/** * \file InsetMathGrid.cpp * This file is part of LyX, the document processor. * Licence details can be found in the file COPYING. * * \author André Pönitz * * Full author contact details are available in file CREDITS. */ #include #include "InsetMathGrid.h" #include "MathArray.h" #include "MathParser.h" #include "MathStream.h" #include "BufferView.h" #include "CutAndPaste.h" #include "FuncStatus.h" #include "LColor.h" #include "Cursor.h" #include "debug.h" #include "FuncRequest.h" #include "gettext.h" #include "Undo.h" #include "frontends/Clipboard.h" #include "frontends/Painter.h" #include "insets/MailInset.h" #include "support/lstrings.h" #include namespace lyx { using support::bformat; using std::endl; using std::max; using std::min; using std::swap; using std::string; using std::auto_ptr; using std::istream; using std::istringstream; using std::vector; class GridInsetMailer : public MailInset { public: GridInsetMailer(InsetMathGrid & inset) : inset_(inset) {} /// virtual string const & name() const { static string const theName = "tabular"; return theName; } /// virtual string const inset2string(Buffer const &) const { odocstringstream data; //data << name() << " active_cell " << inset.getActCell() << '\n'; data << from_utf8(name()) << " active_cell " << 0 << '\n'; WriteStream ws(data); inset_.write(ws); return to_utf8(data.str()); } protected: InsetBase & inset() const { return inset_; } InsetMathGrid & inset_; }; namespace { docstring verboseHLine(int n) { docstring res; for (int i = 0; i < n; ++i) res += "\\hline"; if (n) res += ' '; return res; } int extractInt(istream & is) { int num = 1; is >> num; return (num == 0) ? 1 : num; } } ////////////////////////////////////////////////////////////// InsetMathGrid::CellInfo::CellInfo() : dummy_(false) {} ////////////////////////////////////////////////////////////// InsetMathGrid::RowInfo::RowInfo() : lines_(0), skip_(0), allow_pagebreak_(true) {} int InsetMathGrid::RowInfo::skipPixels() const { return crskip_.inBP(); } ////////////////////////////////////////////////////////////// InsetMathGrid::ColInfo::ColInfo() : align_('c'), lines_(0) {} ////////////////////////////////////////////////////////////// InsetMathGrid::InsetMathGrid(char v, docstring const & h) : InsetMathNest(guessColumns(h)), rowinfo_(2), colinfo_(guessColumns(h) + 1), cellinfo_(1 * guessColumns(h)) { setDefaults(); valign(v); halign(h); //lyxerr << "created grid with " << ncols() << " columns" << endl; } InsetMathGrid::InsetMathGrid() : InsetMathNest(1), rowinfo_(1 + 1), colinfo_(1 + 1), cellinfo_(1), v_align_('c') { setDefaults(); } InsetMathGrid::InsetMathGrid(col_type m, row_type n) : InsetMathNest(m * n), rowinfo_(n + 1), colinfo_(m + 1), cellinfo_(m * n), v_align_('c') { setDefaults(); } InsetMathGrid::InsetMathGrid(col_type m, row_type n, char v, docstring const & h) : InsetMathNest(m * n), rowinfo_(n + 1), colinfo_(m + 1), cellinfo_(m * n), v_align_(v) { setDefaults(); valign(v); halign(h); } auto_ptr InsetMathGrid::doClone() const { return auto_ptr(new InsetMathGrid(*this)); } InsetMath::idx_type InsetMathGrid::index(row_type row, col_type col) const { return col + ncols() * row; } void InsetMathGrid::setDefaults() { if (ncols() <= 0) lyxerr << "positive number of columns expected" << endl; //if (nrows() <= 0) // lyxerr << "positive number of rows expected" << endl; for (col_type col = 0; col < ncols(); ++col) { colinfo_[col].align_ = defaultColAlign(col); colinfo_[col].skip_ = defaultColSpace(col); } } void InsetMathGrid::halign(docstring const & hh) { col_type col = 0; for (docstring::const_iterator it = hh.begin(); it != hh.end(); ++it) { char_type c = *it; if (c == '|') { colinfo_[col].lines_++; } else if (col >= ncols()) { // Only '|' is allowed in the last dummy column break; } else if (c == 'c' || c == 'l' || c == 'r') { colinfo_[col].align_ = (char)c; ++col; colinfo_[col].lines_ = 0; } else { lyxerr << "unknown column separator: '" << c << "'" << endl; } } /* col_type n = hh.size(); if (n > ncols()) n = ncols(); for (col_type col = 0; col < n; ++col) colinfo_[col].align_ = hh[col]; */ } InsetMathGrid::col_type InsetMathGrid::guessColumns(docstring const & hh) const { col_type col = 0; for (docstring::const_iterator it = hh.begin(); it != hh.end(); ++it) if (*it == 'c' || *it == 'l' || *it == 'r') ++col; // let's have at least one column, even if we did not recognize its // alignment if (col == 0) col = 1; return col; } void InsetMathGrid::halign(char h, col_type col) { colinfo_[col].align_ = h; } char InsetMathGrid::halign(col_type col) const { return colinfo_[col].align_; } docstring InsetMathGrid::halign() const { docstring res; for (col_type col = 0; col < ncols(); ++col) { res += docstring(colinfo_[col].lines_, '|'); res += colinfo_[col].align_; } return res + docstring(colinfo_[ncols()].lines_, '|'); } void InsetMathGrid::valign(char c) { v_align_ = c; } char InsetMathGrid::valign() const { return v_align_; } InsetMathGrid::col_type InsetMathGrid::ncols() const { return colinfo_.size() - 1; } InsetMathGrid::row_type InsetMathGrid::nrows() const { return rowinfo_.size() - 1; } InsetMathGrid::col_type InsetMathGrid::col(idx_type idx) const { return idx % ncols(); } InsetMathGrid::row_type InsetMathGrid::row(idx_type idx) const { return idx / ncols(); } void InsetMathGrid::vcrskip(LyXLength const & crskip, row_type row) { rowinfo_[row].crskip_ = crskip; } LyXLength InsetMathGrid::vcrskip(row_type row) const { return rowinfo_[row].crskip_; } void InsetMathGrid::metrics(MetricsInfo & mi) const { // let the cells adjust themselves InsetMathNest::metrics(mi); // compute absolute sizes of vertical structure for (row_type row = 0; row < nrows(); ++row) { int asc = 0; int desc = 0; for (col_type col = 0; col < ncols(); ++col) { MathArray const & c = cell(index(row, col)); asc = max(asc, c.ascent()); desc = max(desc, c.descent()); } rowinfo_[row].ascent_ = asc; rowinfo_[row].descent_ = desc; } rowinfo_[0].ascent_ += hlinesep() * rowinfo_[0].lines_; rowinfo_[nrows()].ascent_ = 0; rowinfo_[nrows()].descent_ = 0; // compute vertical offsets rowinfo_[0].offset_ = 0; for (row_type row = 1; row <= nrows(); ++row) { rowinfo_[row].offset_ = rowinfo_[row - 1].offset_ + rowinfo_[row - 1].descent_ + rowinfo_[row - 1].skipPixels() + rowsep() + rowinfo_[row].lines_ * hlinesep() + rowinfo_[row].ascent_; } // adjust vertical offset int h = 0; switch (v_align_) { case 't': h = 0; break; case 'b': h = rowinfo_[nrows() - 1].offset_; break; default: h = rowinfo_[nrows() - 1].offset_ / 2; } for (row_type row = 0; row <= nrows(); ++row) rowinfo_[row].offset_ -= h; // compute absolute sizes of horizontal structure for (col_type col = 0; col < ncols(); ++col) { int wid = 0; for (row_type row = 0; row < nrows(); ++row) wid = max(wid, cell(index(row, col)).width()); colinfo_[col].width_ = wid; } colinfo_[ncols()].width_ = 0; // compute horizontal offsets colinfo_[0].offset_ = border(); for (col_type col = 1; col <= ncols(); ++col) { colinfo_[col].offset_ = colinfo_[col - 1].offset_ + colinfo_[col - 1].width_ + colinfo_[col - 1].skip_ + colsep() + colinfo_[col].lines_ * vlinesep(); } dim_.wid = colinfo_[ncols() - 1].offset_ + colinfo_[ncols() - 1].width_ + vlinesep() * colinfo_[ncols()].lines_ + border(); dim_.asc = - rowinfo_[0].offset_ + rowinfo_[0].ascent_ + hlinesep() * rowinfo_[0].lines_ + border(); dim_.des = rowinfo_[nrows() - 1].offset_ + rowinfo_[nrows() - 1].descent_ + hlinesep() * rowinfo_[nrows()].lines_ + border(); /* // Increase ws_[i] for 'R' columns (except the first one) for (int i = 1; i < nc_; ++i) if (align_[i] == 'R') ws_[i] += 10 * df_width; // Increase ws_[i] for 'C' column if (align_[0] == 'C') if (ws_[0] < 7 * workwidth / 8) ws_[0] = 7 * workwidth / 8; // Adjust local tabs width = colsep(); for (cxrow = row_.begin(); cxrow; ++cxrow) { int rg = COLSEP; int lf = 0; for (int i = 0; i < nc_; ++i) { bool isvoid = false; if (cxrow->getTab(i) <= 0) { cxrow->setTab(i, df_width); isvoid = true; } switch (align_[i]) { case 'l': lf = 0; break; case 'c': lf = (ws_[i] - cxrow->getTab(i))/2; break; case 'r': case 'R': lf = ws_[i] - cxrow->getTab(i); break; case 'C': if (cxrow == row_.begin()) lf = 0; else if (cxrow.is_last()) lf = ws_[i] - cxrow->getTab(i); else lf = (ws_[i] - cxrow->getTab(i))/2; break; } int const ww = (isvoid) ? lf : lf + cxrow->getTab(i); cxrow->setTab(i, lf + rg); rg = ws_[i] - ww + colsep(); if (cxrow == row_.begin()) width += ws_[i] + colsep(); } cxrow->setBaseline(cxrow->getBaseline() - ascent); } */ metricsMarkers2(dim_); } bool InsetMathGrid::metrics(MetricsInfo & mi, Dimension & dim) const { dim = dim_; metrics(mi); if (dim_ == dim) return false; dim = dim_; return true; } void InsetMathGrid::draw(PainterInfo & pi, int x, int y) const { drawWithMargin(pi, x, y, 0, 0); } void InsetMathGrid::drawWithMargin(PainterInfo & pi, int x, int y, int lmargin, int rmargin) const { for (idx_type idx = 0; idx < nargs(); ++idx) cell(idx).draw(pi, x + lmargin + cellXOffset(idx), y + cellYOffset(idx)); for (row_type row = 0; row <= nrows(); ++row) for (unsigned int i = 0; i < rowinfo_[row].lines_; ++i) { int yy = y + rowinfo_[row].offset_ - rowinfo_[row].ascent_ - i * hlinesep() - hlinesep()/2 - rowsep()/2; pi.pain.line(x + lmargin + 1, yy, x + dim_.width() - rmargin - 1, yy, LColor::foreground); } for (col_type col = 0; col <= ncols(); ++col) for (unsigned int i = 0; i < colinfo_[col].lines_; ++i) { int xx = x + lmargin + colinfo_[col].offset_ - i * vlinesep() - vlinesep()/2 - colsep()/2; pi.pain.line(xx, y - dim_.ascent() + 1, xx, y + dim_.descent() - 1, LColor::foreground); } drawMarkers2(pi, x, y); } void InsetMathGrid::metricsT(TextMetricsInfo const & mi, Dimension & dim) const { // let the cells adjust themselves //InsetMathNest::metrics(mi); for (idx_type i = 0; i < nargs(); ++i) cell(i).metricsT(mi, dim); // compute absolute sizes of vertical structure for (row_type row = 0; row < nrows(); ++row) { int asc = 0; int desc = 0; for (col_type col = 0; col < ncols(); ++col) { MathArray const & c = cell(index(row, col)); asc = max(asc, c.ascent()); desc = max(desc, c.descent()); } rowinfo_[row].ascent_ = asc; rowinfo_[row].descent_ = desc; } //rowinfo_[0].ascent_ += hlinesep() * rowinfo_[0].lines_; rowinfo_[nrows()].ascent_ = 0; rowinfo_[nrows()].descent_ = 0; // compute vertical offsets rowinfo_[0].offset_ = 0; for (row_type row = 1; row <= nrows(); ++row) { rowinfo_[row].offset_ = rowinfo_[row - 1].offset_ + rowinfo_[row - 1].descent_ + //rowinfo_[row - 1].skipPixels() + 1 + //rowsep() + //rowinfo_[row].lines_ * hlinesep() + rowinfo_[row].ascent_; } // adjust vertical offset int h = 0; switch (v_align_) { case 't': h = 0; break; case 'b': h = rowinfo_[nrows() - 1].offset_; break; default: h = rowinfo_[nrows() - 1].offset_ / 2; } for (row_type row = 0; row <= nrows(); ++row) rowinfo_[row].offset_ -= h; // compute absolute sizes of horizontal structure for (col_type col = 0; col < ncols(); ++col) { int wid = 0; for (row_type row = 0; row < nrows(); ++row) wid = max(wid, cell(index(row, col)).width()); colinfo_[col].width_ = wid; } colinfo_[ncols()].width_ = 0; // compute horizontal offsets colinfo_[0].offset_ = border(); for (col_type col = 1; col <= ncols(); ++col) { colinfo_[col].offset_ = colinfo_[col - 1].offset_ + colinfo_[col - 1].width_ + colinfo_[col - 1].skip_ + 1 ; //colsep() + //colinfo_[col].lines_ * vlinesep(); } dim.wid = colinfo_[ncols() - 1].offset_ + colinfo_[ncols() - 1].width_ //+ vlinesep() * colinfo_[ncols()].lines_ + 2; dim.asc = -rowinfo_[0].offset_ + rowinfo_[0].ascent_ //+ hlinesep() * rowinfo_[0].lines_ + 1; dim.des = rowinfo_[nrows() - 1].offset_ + rowinfo_[nrows() - 1].descent_ //+ hlinesep() * rowinfo_[nrows()].lines_ + 1; } void InsetMathGrid::drawT(TextPainter & pain, int x, int y) const { for (idx_type idx = 0; idx < nargs(); ++idx) cell(idx).drawT(pain, x + cellXOffset(idx), y + cellYOffset(idx)); } docstring InsetMathGrid::eolString(row_type row, bool emptyline, bool fragile) const { docstring eol; if (!rowinfo_[row].crskip_.zero()) eol += '[' + from_utf8(rowinfo_[row].crskip_.asLatexString()) + ']'; else if(!rowinfo_[row].allow_pagebreak_) eol += '*'; // make sure an upcoming '[' does not break anything if (row + 1 < nrows()) { MathArray const & c = cell(index(row + 1, 0)); if (c.size() && c.front()->getChar() == '[') //eol += "[0pt]"; eol += "{}"; } // only add \\ if necessary if (eol.empty() && row + 1 == nrows() && (nrows() == 1 || !emptyline)) return docstring(); return (fragile ? "\\protect\\\\" : "\\\\") + eol; } docstring InsetMathGrid::eocString(col_type col, col_type lastcol) const { if (col + 1 == lastcol) return docstring(); return from_ascii(" & "); } void InsetMathGrid::addRow(row_type row) { rowinfo_.insert(rowinfo_.begin() + row + 1, RowInfo()); cells_.insert (cells_.begin() + (row + 1) * ncols(), ncols(), MathArray()); cellinfo_.insert (cellinfo_.begin() + (row + 1) * ncols(), ncols(), CellInfo()); } void InsetMathGrid::appendRow() { rowinfo_.push_back(RowInfo()); //cells_.insert(cells_.end(), ncols(), MathArray()); for (col_type col = 0; col < ncols(); ++col) { cells_.push_back(cells_type::value_type()); cellinfo_.push_back(CellInfo()); } } void InsetMathGrid::delRow(row_type row) { if (nrows() == 1) return; cells_type::iterator it = cells_.begin() + row * ncols(); cells_.erase(it, it + ncols()); vector::iterator jt = cellinfo_.begin() + row * ncols(); cellinfo_.erase(jt, jt + ncols()); rowinfo_.erase(rowinfo_.begin() + row); } void InsetMathGrid::copyRow(row_type row) { addRow(row); for (col_type col = 0; col < ncols(); ++col) cells_[(row + 1) * ncols() + col] = cells_[row * ncols() + col]; } void InsetMathGrid::swapRow(row_type row) { if (nrows() == 1) return; if (row + 1 == nrows()) --row; for (col_type col = 0; col < ncols(); ++col) swap(cells_[row * ncols() + col], cells_[(row + 1) * ncols() + col]); } void InsetMathGrid::addCol(col_type newcol) { const col_type nc = ncols(); const row_type nr = nrows(); cells_type new_cells((nc + 1) * nr); vector new_cellinfo((nc + 1) * nr); for (row_type row = 0; row < nr; ++row) for (col_type col = 0; col < nc; ++col) { new_cells[row * (nc + 1) + col + (col > newcol)] = cells_[row * nc + col]; new_cellinfo[row * (nc + 1) + col + (col > newcol)] = cellinfo_[row * nc + col]; } swap(cells_, new_cells); swap(cellinfo_, new_cellinfo); ColInfo inf; inf.skip_ = defaultColSpace(newcol); inf.align_ = defaultColAlign(newcol); colinfo_.insert(colinfo_.begin() + newcol, inf); } void InsetMathGrid::delCol(col_type col) { if (ncols() == 1) return; cells_type tmpcells; vector tmpcellinfo; for (col_type i = 0; i < nargs(); ++i) if (i % ncols() != col) { tmpcells.push_back(cells_[i]); tmpcellinfo.push_back(cellinfo_[i]); } swap(cells_, tmpcells); swap(cellinfo_, tmpcellinfo); colinfo_.erase(colinfo_.begin() + col); } void InsetMathGrid::copyCol(col_type col) { addCol(col); for (row_type row = 0; row < nrows(); ++row) cells_[row * ncols() + col + 1] = cells_[row * ncols() + col]; } void InsetMathGrid::swapCol(col_type col) { if (ncols() == 1) return; if (col + 1 == ncols()) --col; for (row_type row = 0; row < nrows(); ++row) swap(cells_[row * ncols() + col], cells_[row * ncols() + col + 1]); } int InsetMathGrid::cellXOffset(idx_type idx) const { col_type c = col(idx); int x = colinfo_[c].offset_; char align = colinfo_[c].align_; if (align == 'r' || align == 'R') x += colinfo_[c].width_ - cell(idx).width(); if (align == 'c' || align == 'C') x += (colinfo_[c].width_ - cell(idx).width()) / 2; return x; } int InsetMathGrid::cellYOffset(idx_type idx) const { return rowinfo_[row(idx)].offset_; } bool InsetMathGrid::idxUpDown(Cursor & cur, bool up) const { if (up) { if (cur.row() == 0) return false; cur.idx() -= ncols(); } else { if (cur.row() + 1 >= nrows()) return false; cur.idx() += ncols(); } cur.pos() = cur.cell().x2pos(cur.x_target() - cur.cell().xo(cur.bv())); return true; } bool InsetMathGrid::idxLeft(Cursor & cur) const { // leave matrix if on the left hand edge if (cur.col() == 0) return false; --cur.idx(); cur.pos() = cur.lastpos(); return true; } bool InsetMathGrid::idxRight(Cursor & cur) const { // leave matrix if on the right hand edge if (cur.col() + 1 == ncols()) return false; ++cur.idx(); cur.pos() = 0; return true; } bool InsetMathGrid::idxFirst(Cursor & cur) const { switch (v_align_) { case 't': cur.idx() = 0; break; case 'b': cur.idx() = (nrows() - 1) * ncols(); break; default: cur.idx() = ((nrows() - 1) / 2) * ncols(); } cur.pos() = 0; return true; } bool InsetMathGrid::idxLast(Cursor & cur) const { switch (v_align_) { case 't': cur.idx() = ncols() - 1; break; case 'b': cur.idx() = nargs() - 1; break; default: cur.idx() = ((nrows() - 1) / 2 + 1) * ncols() - 1; } cur.pos() = cur.lastpos(); return true; } bool InsetMathGrid::idxDelete(idx_type & idx) { // nothing to do if we have just one row if (nrows() == 1) return false; // nothing to do if we are in the middle of the last row of the inset if (idx + ncols() > nargs()) return false; // try to delete entire sequence of ncols() empty cells if possible for (idx_type i = idx; i < idx + ncols(); ++i) if (cell(i).size()) return false; // move cells if necessary for (idx_type i = index(row(idx), 0); i < idx; ++i) swap(cell(i), cell(i + ncols())); delRow(row(idx)); if (idx >= nargs()) idx = nargs() - 1; // undo effect of Ctrl-Tab (i.e. pull next cell) //if (idx + 1 != nargs()) // cell(idx).swap(cell(idx + 1)); // we handled the event.. return true; } // reimplement old behaviour when pressing Delete in the last position // of a cell void InsetMathGrid::idxGlue(idx_type idx) { col_type c = col(idx); if (c + 1 == ncols()) { if (row(idx) + 1 != nrows()) { for (col_type cc = 0; cc < ncols(); ++cc) cell(idx).append(cell(idx + cc + 1)); delRow(row(idx) + 1); } } else { cell(idx).append(cell(idx + 1)); for (col_type cc = c + 2; cc < ncols(); ++cc) cell(idx - c + cc - 1) = cell(idx - c + cc); cell(idx - c + ncols() - 1).clear(); } } InsetMathGrid::RowInfo const & InsetMathGrid::rowinfo(row_type row) const { return rowinfo_[row]; } InsetMathGrid::RowInfo & InsetMathGrid::rowinfo(row_type row) { return rowinfo_[row]; } bool InsetMathGrid::idxBetween(idx_type idx, idx_type from, idx_type to) const { row_type const ri = row(idx); row_type const r1 = min(row(from), row(to)); row_type const r2 = max(row(from), row(to)); col_type const ci = col(idx); col_type const c1 = min(col(from), col(to)); col_type const c2 = max(col(from), col(to)); return r1 <= ri && ri <= r2 && c1 <= ci && ci <= c2; } void InsetMathGrid::normalize(NormalStream & os) const { os << "[grid "; for (row_type row = 0; row < nrows(); ++row) { os << "[row "; for (col_type col = 0; col < ncols(); ++col) os << "[cell " << cell(index(row, col)) << ']'; os << ']'; } os << ']'; } void InsetMathGrid::mathmlize(MathStream & os) const { os << MTag("mtable"); for (row_type row = 0; row < nrows(); ++row) { os << MTag("mtr"); for (col_type col = 0; col < ncols(); ++col) os << cell(index(row, col)); os << ETag("mtr"); } os << ETag("mtable"); } void InsetMathGrid::write(WriteStream & os) const { docstring eol; for (row_type row = 0; row < nrows(); ++row) { os << verboseHLine(rowinfo_[row].lines_); // don't write & and empty cells at end of line col_type lastcol = 0; bool emptyline = true; for (col_type col = 0; col < ncols(); ++col) if (!cell(index(row, col)).empty()) { lastcol = col + 1; emptyline = false; } for (col_type col = 0; col < lastcol; ++col) os << cell(index(row, col)) << eocString(col, lastcol); eol = eolString(row, emptyline, os.fragile()); os << eol; // append newline only if line wasn't completely empty // and this was not the last line in the grid if (!emptyline && row + 1 < nrows()) os << "\n"; } docstring const s = verboseHLine(rowinfo_[nrows()].lines_); if (!s.empty()) { if (eol.empty()) { if (os.fragile()) os << "\\protect"; os << "\\\\"; } os << s; } } int InsetMathGrid::colsep() const { return 6; } int InsetMathGrid::rowsep() const { return 6; } int InsetMathGrid::hlinesep() const { return 3; } int InsetMathGrid::vlinesep() const { return 3; } int InsetMathGrid::border() const { return 1; } void InsetMathGrid::splitCell(Cursor & cur) { if (cur.idx() == cur.lastidx()) return; MathArray ar = cur.cell(); ar.erase(0, cur.pos()); cur.cell().erase(cur.pos(), cur.lastpos()); ++cur.idx(); cur.pos() = 0; cur.cell().insert(0, ar); } void InsetMathGrid::doDispatch(Cursor & cur, FuncRequest & cmd) { //lyxerr << "*** InsetMathGrid: request: " << cmd << endl; switch (cmd.action) { case LFUN_MOUSE_RELEASE: //if (cmd.button() == mouse_button::button3) { // GridInsetMailer(*this).showDialog(); // return DispatchResult(true, true); //} InsetMathNest::doDispatch(cur, cmd); break; case LFUN_INSET_DIALOG_UPDATE: GridInsetMailer(*this).updateDialog(&cur.bv()); break; // insert file functions case LFUN_LINE_DELETE: // FIXME: We use recordUndoInset when a change reflects more // than one cell, because recordUndo does not work for // multiple cells. Unfortunately this puts the cursor in front // of the inset after undo. This is (especilally for large // grids) annoying. recordUndoInset(cur); //autocorrect_ = false; //macroModeClose(); //if (selection_) { // selDel(); // break; //} if (nrows() > 1) delRow(cur.row()); if (cur.idx() > cur.lastidx()) cur.idx() = cur.lastidx(); if (cur.pos() > cur.lastpos()) cur.pos() = cur.lastpos(); break; case LFUN_CELL_SPLIT: recordUndo(cur); splitCell(cur); break; case LFUN_CELL_BACKWARD: // See below. cur.selection() = false; if (!idxPrev(cur)) { cmd = FuncRequest(LFUN_FINISHED_LEFT); cur.undispatched(); } break; case LFUN_CELL_FORWARD: // Can't handle selection by additional 'shift' as this is // hard bound to LFUN_CELL_BACKWARD cur.selection() = false; if (!idxNext(cur)) { cmd = FuncRequest(LFUN_FINISHED_RIGHT); cur.undispatched(); } break; case LFUN_BREAK_LINE: { recordUndoInset(cur); row_type const r = cur.row(); addRow(r); // split line for (col_type c = col(cur.idx()) + 1; c < ncols(); ++c) swap(cell(index(r, c)), cell(index(r + 1, c))); // split cell splitCell(cur); swap(cell(cur.idx()), cell(cur.idx() + ncols() - 1)); if (cur.idx() > 0) --cur.idx(); cur.pos() = cur.lastpos(); //mathcursor->normalize(); //cmd = FuncRequest(LFUN_FINISHED_LEFT); break; } case LFUN_TABULAR_FEATURE: { recordUndoInset(cur); //lyxerr << "handling tabular-feature " << to_utf8(cmd.argument()) << endl; istringstream is(to_utf8(cmd.argument())); string s; is >> s; if (s == "valign-top") valign('t'); else if (s == "valign-middle") valign('c'); else if (s == "valign-bottom") valign('b'); else if (s == "align-left") halign('l', cur.col()); else if (s == "align-right") halign('r', cur.col()); else if (s == "align-center") halign('c', cur.col()); else if (s == "append-row") for (int i = 0, n = extractInt(is); i < n; ++i) addRow(cur.row()); else if (s == "delete-row") { for (int i = 0, n = extractInt(is); i < n; ++i) { delRow(cur.row()); if (cur.idx() >= nargs()) cur.idx() -= ncols(); } cur.pos() = 0; // trick, see below } else if (s == "copy-row") { // Here (as later) we save the cursor col/row // in order to restore it after operation. row_type const r = cur.row(); col_type const c = cur.col(); for (int i = 0, n = extractInt(is); i < n; ++i) copyRow(cur.row()); cur.idx() = index(r, c); } else if (s == "swap-row") { swapRow(cur.row()); // Trick to suppress same-idx-means-different-cell // assertion crash: cur.pos() = 0; } else if (s == "add-hline-above") rowinfo_[cur.row()].lines_++; else if (s == "add-hline-below") rowinfo_[cur.row()+1].lines_++; else if (s == "delete-hline-above") rowinfo_[cur.row()].lines_--; else if (s == "delete-hline-below") rowinfo_[cur.row()+1].lines_--; else if (s == "append-column") { row_type const r = cur.row(); col_type const c = cur.col(); for (int i = 0, n = extractInt(is); i < n; ++i) addCol(cur.col()); cur.idx() = index(r, c); } else if (s == "delete-column") { row_type const r = cur.row(); col_type const c = cur.col(); for (int i = 0, n = extractInt(is); i < n; ++i) delCol(col(cur.idx())); cur.idx() = index(r, min(c, cur.ncols() - 1)); cur.pos() = 0; // trick, see above } else if (s == "copy-column") { row_type const r = cur.row(); col_type const c = cur.col(); copyCol(cur.col()); cur.idx() = index(r, c); } else if (s == "swap-column") { swapCol(cur.col()); cur.pos() = 0; // trick, see above } else if (s == "add-vline-left") colinfo_[cur.col()].lines_++; else if (s == "add-vline-right") colinfo_[cur.col()+1].lines_++; else if (s == "delete-vline-left") colinfo_[cur.col()].lines_--; else if (s == "delete-vline-right") colinfo_[cur.col()+1].lines_--; else { cur.undispatched(); break; } lyxerr << "returning FINISHED_LEFT" << endl; break; } case LFUN_PASTE: { cur.message(_("Paste")); cap::replaceSelection(cur); docstring topaste; if (cmd.argument().empty() && !theClipboard().isInternal()) topaste = theClipboard().getAsText(); else { idocstringstream is(cmd.argument()); int n = 0; is >> n; topaste = cap::getSelection(cur.buffer(), n); } InsetMathGrid grid(1, 1); if (!topaste.empty()) mathed_parse_normal(grid, topaste); if (grid.nargs() == 1) { // single cell/part of cell recordUndo(cur); cur.cell().insert(cur.pos(), grid.cell(0)); cur.pos() += grid.cell(0).size(); } else { // multiple cells recordUndoInset(cur); col_type const numcols = min(grid.ncols(), ncols() - col(cur.idx())); row_type const numrows = min(grid.nrows(), nrows() - cur.row()); for (row_type r = 0; r < numrows; ++r) { for (col_type c = 0; c < numcols; ++c) { idx_type i = index(r + cur.row(), c + col(cur.idx())); cell(i).insert(0, grid.cell(grid.index(r, c))); } // append the left over horizontal cells to the last column idx_type i = index(r + cur.row(), ncols() - 1); for (InsetMath::col_type c = numcols; c < grid.ncols(); ++c) cell(i).append(grid.cell(grid.index(r, c))); } // append the left over vertical cells to the last _cell_ idx_type i = nargs() - 1; for (row_type r = numrows; r < grid.nrows(); ++r) for (col_type c = 0; c < grid.ncols(); ++c) cell(i).append(grid.cell(grid.index(r, c))); } cur.clearSelection(); // bug 393 cur.bv().switchKeyMap(); finishUndo(); break; } case LFUN_LINE_BEGIN_SELECT: case LFUN_LINE_BEGIN: case LFUN_WORD_BACKWARD_SELECT: case LFUN_WORD_BACKWARD: cur.selHandle(cmd.action == LFUN_WORD_BACKWARD_SELECT || cmd.action == LFUN_LINE_BEGIN_SELECT); cur.macroModeClose(); if (cur.pos() != 0) { cur.pos() = 0; } else if (cur.idx() % cur.ncols() != 0) { cur.idx() -= cur.idx() % cur.ncols(); cur.pos() = 0; } else if (cur.idx() != 0) { cur.idx() = 0; cur.pos() = 0; } else { cmd = FuncRequest(LFUN_FINISHED_LEFT); cur.undispatched(); } break; case LFUN_WORD_FORWARD_SELECT: case LFUN_WORD_FORWARD: case LFUN_LINE_END_SELECT: case LFUN_LINE_END: cur.selHandle(cmd.action == LFUN_WORD_FORWARD_SELECT || cmd.action == LFUN_LINE_END_SELECT); cur.macroModeClose(); cur.clearTargetX(); if (cur.pos() != cur.lastpos()) { cur.pos() = cur.lastpos(); } else if ((cur.idx() + 1) % cur.ncols() != 0) { cur.idx() += cur.ncols() - 1 - cur.idx() % cur.ncols(); cur.pos() = cur.lastpos(); } else if (cur.idx() != cur.lastidx()) { cur.idx() = cur.lastidx(); cur.pos() = cur.lastpos(); } else { cmd = FuncRequest(LFUN_FINISHED_RIGHT); cur.undispatched(); } break; default: InsetMathNest::doDispatch(cur, cmd); } } bool InsetMathGrid::getStatus(Cursor & cur, FuncRequest const & cmd, FuncStatus & status) const { switch (cmd.action) { case LFUN_TABULAR_FEATURE: { string const s = to_utf8(cmd.argument()); if (nrows() <= 1 && (s == "delete-row" || s == "swap-row")) { status.enabled(false); status.message(from_utf8(N_("Only one row"))); return true; } if (ncols() <= 1 && (s == "delete-column" || s == "swap-column")) { status.enabled(false); status.message(from_utf8(N_("Only one column"))); return true; } if ((rowinfo_[cur.row()].lines_ == 0 && s == "delete-hline-above") || (rowinfo_[cur.row() + 1].lines_ == 0 && s == "delete-hline-below")) { status.enabled(false); status.message(from_utf8(N_("No hline to delete"))); return true; } if ((colinfo_[cur.col()].lines_ == 0 && s == "delete-vline-left") || (colinfo_[cur.col() + 1].lines_ == 0 && s == "delete-vline-right")) { status.enabled(false); status.message(from_utf8(N_("No vline to delete"))); return true; } if (s == "valign-top" || s == "valign-middle" || s == "valign-bottom" || s == "align-left" || s == "align-right" || s == "align-center" || s == "append-row" || s == "delete-row" || s == "copy-row" || s == "swap-row" || s == "add-hline-above" || s == "add-hline-below" || s == "delete-hline-above" || s == "delete-hline-below" || s == "append-column" || s == "delete-column" || s == "copy-column" || s == "swap-column" || s == "add-vline-left" || s == "add-vline-right" || s == "delete-vline-left" || s == "delete-vline-right") status.enabled(true); else { status.enabled(false); status.message(bformat( from_utf8(N_("Unknown tabular feature '%1$s'")), lyx::from_ascii(s))); } status.setOnOff(s == "align-left" && halign(cur.col()) == 'l' || s == "align-right" && halign(cur.col()) == 'r' || s == "align-center" && halign(cur.col()) == 'c' || s == "valign-top" && valign() == 't' || s == "valign-bottom" && valign() == 'b' || s == "valign-middle" && valign() == 'm'); #if 0 // FIXME: What did this code do? // Please check whether it is still needed! // should be more precise if (v_align_ == '\0') { status.enable(true); break; } if (cmd.argument().empty()) { status.enable(false); break; } if (!support::contains("tcb", cmd.argument()[0])) { status.enable(false); break; } status.setOnOff(cmd.argument()[0] == v_align_); status.enabled(true); #endif return true; } case LFUN_CELL_SPLIT: status.enabled(true); return true; case LFUN_CELL_BACKWARD: case LFUN_CELL_FORWARD: status.enabled(true); return true; default: return InsetMathNest::getStatus(cur, cmd, status); } } } // namespace lyx