/** * \file Row.cpp * This file is part of LyX, the document processor. * Licence details can be found in the file COPYING. * * \author Lars Gullik Bjønnes * \author John Levon * \author André Pönitz * \author Jürgen Vigna * \author Jean-Marc Lasgouttes * * Full author contact details are available in file CREDITS. * * Metrics for an on-screen text row. */ #include #include "Row.h" #include "DocIterator.h" #include "frontends/FontMetrics.h" #include "support/debug.h" #include "support/lassert.h" #include "support/lstrings.h" #include "support/lyxalgo.h" #include using namespace std; namespace lyx { using support::rtrim; using frontend::FontMetrics; // Maximum length that a space can be stretched when justifying text static double const MAX_SPACE_STRETCH = 1.5; //em int Row::Element::countSeparators() const { if (type != STRING) return 0; return count(str.begin(), str.end(), ' '); } int Row::Element::countExpanders() const { if (type != STRING) return 0; return theFontMetrics(font).countExpanders(str); } int Row::Element::expansionAmount() const { if (type != STRING) return 0; return countExpanders() * theFontMetrics(font).em(); } void Row::Element::setExtra(double extra_per_em) { if (type != STRING) return; extra = extra_per_em * theFontMetrics(font).em(); } double Row::Element::pos2x(pos_type const i) const { // This can happen with inline completion when clicking on the // row after the completion. if (i < pos || i > endpos) return 0; double w = 0; //handle first the two bounds of the element if (i == endpos && type != VIRTUAL) w = isRTL() ? 0 : full_width(); else if (i == pos || type != STRING) w = isRTL() ? full_width() : 0; else { FontMetrics const & fm = theFontMetrics(font); w = fm.pos2x(str, i - pos, isRTL(), extra); } return w; } pos_type Row::Element::x2pos(int &x) const { //lyxerr << "x2pos: x=" << x << " w=" << width() << " " << *this; size_t i = 0; switch (type) { case STRING: { FontMetrics const & fm = theFontMetrics(font); i = fm.x2pos(str, x, isRTL(), extra); break; } case VIRTUAL: // those elements are actually empty (but they have a width) i = 0; x = isRTL() ? int(full_width()) : 0; break; case INSET: case SPACE: // those elements contain only one position. Round to // the closest side. if (x > (full_width() + 1) / 2) { x = int(full_width()); i = !isRTL(); } else { x = 0; i = isRTL(); } } //lyxerr << "=> p=" << pos + i << " x=" << x << endl; return pos + i; } bool Row::Element::breakAt(int w, bool force) { if (type != STRING || dim.wid <= w) return false; FontMetrics const & fm = theFontMetrics(font); int x = w; if(fm.breakAt(str, x, isRTL(), force)) { dim.wid = x; endpos = pos + str.length(); //lyxerr << "breakAt(" << w << ") Row element Broken at " << x << "(w(str)=" << fm.width(str) << "): e=" << *this << endl; return true; } return false; } pos_type Row::Element::left_pos() const { return isRTL() ? endpos : pos; } pos_type Row::Element::right_pos() const { return isRTL() ? pos : endpos; } Row::Row() : separator(0), label_hfill(0), left_margin(0), right_margin(0), sel_beg(-1), sel_end(-1), begin_margin_sel(false), end_margin_sel(false), changed_(false), crc_(0), pit_(0), pos_(0), end_(0), right_boundary_(false), flushed_(false), rtl_(false) {} void Row::setCrc(size_type crc) const { changed_ = crc != crc_; crc_ = crc; } bool Row::isMarginSelected(bool left_margin, DocIterator const & beg, DocIterator const & end) const { pos_type const sel_pos = left_margin ? sel_beg : sel_end; pos_type const margin_pos = left_margin ? pos_ : end_; // Is the chosen margin selected ? if (sel_pos == margin_pos) { if (beg.pos() == end.pos()) // This is a special case in which the space between after // pos i-1 and before pos i is selected, i.e. the margins // (see DocIterator::boundary_). return beg.boundary() && !end.boundary(); else if (end.pos() == margin_pos) // If the selection ends around the margin, it is only // drawn if the cursor is after the margin. return !end.boundary(); else if (beg.pos() == margin_pos) // If the selection begins around the margin, it is // only drawn if the cursor is before the margin. return beg.boundary(); else return true; } return false; } void Row::setSelectionAndMargins(DocIterator const & beg, DocIterator const & end) const { setSelection(beg.pos(), end.pos()); if (selection()) { end_margin_sel = isMarginSelected(false, beg, end); begin_margin_sel = isMarginSelected(true, beg, end); } } void Row::setSelection(pos_type beg, pos_type end) const { if (pos_ >= beg && pos_ <= end) sel_beg = pos_; else if (beg > pos_ && beg <= end_) sel_beg = beg; else sel_beg = -1; if (end_ >= beg && end_ <= end) sel_end = end_; else if (end < end_ && end >= pos_) sel_end = end; else sel_end = -1; } bool Row::selection() const { return sel_beg != -1 && sel_end != -1; } ostream & operator<<(ostream & os, Row::Element const & e) { if (e.isRTL()) os << e.endpos << "<<" << e.pos << " "; else os << e.pos << ">>" << e.endpos << " "; switch (e.type) { case Row::STRING: os << "STRING: `" << to_utf8(e.str) << "' (" << e.countExpanders() << " expanders.), "; break; case Row::VIRTUAL: os << "VIRTUAL: `" << to_utf8(e.str) << "', "; break; case Row::INSET: os << "INSET: " << to_utf8(e.inset->layoutName()) << ", "; break; case Row::SPACE: os << "SPACE: "; break; } os << "width=" << e.full_width(); return os; } ostream & operator<<(ostream & os, Row const & row) { os << " pos: " << row.pos_ << " end: " << row.end_ << " left_margin: " << row.left_margin << " width: " << row.dim_.wid << " right_margin: " << row.right_margin << " ascent: " << row.dim_.asc << " descent: " << row.dim_.des << " separator: " << row.separator << " label_hfill: " << row.label_hfill << " row_boundary: " << row.right_boundary() << "\n"; double x = row.left_margin; Row::Elements::const_iterator it = row.elements_.begin(); for ( ; it != row.elements_.end() ; ++it) { os << "x=" << x << " => " << *it << endl; x += it->full_width(); } return os; } int Row::left_x() const { double x = left_margin; const_iterator const end = elements_.end(); const_iterator cit = elements_.begin(); while (cit != end && cit->isVirtual()) { x += cit->full_width(); ++cit; } return int(x + 0.5); } int Row::right_x() const { double x = dim_.wid; const_iterator const begin = elements_.begin(); const_iterator cit = elements_.end(); while (cit != begin) { --cit; if (cit->isVirtual()) x -= cit->full_width(); else break; } return int(x + 0.5); } int Row::countSeparators() const { int n = 0; const_iterator const end = elements_.end(); for (const_iterator cit = elements_.begin() ; cit != end ; ++cit) n += cit->countSeparators(); return n; } bool Row::setExtraWidth(int w) { if (w < 0) // this is not expected to happen (but it does) return false; // amount of expansion: number of expanders time the em value for each // string element int exp_amount = 0; for (Row::Element const & e : elements_) exp_amount += e.expansionAmount(); if (!exp_amount) return false; // extra length per expander per em double extra_per_em = double(w) / exp_amount; if (extra_per_em > MAX_SPACE_STRETCH) // do not stretch more than MAX_SPACE_STRETCH em per expander return false; // add extra length to each element proportionally to its em. for (Row::Element & e : elements_) if (e.type == Row::STRING) e.setExtra(extra_per_em); // update row dimension dim_.wid += w; return true; } bool Row::sameString(Font const & f, Change const & ch) const { if (elements_.empty()) return false; Element const & elt = elements_.back(); return elt.type == STRING && !elt.final && elt.font == f && elt.change == ch; } void Row::finalizeLast() { if (elements_.empty()) return; Element & elt = elements_.back(); if (elt.final) return; elt.final = true; if (elt.type == STRING) { dim_.wid -= elt.dim.wid; elt.dim.wid = theFontMetrics(elt.font).width(elt.str); dim_.wid += elt.dim.wid; } } void Row::add(pos_type const pos, Inset const * ins, Dimension const & dim, Font const & f, Change const & ch) { finalizeLast(); Element e(INSET, pos, f, ch); e.inset = ins; e.dim = dim; elements_.push_back(e); dim_.wid += dim.wid; } void Row::add(pos_type const pos, char_type const c, Font const & f, Change const & ch) { if (!sameString(f, ch)) { finalizeLast(); Element e(STRING, pos, f, ch); elements_.push_back(e); } if (back().str.length() % 30 == 0) { dim_.wid -= back().dim.wid; back().str += c; back().endpos = pos + 1; back().dim.wid = theFontMetrics(back().font).width(back().str); dim_.wid += back().dim.wid; } else { back().str += c; back().endpos = pos + 1; } } void Row::addVirtual(pos_type const pos, docstring const & s, Font const & f, Change const & ch) { finalizeLast(); Element e(VIRTUAL, pos, f, ch); e.str = s; e.dim.wid = theFontMetrics(f).width(s); dim_.wid += e.dim.wid; e.endpos = pos; elements_.push_back(e); finalizeLast(); } void Row::addSpace(pos_type const pos, int const width, Font const & f, Change const & ch) { finalizeLast(); Element e(SPACE, pos, f, ch); e.dim.wid = width; elements_.push_back(e); dim_.wid += e.dim.wid; } void Row::pop_back() { dim_.wid -= elements_.back().dim.wid; elements_.pop_back(); } bool Row::shortenIfNeeded(pos_type const keep, int const w, int const next_width) { if (empty() || width() <= w) return false; Elements::iterator const beg = elements_.begin(); Elements::iterator const end = elements_.end(); int wid = left_margin; // Search for the first element that goes beyond right margin Elements::iterator cit = beg; for ( ; cit != end ; ++cit) { if (wid + cit->dim.wid > w) break; wid += cit->dim.wid; } if (cit == end) { // This should not happen since the row is too long. LYXERR0("Something is wrong cannot shorten row: " << *this); return false; } // Iterate backwards over breakable elements and try to break them Elements::iterator cit_brk = cit; int wid_brk = wid + cit_brk->dim.wid; ++cit_brk; while (cit_brk != beg) { --cit_brk; // make a copy of the element to work on it. Element brk = *cit_brk; wid_brk -= brk.dim.wid; if (brk.countSeparators() == 0 || brk.pos < keep) continue; /* We have found a suitable separable element. This is the common case. * Try to break it cleanly (at word boundary) at a length that is both * - less than the available space on the row * - shorter than the natural width of the element, in order to enforce * break-up. */ if (brk.breakAt(min(w - wid_brk, brk.dim.wid - 2), false)) { /* if this element originally did not cause a row overflow * in itself, and the remainder of the row would still be * too large after breaking, then we will have issues in * next row. Thus breaking does not help. */ if (wid_brk + cit_brk->dim.wid < w && dim_.wid - (wid_brk + brk.dim.wid) >= next_width) { break; } end_ = brk.endpos; /* after breakAt, there may be spaces at the end of the * string, but they are not counted in the string length * (QTextLayout feature, actually). We remove them, but do * not change the end of the row, since spaces at row * break are invisible. */ brk.str = rtrim(brk.str); brk.endpos = brk.pos + brk.str.length(); *cit_brk = brk; dim_.wid = wid_brk + brk.dim.wid; // If there are other elements, they should be removed. elements_.erase(cit_brk + 1, end); return true; } } if (cit != beg && cit->type == VIRTUAL) { // It is not possible to separate a virtual element from the // previous one. --cit; wid -= cit->dim.wid; } if (cit != beg) { // There is no usable separator, but several elements have // been added. We can cut right here. end_ = cit->pos; dim_.wid = wid; elements_.erase(cit, end); return true; } /* If we are here, it means that we have not found a separator to * shorten the row. Let's try to break it again, but not at word * boundary this time. */ if (cit->breakAt(w - wid, true)) { end_ = cit->endpos; // See comment above. cit->str = rtrim(cit->str); cit->endpos = cit->pos + cit->str.length(); dim_.wid = wid + cit->dim.wid; // If there are other elements, they should be removed. elements_.erase(next(cit, 1), end); return true; } return false; } void Row::reverseRTL(bool const rtl_par) { pos_type i = 0; pos_type const end = elements_.size(); while (i < end) { // gather a sequence of elements with the same direction bool const rtl = elements_[i].isRTL(); pos_type j = i; while (j < end && elements_[j].isRTL() == rtl) ++j; // if the direction is not the same as the paragraph // direction, the sequence has to be reverted. if (rtl != rtl_par) reverse(elements_.begin() + i, elements_.begin() + j); i = j; } // If the paragraph itself is RTL, reverse everything if (rtl_par) reverse(elements_.begin(), elements_.end()); rtl_ = rtl_par; } Row::const_iterator const Row::findElement(pos_type const pos, bool const boundary, double & x) const { /** * When boundary is true, position i is in the row element (pos, endpos) * if * pos < i <= endpos * whereas, when boundary is false, the test is * pos <= i < endpos * The correction below allows to handle both cases. */ int const boundary_corr = (boundary && pos) ? -1 : 0; x = left_margin; /** Early return in trivial cases * 1) the row is empty * 2) the position is the left-most position of the row; there * is a quirk here however: if the first element is virtual * (end-of-par marker for example), then we have to look * closer */ if (empty() || (pos == begin()->left_pos() && !boundary && !begin()->isVirtual())) return begin(); Row::const_iterator cit = begin(); for ( ; cit != end() ; ++cit) { /** Look whether the cursor is inside the element's * span. Note that it is necessary to take the * boundary into account, and to accept virtual * elements, which have pos == endpos. */ if (pos + boundary_corr >= cit->pos && (pos + boundary_corr < cit->endpos || cit->isVirtual())) { x += cit->pos2x(pos); break; } x += cit->full_width(); } if (cit == end()) --cit; return cit; } } // namespace lyx