-rw-r--r-- | noncore/unsupported/qpdf/xpdf/Gfx.cc | 2 | ||||
-rw-r--r-- | noncore/unsupported/qpdf/xpdf/Object.cc | 2 | ||||
-rw-r--r-- | noncore/unsupported/qpdf/xpdf/Page.cc | 4 |
3 files changed, 4 insertions, 4 deletions
diff --git a/noncore/unsupported/qpdf/xpdf/Gfx.cc b/noncore/unsupported/qpdf/xpdf/Gfx.cc index 17d613e..f016c0e 100644 --- a/noncore/unsupported/qpdf/xpdf/Gfx.cc +++ b/noncore/unsupported/qpdf/xpdf/Gfx.cc @@ -1099,1537 +1099,1537 @@ void Gfx::opEOFill(Object args[], int numArgs) { return; } if (state->isPath()) { if (state->getFillColorSpace()->getMode() == csPattern) { doPatternFill(gTrue); } else { out->eoFill(state); } } doEndPath(); } void Gfx::opFillStroke(Object args[], int numArgs) { if (!state->isCurPt()) { //error(getPos(), "No path in fill/stroke"); return; } if (state->isPath()) { if (state->getFillColorSpace()->getMode() == csPattern) { doPatternFill(gFalse); } else { out->fill(state); } out->stroke(state); } doEndPath(); } void Gfx::opCloseFillStroke(Object args[], int numArgs) { if (!state->isCurPt()) { //error(getPos(), "No path in closepath/fill/stroke"); return; } if (state->isPath()) { state->closePath(); if (state->getFillColorSpace()->getMode() == csPattern) { doPatternFill(gFalse); } else { out->fill(state); } out->stroke(state); } doEndPath(); } void Gfx::opEOFillStroke(Object args[], int numArgs) { if (!state->isCurPt()) { //error(getPos(), "No path in eofill/stroke"); return; } if (state->isPath()) { if (state->getFillColorSpace()->getMode() == csPattern) { doPatternFill(gTrue); } else { out->eoFill(state); } out->stroke(state); } doEndPath(); } void Gfx::opCloseEOFillStroke(Object args[], int numArgs) { if (!state->isCurPt()) { //error(getPos(), "No path in closepath/eofill/stroke"); return; } if (state->isPath()) { state->closePath(); if (state->getFillColorSpace()->getMode() == csPattern) { doPatternFill(gTrue); } else { out->eoFill(state); } out->stroke(state); } doEndPath(); } void Gfx::doPatternFill(GBool eoFill) { GfxPatternColorSpace *patCS; GfxPattern *pattern; GfxTilingPattern *tPat; GfxColorSpace *cs; fouble xMin, yMin, xMax, yMax, x, y, x1, y1; fouble cxMin, cyMin, cxMax, cyMax; int xi0, yi0, xi1, yi1, xi, yi; fouble *ctm, *btm, *ptm; fouble m[6], ictm[6], m1[6], imb[6]; fouble det; fouble xstep, ystep; int i; // this is a bit of a kludge -- patterns can be really slow, so we // skip them if we're only doing text extraction, since they almost // certainly don't contain any text if (!out->needNonText()) { return; } // get color space patCS = (GfxPatternColorSpace *)state->getFillColorSpace(); // get pattern if (!(pattern = state->getFillPattern())) { return; } if (pattern->getType() != 1) { return; } tPat = (GfxTilingPattern *)pattern; // construct a (pattern space) -> (current space) transform matrix ctm = state->getCTM(); btm = baseMatrix; ptm = tPat->getMatrix(); // iCTM = invert 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; // m1 = PTM * BTM = PTM * base transform matrix m1[0] = ptm[0] * btm[0] + ptm[1] * btm[2]; m1[1] = ptm[0] * btm[1] + ptm[1] * btm[3]; m1[2] = ptm[2] * btm[0] + ptm[3] * btm[2]; m1[3] = ptm[2] * btm[1] + ptm[3] * btm[3]; m1[4] = ptm[4] * btm[0] + ptm[5] * btm[2] + btm[4]; m1[5] = ptm[4] * btm[1] + ptm[5] * btm[3] + btm[5]; // m = m1 * iCTM = (PTM * BTM) * (iCTM) m[0] = m1[0] * ictm[0] + m1[1] * ictm[2]; m[1] = m1[0] * ictm[1] + m1[1] * ictm[3]; m[2] = m1[2] * ictm[0] + m1[3] * ictm[2]; m[3] = m1[2] * ictm[1] + m1[3] * ictm[3]; m[4] = m1[4] * ictm[0] + m1[5] * ictm[2] + ictm[4]; m[5] = m1[4] * ictm[1] + m1[5] * ictm[3] + ictm[5]; // construct a (base space) -> (pattern space) transform matrix det = 1 / (m1[0] * m1[3] - m1[1] * m1[2]); imb[0] = m1[3] * det; imb[1] = -m1[1] * det; imb[2] = -m1[2] * det; imb[3] = m1[0] * det; imb[4] = (m1[2] * m1[5] - m1[3] * m1[4]) * det; imb[5] = (m1[1] * m1[4] - m1[0] * m1[5]) * det; // save current graphics state out->saveState(state); state = state->save(); // set underlying color space (for uncolored tiling patterns) if (tPat->getPaintType() == 2 && (cs = patCS->getUnder())) { state->setFillColorSpace(cs->copy()); } else { state->setFillColorSpace(new GfxDeviceGrayColorSpace()); } state->setFillPattern(NULL); out->updateFillColor(state); // clip to current path state->clip(); if (eoFill) { out->eoClip(state); } else { out->clip(state); } state->clearPath(); // transform clip region bbox to pattern space state->getClipBBox(&cxMin, &cyMin, &cxMax, &cyMax); xMin = xMax = cxMin * imb[0] + cyMin * imb[2] + imb[4]; yMin = yMax = cxMin * imb[1] + cyMin * imb[3] + imb[5]; x1 = cxMin * imb[0] + cyMax * imb[2] + imb[4]; y1 = cxMin * imb[1] + cyMax * imb[3] + imb[5]; if (x1 < xMin) { xMin = x1; } else if (x1 > xMax) { xMax = x1; } if (y1 < yMin) { yMin = y1; } else if (y1 > yMax) { yMax = y1; } x1 = cxMax * imb[0] + cyMin * imb[2] + imb[4]; y1 = cxMax * imb[1] + cyMin * imb[3] + imb[5]; if (x1 < xMin) { xMin = x1; } else if (x1 > xMax) { xMax = x1; } if (y1 < yMin) { yMin = y1; } else if (y1 > yMax) { yMax = y1; } x1 = cxMax * imb[0] + cyMax * imb[2] + imb[4]; y1 = cxMax * imb[1] + cyMax * imb[3] + imb[5]; if (x1 < xMin) { xMin = x1; } else if (x1 > xMax) { xMax = x1; } if (y1 < yMin) { yMin = y1; } else if (y1 > yMax) { yMax = y1; } // draw the pattern //~ this should treat negative steps differently -- start at right/top //~ edge instead of left/bottom (?) xstep = fabs(tPat->getXStep()); ystep = fabs(tPat->getYStep()); xi0 = (int)floor(xMin / xstep); xi1 = (int)ceil(xMax / xstep); yi0 = (int)floor(yMin / ystep); yi1 = (int)ceil(yMax / ystep); for (i = 0; i < 4; ++i) { m1[i] = m[i]; } for (yi = yi0; yi < yi1; ++yi) { for (xi = xi0; xi < xi1; ++xi) { x = xi * xstep; y = yi * ystep; m1[4] = x * m[0] + y * m[2] + m[4]; m1[5] = x * m[1] + y * m[3] + m[5]; doForm1(tPat->getContentStream(), tPat->getResDict(), m1, tPat->getBBox()); } } // restore graphics state state = state->restore(); out->restoreState(state); } void Gfx::opShFill(Object args[], int numArgs) { GfxShading *shading; fouble xMin, yMin, xMax, yMax; if (!(shading = res->lookupShading(args[0].getName()))) { return; } // save current graphics state out->saveState(state); state = state->save(); // clip to bbox if (shading->getHasBBox()) { shading->getBBox(&xMin, &yMin, &xMax, &yMax); state->moveTo(xMin, yMin); state->lineTo(xMax, yMin); state->lineTo(xMax, yMax); state->lineTo(xMin, yMax); state->closePath(); state->clip(); out->clip(state); state->clearPath(); } // set the color space state->setFillColorSpace(shading->getColorSpace()->copy()); // do shading type-specific operations switch (shading->getType()) { case 2: doAxialShFill((GfxAxialShading *)shading); break; case 3: doRadialShFill((GfxRadialShading *)shading); break; } // restore graphics state state = state->restore(); out->restoreState(state); delete shading; } void Gfx::doAxialShFill(GfxAxialShading *shading) { fouble xMin, yMin, xMax, yMax; fouble x0, y0, x1, y1; fouble dx, dy, mul; fouble tMin, tMax, t, tx, ty; fouble s[4], sMin, sMax, tmp; fouble ux0, uy0, ux1, uy1, vx0, vy0, vx1, vy1; fouble t0, t1, tt; fouble ta[axialMaxSplits + 1]; int next[axialMaxSplits + 1]; GfxColor color0, color1; int nComps; int i, j, k, kk; // get the clip region bbox state->getUserClipBBox(&xMin, &yMin, &xMax, &yMax); // compute min and max t values, based on the four corners of the // clip region bbox shading->getCoords(&x0, &y0, &x1, &y1); dx = x1 - x0; dy = y1 - y0; mul = 1 / (dx * dx + dy * dy); tMin = tMax = ((xMin - x0) * dx + (yMin - y0) * dy) * mul; t = ((xMin - x0) * dx + (yMax - y0) * dy) * mul; if (t < tMin) { tMin = t; } else if (t > tMax) { tMax = t; } t = ((xMax - x0) * dx + (yMin - y0) * dy) * mul; if (t < tMin) { tMin = t; } else if (t > tMax) { tMax = t; } t = ((xMax - x0) * dx + (yMax - y0) * dy) * mul; if (t < tMin) { tMin = t; } else if (t > tMax) { tMax = t; } if (tMin < 0 && !shading->getExtend0()) { tMin = 0; } if (tMax > 1 && !shading->getExtend1()) { tMax = 1; } // get the function domain t0 = shading->getDomain0(); t1 = shading->getDomain1(); // Traverse the t axis and do the shading. // // For each point (tx, ty) on the t axis, consider a line through // that point perpendicular to the t axis: // // x(s) = tx + s * -dy --> s = (x - tx) / -dy // y(s) = ty + s * dx --> s = (y - ty) / dx // // Then look at the intersection of this line with the bounding box // (xMin, yMin, xMax, yMax). In the general case, there are four // intersection points: // // s0 = (xMin - tx) / -dy // s1 = (xMax - tx) / -dy // s2 = (yMin - ty) / dx // s3 = (yMax - ty) / dx // // and we want the middle two s values. // // In the case where dx = 0, take s0 and s1; in the case where dy = // 0, take s2 and s3. // // Each filled polygon is bounded by two of these line segments // perpdendicular to the t axis. // // The t axis is bisected into smaller regions until the color // difference across a region is small enough, and then the region // is painted with a single color. // set up nComps = shading->getColorSpace()->getNComps(); ta[0] = tMin; ta[axialMaxSplits] = tMax; next[0] = axialMaxSplits; // compute the color at t = tMin if (tMin < 0) { tt = t0; } else if (tMin > 1) { tt = t1; } else { tt = t0 + (t1 - t0) * tMin; } shading->getColor(tt, &color0); // compute the coordinates of the point on the t axis at t = tMin; // then compute the intersection of the perpendicular line with the // bounding box tx = x0 + tMin * dx; ty = y0 + tMin * dy; if (dx == 0 && dy == 0) { sMin = sMax = 0; } if (dx == 0) { sMin = (xMin - tx) / -dy; sMax = (xMax - tx) / -dy; if (sMin > sMax) { tmp = sMin; sMin = sMax; sMax = tmp; } } else if (dy == 0) { sMin = (yMin - ty) / dx; sMax = (yMax - ty) / dx; if (sMin > sMax) { tmp = sMin; sMin = sMax; sMax = tmp; } } else { s[0] = (yMin - ty) / dx; s[1] = (yMax - ty) / dx; s[2] = (xMin - tx) / -dy; s[3] = (xMax - tx) / -dy; for (j = 0; j < 3; ++j) { kk = j; for (k = j + 1; k < 4; ++k) { if (s[k] < s[kk]) { kk = k; } } tmp = s[j]; s[j] = s[kk]; s[kk] = tmp; } sMin = s[1]; sMax = s[2]; } ux0 = tx - sMin * dy; uy0 = ty + sMin * dx; vx0 = tx - sMax * dy; vy0 = ty + sMax * dx; i = 0; while (i < axialMaxSplits) { // bisect until color difference is small enough or we hit the // bisection limit j = next[i]; while (j > i + 1) { if (ta[j] < 0) { tt = t0; } else if (ta[j] > 1) { tt = t1; } else { tt = t0 + (t1 - t0) * ta[j]; } shading->getColor(tt, &color1); for (k = 0; k < nComps; ++k) { if (fabs(color1.c[k] - color0.c[k]) > axialColorDelta) { break; } } if (k == nComps) { break; } k = (i + j) / 2; ta[k] = 0.5 * (ta[i] + ta[j]); next[i] = k; next[k] = j; j = k; } // use the average of the colors of the two sides of the region for (k = 0; k < nComps; ++k) { color0.c[k] = 0.5 * (color0.c[k] + color1.c[k]); } // compute the coordinates of the point on the t axis; then // compute the intersection of the perpendicular line with the // bounding box tx = x0 + ta[j] * dx; ty = y0 + ta[j] * dy; if (dx == 0 && dy == 0) { sMin = sMax = 0; } if (dx == 0) { sMin = (xMin - tx) / -dy; sMax = (xMax - tx) / -dy; if (sMin > sMax) { tmp = sMin; sMin = sMax; sMax = tmp; } } else if (dy == 0) { sMin = (yMin - ty) / dx; sMax = (yMax - ty) / dx; if (sMin > sMax) { tmp = sMin; sMin = sMax; sMax = tmp; } } else { s[0] = (yMin - ty) / dx; s[1] = (yMax - ty) / dx; s[2] = (xMin - tx) / -dy; s[3] = (xMax - tx) / -dy; for (j = 0; j < 3; ++j) { kk = j; for (k = j + 1; k < 4; ++k) { if (s[k] < s[kk]) { kk = k; } } tmp = s[j]; s[j] = s[kk]; s[kk] = tmp; } sMin = s[1]; sMax = s[2]; } ux1 = tx - sMin * dy; uy1 = ty + sMin * dx; vx1 = tx - sMax * dy; vy1 = ty + sMax * dx; // set the color state->setFillColor(&color0); out->updateFillColor(state); // fill the region state->moveTo(ux0, uy0); state->lineTo(vx0, vy0); state->lineTo(vx1, vy1); state->lineTo(ux1, uy1); state->closePath(); out->fill(state); state->clearPath(); // set up for next region ux0 = ux1; uy0 = uy1; vx0 = vx1; vy0 = vy1; color0 = color1; i = next[i]; } } void Gfx::doRadialShFill(GfxRadialShading *shading) { fouble sMin, sMax, xMin, yMin, xMax, yMax; fouble x0, y0, r0, x1, y1, r1, t0, t1; int nComps; GfxColor colorA, colorB; fouble xa, ya, xb, yb, ra, rb; fouble ta, tb, sa, sb; int ia, ib, k, n; fouble *ctm; fouble angle, t; // get the shading info shading->getCoords(&x0, &y0, &r0, &x1, &y1, &r1); t0 = shading->getDomain0(); t1 = shading->getDomain1(); nComps = shading->getColorSpace()->getNComps(); // compute the (possibly extended) s range sMin = 0; sMax = 1; if (shading->getExtend0()) { if (r0 < r1) { // extend the smaller end sMin = -r0 / (r1 - r0); } else { // extend the larger end //~ this computes the diagonal of the bounding box -- we should //~ really compute the intersection of the moving/expanding //~ circles with each of the four corners and look for the max //~ radius state->getUserClipBBox(&xMin, &yMin, &xMax, &yMax); sMin = (sqrt((xMax - xMin) * (xMax - xMin) + (yMax - yMin) * (yMax - yMin)) - r0) / (r1 - r0); if (sMin > 0) { sMin = 0; } else if (sMin < -20) { // sanity check sMin = -20; } } } if (shading->getExtend1()) { if (r1 < r0) { // extend the smaller end sMax = -r0 / (r1 - r0); } else if (r1 > r0) { // extend the larger end state->getUserClipBBox(&xMin, &yMin, &xMax, &yMax); sMax = (sqrt((xMax - xMin) * (xMax - xMin) + (yMax - yMin) * (yMax - yMin)) - r0) / (r1 - r0); if (sMax < 1) { sMin = 1; } else if (sMax > 20) { // sanity check sMax = 20; } } } // compute the number of steps into which circles must be divided to // achieve a curve flatness of 0.1 pixel in device space for the // largest circle (note that "device space" is 72 dpi when generating // PostScript, hence the relatively small 0.1 pixel accuracy) ctm = state->getCTM(); t = fabs(ctm[0]); if (fabs(ctm[1]) > t) { t = fabs(ctm[1]); } if (fabs(ctm[2]) > t) { t = fabs(ctm[2]); } if (fabs(ctm[3]) > t) { t = fabs(ctm[3]); } if (r0 > r1) { t *= r0; } else { t *= r1; } if (t < 1) { n = 3; } else { n = (int)(M_PI / acos(1 - 0.1 / t)); if (n < 3) { n = 3; } else if (n > 200) { n = 200; } } // Traverse the t axis and do the shading. // // This generates and fills a series of rings. Each ring is defined // by two circles: // sa, ta, xa, ya, ra, colorA // sb, tb, xb, yb, rb, colorB // // The s/t axis is divided into radialMaxSplits parts; these parts // are combined as much as possible while respecting the // radialColorDelta parameter. // setup for the start circle ia = 0; sa = sMin; ta = t0 + sa * (t1 - t0); xa = x0 + sa * (x1 - x0); ya = y0 + sa * (y1 - y0); ra = r0 + sa * (r1 - r0); if (ta < t0) { shading->getColor(t0, &colorA); } else if (ta > t1) { shading->getColor(t1, &colorA); } else { shading->getColor(ta, &colorA); } while (ia < radialMaxSplits) { // go as far along the t axis (toward t1) as we can, such that the // color difference is within the tolerance (radialColorDelta) -- // this uses bisection (between the current value, t, and t1), // limited to radialMaxSplits points along the t axis ib = radialMaxSplits; sb = sMin + ((fouble)ib / (fouble)radialMaxSplits) * (sMax - sMin); tb = t0 + sb * (t1 - t0); if (tb < t0) { shading->getColor(t0, &colorB); } else if (tb > t1) { shading->getColor(t1, &colorB); } else { shading->getColor(tb, &colorB); } while (ib - ia > 1) { for (k = 0; k < nComps; ++k) { if (fabs(colorB.c[k] - colorA.c[k]) > radialColorDelta) { break; } } if (k == nComps) { break; } ib = (ia + ib) / 2; sb = sMin + ((fouble)ib / (fouble)radialMaxSplits) * (sMax - sMin); tb = t0 + sb * (t1 - t0); if (tb < t0) { shading->getColor(t0, &colorB); } else if (tb > t1) { shading->getColor(t1, &colorB); } else { shading->getColor(tb, &colorB); } } // compute center and radius of the circle xb = x0 + sb * (x1 - x0); yb = y0 + sb * (y1 - y0); rb = r0 + sb * (r1 - r0); // use the average of the colors at the two circles for (k = 0; k < nComps; ++k) { colorA.c[k] = 0.5 * (colorA.c[k] + colorB.c[k]); } state->setFillColor(&colorA); out->updateFillColor(state); // construct path for first circle state->moveTo(xa + ra, ya); for (k = 1; k < n; ++k) { angle = ((fouble)k / (fouble)n) * 2 * M_PI; state->lineTo(xa + ra * cos(angle), ya + ra * sin(angle)); } state->closePath(); // construct and append path for second circle state->moveTo(xb + rb, yb); for (k = 1; k < n; ++k) { angle = ((fouble)k / (fouble)n) * 2 * M_PI; state->lineTo(xb + rb * cos(angle), yb + rb * sin(angle)); } state->closePath(); // fill the ring out->eoFill(state); state->clearPath(); // step to the next value of t ia = ib; sa = sb; ta = tb; xa = xb; ya = yb; ra = rb; colorA = colorB; } } void Gfx::doEndPath() { if (state->isPath() && clip != clipNone) { state->clip(); if (clip == clipNormal) { out->clip(state); } else { out->eoClip(state); } } clip = clipNone; state->clearPath(); } //------------------------------------------------------------------------ // path clipping operators //------------------------------------------------------------------------ void Gfx::opClip(Object args[], int numArgs) { clip = clipNormal; } void Gfx::opEOClip(Object args[], int numArgs) { clip = clipEO; } //------------------------------------------------------------------------ // text object operators //------------------------------------------------------------------------ void Gfx::opBeginText(Object args[], int numArgs) { state->setTextMat(1, 0, 0, 1, 0, 0); state->textMoveTo(0, 0); out->updateTextMat(state); out->updateTextPos(state); fontChanged = gTrue; } void Gfx::opEndText(Object args[], int numArgs) { } //------------------------------------------------------------------------ // text state operators //------------------------------------------------------------------------ void Gfx::opSetCharSpacing(Object args[], int numArgs) { state->setCharSpace(args[0].getNum()); out->updateCharSpace(state); } void Gfx::opSetFont(Object args[], int numArgs) { GfxFont *font; if (!(font = res->lookupFont(args[0].getName()))) { return; } if (printCommands) { printf(" font: tag=%s name='%s' %g\n", font->getTag()->getCString(), font->getName() ? font->getName()->getCString() : "???", - args[1].getNum()); + static_cast<double>(args[1].getNum())); fflush(stdout); } state->setFont(font, args[1].getNum()); fontChanged = gTrue; } void Gfx::opSetTextLeading(Object args[], int numArgs) { state->setLeading(args[0].getNum()); } void Gfx::opSetTextRender(Object args[], int numArgs) { state->setRender(args[0].getInt()); out->updateRender(state); } void Gfx::opSetTextRise(Object args[], int numArgs) { state->setRise(args[0].getNum()); out->updateRise(state); } void Gfx::opSetWordSpacing(Object args[], int numArgs) { state->setWordSpace(args[0].getNum()); out->updateWordSpace(state); } void Gfx::opSetHorizScaling(Object args[], int numArgs) { state->setHorizScaling(args[0].getNum()); out->updateHorizScaling(state); fontChanged = gTrue; } //------------------------------------------------------------------------ // text positioning operators //------------------------------------------------------------------------ void Gfx::opTextMove(Object args[], int numArgs) { fouble tx, ty; tx = state->getLineX() + args[0].getNum(); ty = state->getLineY() + args[1].getNum(); state->textMoveTo(tx, ty); out->updateTextPos(state); } void Gfx::opTextMoveSet(Object args[], int numArgs) { fouble tx, ty; tx = state->getLineX() + args[0].getNum(); ty = args[1].getNum(); state->setLeading(-ty); ty += state->getLineY(); state->textMoveTo(tx, ty); out->updateTextPos(state); } void Gfx::opSetTextMatrix(Object args[], int numArgs) { state->setTextMat(args[0].getNum(), args[1].getNum(), args[2].getNum(), args[3].getNum(), args[4].getNum(), args[5].getNum()); state->textMoveTo(0, 0); out->updateTextMat(state); out->updateTextPos(state); fontChanged = gTrue; } void Gfx::opTextNextLine(Object args[], int numArgs) { fouble tx, ty; tx = state->getLineX(); ty = state->getLineY() - state->getLeading(); state->textMoveTo(tx, ty); out->updateTextPos(state); } //------------------------------------------------------------------------ // text string operators //------------------------------------------------------------------------ void Gfx::opShowText(Object args[], int numArgs) { if (!state->getFont()) { error(getPos(), "No font in show"); return; } doShowText(args[0].getString()); } void Gfx::opMoveShowText(Object args[], int numArgs) { fouble tx, ty; if (!state->getFont()) { error(getPos(), "No font in move/show"); return; } tx = state->getLineX(); ty = state->getLineY() - state->getLeading(); state->textMoveTo(tx, ty); out->updateTextPos(state); doShowText(args[0].getString()); } void Gfx::opMoveSetShowText(Object args[], int numArgs) { fouble tx, ty; if (!state->getFont()) { error(getPos(), "No font in move/set/show"); return; } state->setWordSpace(args[0].getNum()); state->setCharSpace(args[1].getNum()); tx = state->getLineX(); ty = state->getLineY() - state->getLeading(); state->textMoveTo(tx, ty); out->updateWordSpace(state); out->updateCharSpace(state); out->updateTextPos(state); doShowText(args[2].getString()); } void Gfx::opShowSpaceText(Object args[], int numArgs) { Array *a; Object obj; int wMode; int i; if (!state->getFont()) { error(getPos(), "No font in show/space"); return; } wMode = state->getFont()->getWMode(); a = args[0].getArray(); for (i = 0; i < a->getLength(); ++i) { a->get(i, &obj); if (obj.isNum()) { if (wMode) { state->textShift(0, -obj.getNum() * 0.001 * state->getFontSize()); } else { state->textShift(-obj.getNum() * 0.001 * state->getFontSize(), 0); } out->updateTextShift(state, obj.getNum()); } else if (obj.isString()) { doShowText(obj.getString()); } else { error(getPos(), "Element of show/space array must be number or string"); } obj.free(); } } void Gfx::doShowText(GString *s) { GfxFont *font; int wMode; fouble riseX, riseY; CharCode code; Unicode u[8]; fouble x, y, dx, dy, dx2, dy2, curX, curY, tdx, tdy; fouble originX, originY, tOriginX, tOriginY; fouble oldCTM[6], newCTM[6]; fouble *mat; Object charProc; Dict *resDict; Parser *oldParser; char *p; int len, n, uLen, nChars, nSpaces, i; if (fontChanged) { out->updateFont(state); fontChanged = gFalse; } font = state->getFont(); wMode = font->getWMode(); if (out->useDrawChar()) { out->beginString(state, s); } // handle a Type 3 char if (font->getType() == fontType3 && out->interpretType3Chars()) { mat = state->getCTM(); for (i = 0; i < 6; ++i) { oldCTM[i] = mat[i]; } mat = state->getTextMat(); newCTM[0] = mat[0] * oldCTM[0] + mat[1] * oldCTM[2]; newCTM[1] = mat[0] * oldCTM[1] + mat[1] * oldCTM[3]; newCTM[2] = mat[2] * oldCTM[0] + mat[3] * oldCTM[2]; newCTM[3] = mat[2] * oldCTM[1] + mat[3] * oldCTM[3]; mat = font->getFontMatrix(); newCTM[0] = mat[0] * newCTM[0] + mat[1] * newCTM[2]; newCTM[1] = mat[0] * newCTM[1] + mat[1] * newCTM[3]; newCTM[2] = mat[2] * newCTM[0] + mat[3] * newCTM[2]; newCTM[3] = mat[2] * newCTM[1] + mat[3] * newCTM[3]; newCTM[0] *= state->getFontSize(); newCTM[3] *= state->getFontSize(); newCTM[0] *= state->getHorizScaling(); newCTM[2] *= state->getHorizScaling(); state->textTransformDelta(0, state->getRise(), &riseX, &riseY); curX = state->getCurX(); curY = state->getCurY(); oldParser = parser; p = s->getCString(); len = s->getLength(); while (len > 0) { n = font->getNextChar(p, len, &code, u, (int)(sizeof(u) / sizeof(Unicode)), &uLen, &dx, &dy, &originX, &originY); dx = dx * state->getFontSize() + state->getCharSpace(); if (n == 1 && *p == ' ') { dx += state->getWordSpace(); } dx *= state->getHorizScaling(); dy *= state->getFontSize(); state->textTransformDelta(dx, dy, &tdx, &tdy); state->transform(curX + riseX, curY + riseY, &x, &y); out->saveState(state); state = state->save(); state->setCTM(newCTM[0], newCTM[1], newCTM[2], newCTM[3], x, y); //~ out->updateCTM(???) if (!out->beginType3Char(state, code, u, uLen)) { ((Gfx8BitFont *)font)->getCharProc(code, &charProc); if ((resDict = ((Gfx8BitFont *)font)->getResources())) { pushResources(resDict); } if (charProc.isStream()) { display(&charProc, gFalse); } else { error(getPos(), "Missing or bad Type3 CharProc entry"); } out->endType3Char(state); if (resDict) { popResources(); } charProc.free(); } state = state->restore(); out->restoreState(state); // GfxState::restore() does *not* restore the current position, // so we track it here with (curX, curY) curX += tdx; curY += tdy; state->moveTo(curX, curY); p += n; len -= n; } parser = oldParser; } else if (out->useDrawChar()) { state->textTransformDelta(0, state->getRise(), &riseX, &riseY); p = s->getCString(); len = s->getLength(); while (len > 0) { n = font->getNextChar(p, len, &code, u, (int)(sizeof(u) / sizeof(Unicode)), &uLen, &dx, &dy, &originX, &originY); if (wMode) { dx *= state->getFontSize(); dy = dy * state->getFontSize() + state->getCharSpace(); if (n == 1 && *p == ' ') { dy += state->getWordSpace(); } } else { dx = dx * state->getFontSize() + state->getCharSpace(); if (n == 1 && *p == ' ') { dx += state->getWordSpace(); } dx *= state->getHorizScaling(); dy *= state->getFontSize(); } state->textTransformDelta(dx, dy, &tdx, &tdy); originX *= state->getFontSize(); originY *= state->getFontSize(); state->textTransformDelta(originX, originY, &tOriginX, &tOriginY); out->drawChar(state, state->getCurX() + riseX, state->getCurY() + riseY, tdx, tdy, tOriginX, tOriginY, code, u, uLen); state->shift(tdx, tdy); p += n; len -= n; } } else { dx = dy = 0; p = s->getCString(); len = s->getLength(); nChars = nSpaces = 0; while (len > 0) { n = font->getNextChar(p, len, &code, u, (int)(sizeof(u) / sizeof(Unicode)), &uLen, &dx2, &dy2, &originX, &originY); dx += dx2; dy += dy2; if (n == 1 && *p == ' ') { ++nSpaces; } ++nChars; p += n; len -= n; } if (wMode) { dx *= state->getFontSize(); dy = dy * state->getFontSize() + nChars * state->getCharSpace() + nSpaces * state->getWordSpace(); } else { dx = dx * state->getFontSize() + nChars * state->getCharSpace() + nSpaces * state->getWordSpace(); dx *= state->getHorizScaling(); dy *= state->getFontSize(); } state->textTransformDelta(dx, dy, &tdx, &tdy); out->drawString(state, s); state->shift(tdx, tdy); } if (out->useDrawChar()) { out->endString(state); } updateLevel += 10 * s->getLength(); } //------------------------------------------------------------------------ // XObject operators //------------------------------------------------------------------------ void Gfx::opXObject(Object args[], int numArgs) { Object obj1, obj2, obj3, refObj; #if OPI_SUPPORT Object opiDict; #endif if (!res->lookupXObject(args[0].getName(), &obj1)) { return; } if (!obj1.isStream()) { error(getPos(), "XObject '%s' is wrong type", args[0].getName()); obj1.free(); return; } #if OPI_SUPPORT obj1.streamGetDict()->lookup("OPI", &opiDict); if (opiDict.isDict()) { out->opiBegin(state, opiDict.getDict()); } #endif obj1.streamGetDict()->lookup("Subtype", &obj2); if (obj2.isName("Image")) { res->lookupXObjectNF(args[0].getName(), &refObj); doImage(&refObj, obj1.getStream(), gFalse); refObj.free(); } else if (obj2.isName("Form")) { doForm(&obj1); } else if (obj2.isName("PS")) { obj1.streamGetDict()->lookup("Level1", &obj3); out->psXObject(obj1.getStream(), obj3.isStream() ? obj3.getStream() : (Stream *)NULL); } else if (obj2.isName()) { error(getPos(), "Unknown XObject subtype '%s'", obj2.getName()); } else { error(getPos(), "XObject subtype is missing or wrong type"); } obj2.free(); #if OPI_SUPPORT if (opiDict.isDict()) { out->opiEnd(state, opiDict.getDict()); } opiDict.free(); #endif obj1.free(); } void Gfx::doImage(Object *ref, Stream *str, GBool inlineImg) { Dict *dict; int width, height; int bits; GBool mask; GBool invert; GfxColorSpace *colorSpace; GfxImageColorMap *colorMap; Object maskObj; GBool haveMask; int maskColors[2*gfxColorMaxComps]; Object obj1, obj2; int i; // get stream dict dict = str->getDict(); // get size dict->lookup("Width", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("W", &obj1); } if (!obj1.isInt()) goto err2; width = obj1.getInt(); obj1.free(); dict->lookup("Height", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("H", &obj1); } if (!obj1.isInt()) goto err2; height = obj1.getInt(); obj1.free(); // image or mask? dict->lookup("ImageMask", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("IM", &obj1); } mask = gFalse; if (obj1.isBool()) mask = obj1.getBool(); else if (!obj1.isNull()) goto err2; obj1.free(); // bit depth dict->lookup("BitsPerComponent", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("BPC", &obj1); } if (!obj1.isInt()) goto err2; bits = obj1.getInt(); obj1.free(); // display a mask if (mask) { // check for inverted mask if (bits != 1) goto err1; invert = gFalse; dict->lookup("Decode", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("D", &obj1); } if (obj1.isArray()) { obj1.arrayGet(0, &obj2); if (obj2.isInt() && obj2.getInt() == 1) invert = gTrue; obj2.free(); } else if (!obj1.isNull()) { goto err2; } obj1.free(); // draw it out->drawImageMask(state, ref, str, width, height, invert, inlineImg); } else { // get color space and color map dict->lookup("ColorSpace", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("CS", &obj1); } if (obj1.isName()) { res->lookupColorSpace(obj1.getName(), &obj2); if (!obj2.isNull()) { obj1.free(); obj1 = obj2; } else { obj2.free(); } } colorSpace = GfxColorSpace::parse(&obj1); obj1.free(); if (!colorSpace) { goto err1; } dict->lookup("Decode", &obj1); if (obj1.isNull()) { obj1.free(); dict->lookup("D", &obj1); } colorMap = new GfxImageColorMap(bits, &obj1, colorSpace); obj1.free(); if (!colorMap->isOk()) { delete colorMap; goto err1; } // get the mask haveMask = gFalse; dict->lookup("Mask", &maskObj); if (maskObj.isArray()) { for (i = 0; i < maskObj.arrayGetLength(); ++i) { maskObj.arrayGet(i, &obj1); maskColors[i] = obj1.getInt(); obj1.free(); } haveMask = gTrue; } // draw it out->drawImage(state, ref, str, width, height, colorMap, haveMask ? maskColors : (int *)NULL, inlineImg); delete colorMap; maskObj.free(); } if ((i = width * height) > 1000) { i = 1000; } updateLevel += i; return; err2: obj1.free(); err1: error(getPos(), "Bad image parameters"); } void Gfx::doForm(Object *str) { Dict *dict; Object matrixObj, bboxObj; fouble m[6], bbox[6]; Object resObj; Dict *resDict; Object obj1; int i; // get stream dict dict = str->streamGetDict(); // check form type dict->lookup("FormType", &obj1); if (!(obj1.isInt() && obj1.getInt() == 1)) { error(getPos(), "Unknown form type"); } obj1.free(); // get bounding box dict->lookup("BBox", &bboxObj); if (!bboxObj.isArray()) { matrixObj.free(); bboxObj.free(); error(getPos(), "Bad form bounding box"); return; } for (i = 0; i < 4; ++i) { bboxObj.arrayGet(i, &obj1); bbox[i] = obj1.getNum(); obj1.free(); } bboxObj.free(); // get matrix dict->lookup("Matrix", &matrixObj); if (matrixObj.isArray()) { for (i = 0; i < 6; ++i) { matrixObj.arrayGet(i, &obj1); m[i] = obj1.getNum(); obj1.free(); } } else { m[0] = 1; m[1] = 0; m[2] = 0; m[3] = 1; m[4] = 0; m[5] = 0; } matrixObj.free(); // get resources dict->lookup("Resources", &resObj); resDict = resObj.isDict() ? resObj.getDict() : (Dict *)NULL; // draw it doForm1(str, resDict, m, bbox); resObj.free(); } void Gfx::doAnnot(Object *str, fouble xMin, fouble yMin, fouble xMax, fouble yMax) { Dict *dict, *resDict; Object matrixObj, bboxObj, resObj; Object obj1; fouble m[6], bbox[6], ictm[6]; fouble *ctm; fouble formX0, formY0, formX1, formY1; fouble annotX0, annotY0, annotX1, annotY1; fouble det, x, y, sx, sy; int i; // get stream dict dict = str->streamGetDict(); // get the form bounding box dict->lookup("BBox", &bboxObj); if (!bboxObj.isArray()) { bboxObj.free(); error(getPos(), "Bad form bounding box"); return; } for (i = 0; i < 4; ++i) { bboxObj.arrayGet(i, &obj1); bbox[i] = obj1.getNum(); obj1.free(); } bboxObj.free(); // get the form matrix dict->lookup("Matrix", &matrixObj); if (matrixObj.isArray()) { for (i = 0; i < 6; ++i) { matrixObj.arrayGet(i, &obj1); m[i] = obj1.getNum(); obj1.free(); } } else { m[0] = 1; m[1] = 0; m[2] = 0; m[3] = 1; m[4] = 0; m[5] = 0; } matrixObj.free(); // transform the form bbox from form space to user space formX0 = bbox[0] * m[0] + bbox[1] * m[2] + m[4]; formY0 = bbox[0] * m[1] + bbox[1] * m[3] + m[5]; formX1 = bbox[2] * m[0] + bbox[3] * m[2] + m[4]; formY1 = bbox[2] * m[1] + bbox[3] * m[3] + m[5]; // transform the annotation bbox from default user space to user // space: (bbox * baseMatrix) * iCTM ctm = state->getCTM(); 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; x = baseMatrix[0] * xMin + baseMatrix[2] * yMin + baseMatrix[4]; y = baseMatrix[1] * xMin + baseMatrix[3] * yMin + baseMatrix[5]; annotX0 = ictm[0] * x + ictm[2] * y + ictm[4]; annotY0 = ictm[1] * x + ictm[3] * y + ictm[5]; x = baseMatrix[0] * xMax + baseMatrix[2] * yMax + baseMatrix[4]; y = baseMatrix[1] * xMax + baseMatrix[3] * yMax + baseMatrix[5]; annotX1 = ictm[0] * x + ictm[2] * y + ictm[4]; annotY1 = ictm[1] * x + ictm[3] * y + ictm[5]; // swap min/max coords if (formX0 > formX1) { x = formX0; formX0 = formX1; formX1 = x; } if (formY0 > formY1) { y = formY0; formY0 = formY1; formY1 = y; } if (annotX0 > annotX1) { x = annotX0; annotX0 = annotX1; annotX1 = x; } if (annotY0 > annotY1) { y = annotY0; annotY0 = annotY1; annotY1 = y; } // scale the form to fit the annotation bbox if (formX1 == formX0) { // this shouldn't happen sx = 1; } else { sx = (annotX1 - annotX0) / (formX1 - formX0); } if (formY1 == formY0) { // this shouldn't happen sy = 1; } else { sy = (annotY1 - annotY0) / (formY1 - formY0); } m[0] *= sx; m[2] *= sx; m[4] = (m[4] - formX0) * sx + annotX0; m[1] *= sy; m[3] *= sy; m[5] = (m[5] - formY0) * sy + annotY0; // get resources dict->lookup("Resources", &resObj); resDict = resObj.isDict() ? resObj.getDict() : (Dict *)NULL; // draw it doForm1(str, resDict, m, bbox); resObj.free(); bboxObj.free(); } void Gfx::doForm1(Object *str, Dict *resDict, fouble *matrix, fouble *bbox) { Parser *oldParser; fouble oldBaseMatrix[6]; int i; // push new resources on stack pushResources(resDict); // save current graphics state out->saveState(state); state = state->save(); // save current parser oldParser = parser; // set form transformation matrix state->concatCTM(matrix[0], matrix[1], matrix[2], matrix[3], matrix[4], matrix[5]); out->updateCTM(state, matrix[0], matrix[1], matrix[2], matrix[3], matrix[4], matrix[5]); // set new base matrix for (i = 0; i < 6; ++i) { oldBaseMatrix[i] = baseMatrix[i]; baseMatrix[i] = state->getCTM()[i]; } // set form bounding box state->moveTo(bbox[0], bbox[1]); state->lineTo(bbox[2], bbox[1]); state->lineTo(bbox[2], bbox[3]); state->lineTo(bbox[0], bbox[3]); state->closePath(); state->clip(); out->clip(state); state->clearPath(); // draw the form display(str, gFalse); // restore base matrix for (i = 0; i < 6; ++i) { baseMatrix[i] = oldBaseMatrix[i]; } // restore parser parser = oldParser; // restore graphics state state = state->restore(); out->restoreState(state); // pop resource stack popResources(); return; } void Gfx::pushResources(Dict *resDict) { res = new GfxResources(xref, resDict, res); } void Gfx::popResources() { GfxResources *resPtr; resPtr = res->getNext(); delete res; res = resPtr; } //------------------------------------------------------------------------ // in-line image operators diff --git a/noncore/unsupported/qpdf/xpdf/Object.cc b/noncore/unsupported/qpdf/xpdf/Object.cc index 6d92c6a..77f1317 100644 --- a/noncore/unsupported/qpdf/xpdf/Object.cc +++ b/noncore/unsupported/qpdf/xpdf/Object.cc @@ -1,223 +1,223 @@ //======================================================================== // // Object.cc // // Copyright 1996-2002 Glyph & Cog, LLC // //======================================================================== #ifdef __GNUC__ #pragma implementation #endif #include <aconf.h> #include <stddef.h> #include "Object.h" #include "Array.h" #include "Dict.h" #include "Error.h" #include "Stream.h" #include "XRef.h" //------------------------------------------------------------------------ // Object //------------------------------------------------------------------------ char *objTypeNames[numObjTypes] = { "boolean", "integer", "real", "string", "name", "null", "array", "dictionary", "stream", "ref", "cmd", "error", "eof", "none" }; #ifdef DEBUG_MEM int Object::numAlloc[numObjTypes] = {0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; #endif Object *Object::initArray(XRef *xref) { initObj(objArray); array = new Array(xref); return this; } Object *Object::initDict(XRef *xref) { initObj(objDict); dict = new Dict(xref); return this; } Object *Object::initStream(Stream *streamA) { initObj(objStream); stream = streamA; return this; } Object *Object::copy(Object *obj) { *obj = *this; switch (type) { case objString: obj->string = string->copy(); break; case objName: obj->name = copyString(name); break; case objArray: array->incRef(); break; case objDict: dict->incRef(); break; case objStream: stream->incRef(); break; case objCmd: obj->cmd = copyString(cmd); break; default: break; } #ifdef DEBUG_MEM ++numAlloc[type]; #endif return obj; } Object *Object::fetch(XRef *xref, Object *obj) { return (type == objRef && xref) ? xref->fetch(ref.num, ref.gen, obj) : copy(obj); } void Object::free() { switch (type) { case objString: delete string; break; case objName: gfree(name); break; case objArray: if (!array->decRef()) { delete array; } break; case objDict: if (!dict->decRef()) { delete dict; } break; case objStream: if (!stream->decRef()) { delete stream; } break; case objCmd: gfree(cmd); break; default: break; } #ifdef DEBUG_MEM --numAlloc[type]; #endif type = objNone; } char *Object::getTypeName() { return objTypeNames[type]; } void Object::print(FILE *f) { Object obj; int i; switch (type) { case objBool: fprintf(f, "%s", booln ? "true" : "false"); break; case objInt: fprintf(f, "%d", intg); break; case objReal: - fprintf(f, "%g", real); + fprintf(f, "%g", static_cast<double>(real)); break; case objString: fprintf(f, "("); fwrite(string->getCString(), 1, string->getLength(), stdout); fprintf(f, ")"); break; case objName: fprintf(f, "/%s", name); break; case objNull: fprintf(f, "null"); break; case objArray: fprintf(f, "["); for (i = 0; i < arrayGetLength(); ++i) { if (i > 0) fprintf(f, " "); arrayGetNF(i, &obj); obj.print(f); obj.free(); } fprintf(f, "]"); break; case objDict: fprintf(f, "<<"); for (i = 0; i < dictGetLength(); ++i) { fprintf(f, " /%s ", dictGetKey(i)); dictGetValNF(i, &obj); obj.print(f); obj.free(); } fprintf(f, " >>"); break; case objStream: fprintf(f, "<stream>"); break; case objRef: fprintf(f, "%d %d R", ref.num, ref.gen); break; case objCmd: fprintf(f, "%s", cmd); break; case objError: fprintf(f, "<error>"); break; case objEOF: fprintf(f, "<EOF>"); break; case objNone: fprintf(f, "<none>"); break; } } void Object::memCheck(FILE *f) { #ifdef DEBUG_MEM int i; int t; t = 0; for (i = 0; i < numObjTypes; ++i) t += numAlloc[i]; if (t > 0) { fprintf(f, "Allocated objects:\n"); for (i = 0; i < numObjTypes; ++i) { if (numAlloc[i] > 0) fprintf(f, " %-20s: %6d\n", objTypeNames[i], numAlloc[i]); } } #endif } diff --git a/noncore/unsupported/qpdf/xpdf/Page.cc b/noncore/unsupported/qpdf/xpdf/Page.cc index 9cc08c4..aead7da 100644 --- a/noncore/unsupported/qpdf/xpdf/Page.cc +++ b/noncore/unsupported/qpdf/xpdf/Page.cc @@ -1,281 +1,281 @@ //======================================================================== // // Page.cc // // Copyright 1996-2002 Glyph & Cog, LLC // //======================================================================== #ifdef __GNUC__ #pragma implementation #endif #include <aconf.h> #include <stddef.h> #include "Object.h" #include "Array.h" #include "Dict.h" #include "XRef.h" #include "Link.h" #include "OutputDev.h" #ifndef PDF_PARSER_ONLY #include "Gfx.h" #include "Annot.h" #endif #include "Error.h" #include "Page.h" //------------------------------------------------------------------------ // PageAttrs //------------------------------------------------------------------------ PageAttrs::PageAttrs(PageAttrs *attrs, Dict *dict) { Object obj1; fouble w, h; // get old/default values if (attrs) { mediaBox = attrs->mediaBox; cropBox = attrs->cropBox; haveCropBox = attrs->haveCropBox; rotate = attrs->rotate; attrs->resources.copy(&resources); } else { // set default MediaBox to 8.5" x 11" -- this shouldn't be necessary // but some (non-compliant) PDF files don't specify a MediaBox mediaBox.x1 = 0; mediaBox.y1 = 0; mediaBox.x2 = 612; mediaBox.y2 = 792; cropBox.x1 = cropBox.y1 = cropBox.x2 = cropBox.y2 = 0; haveCropBox = gFalse; rotate = 0; resources.initNull(); } // media box readBox(dict, "MediaBox", &mediaBox); // crop box cropBox = mediaBox; haveCropBox = readBox(dict, "CropBox", &cropBox); // if the MediaBox is excessively larger than the CropBox, // just use the CropBox limitToCropBox = gFalse; if (haveCropBox) { w = 0.25 * (cropBox.x2 - cropBox.x1); h = 0.25 * (cropBox.y2 - cropBox.y1); if ((cropBox.x1 - mediaBox.x1) + (mediaBox.x2 - cropBox.x2) > w || (cropBox.y1 - mediaBox.y1) + (mediaBox.y2 - cropBox.y2) > h) { limitToCropBox = gTrue; } } // other boxes bleedBox = cropBox; readBox(dict, "BleedBox", &bleedBox); trimBox = cropBox; readBox(dict, "TrimBox", &trimBox); artBox = cropBox; readBox(dict, "ArtBox", &artBox); // rotate dict->lookup("Rotate", &obj1); if (obj1.isInt()) { rotate = obj1.getInt(); } obj1.free(); while (rotate < 0) { rotate += 360; } while (rotate >= 360) { rotate -= 360; } // misc attributes dict->lookup("LastModified", &lastModified); dict->lookup("BoxColorInfo", &boxColorInfo); dict->lookup("Group", &group); dict->lookup("Metadata", &metadata); dict->lookup("PieceInfo", &pieceInfo); dict->lookup("SeparationInfo", &separationInfo); // resource dictionary dict->lookup("Resources", &obj1); if (obj1.isDict()) { resources.free(); obj1.copy(&resources); } obj1.free(); } PageAttrs::~PageAttrs() { lastModified.free(); boxColorInfo.free(); group.free(); metadata.free(); pieceInfo.free(); separationInfo.free(); resources.free(); } GBool PageAttrs::readBox(Dict *dict, char *key, PDFRectangle *box) { PDFRectangle tmp; Object obj1, obj2; GBool ok; dict->lookup(key, &obj1); if (obj1.isArray() && obj1.arrayGetLength() == 4) { ok = gTrue; obj1.arrayGet(0, &obj2); if (obj2.isNum()) { tmp.x1 = obj2.getNum(); } else { ok = gFalse; } obj2.free(); obj1.arrayGet(1, &obj2); if (obj2.isNum()) { tmp.y1 = obj2.getNum(); } else { ok = gFalse; } obj2.free(); obj1.arrayGet(2, &obj2); if (obj2.isNum()) { tmp.x2 = obj2.getNum(); } else { ok = gFalse; } obj2.free(); obj1.arrayGet(3, &obj2); if (obj2.isNum()) { tmp.y2 = obj2.getNum(); } else { ok = gFalse; } obj2.free(); if (ok) { *box = tmp; } } else { ok = gFalse; } obj1.free(); return ok; } //------------------------------------------------------------------------ // Page //------------------------------------------------------------------------ Page::Page(XRef *xrefA, int numA, Dict *pageDict, PageAttrs *attrsA, GBool printCommandsA) { ok = gTrue; xref = xrefA; num = numA; printCommands = printCommandsA; // get attributes attrs = attrsA; // annotations pageDict->lookupNF("Annots", &annots); if (!(annots.isRef() || annots.isArray() || annots.isNull())) { error(-1, "Page annotations object (page %d) is wrong type (%s)", num, annots.getTypeName()); annots.free(); goto err2; } // contents pageDict->lookupNF("Contents", &contents); if (!(contents.isRef() || contents.isArray() || contents.isNull())) { error(-1, "Page contents object (page %d) is wrong type (%s)", num, contents.getTypeName()); contents.free(); goto err1; } return; err2: annots.initNull(); err1: contents.initNull(); ok = gFalse; } Page::~Page() { delete attrs; annots.free(); contents.free(); } void Page::display(OutputDev *out, fouble dpi, int rotate, Links *links, Catalog *catalog) { #ifndef PDF_PARSER_ONLY PDFRectangle *box, *cropBox; Gfx *gfx; Object obj; Link *link; int i; Annots *annotList; box = getBox(); cropBox = getCropBox(); if (printCommands) { printf("***** MediaBox = ll:%g,%g ur:%g,%g\n", - box->x1, box->y1, box->x2, box->y2); + static_cast<double>(box->x1), static_cast<double>(box->y1), static_cast<double>(box->x2), static_cast<double>(box->y2)); if (isCropped()) { printf("***** CropBox = ll:%g,%g ur:%g,%g\n", - cropBox->x1, cropBox->y1, cropBox->x2, cropBox->y2); + static_cast<double>(cropBox->x1), static_cast<double>(cropBox->y1), static_cast<double>(cropBox->x2), static_cast<double>(cropBox->y2)); } printf("***** Rotate = %d\n", attrs->getRotate()); } rotate += getRotate(); if (rotate >= 360) { rotate -= 360; } else if (rotate < 0) { rotate += 360; } gfx = new Gfx(xref, out, num, attrs->getResourceDict(), dpi, box, isCropped(), cropBox, rotate, printCommands); contents.fetch(xref, &obj); if (!obj.isNull()) { gfx->display(&obj); } obj.free(); // draw links if (links) { for (i = 0; i < links->getNumLinks(); ++i) { link = links->getLink(i); out->drawLink(link, catalog); } out->dump(); } // draw non-link annotations //~ need to reset CTM ??? annotList = new Annots(xref, annots.fetch(xref, &obj)); obj.free(); if (annotList->getNumAnnots() > 0) { if (printCommands) { printf("***** Annotations\n"); } for (i = 0; i < annotList->getNumAnnots(); ++i) { annotList->getAnnot(i)->draw(gfx); } out->dump(); } delete annotList; delete gfx; #endif } |