/** * \file InsetMathRoot.cpp * This file is part of LyX, the document processor. * Licence details can be found in the file COPYING. * * \author Alejandro Aguilar Sierra * \author André Pönitz * * Full author contact details are available in file CREDITS. */ #include #include "InsetMathRoot.h" #include "MathStream.h" #include "MathSupport.h" #include "Cursor.h" #include "LaTeXFeatures.h" #include "MetricsInfo.h" #include "frontends/Painter.h" #include "support/lassert.h" using namespace std; namespace lyx { using namespace frontend; InsetMathRoot::InsetMathRoot(Buffer * buf) : InsetMathNest(buf, 2) {} Inset * InsetMathRoot::clone() const { return new InsetMathRoot(*this); } void mathed_root_metrics(MetricsInfo & mi, MathData const & nucleus, MathData const * root, Dimension & dim) { Changer dummy = mi.base.changeEnsureMath(); Dimension dimr; if (root) { Changer script = mi.base.font.changeStyle(SCRIPTSCRIPT_STYLE); // make sure that the dim is high enough for any character root->metrics(mi, dimr, false); } Dimension dimn; nucleus.metrics(mi, dimn); // Some room for the decoration // The width of left decoration was 9 pixels with a 10em font int const w = 9 * mathed_font_em(mi.base.font) / 10; /* See rule 11 in Appendix G of Rhe TeXbook for the computation of the spacing * above nucleus. * FIXME more work is needed to implement properly rule 11. * * Ideally, we should use sqrt glyphs from the math fonts. Note that then we would get rule thickness from there. * * The positioning of the root MathData is arbitrary. It should * follow the definition of \root...\of... in The Texbook in * Apprendix B page 360. * */ int const t = mi.base.solidLineThickness(); int const x_height = mathed_font_x_height(mi.base.font); int const phi = (mi.base.font.style() == DISPLAY_STYLE) ? x_height : t; // first part is the spacing, second part is the line width // itself, and last one is the spacing above. int const space_above = (t + phi / 4) + t + t; int const a = dimn.ascent(); int const d = dimn.descent(); // Not sure what the 1 stands for, it is needed to have some spacing at small sizes. dim.asc = max(dimr.ascent() + (d - a) / 2, a + space_above) + 1; dim.des = max(dimr.descent() - (d - a) / 2, d); dim.wid = max(dimr.width() + 3 * w / 8, w) + dimn.width(); } void InsetMathRoot::metrics(MetricsInfo & mi, Dimension & dim) const { mathed_root_metrics(mi, cell(0), &cell(1), dim); } void mathed_draw_root(PainterInfo & pi, int x, int y, MathData const & nucleus, MathData const * root, Dimension const & dim) { Changer dummy = pi.base.changeEnsureMath(); // The width of left decoration was 9 pixels with a 10em font int const w = 9 * mathed_font_em(pi.base.font) / 10; // the height of the hook was 5 with a 10em font int const h = 5 * mathed_font_em(pi.base.font) / 10; int const a = dim.ascent(); int const d = dim.descent(); int const t = pi.base.solidLineThickness(); Dimension const dimn = nucleus.dimension(*pi.base.bv); // the width of the left part of the root int const wl = dim.width() - dimn.width(); // the "exponent" if (root) { Changer script = pi.base.font.changeStyle(SCRIPTSCRIPT_STYLE); Dimension const dimr = root->dimension(*pi.base.bv); int const root_offset = wl - 3 * w / 8 - dimr.width(); root->draw(pi, x + root_offset, y + (d - a)/2); } // the "base" nucleus.draw(pi, x + wl, y); int xp[4]; int yp[4]; pi.pain.line(x + dim.width(), y - a + 2 * t, x + wl, y - a + 2 * t, pi.base.font.color(), Painter::line_solid, t); xp[0] = x + wl; yp[0] = y - a + 2 * t + 1; xp[1] = x + wl - w / 2; yp[1] = y + d; xp[2] = x + wl - w + h / 4; yp[2] = y + d - h; xp[3] = x + wl - w; yp[3] = y + d - h + h / 4; pi.pain.lines(xp, yp, 4, pi.base.font.color(), Painter::fill_none, Painter::line_solid, t); } void InsetMathRoot::draw(PainterInfo & pi, int x, int y) const { mathed_draw_root(pi, x, y, cell(0), &cell(1), dimension(*pi.base.bv)); } void InsetMathRoot::write(WriteStream & os) const { MathEnsurer ensurer(os); os << "\\sqrt[" << cell(1) << "]{" << cell(0) << '}'; } void InsetMathRoot::normalize(NormalStream & os) const { os << "[root " << cell(1) << ' ' << cell(0) << ']'; } bool InsetMathRoot::idxUpDown(Cursor & cur, bool up) const { Cursor::idx_type const target = up; //up ? 1 : 0; if (cur.idx() == target) return false; cur.idx() = target; cur.pos() = up ? cur.lastpos() : 0; return true; } bool InsetMathRoot::idxForward(Cursor & cur) const { // nucleus is 0 and is on the right if (cur.idx() == 0) return false; cur.idx() = 0; cur.pos() = 0; return true; } bool InsetMathRoot::idxBackward(Cursor & cur) const { // nucleus is 0 and is on the right if (cur.idx() == 1) return false; cur.idx() = 1; cur.pos() = cur.lastpos(); return true; } bool InsetMathRoot::idxFirst(Cursor & cur) const { LASSERT(&cur.inset() == this, return false); cur.idx() = 1; cur.pos() = 0; return true; } bool InsetMathRoot::idxLast(Cursor & cur) const { LASSERT(&cur.inset() == this, return false); cur.idx() = 0; cur.pos() = cur.lastpos(); return true; } void InsetMathRoot::maple(MapleStream & os) const { os << '(' << cell(0) << ")^(1/(" << cell(1) <<"))"; } void InsetMathRoot::mathematica(MathematicaStream & os) const { os << '(' << cell(0) << ")^(1/(" << cell(1) <<"))"; } void InsetMathRoot::octave(OctaveStream & os) const { os << '(' << cell(0) << ")^(1/(" << cell(1) <<"))"; } void InsetMathRoot::mathmlize(MathStream & os) const { os << MTag("mroot") << cell(0) << cell(1) << ETag("mroot"); } void InsetMathRoot::htmlize(HtmlStream & os) const { os << MTag("span", "class='root'") << MTag("sup") << cell(1) << ETag("sup") << from_ascii("√") << MTag("span", "class='rootof'") << cell(0) << ETag("span") << ETag("span"); } void InsetMathRoot::validate(LaTeXFeatures & features) const { if (features.runparams().math_flavor == OutputParams::MathAsHTML) features.addCSSSnippet( "span.rootof{border-top: thin solid black;}\n" "span.root sup{font-size: 75%;}"); InsetMathNest::validate(features); } } // namespace lyx