+ for (i = 0; i < gfxColorMaxComps; ++i) {
+ background.c[i] = 0;
+ }
+ hasBackground = gFalse;
+ if (dict->lookup("Background", &obj1)->isArray()) {
+ if (obj1.arrayGetLength() == colorSpace->getNComps()) {
+ hasBackground = gTrue;
+ for (i = 0; i < colorSpace->getNComps(); ++i) {
+ background.c[i] = obj1.arrayGet(i, &obj2)->getNum();
+ obj2.free();
+ }
+ } else {
+ error(-1, "Bad Background in shading dictionary");
+ }
+ }
+ obj1.free();
+
+ xMin = yMin = xMax = yMax = 0;
+ hasBBox = gFalse;
+ if (dict->lookup("BBox", &obj1)->isArray()) {
+ if (obj1.arrayGetLength() == 4) {
+ hasBBox = gTrue;
+ xMin = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ yMin = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ xMax = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ yMax = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ } else {
+ error(-1, "Bad BBox in shading dictionary");
+ }
+ }
+ obj1.free();
+
+ return gTrue;
+}
+
+//------------------------------------------------------------------------
+// GfxFunctionShading
+//------------------------------------------------------------------------
+
+GfxFunctionShading::GfxFunctionShading(double x0A, double y0A,
+ double x1A, double y1A,
+ double *matrixA,
+ Function **funcsA, int nFuncsA):
+ GfxShading(1)
+{
+ int i;
+
+ x0 = x0A;
+ y0 = y0A;
+ x1 = x1A;
+ y1 = y1A;
+ for (i = 0; i < 6; ++i) {
+ matrix[i] = matrixA[i];
+ }
+ nFuncs = nFuncsA;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = funcsA[i];
+ }
+}
+
+GfxFunctionShading::GfxFunctionShading(GfxFunctionShading *shading):
+ GfxShading(shading)
+{
+ int i;
+
+ x0 = shading->x0;
+ y0 = shading->y0;
+ x1 = shading->x1;
+ y1 = shading->y1;
+ for (i = 0; i < 6; ++i) {
+ matrix[i] = shading->matrix[i];
+ }
+ nFuncs = shading->nFuncs;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = shading->funcs[i]->copy();
+ }
+}
+
+GfxFunctionShading::~GfxFunctionShading() {
+ int i;
+
+ for (i = 0; i < nFuncs; ++i) {
+ delete funcs[i];
+ }
+}
+
+GfxFunctionShading *GfxFunctionShading::parse(Dict *dict) {
+ GfxFunctionShading *shading;
+ double x0A, y0A, x1A, y1A;
+ double matrixA[6];
+ Function *funcsA[gfxColorMaxComps];
+ int nFuncsA;
+ Object obj1, obj2;
+ int i;
+
+ x0A = y0A = 0;
+ x1A = y1A = 1;
+ if (dict->lookup("Domain", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 4) {
+ x0A = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ y0A = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ x1A = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ y1A = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ }
+ obj1.free();
+
+ matrixA[0] = 1; matrixA[1] = 0;
+ matrixA[2] = 0; matrixA[3] = 1;
+ matrixA[4] = 0; matrixA[5] = 0;
+ if (dict->lookup("Matrix", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 6) {
+ matrixA[0] = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ matrixA[1] = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ matrixA[2] = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ matrixA[3] = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ matrixA[4] = obj1.arrayGet(4, &obj2)->getNum();
+ obj2.free();
+ matrixA[5] = obj1.arrayGet(5, &obj2)->getNum();
+ obj2.free();
+ }
+ obj1.free();
+
+ dict->lookup("Function", &obj1);
+ 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))) {
+ goto err2;
+ }
+ obj2.free();
+ }
+ } else {
+ nFuncsA = 1;
+ if (!(funcsA[0] = Function::parse(&obj1))) {
+ goto err1;
+ }
+ }
+ obj1.free();
+
+ shading = new GfxFunctionShading(x0A, y0A, x1A, y1A, matrixA,
+ funcsA, nFuncsA);
+ if (!shading->init(dict)) {
+ delete shading;
+ return NULL;
+ }
+ return shading;
+
+ err2:
+ obj2.free();
+ err1:
+ obj1.free();
+ return NULL;
+}
+
+GfxShading *GfxFunctionShading::copy() {
+ return new GfxFunctionShading(this);
+}
+
+void GfxFunctionShading::getColor(double x, double y, GfxColor *color) {
+ double in[2];
+ int i;
+
+ in[0] = x;
+ in[1] = y;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i]->transform(in, &color->c[i]);
+ }
+}
+
+//------------------------------------------------------------------------
+// GfxAxialShading
+//------------------------------------------------------------------------
+
+GfxAxialShading::GfxAxialShading(double x0A, double y0A,
+ double x1A, double y1A,
+ double t0A, double t1A,
+ Function **funcsA, int nFuncsA,
+ GBool extend0A, GBool extend1A):
+ GfxShading(2)
+{
+ int i;
+
+ x0 = x0A;
+ y0 = y0A;
+ x1 = x1A;
+ y1 = y1A;
+ t0 = t0A;
+ t1 = t1A;
+ nFuncs = nFuncsA;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = funcsA[i];
+ }
+ extend0 = extend0A;
+ extend1 = extend1A;
+}
+
+GfxAxialShading::GfxAxialShading(GfxAxialShading *shading):
+ GfxShading(shading)
+{
+ int i;
+
+ x0 = shading->x0;
+ y0 = shading->y0;
+ x1 = shading->x1;
+ y1 = shading->y1;
+ t0 = shading->t0;
+ y1 = shading->t1;
+ nFuncs = shading->nFuncs;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = shading->funcs[i]->copy();
+ }
+ extend0 = shading->extend0;
+ extend1 = shading->extend1;
+}
+
+GfxAxialShading::~GfxAxialShading() {
+ int i;
+
+ for (i = 0; i < nFuncs; ++i) {
+ delete funcs[i];
+ }
+}
+
+GfxAxialShading *GfxAxialShading::parse(Dict *dict) {
+ GfxAxialShading *shading;
+ double x0A, y0A, x1A, y1A;
+ double t0A, t1A;
+ Function *funcsA[gfxColorMaxComps];
+ int nFuncsA;
+ GBool extend0A, extend1A;
+ Object obj1, obj2;
+ int i;
+
+ x0A = y0A = x1A = y1A = 0;
+ if (dict->lookup("Coords", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 4) {
+ x0A = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ y0A = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ x1A = obj1.arrayGet(2, &obj2)->getNum();
+ obj2.free();
+ y1A = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ } else {
+ error(-1, "Missing or invalid Coords in shading dictionary");
+ goto err1;
+ }
+ obj1.free();
+
+ t0A = 0;
+ t1A = 1;
+ if (dict->lookup("Domain", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 2) {
+ t0A = obj1.arrayGet(0, &obj2)->getNum();
+ obj2.free();
+ t1A = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ }
+ obj1.free();
+
+ dict->lookup("Function", &obj1);
+ 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;
+ }
+ }
+ obj1.free();
+
+ extend0A = extend1A = gFalse;
+ if (dict->lookup("Extend", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 2) {
+ extend0A = obj1.arrayGet(0, &obj2)->getBool();
+ obj2.free();
+ extend1A = obj1.arrayGet(1, &obj2)->getBool();
+ obj2.free();
+ }
+ obj1.free();
+
+ shading = new GfxAxialShading(x0A, y0A, x1A, y1A, t0A, t1A,
+ funcsA, nFuncsA, extend0A, extend1A);
+ if (!shading->init(dict)) {
+ delete shading;
+ return NULL;
+ }
+ return shading;
+
+ err1:
+ return NULL;
}
-void GfxColorSpace::getColor(double x[4], GfxColor *color) {
- double y[4];
- Guchar *p;
+GfxShading *GfxAxialShading::copy() {
+ return new GfxAxialShading(this);
+}
- if (sepFunc) {
- sepFunc->transform(x, y);
- } else {
- y[0] = x[0];
- y[1] = x[1];
- y[2] = x[2];
- y[3] = x[3];
- }
- if (indexed) {
- p = lookup[(int)(y[0] + 0.5)];
- switch (mode) {
- case colorGray:
- color->setGray(p[0] / 255.0);
- break;
- case colorCMYK:
- color->setCMYK(p[0] / 255.0, p[1] / 255.0, p[2] / 255.0, p[3] / 255.0);
- break;
- case colorRGB:
- color->setRGB(p[0] / 255.0, p[1] / 255.0, p[2] / 255.0);
- break;
- }
- } else {
- switch (mode) {
- case colorGray:
- color->setGray(y[0]);
- break;
- case colorCMYK:
- color->setCMYK(y[0], y[1], y[2], y[3]);
- break;
- case colorRGB:
- color->setRGB(y[0], y[1], y[2]);
- break;
- }
+void GfxAxialShading::getColor(double t, GfxColor *color) {
+ 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 < nFuncs; ++i) {
+ funcs[i]->transform(&t, &color->c[i]);
}
}
//------------------------------------------------------------------------
-// Function
+// GfxRadialShading
//------------------------------------------------------------------------
-Function::Function(Object *funcObj) {
- Stream *str;
- Dict *dict;
- int nSamples, sampleBits;
- double sampleMul;
- Object obj1, obj2;
- Guint buf, bitMask;
- int bits;
- int s;
+GfxRadialShading::GfxRadialShading(double x0A, double y0A, double r0A,
+ double x1A, double y1A, double r1A,
+ double t0A, double t1A,
+ Function **funcsA, int nFuncsA,
+ GBool extend0A, GBool extend1A):
+ GfxShading(3)
+{
int i;
- ok = gFalse;
- samples = NULL;
-
- if (!funcObj->isStream()) {
- error(-1, "Expected function dictionary");
- goto err3;
+ x0 = x0A;
+ y0 = y0A;
+ r0 = r0A;
+ x1 = x1A;
+ y1 = y1A;
+ r1 = r1A;
+ t0 = t0A;
+ t1 = t1A;
+ nFuncs = nFuncsA;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = funcsA[i];
}
- str = funcObj->getStream();
- dict = str->getDict();
+ extend0 = extend0A;
+ extend1 = extend1A;
+}
- //----- FunctionType
- if (!dict->lookup("FunctionType", &obj1)->isInt() ||
- obj1.getInt() != 0) {
- error(-1, "Unknown function type");
- goto err2;
- }
- obj1.free();
+GfxRadialShading::GfxRadialShading(GfxRadialShading *shading):
+ GfxShading(shading)
+{
+ int i;
- //----- Domain
- if (!dict->lookup("Domain", &obj1)->isArray()) {
- error(-1, "Function is missing domain");
- goto err2;
+ x0 = shading->x0;
+ y0 = shading->y0;
+ r0 = shading->r0;
+ x1 = shading->x1;
+ y1 = shading->y1;
+ r1 = shading->r1;
+ t0 = shading->t0;
+ y1 = shading->t1;
+ nFuncs = shading->nFuncs;
+ for (i = 0; i < nFuncs; ++i) {
+ funcs[i] = shading->funcs[i]->copy();
}
- m = obj1.arrayGetLength() / 2;
- if (m > 4) {
- error(-1, "Functions with more than 1 input are unsupported");
- goto err2;
+ extend0 = shading->extend0;
+ extend1 = shading->extend1;
+}
+
+GfxRadialShading::~GfxRadialShading() {
+ int i;
+
+ for (i = 0; i < nFuncs; ++i) {
+ delete funcs[i];
}
- for (i = 0; i < m; ++i) {
- obj1.arrayGet(2*i, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function domain array");
- goto err1;
- }
- domain[i][0] = obj2.getNum();
+}
+
+GfxRadialShading *GfxRadialShading::parse(Dict *dict) {
+ GfxRadialShading *shading;
+ double x0A, y0A, r0A, x1A, y1A, r1A;
+ double t0A, t1A;
+ Function *funcsA[gfxColorMaxComps];
+ int nFuncsA;
+ GBool extend0A, extend1A;
+ Object obj1, obj2;
+ int i;
+
+ x0A = y0A = r0A = x1A = y1A = r1A = 0;
+ if (dict->lookup("Coords", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 6) {
+ x0A = obj1.arrayGet(0, &obj2)->getNum();
obj2.free();
- obj1.arrayGet(2*i+1, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function domain array");
- goto err1;
- }
- domain[i][1] = obj2.getNum();
+ y0A = obj1.arrayGet(1, &obj2)->getNum();
+ obj2.free();
+ r0A = obj1.arrayGet(2, &obj2)->getNum();
obj2.free();
+ x1A = obj1.arrayGet(3, &obj2)->getNum();
+ obj2.free();
+ y1A = obj1.arrayGet(4, &obj2)->getNum();
+ obj2.free();
+ r1A = obj1.arrayGet(5, &obj2)->getNum();
+ obj2.free();
+ } else {
+ error(-1, "Missing or invalid Coords in shading dictionary");
+ goto err1;
}
obj1.free();
- //----- Range
- if (!dict->lookup("Range", &obj1)->isArray()) {
- error(-1, "Function is missing range");
- goto err2;
- }
- n = obj1.arrayGetLength() / 2;
- if (n > 4) {
- error(-1, "Functions with more than 4 outputs are unsupported");
- goto err2;
- }
- for (i = 0; i < n; ++i) {
- obj1.arrayGet(2*i, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function range array");
- goto err1;
- }
- range[i][0] = obj2.getNum();
+ t0A = 0;
+ t1A = 1;
+ if (dict->lookup("Domain", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 2) {
+ t0A = obj1.arrayGet(0, &obj2)->getNum();
obj2.free();
- obj1.arrayGet(2*i+1, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function range array");
- goto err1;
- }
- range[i][1] = obj2.getNum();
+ t1A = obj1.arrayGet(1, &obj2)->getNum();
obj2.free();
}
obj1.free();
- //----- Size
- if (!dict->lookup("Size", &obj1)->isArray() ||
- obj1.arrayGetLength() != m) {
- error(-1, "Function has missing or invalid size array");
- goto err2;
- }
- for (i = 0; i < m; ++i) {
- obj1.arrayGet(i, &obj2);
- if (!obj2.isInt()) {
- error(-1, "Illegal value in function size array");
+ dict->lookup("Function", &obj1);
+ if (obj1.isArray()) {
+ nFuncsA = obj1.arrayGetLength();
+ if (nFuncsA > gfxColorMaxComps) {
+ error(-1, "Invalid Function array in shading dictionary");
goto err1;
}
- sampleSize[i] = obj2.getInt();
- obj2.free();
- }
- obj1.free();
-
- //----- BitsPerSample
- if (!dict->lookup("BitsPerSample", &obj1)->isInt()) {
- error(-1, "Function has missing or invalid BitsPerSample");
- goto err2;
- }
- sampleBits = obj1.getInt();
- sampleMul = 1.0 / (double)((1 << sampleBits) - 1);
- obj1.free();
-
- //----- Encode
- if (dict->lookup("Encode", &obj1)->isArray() &&
- obj1.arrayGetLength() == 2*m) {
- for (i = 0; i < m; ++i) {
- obj1.arrayGet(2*i, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function encode array");
+ for (i = 0; i < nFuncsA; ++i) {
+ obj1.arrayGet(i, &obj2);
+ if (!(funcsA[i] = Function::parse(&obj2))) {
+ obj1.free();
+ obj2.free();
goto err1;
}
- encode[i][0] = obj2.getNum();
- obj2.free();
- obj1.arrayGet(2*i+1, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function encode array");
- goto err1;
- }
- encode[i][1] = obj2.getNum();
obj2.free();
}
} else {
- for (i = 0; i < m; ++i) {
- encode[i][0] = 0;
- encode[i][1] = sampleSize[i] - 1;
+ nFuncsA = 1;
+ if (!(funcsA[0] = Function::parse(&obj1))) {
+ obj1.free();
+ goto err1;
}
}
obj1.free();
- //----- Decode
- if (dict->lookup("Decode", &obj1)->isArray() &&
- obj1.arrayGetLength() == 2*n) {
- for (i = 0; i < n; ++i) {
- obj1.arrayGet(2*i, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function decode array");
- goto err1;
- }
- decode[i][0] = obj2.getNum();
- obj2.free();
- obj1.arrayGet(2*i+1, &obj2);
- if (!obj2.isNum()) {
- error(-1, "Illegal value in function decode array");
- goto err1;
- }
- decode[i][1] = obj2.getNum();
- obj2.free();
- }
- } else {
- for (i = 0; i < n; ++i) {
- decode[i][0] = range[i][0];
- decode[i][1] = range[i][1];
- }
- }
- obj1.free();
-
- //----- samples
- nSamples = n;
- for (i = 0; i < m; ++i)
- nSamples *= sampleSize[i];
- samples = (double *)gmalloc(nSamples * sizeof(double));
- buf = 0;
- bits = 0;
- bitMask = (1 << sampleBits) - 1;
- str->reset();
- for (i = 0; i < nSamples; ++i) {
- if (sampleBits == 8) {
- s = str->getChar();
- } else if (sampleBits == 16) {
- s = str->getChar();
- s = (s << 8) + str->getChar();
- } else if (sampleBits == 32) {
- s = str->getChar();
- s = (s << 8) + str->getChar();
- s = (s << 8) + str->getChar();
- s = (s << 8) + str->getChar();
- } else {
- while (bits < sampleBits) {
- buf = (buf << 8) | (str->getChar() & 0xff);
- bits += 8;
- }
- s = (buf >> (bits - sampleBits)) & bitMask;
- bits -= sampleBits;
- }
- samples[i] = (double)s * sampleMul;
+ extend0A = extend1A = gFalse;
+ if (dict->lookup("Extend", &obj1)->isArray() &&
+ obj1.arrayGetLength() == 2) {
+ extend0A = obj1.arrayGet(0, &obj2)->getBool();
+ obj2.free();
+ extend1A = obj1.arrayGet(1, &obj2)->getBool();
+ obj2.free();
}
-
- ok = gTrue;
- return;
-
- err1:
- obj2.free();
- err2:
obj1.free();
- err3:
- return;
-}
-
-Function::Function(Function *func) {
- int nSamples, i;
- m = func->m;
- n = func->n;
- memcpy(domain, func->domain, sizeof(domain));
- memcpy(range, func->range, sizeof(range));
- memcpy(sampleSize, func->sampleSize, sizeof(sampleSize));
- memcpy(encode, func->encode, sizeof(encode));
- memcpy(decode, func->decode, sizeof(decode));
-
- nSamples = n;
- for (i = 0; i < m; ++i)
- nSamples *= sampleSize[i];
- samples = (double *)gmalloc(nSamples * sizeof(double));
- memcpy(samples, func->samples, nSamples * sizeof(double));
+ shading = new GfxRadialShading(x0A, y0A, r0A, x1A, y1A, r1A, t0A, t1A,
+ funcsA, nFuncsA, extend0A, extend1A);
+ if (!shading->init(dict)) {
+ delete shading;
+ return NULL;
+ }
+ return shading;
- ok = gTrue;
+ err1:
+ return NULL;
}
-Function::~Function() {
- if (samples)
- gfree(samples);
+GfxShading *GfxRadialShading::copy() {
+ return new GfxRadialShading(this);
}
-void Function::transform(double *in, double *out) {
- double e[4];
- double s;
- double x0, x1;
- int e0, e1;
- double efrac;
+void GfxRadialShading::getColor(double t, GfxColor *color) {
int i;
- // map input values into sample array
- for (i = 0; i < m; ++i) {
- e[i] = ((in[i] - domain[i][0]) / (domain[i][1] - domain[i][0])) *
- (encode[i][1] - encode[i][0]) + encode[i][0];
- if (e[i] < 0)
- e[i] = 0;
- else if (e[i] > sampleSize[i] - 1)
- e[i] = sampleSize[i] - 1;
- }
-
- for (i = 0; i < n; ++i) {
-
- // m-linear interpolation
- // (only m=1 is currently supported)
- e0 = (int)floor(e[0]);
- e1 = (int)ceil(e[0]);
- efrac = e[0] - e0;
- x0 = samples[e0 * n + i];
- x1 = samples[e1 * n + i];
- s = (1 - efrac) * x0 + efrac * x1;
-
- // map output values to range
- out[i] = s * (decode[i][1] - decode[i][0]) + decode[i][0];
- if (out[i] < range[i][0])
- out[i] = range[i][0];
- else if (out[i] > range[i][1])
- out[i] = range[i][1];
+ // 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 < nFuncs; ++i) {
+ funcs[i]->transform(&t, &color->c[i]);
}
}
// GfxImageColorMap
//------------------------------------------------------------------------
-GfxImageColorMap::GfxImageColorMap(int bits1, Object *decode,
- GfxColorSpace *colorSpace1) {
- GfxColor color;
- double x[4];
- int maxPixel;
+GfxImageColorMap::GfxImageColorMap(int bitsA, Object *decode,
+ GfxColorSpace *colorSpaceA) {
+ GfxIndexedColorSpace *indexedCS;
+ GfxSeparationColorSpace *sepCS;
+ int maxPixel, indexHigh;
+ Guchar *lookup2;
+ Function *sepFunc;
Object obj;
- int i, j;
+ double x[gfxColorMaxComps];
+ double y[gfxColorMaxComps];
+ int i, j, k;
ok = gTrue;
- // bits per component and colorspace
- bits = bits1;
+ // bits per component and color space
+ bits = bitsA;
maxPixel = (1 << bits) - 1;
- colorSpace = colorSpace1;
- mode = colorSpace->getMode();
-
- // work around a bug in Distiller (?)
- if (colorSpace->isIndexed() && maxPixel > colorSpace->getIndexHigh()) {
- maxPixel = colorSpace->getIndexHigh();
- }
+ colorSpace = colorSpaceA;
// get decode map
if (decode->isNull()) {
- if (colorSpace->isIndexed()) {
- indexed = gTrue;
- numComps = 1;
- decodeLow[0] = 0;
- decodeRange[0] = maxPixel;
- } else {
- indexed = gFalse;
- numComps = colorSpace->getNumPixelComps();
- for (i = 0; i < numComps; ++i) {
- decodeLow[i] = 0;
- decodeRange[i] = 1;
- }
- }
+ nComps = colorSpace->getNComps();
+ colorSpace->getDefaultRanges(decodeLow, decodeRange, maxPixel);
} else if (decode->isArray()) {
- numComps = decode->arrayGetLength() / 2;
- if (numComps != colorSpace->getNumPixelComps())
+ nComps = decode->arrayGetLength() / 2;
+ if (nComps != colorSpace->getNComps()) {
goto err1;
- indexed = colorSpace->isIndexed();
- for (i = 0; i < numComps; ++i) {
+ }
+ for (i = 0; i < nComps; ++i) {
decode->arrayGet(2*i, &obj);
- if (!obj.isNum())
+ if (!obj.isNum()) {
goto err2;
+ }
decodeLow[i] = obj.getNum();
obj.free();
decode->arrayGet(2*i+1, &obj);
- if (!obj.isNum())
+ if (!obj.isNum()) {
goto err2;
+ }
decodeRange[i] = obj.getNum() - decodeLow[i];
obj.free();
}
goto err1;
}
- // construct lookup table
- lookup = (double (*)[4])gmalloc((maxPixel + 1) * 4 * sizeof(double));
- if (indexed) {
+ // Construct a lookup table -- this stores pre-computed decoded
+ // values for each component, i.e., the result of applying the
+ // decode mapping to each possible image pixel component value.
+ //
+ // Optimization: for Indexed and Separation color spaces (which have
+ // only one component), we store color values in the lookup table
+ // rather than component values.
+ colorSpace2 = NULL;
+ nComps2 = 0;
+ if (colorSpace->getMode() == csIndexed) {
+ // Note that indexHigh may not be the same as maxPixel --
+ // Distiller will remove unused palette entries, resulting in
+ // indexHigh < maxPixel.
+ indexedCS = (GfxIndexedColorSpace *)colorSpace;
+ colorSpace2 = indexedCS->getBase();
+ indexHigh = indexedCS->getIndexHigh();
+ nComps2 = colorSpace2->getNComps();
+ lookup = (double *)gmalloc((maxPixel + 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];
+ }
+ }
+ } else if (colorSpace->getMode() == csSeparation) {
+ sepCS = (GfxSeparationColorSpace *)colorSpace;
+ colorSpace2 = sepCS->getAlt();
+ nComps2 = colorSpace2->getNComps();
+ lookup = (double *)gmalloc((maxPixel + 1) * nComps2 * sizeof(double));
+ sepFunc = sepCS->getFunc();
for (i = 0; i <= maxPixel; ++i) {
- x[0] = (double)i;
- colorSpace->getColor(x, &color);
- lookup[i][0] = color.getR();
- lookup[i][1] = color.getG();
- lookup[i][2] = color.getB();
+ x[0] = decodeLow[0] + (i * decodeRange[0]) / maxPixel;
+ sepFunc->transform(x, y);
+ for (k = 0; k < nComps2; ++k) {
+ lookup[i*nComps2 + k] = y[k];
+ }
}
} else {
- for (i = 0; i <= maxPixel; ++i)
- for (j = 0; j < numComps; ++j)
- lookup[i][j] = decodeLow[j] + (i * decodeRange[j]) / maxPixel;
+ lookup = (double *)gmalloc((maxPixel + 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;
+ }
+ }
}
return;
ok = gFalse;
}
+GfxImageColorMap::GfxImageColorMap(GfxImageColorMap *colorMap) {
+ int n, i;
+
+ colorSpace = colorMap->colorSpace->copy();
+ bits = colorMap->bits;
+ nComps = colorMap->nComps;
+ nComps2 = colorMap->nComps2;
+ colorSpace2 = NULL;
+ lookup = NULL;
+ n = 1 << bits;
+ if (colorSpace->getMode() == csIndexed) {
+ colorSpace2 = ((GfxIndexedColorSpace *)colorSpace)->getBase();
+ n = n * nComps2 * sizeof(double);
+ } else if (colorSpace->getMode() == csSeparation) {
+ colorSpace2 = ((GfxSeparationColorSpace *)colorSpace)->getAlt();
+ n = n * nComps2 * sizeof(double);
+ } else {
+ n = n * nComps * sizeof(double);
+ }
+ 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];
+ }
+ ok = gTrue;
+}
+
GfxImageColorMap::~GfxImageColorMap() {
delete colorSpace;
gfree(lookup);
}
-void GfxImageColorMap::getColor(Guchar x[4], GfxColor *color) {
+void GfxImageColorMap::getGray(Guchar *x, double *gray) {
+ GfxColor color;
+ double *p;
+ int i;
+
+ if (colorSpace2) {
+ p = &lookup[x[0] * nComps2];
+ for (i = 0; i < nComps2; ++i) {
+ color.c[i] = *p++;
+ }
+ colorSpace2->getGray(&color, gray);
+ } else {
+ for (i = 0; i < nComps; ++i) {
+ color.c[i] = lookup[x[i] * nComps + i];
+ }
+ colorSpace->getGray(&color, gray);
+ }
+}
+
+void GfxImageColorMap::getRGB(Guchar *x, GfxRGB *rgb) {
+ GfxColor color;
double *p;
+ int i;
- if (indexed) {
- p = lookup[x[0]];
- color->setRGB(p[0], p[1], p[2]);
+ if (colorSpace2) {
+ p = &lookup[x[0] * nComps2];
+ for (i = 0; i < nComps2; ++i) {
+ color.c[i] = *p++;
+ }
+ colorSpace2->getRGB(&color, rgb);
} else {
- switch (mode) {
- case colorGray:
- color->setGray(lookup[x[0]][0]);
- break;
- case colorCMYK:
- color->setCMYK(lookup[x[0]][0], lookup[x[1]][1],
- lookup[x[2]][2], lookup[x[3]][3]);
- break;
- case colorRGB:
- color->setRGB(lookup[x[0]][0], lookup[x[1]][1], lookup[x[2]][2]);
- break;
+ for (i = 0; i < nComps; ++i) {
+ color.c[i] = lookup[x[i] * nComps + 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++;
+ }
+ colorSpace2->getCMYK(&color, cmyk);
+ } else {
+ for (i = 0; i < nComps; ++i) {
+ color.c[i] = lookup[x[i] * nComps + i];
}
+ colorSpace->getCMYK(&color, cmyk);
+ }
+}
+
+void GfxImageColorMap::getColor(Guchar *x, GfxColor *color) {
+ int maxPixel, i;
+
+ maxPixel = (1 << bits) - 1;
+ for (i = 0; i < nComps; ++i) {
+ color->c[i] = decodeLow[i] + (x[i] * decodeRange[i]) / maxPixel;
}
}
x[0] = x1;
y[0] = y1;
curve[0] = gFalse;
+ closed = gFalse;
}
GfxSubpath::~GfxSubpath() {
memcpy(x, subpath->x, n * sizeof(double));
memcpy(y, subpath->y, n * sizeof(double));
memcpy(curve, subpath->curve, n * sizeof(GBool));
+ closed = subpath->closed;
}
void GfxSubpath::lineTo(double x1, double y1) {
n += 3;
}
+void GfxSubpath::close() {
+ if (x[n-1] != x[0] || y[n-1] != y[0]) {
+ lineTo(x[0], y[0]);
+ }
+ closed = gTrue;
+}
+
+void GfxSubpath::offset(double dx, double dy) {
+ int i;
+
+ for (i = 0; i < n; ++i) {
+ x[i] += dx;
+ y[i] += dy;
+ }
+}
+
GfxPath::GfxPath() {
justMoved = gFalse;
size = 16;
n = 0;
+ firstX = firstY = 0;
subpaths = (GfxSubpath **)gmalloc(size * sizeof(GfxSubpath *));
}
subpaths[n-1]->curveTo(x1, y1, x2, y2, x3, y3);
}
+void GfxPath::close() {
+ // this is necessary to handle the pathological case of
+ // moveto/closepath/clip, which defines an empty clipping region
+ if (justMoved) {
+ if (n >= size) {
+ size += 16;
+ subpaths = (GfxSubpath **)
+ grealloc(subpaths, size * sizeof(GfxSubpath *));
+ }
+ subpaths[n] = new GfxSubpath(firstX, firstY);
+ ++n;
+ justMoved = gFalse;
+ }
+ subpaths[n-1]->close();
+}
+
+void GfxPath::append(GfxPath *path) {
+ int i;
+
+ if (n + path->n > size) {
+ size = n + path->n;
+ subpaths = (GfxSubpath **)
+ grealloc(subpaths, size * sizeof(GfxSubpath *));
+ }
+ for (i = 0; i < path->n; ++i) {
+ subpaths[n++] = path->subpaths[i]->copy();
+ }
+ justMoved = gFalse;
+}
+
+void GfxPath::offset(double dx, double dy) {
+ int i;
+
+ for (i = 0; i < n; ++i) {
+ subpaths[i]->offset(dx, dy);
+ }
+}
//------------------------------------------------------------------------
// GfxState
//------------------------------------------------------------------------
-GfxState::GfxState(int dpi, double px1a, double py1a, double px2a, double py2a,
+GfxState::GfxState(double hDPI, double vDPI, PDFRectangle *pageBox,
int rotate, GBool upsideDown) {
- double k;
-
- px1 = px1a;
- py1 = py1a;
- px2 = px2a;
- py2 = py2a;
- k = (double)dpi / 72.0;
+ double kx, ky;
+
+ px1 = pageBox->x1;
+ py1 = pageBox->y1;
+ px2 = pageBox->x2;
+ py2 = pageBox->y2;
+ kx = hDPI / 72.0;
+ ky = vDPI / 72.0;
if (rotate == 90) {
ctm[0] = 0;
- ctm[1] = upsideDown ? k : -k;
- ctm[2] = k;
+ ctm[1] = upsideDown ? ky : -ky;
+ ctm[2] = kx;
ctm[3] = 0;
- ctm[4] = -k * py1;
- ctm[5] = k * (upsideDown ? -px1 : px2);
- pageWidth = (int)(k * (py2 - py1));
- pageHeight = (int)(k * (px2 - px1));
+ ctm[4] = -kx * py1;
+ ctm[5] = ky * (upsideDown ? -px1 : px2);
+ pageWidth = kx * (py2 - py1);
+ pageHeight = ky * (px2 - px1);
} else if (rotate == 180) {
- ctm[0] = -k;
+ ctm[0] = -kx;
ctm[1] = 0;
ctm[2] = 0;
- ctm[3] = upsideDown ? k : -k;
- ctm[4] = k * px2;
- ctm[5] = k * (upsideDown ? -py1 : py2);
- pageWidth = (int)(k * (px2 - px1));
- pageHeight = (int)(k * (py2 - py1));
+ ctm[3] = upsideDown ? ky : -ky;
+ ctm[4] = kx * px2;
+ ctm[5] = ky * (upsideDown ? -py1 : py2);
+ pageWidth = kx * (px2 - px1);
+ pageHeight = ky * (py2 - py1);
} else if (rotate == 270) {
ctm[0] = 0;
- ctm[1] = upsideDown ? -k : k;
- ctm[2] = -k;
+ ctm[1] = upsideDown ? -ky : ky;
+ ctm[2] = -kx;
ctm[3] = 0;
- ctm[4] = k * py2;
- ctm[5] = k * (upsideDown ? px2 : -px1);
- pageWidth = (int)(k * (py2 - py1));
- pageHeight = (int)(k * (px2 - px1));
+ ctm[4] = kx * py2;
+ ctm[5] = ky * (upsideDown ? px2 : -px1);
+ pageWidth = kx * (py2 - py1);
+ pageHeight = ky * (px2 - px1);
} else {
- ctm[0] = k;
+ ctm[0] = kx;
ctm[1] = 0;
ctm[2] = 0;
- ctm[3] = upsideDown ? -k : k;
- ctm[4] = -k * px1;
- ctm[5] = k * (upsideDown ? py2 : -py1);
- pageWidth = (int)(k * (px2 - px1));
- pageHeight = (int)(k * (py2 - py1));
+ ctm[3] = upsideDown ? -ky : ky;
+ ctm[4] = -kx * px1;
+ ctm[5] = ky * (upsideDown ? py2 : -py1);
+ pageWidth = kx * (px2 - px1);
+ pageHeight = ky * (py2 - py1);
}
- fillColorSpace = new GfxColorSpace(colorGray);
- strokeColorSpace = new GfxColorSpace(colorGray);
- fillColor.setGray(0);
- strokeColor.setGray(0);
+ fillColorSpace = new GfxDeviceGrayColorSpace();
+ strokeColorSpace = new GfxDeviceGrayColorSpace();
+ fillColor.c[0] = 0;
+ strokeColor.c[0] = 0;
+ fillPattern = NULL;
+ strokePattern = NULL;
+ fillOpacity = 1;
+ strokeOpacity = 1;
lineWidth = 1;
lineDash = NULL;
lineDashLength = 0;
lineDashStart = 0;
- flatness = 0;
+ flatness = 1;
lineJoin = 0;
lineCap = 0;
miterLimit = 10;
curX = curY = 0;
lineX = lineY = 0;
+ clipXMin = 0;
+ clipYMin = 0;
+ clipXMax = pageWidth;
+ clipYMax = pageHeight;
+
saved = NULL;
}
GfxState::~GfxState() {
- if (fillColorSpace)
+ if (fillColorSpace) {
delete fillColorSpace;
- if (strokeColorSpace)
+ }
+ if (strokeColorSpace) {
delete strokeColorSpace;
+ }
+ if (fillPattern) {
+ delete fillPattern;
+ }
+ if (strokePattern) {
+ delete strokePattern;
+ }
gfree(lineDash);
- delete path;
- if (saved)
+ if (path) {
+ // this gets set to NULL by restore()
+ delete path;
+ }
+ if (saved) {
delete saved;
+ }
}
// Used for copy();
GfxState::GfxState(GfxState *state) {
memcpy(this, state, sizeof(GfxState));
- if (fillColorSpace)
+ if (fillColorSpace) {
fillColorSpace = state->fillColorSpace->copy();
- if (strokeColorSpace)
+ }
+ if (strokeColorSpace) {
strokeColorSpace = state->strokeColorSpace->copy();
+ }
+ if (fillPattern) {
+ fillPattern = state->fillPattern->copy();
+ }
+ if (strokePattern) {
+ strokePattern = state->strokePattern->copy();
+ }
if (lineDashLength > 0) {
lineDash = (double *)gmalloc(lineDashLength * sizeof(double));
memcpy(lineDash, state->lineDash, lineDashLength * sizeof(double));
}
- path = state->path->copy();
saved = NULL;
}
+void GfxState::setPath(GfxPath *pathA) {
+ delete path;
+ path = pathA;
+}
+
+void GfxState::getUserClipBBox(double *xMin, double *yMin,
+ double *xMax, double *yMax) {
+ double ictm[6];
+ double xMin1, yMin1, xMax1, yMax1, det, tx, ty;
+
+ // invert the CTM
+ det = 1 / (ctm[0] * ctm[3] - ctm[1] * ctm[2]);
+ ictm[0] = ctm[3] * det;
+ ictm[1] = -ctm[1] * det;
+ ictm[2] = -ctm[2] * det;
+ ictm[3] = ctm[0] * det;
+ ictm[4] = (ctm[2] * ctm[5] - ctm[3] * ctm[4]) * det;
+ ictm[5] = (ctm[1] * ctm[4] - ctm[0] * ctm[5]) * det;
+
+ // transform all four corners of the clip bbox; find the min and max
+ // x and y values
+ xMin1 = xMax1 = clipXMin * ictm[0] + clipYMin * ictm[2] + ictm[4];
+ yMin1 = yMax1 = clipXMin * ictm[1] + clipYMin * ictm[3] + ictm[5];
+ tx = clipXMin * ictm[0] + clipYMax * ictm[2] + ictm[4];
+ ty = clipXMin * ictm[1] + clipYMax * ictm[3] + ictm[5];
+ if (tx < xMin1) {
+ xMin1 = tx;
+ } else if (tx > xMax1) {
+ xMax1 = tx;
+ }
+ if (ty < yMin1) {
+ yMin1 = ty;
+ } else if (ty > yMax1) {
+ yMax1 = ty;
+ }
+ tx = clipXMax * ictm[0] + clipYMin * ictm[2] + ictm[4];
+ ty = clipXMax * ictm[1] + clipYMin * ictm[3] + ictm[5];
+ if (tx < xMin1) {
+ xMin1 = tx;
+ } else if (tx > xMax1) {
+ xMax1 = tx;
+ }
+ if (ty < yMin1) {
+ yMin1 = ty;
+ } else if (ty > yMax1) {
+ yMax1 = ty;
+ }
+ tx = clipXMax * ictm[0] + clipYMax * ictm[2] + ictm[4];
+ ty = clipXMax * ictm[1] + clipYMax * ictm[3] + ictm[5];
+ if (tx < xMin1) {
+ xMin1 = tx;
+ } else if (tx > xMax1) {
+ xMax1 = tx;
+ }
+ if (ty < yMin1) {
+ yMin1 = ty;
+ } else if (ty > yMax1) {
+ yMax1 = ty;
+ }
+
+ *xMin = xMin1;
+ *yMin = yMin1;
+ *xMax = xMax1;
+ *yMax = yMax1;
+}
+
double GfxState::transformWidth(double w) {
double x, y;
*m22 = (textMat[2] * ctm[1] + textMat[3] * ctm[3]) * fontSize;
}
+void GfxState::setCTM(double a, double b, double c,
+ double d, double e, double f) {
+ int i;
+
+ ctm[0] = a;
+ ctm[1] = b;
+ ctm[2] = c;
+ ctm[3] = d;
+ ctm[4] = e;
+ ctm[5] = f;
+
+ // avoid FP exceptions on badly messed up PDF files
+ for (i = 0; i < 6; ++i) {
+ if (ctm[i] > 1e10) {
+ ctm[i] = 1e10;
+ } else if (ctm[i] < -1e10) {
+ ctm[i] = -1e10;
+ }
+ }
+}
+
void GfxState::concatCTM(double a, double b, double c,
double d, double e, double f) {
double a1 = ctm[0];
double b1 = ctm[1];
double c1 = ctm[2];
double d1 = ctm[3];
+ int i;
ctm[0] = a * a1 + b * c1;
ctm[1] = a * b1 + b * d1;
ctm[3] = c * b1 + d * d1;
ctm[4] = e * a1 + f * c1 + ctm[4];
ctm[5] = e * b1 + f * d1 + ctm[5];
+
+ // avoid FP exceptions on badly messed up PDF files
+ for (i = 0; i < 6; ++i) {
+ if (ctm[i] > 1e10) {
+ ctm[i] = 1e10;
+ } else if (ctm[i] < -1e10) {
+ ctm[i] = -1e10;
+ }
+ }
}
void GfxState::setFillColorSpace(GfxColorSpace *colorSpace) {
- if (fillColorSpace)
+ if (fillColorSpace) {
delete fillColorSpace;
+ }
fillColorSpace = colorSpace;
}
void GfxState::setStrokeColorSpace(GfxColorSpace *colorSpace) {
- if (strokeColorSpace)
+ if (strokeColorSpace) {
delete strokeColorSpace;
+ }
strokeColorSpace = colorSpace;
}
+void GfxState::setFillPattern(GfxPattern *pattern) {
+ if (fillPattern) {
+ delete fillPattern;
+ }
+ fillPattern = pattern;
+}
+
+void GfxState::setStrokePattern(GfxPattern *pattern) {
+ if (strokePattern) {
+ delete strokePattern;
+ }
+ strokePattern = pattern;
+}
+
void GfxState::setLineDash(double *dash, int length, double start) {
if (lineDash)
gfree(lineDash);
path = new GfxPath();
}
-void GfxState::textShift(double tx) {
- double dx, dy;
+void GfxState::clip() {
+ double xMin, yMin, xMax, yMax, x, y;
+ GfxSubpath *subpath;
+ int i, j;
- textTransformDelta(tx, 0, &dx, &dy);
- curX += dx;
- curY += dy;
+ xMin = xMax = yMin = yMax = 0; // make gcc happy
+ for (i = 0; i < path->getNumSubpaths(); ++i) {
+ subpath = path->getSubpath(i);
+ for (j = 0; j < subpath->getNumPoints(); ++j) {
+ transform(subpath->getX(j), subpath->getY(j), &x, &y);
+ if (i == 0 && j == 0) {
+ xMin = xMax = x;
+ yMin = yMax = y;
+ } else {
+ if (x < xMin) {
+ xMin = x;
+ } else if (x > xMax) {
+ xMax = x;
+ }
+ if (y < yMin) {
+ yMin = y;
+ } else if (y > yMax) {
+ yMax = y;
+ }
+ }
+ }
+ }
+ if (xMin > clipXMin) {
+ clipXMin = xMin;
+ }
+ if (yMin > clipYMin) {
+ clipYMin = yMin;
+ }
+ if (xMax < clipXMax) {
+ clipXMax = xMax;
+ }
+ if (yMax < clipYMax) {
+ clipYMax = yMax;
+ }
}
void GfxState::textShift(double tx, double ty) {
curY += dy;
}
+void GfxState::shift(double dx, double dy) {
+ curX += dx;
+ curY += dy;
+}
+
GfxState *GfxState::save() {
GfxState *newState;
if (saved) {
oldState = saved;
+
+ // these attributes aren't saved/restored by the q/Q operators
+ oldState->path = path;
+ oldState->curX = curX;
+ oldState->curY = curY;
+ oldState->lineX = lineX;
+ oldState->lineY = lineY;
+
+ path = NULL;
saved = NULL;
delete this;
+
} else {
oldState = this;
}
+
return oldState;
}