lyx_mirror/src/mathed/math_cursor.C

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/*
* File: math_cursor.C
* Purpose: Interaction for mathed
* Author: Alejandro Aguilar Sierra <asierra@servidor.unam.mx>
* Created: January 1996
* Description: Math interaction for a WYSIWYG math editor.
*
* Dependencies: Xlib, XForms
*
* Copyright: 1996, Alejandro Aguilar Sierra
*
* Version: 0.8beta, Math & Lyx project.
*
* You are free to use and modify this code under the terms of
* the GNU General Public Licence version 2 or later.
*/
#ifdef __GNUG__
#pragma implementation
#endif
#include <config.h>
#include <algorithm>
#include <cctype>
#include "debug.h"
#include "LColor.h"
#include "Painter.h"
#include "mathed/support.h"
#include "formulabase.h"
#include "math_cursor.h"
#include "math_arrayinset.h"
#include "math_bigopinset.h"
#include "math_decorationinset.h"
#include "math_deliminset.h"
#include "math_dotsinset.h"
#include "math_fracinset.h"
#include "math_funcinset.h"
#include "math_gridinset.h"
#include "math_macro.h"
#include "math_macroarg.h"
#include "math_macrotable.h"
#include "math_macrotemplate.h"
#include "math_matrixinset.h"
#include "math_rootinset.h"
#include "math_spaceinset.h"
#include "math_sqrtinset.h"
#include "support/lstrings.h"
#include "math_scriptinset.h"
#include "math_parser.h"
using std::endl;
using std::min;
using std::max;
using std::isalnum;
namespace {
struct Selection
{
void grab(MathCursor const & cursor)
{
data_.clear();
MathCursorPos i1;
MathCursorPos i2;
cursor.getSelection(i1, i2);
if (i1.idx_ == i2.idx_)
data_.push_back(MathArray(i1.cell(), i1.pos_, i2.pos_));
else {
#ifdef RECTANGULAR_SELECT
std::vector<int> indices = i1.par_->idxBetween(i1.idx_, i2.idx_);
for (unsigned i = 0; i < indices.size(); ++i)
data_.push_back(i1.cell(indices[i]));
#else
data_.push_back(MathArray(i1.cell(), i1.pos_, i1.cell().size()));
for (int i = i1.idx_ + 1; i < i2.idx_; ++i)
data_.push_back(i1.cell(i));
data_.push_back(MathArray(i2.cell(), 0, i2.pos_));
#endif
}
}
void erase(MathCursor & cursor)
{
MathCursorPos i1;
MathCursorPos i2;
cursor.getSelection(i1, i2);
if (i1.idx_ == i2.idx_) {
i1.cell().erase(i1.pos_, i2.pos_);
} else {
std::vector<int> indices = i1.par_->idxBetween(i1.idx_, i2.idx_);
for (unsigned i = 0; i < indices.size(); ++i)
i1.cell(indices[i]).erase();
}
cursor.cursor() = i1;
}
void paste(MathCursor & cursor) const
{
cursor.cursor().cell().push_back(glue());
}
// glues selection to one cell
MathArray glue() const
{
MathArray ar;
for (unsigned i = 0; i < data_.size(); ++i)
ar.push_back(data_[i]);
return ar;
}
void clear()
{
data_.clear();
}
std::vector<MathArray> data_;
};
Selection theSelection;
bool IsMacro(short tok, int id)
{
return tok != LM_TK_STACK &&
tok != LM_TK_FRAC &&
tok != LM_TK_SQRT &&
tok != LM_TK_DECORATION &&
tok != LM_TK_SPACE &&
tok != LM_TK_DOTS &&
tok != LM_TK_FUNCLIM &&
tok != LM_TK_BIGSYM &&
!(tok == LM_TK_SYM && id < 255);
}
std::ostream & operator<<(std::ostream & os, MathCursorPos const & p)
{
os << "(par: " << p.par_ << " idx: " << p.idx_
<< " pos: " << p.pos_ << ")";
return os;
}
}
MathCursor::MathCursor(InsetFormulaBase * formula)
: formula_(formula)
{
lastcode = LM_TC_MIN;
macro_mode = false;
selection = false;
first();
}
void MathCursor::push(MathInset * par, bool first)
{
MathCursorPos p;
p.par_ = par;
if (first)
par->idxFirst(p.idx_, p.pos_);
else
par->idxLast(p.idx_, p.pos_);
Cursor_.push_back(p);
}
bool MathCursor::pop()
{
if (Cursor_.size() <= 1)
return false;
Cursor_.pop_back();
return true;
}
MathInset * MathCursor::parInset(int i) const
{
return Cursor_[i].par_;
}
void MathCursor::dump(char const * what) const
{
return;
lyxerr << "MC: " << what << "\n";
for (unsigned i = 0; i < Cursor_.size(); ++i)
lyxerr << " i: " << i
<< " pos: " << Cursor_[i].pos_
<< " idx: " << Cursor_[i].idx_
<< " par: " << Cursor_[i].par_ << "\n";
//lyxerr << " sel: " << selection << " data: " << array() << "\n";
}
void MathCursor::seldump(char const *) const
{
//lyxerr << "SEL: " << str << ": '" << theSelection << "'\n";
//dump(" Pos");
return;
//lyxerr << "\n\n\\n=================vvvvvvvvvvvvv======================= "
// << str << "\ntheSelection: " << theSelection;
//for (unsigned int i = 0; i < Cursor_.size(); ++i)
// lyxerr << Cursor_[i].par_ << "\n'" << Cursor_[i].cell() << "'\n";
//lyxerr << "\ncursor.pos_: " << cursor().pos_;
//lyxerr << "\nanchor.pos_: " << anchor().pos_;
//lyxerr << "\n===================^^^^^^^^^^^^=====================\n\n\n";
}
bool MathCursor::isInside(MathInset * p) const
{
for (unsigned i = 0; i < Cursor_.size(); ++i)
if (parInset(i) == p)
return true;
return false;
}
bool MathCursor::openable(MathInset * p, bool sel, bool useupdown) const
{
if (!p)
return false;
if (!(p->isActive() || (useupdown && p->isUpDownInset())))
return false;
if (sel) {
// we can't move into everything during selection
if (Cursor_.size() == Anchor_.size())
return false;
if (p != Anchor_[Cursor_.size()].par_)
return false;
}
return true;
}
bool MathCursor::plainLeft()
{
return array().prev(cursor().pos_);
}
bool MathCursor::Left(bool sel)
{
dump("Left 1");
if (macro_mode) {
// was MacroModeBack()
if (!imacro->name().empty()) {
imacro->SetName(imacro->name().substr(0, imacro->name().length()-1));
imacro->Metrics(imacro->size());
} else
MacroModeClose();
return true;
}
SelHandle(sel);
clearLastCode();
MathInset * p = prevInset();
if (openable(p, sel, false)) {
plainLeft();
push(p, false);
return true;
}
if (plainLeft())
return true;
if (cursor().par_->idxLeft(cursor().idx_, cursor().pos_))
return true;
if (pop())
return true;
return false;
}
bool MathCursor::plainRight()
{
return array().next(cursor().pos_);
}
bool MathCursor::Right(bool sel)
{
dump("Right 1");
if (macro_mode) {
MacroModeClose();
return true;
}
SelHandle(sel);
clearLastCode();
MathInset * p = nextInset();
if (openable(p, sel, false)) {
push(p, true);
return true;
}
if (array().next(cursor().pos_))
return true;
if (cursor().par_->idxRight(cursor().idx_, cursor().pos_))
return true;
if (!pop())
return false;
array().next(cursor().pos_);
return true;
}
void MathCursor::first()
{
Cursor_.clear();
push(formula_->par(), true);
}
void MathCursor::last()
{
Cursor_.clear();
push(formula_->par(), false);
}
void MathCursor::SetPos(int x, int y)
{
dump("SetPos 1");
//lyxerr << "MathCursor::SetPos x: " << x << " y: " << y << "\n";
MacroModeClose();
lastcode = LM_TC_MIN;
first();
cursor().par_ = formula()->par();
while (1) {
cursor().idx_ = -1;
cursor().pos_ = -1;
//lyxerr << "found idx: " << idx_ << " cursor: " << cursor().pos_ << "\n";
int distmin = 1 << 30; // large enough
for (int i = 0; i < cursor().par_->nargs(); ++i) {
MathXArray const & ar = cursor().par_->xcell(i);
int x1 = x - ar.xo();
int y1 = y - ar.yo();
int c = ar.x2pos(x1);
int xx = abs(x1 - ar.pos2x(c));
int yy = abs(y1);
//lyxerr << "idx: " << i << " xx: " << xx << " yy: " << yy
// << " c: " << c << " xo: " << ar.xo() << "\n";
if (yy + xx <= distmin) {
distmin = yy + xx;
cursor().idx_ = i;
cursor().pos_ = c;
}
}
//lyxerr << "found idx: " << cursor().idx_ << " cursor: "
// << cursor().pos_ << "\n";
MathInset * n = nextInset();
MathInset * p = prevInset();
if (openable(n, selection, true) && n->covers(x, y))
push(n, true);
else if (openable(p, selection, true) && p->covers(x, y)) {
plainLeft();
push(p, false);
} else
break;
}
dump("SetPos 2");
}
void MathCursor::Home()
{
dump("Home 1");
if (macro_mode)
MacroModeClose();
clearLastCode();
if (!cursor().par_->idxHome(cursor().idx_, cursor().pos_))
pop();
dump("Home 2");
}
void MathCursor::End()
{
dump("End 1");
if (macro_mode)
MacroModeClose();
clearLastCode();
if (!cursor().par_->idxEnd(cursor().idx_, cursor().pos_)) {
pop();
array().next(cursor().pos_);
}
dump("End 2");
}
void MathCursor::insert(char c, MathTextCodes t)
{
//lyxerr << "inserting '" << c << "'\n";
if (selection)
SelDel();
if (t == LM_TC_MIN)
t = lastcode;
if (macro_mode && !(MathIsAlphaFont(t) || t == LM_TC_MIN))
MacroModeClose();
if (macro_mode) {
if (MathIsAlphaFont(t) || t == LM_TC_MIN) {
// was MacroModeinsert(c);
imacro->SetName(imacro->name() + static_cast<char>(c));
return;
}
}
array().insert(cursor().pos_, c, t);
array().next(cursor().pos_);
lastcode = t;
}
void MathCursor::insert(MathInset * p)
{
MacroModeClose();
if (selection) {
if (p->nargs())
SelCut();
else
SelDel();
}
array().insert(cursor().pos_, p);
array().next(cursor().pos_);
}
void MathCursor::insert(MathArray const & ar)
{
MacroModeClose();
if (selection)
SelCut();
array().insert(cursor().pos_, ar);
cursor().pos_ += ar.size();
}
void MathCursor::Delete()
{
dump("Delete 1");
if (macro_mode)
return;
if (selection) {
SelDel();
return;
}
// delete empty cells if necessary
if (cursor().pos_ == 0 && array().size() == 0) {
bool popit;
bool removeit;
cursor().par_->idxDelete(cursor().idx_, popit, removeit);
if (popit && pop() && removeit)
Delete();
return;
}
if (cursor().pos_ < array().size())
array().erase(cursor().pos_);
dump("Delete 2");
}
void MathCursor::DelLine()
{
MacroModeClose();
if (selection) {
SelDel();
return;
}
if (cursor().par_->nrows() > 1)
cursor().par_->delRow(row());
}
bool MathCursor::Up(bool sel)
{
dump("Up 1");
MacroModeClose();
SelHandle(sel);
if (selection) {
int x = xarray().pos2x(cursor().pos_);
if (cursor().par_->idxUp(cursor().idx_, cursor().pos_)) {
cursor().pos_ = xarray().x2pos(x);
return true;
}
if (pop())
return true;
return false;
}
// check whether we could move into an inset on the right or on the left
MathInset * p = nextInset();
if (p) {
int idx, pos;
if (p->idxFirstUp(idx, pos)) {
push(p, true);
cursor().par_ = p;
cursor().idx_ = idx;
cursor().pos_ = pos;
dump("Up 3");
return true;
}
}
p = prevInset();
if (p) {
int idx, pos;
if (p->idxLastUp(idx, pos)) {
plainLeft();
push(p, false);
cursor().par_ = p;
cursor().idx_ = idx;
cursor().pos_ = pos;
dump("Up 4");
return true;
}
}
int x = xarray().pos2x(cursor().pos_);
if (cursor().idxUp()) {
cursor().pos_ = xarray().x2pos(x);
return true;
}
if (pop())
return true;
return false;
}
bool MathCursor::Down(bool sel)
{
dump("Down 1");
MacroModeClose();
SelHandle(sel);
if (selection) {
int x = xarray().pos2x(cursor().pos_);
if (cursor().idxDown()) {
cursor().pos_ = xarray().x2pos(x);
return true;
}
if (pop())
return true;
return false;
}
// check whether we could move into an inset on the right or on the left
MathInset * p = nextInset();
if (p) {
int idx, pos;
if (p->idxFirstDown(idx, pos)) {
push(p, true);
cursor().idx_ = idx;
cursor().pos_ = pos;
dump("Down 3");
return true;
}
}
p = prevInset();
if (p) {
int idx, pos;
if (p->idxLastDown(idx, pos)) {
plainLeft();
push(p, false);
cursor().idx_ = idx;
cursor().pos_ = pos;
dump("Down 4");
return true;
}
}
int x = xarray().pos2x(cursor().pos_);
if (cursor().par_->idxDown(cursor().idx_, cursor().pos_)) {
cursor().pos_ = xarray().x2pos(x);
return true;
}
if (pop())
return true;
return false;
}
bool MathCursor::toggleLimits()
{
if (!prevIsInset())
return false;
MathInset * p = prevInset();
int old = p->limits();
p->limits(old < 0 ? 1 : -1);
return old != p->limits();
}
void MathCursor::SetSize(MathStyles size)
{
cursor().par_->UserSetSize(size);
}
void MathCursor::Interpret(string const & s)
{
lyxerr << "Interpret: '" << s << "' ('" << s.substr(0, 7) << "' " <<
in_word_set(s) << " \n";
if (s[0] == '^' || s[0] == '_') {
bool const up = (s[0] == '^');
SelCut();
MathUpDownInset * p = prevUpDownInset();
if (!p) {
p = new MathScriptInset(up, !up);
insert(p);
plainLeft();
}
push(p, true);
if (up)
p->up(true);
else
p->down(true);
cursor().idx_ = up ? 0 : 1;
cursor().pos_ = 0;
SelPaste();
return;
}
if (s[0] == '!' || s[0] == ',' || s[0] == ':' || s[0] == ';') {
int sp = (s[0] == ',') ? 1:((s[0] == ':') ? 2:((s[0] == ';') ? 3: 0));
insert(new MathSpaceInset(sp));
return;
}
MathInset * p = 0;
latexkeys const * l = in_word_set(s);
if (l == 0) {
if (s == "root")
p = new MathRootInset;
else if (MathMacroTable::hasTemplate(s))
p = new MathMacro(MathMacroTable::provideTemplate(s));
else if (s.size() > 7 && s.substr(0, 7) == "matrix ") {
int m = 1;
int n = 1;
string v_align;
string h_align;
istringstream is(s.substr(7).c_str());
is >> m >> n >> v_align >> h_align;
m = std::max(1, m);
n = std::max(1, n);
v_align += 'c';
MathArrayInset * pp = new MathArrayInset(m, n);
pp->valign(v_align[0]);
pp->halign(h_align);
p = pp;
}
else
p = new MathFuncInset(s, LM_OT_UNDEF);
} else {
switch (l->token) {
case LM_TK_BIGSYM:
p = new MathBigopInset(l->name, l->id);
break;
case LM_TK_SYM: {
MathTextCodes code = static_cast<MathTextCodes>(l->id);
if (code < 255)
insert(l->id, MathIsBOPS(code) ? LM_TC_BOPS : LM_TC_SYMB);
else
p = new MathFuncInset(l->name);
break;
}
case LM_TK_STACK:
p = new MathFracInset("stackrel");
break;
case LM_TK_FRAC:
p = new MathFracInset("frac");
break;
case LM_TK_SQRT:
p = new MathSqrtInset;
break;
case LM_TK_DECORATION:
p = new MathDecorationInset(l->name, l->id);
break;
case LM_TK_FUNCLIM:
p = new MathFuncInset(l->name, LM_OT_FUNCLIM);
break;
case LM_TK_SPACE:
p = new MathSpaceInset(l->id);
break;
case LM_TK_DOTS:
p = new MathDotsInset(l->name, l->id);
break;
case LM_TK_MACRO:
p = new MathMacro(MathMacroTable::provideTemplate(s));
break;
default:
p = new MathFuncInset(l->name);
break;
}
}
if (p) {
bool oldsel = selection;
if (oldsel)
SelCut();
insert(p);
if (p->nargs()) {
plainLeft();
//push(p, true);
Right(); // do not push for e.g. MathBigopInset
if (oldsel)
SelPaste();
}
p->Metrics(p->size());
}
}
void MathCursor::MacroModeOpen()
{
if (!macro_mode) {
imacro = new MathFuncInset("");
insert(imacro);
macro_mode = true;
} else
lyxerr << "Math Warning: Already in macro mode" << endl;
}
void MathCursor::MacroModeClose()
{
if (macro_mode) {
macro_mode = false;
latexkeys const * l = in_word_set(imacro->name());
if (!imacro->name().empty()
&& (!l || (l && IsMacro(l->token, l->id)))
&& !MathMacroTable::hasTemplate(imacro->name()))
{
if (!l) {
//imacro->SetName(macrobf);
// This guarantees that the string will be removed by destructor
imacro->SetType(LM_OT_UNDEF);
} else
imacro->SetName(l->name);
} else {
Left();
array().erase(cursor().pos_);
if (l || MathMacroTable::hasTemplate(imacro->name()))
Interpret(imacro->name());
imacro->SetName(string());
}
imacro = 0;
}
}
void MathCursor::SelCopy()
{
seldump("SelCopy");
if (selection) {
theSelection.grab(*this);
SelClear();
}
}
void MathCursor::SelCut()
{
seldump("SelCut");
if (selection) {
theSelection.grab(*this);
theSelection.erase(*this);
SelClear();
}
}
void MathCursor::SelDel()
{
seldump("SelDel");
if (selection) {
theSelection.erase(*this);
SelClear();
}
}
void MathCursor::SelPaste()
{
seldump("SelPaste");
theSelection.paste(*this);
SelClear();
}
void MathCursor::SelHandle(bool sel)
{
if (sel && !selection)
SelStart();
if (!sel && selection)
SelClear();
}
void MathCursor::SelStart()
{
seldump("SelStart");
if (selection)
return;
Anchor_ = Cursor_;
selection = true;
}
void MathCursor::SelClear()
{
selection = false;
}
void MathCursor::drawSelection(Painter & pain) const
{
if (!selection)
return;
MathCursorPos i1;
MathCursorPos i2;
getSelection(i1, i2);
//lyxerr << "selection from: " << i1 << " to " << i2 << "\n";
if (i1.idx_ == i2.idx_) {
MathXArray & c = i1.xcell();
int x1 = c.xo() + c.pos2x(i1.pos_);
int y1 = c.yo() - c.ascent();
int x2 = c.xo() + c.pos2x(i2.pos_);
int y2 = c.yo() + c.descent();
pain.fillRectangle(x1, y1, x2 - x1, y2 - y1, LColor::selection);
} else {
std::vector<int> indices = i1.par_->idxBetween(i1.idx_, i2.idx_);
for (unsigned i = 0; i < indices.size(); ++i) {
MathXArray & c = i1.xcell(indices[i]);
int x1 = c.xo();
int y1 = c.yo() - c.ascent();
int x2 = c.xo() + c.width();
int y2 = c.yo() + c.descent();
pain.fillRectangle(x1, y1, x2 - x1, y2 - y1, LColor::selection);
}
}
}
void MathCursor::handleFont(MathTextCodes t)
{
if (selection) {
MathCursorPos i1;
MathCursorPos i2;
getSelection(i1, i2);
if (i1.idx_ == i2.idx_) {
MathArray & ar = i1.cell();
for (int pos = i1.pos_; pos != i2.pos_; ar.next(pos))
if (!ar.isInset(pos) && isalnum(ar.GetChar(pos))) {
MathTextCodes c = ar.GetCode(pos) == t ? LM_TC_VAR : t;
ar.setCode(pos, c);
}
}
} else {
lastcode = (lastcode == t) ? LM_TC_VAR : t;
}
}
void MathCursor::handleAccent(string const & name, int code)
{
MathDecorationInset * p = new MathDecorationInset(name, code);
if (selection) {
SelCut();
p->cell(0) = theSelection.glue();
}
insert(p);
push(p, true);
}
void MathCursor::handleDelim(int l, int r)
{
MathDelimInset * p = new MathDelimInset(l, r);
if (selection) {
SelCut();
p->cell(0) = theSelection.glue();
}
insert(p);
plainLeft();
push(p, true);
}
void MathCursor::GetPos(int & x, int & y)
{
x = xarray().xo() + xarray().pos2x(cursor().pos_);
y = xarray().yo();
}
MathTextCodes MathCursor::nextCode() const
{
return array().GetCode(cursor().pos_);
}
MathTextCodes MathCursor::prevCode() const
{
return array().GetCode(cursor().pos_ - 1);
}
MathInset * MathCursor::par() const
{
return cursor().par_;
}
InsetFormulaBase const * MathCursor::formula()
{
return formula_;
}
int MathCursor::pos() const
{
return cursor().pos_;
}
bool MathCursor::InMacroMode() const
{
return macro_mode;
}
bool MathCursor::Selection() const
{
return selection;
}
void MathCursor::clearLastCode()
{
lastcode = LM_TC_MIN;
}
void MathCursor::setLastCode(MathTextCodes t)
{
lastcode = t;
}
MathTextCodes MathCursor::getLastCode() const
{
return lastcode;
}
MathInset * MathCursor::enclosing(MathInsetTypes t, int & idx) const
{
for (int i = Cursor_.size() - 1; i >= 0; --i) {
//lyxerr << "checking level " << i << "\n";
if (Cursor_[i].par_->GetType() == t) {
idx = Cursor_[i].idx_;
return Cursor_[i].par_;
}
}
return 0;
}
void MathCursor::pullArg(bool goright)
{
// pullArg
dump("pullarg");
MathArray a = array();
if (pop()) {
array().erase(cursor().pos_);
array().insert(cursor().pos_, a);
if (goright)
cursor().pos_ += a.size();
}
}
MathStyles MathCursor::style() const
{
return xarray().style();
}
void MathCursor::normalize() const
{
#ifdef WITH_WARNINGS
#warning This is evil!
#endif
MathCursor * it = const_cast<MathCursor *>(this);
if (cursor().idx_ < 0 || cursor().idx_ > cursor().par_->nargs())
lyxerr << "this should not really happen - 1\n";
it->cursor().idx_ = max(cursor().idx_, 0);
it->cursor().idx_ = min(cursor().idx_, cursor().par_->nargs());
if (cursor().pos_ < 0 || cursor().pos_ > array().size())
lyxerr << "this should not really happen - 2\n";
it->cursor().pos_ = max(cursor().pos_, 0);
it->cursor().pos_ = min(cursor().pos_, array().size());
}
int MathCursor::col() const
{
return par()->col(cursor().idx_);
}
int MathCursor::row() const
{
return par()->row(cursor().idx_);
}
/*
char MathCursorPos::GetChar() const
{
return array().GetChar(cursor().pos_);
}
string MathCursorPos::readString()
{
string s;
int code = nextCode();
for ( ; OK() && nextCode() == code; Next())
s += GetChar();
return s;
}
*/
MathInset * MathCursor::prevInset() const
{
normalize();
int c = cursor().pos_;
if (!array().prev(c))
return 0;
return array().nextInset(c);
}
MathInset * MathCursor::nextInset() const
{
normalize();
return array().nextInset(cursor().pos_);
}
MathUpDownInset * MathCursor::prevUpDownInset() const
{
normalize();
MathInset * p = array().prevInset(cursor().pos_);
return (p && p->isUpDownInset()) ? static_cast<MathUpDownInset *>(p) : 0;
}
MathArray & MathCursor::array() const
{
static MathArray dummy;
if (!cursor().par_) {
lyxerr << "############ par_ not valid\n";
return dummy;
}
if (cursor().idx_ < 0 || cursor().idx_ >= cursor().par_->nargs()) {
lyxerr << "############ idx_ " << cursor().idx_ << " not valid\n";
return dummy;
}
return cursor().cell();
}
MathXArray & MathCursor::xarray() const
{
return cursor().xcell();
}
bool MathCursor::nextIsInset() const
{
return cursor().pos_ < array().size() && MathIsInset(nextCode());
}
bool MathCursor::prevIsInset() const
{
return cursor().pos_ > 0 && MathIsInset(prevCode());
}
int MathCursor::xpos() const
{
normalize();
return xarray().pos2x(cursor().pos_);
}
void MathCursor::gotoX(int x)
{
cursor().pos_ = xarray().x2pos(x);
}
void MathCursor::idxNext()
{
cursor().par_->idxNext(cursor().idx_, cursor().pos_);
}
void MathCursor::idxPrev()
{
cursor().par_->idxPrev(cursor().idx_, cursor().pos_);
}
void MathCursor::splitCell()
{
if (cursor().idx_ == cursor().par_->nargs() - 1)
return;
MathArray ar = array();
ar.erase(0, cursor().pos_);
array().erase(cursor().pos_, array().size());
++cursor().idx_;
cursor().pos_ = 0;
array().insert(0, ar);
}
void MathCursor::breakLine()
{
MathMatrixInset * p = static_cast<MathMatrixInset *>(formula()->par());
if (p->GetType() == LM_OT_SIMPLE || p->GetType() == LM_OT_EQUATION) {
p->mutate(LM_OT_EQNARRAY);
p->addRow(0);
cursor().idx_ = p->nrows();
cursor().pos_ = 0;
} else {
p->addRow(row());
// split line
const int r = row();
for (int c = col() + 1; c < p->ncols(); ++c) {
const int i1 = p->index(r, c);
const int i2 = p->index(r + 1, c);
lyxerr << "swapping cells " << i1 << " and " << i2 << "\n";
p->cell(i1).swap(p->cell(i2));
}
// split cell
splitCell();
p->cell(cursor().idx_).swap(p->cell(cursor().idx_ + p->ncols() - 1));
}
}
char MathCursor::valign() const
{
int idx;
MathGridInset * p =
static_cast<MathGridInset *>(enclosing(LM_OT_MATRIX, idx));
return p ? p->valign() : 0;
}
char MathCursor::halign() const
{
int idx;
MathGridInset * p =
static_cast<MathGridInset *>(enclosing(LM_OT_MATRIX, idx));
return p ? p->halign(idx % p->ncols()) : 0;
}
MathCursorPos MathCursor::firstSelectionPos() const
{
MathCursorPos anc = normalAnchor();
return anc < cursor() ? anc : cursor();
}
MathCursorPos MathCursor::lastSelectionPos() const
{
MathCursorPos anc = normalAnchor();
return anc < cursor() ? cursor() : anc;
}
void MathCursor::getSelection(MathCursorPos & i1, MathCursorPos & i2) const
{
MathCursorPos anc = normalAnchor();
if (anc < cursor()) {
i1 = anc;
i2 = cursor();
} else {
i1 = cursor();
i2 = anc;
}
}
MathCursorPos & MathCursor::cursor()
{
return Cursor_.back();
}
MathCursorPos const & MathCursor::cursor() const
{
return Cursor_.back();
}
////////////////////////////////////////////////////////////////////////
bool operator==(MathCursorPos const & ti, MathCursorPos const & it)
{
return ti.par_ == it.par_ && ti.idx_ == it.idx_ && ti.pos_ == it.pos_;
}
bool operator<(MathCursorPos const & ti, MathCursorPos const & it)
{
if (ti.par_ != it.par_) {
lyxerr << "can't compare cursor and anchor in different insets\n";
return true;
}
if (ti.idx_ != it.idx_)
return ti.idx_ < it.idx_;
return ti.pos_ < it.pos_;
}
MathArray & MathCursorPos::cell(int idx) const
{
return par_->cell(idx);
}
MathArray & MathCursorPos::cell() const
{
return par_->cell(idx_);
}
MathXArray & MathCursorPos::xcell(int idx) const
{
return par_->xcell(idx);
}
MathXArray & MathCursorPos::xcell() const
{
return par_->xcell(idx_);
}
MathCursorPos MathCursor::normalAnchor() const
{
// use Anchor on the same level as Cursor
MathCursorPos normal = Anchor_[Cursor_.size() - 1];
if (Cursor_.size() < Anchor_.size() && !(normal < cursor())) {
// anchor is behind cursor -> move anchor behind the inset
normal.cell().next(normal.pos_);
}
//lyxerr << "normalizing: from " << Anchor_[Anchor_.size() - 1] << " to "
// << normal << "\n";
return normal;
}
bool MathCursorPos::idxUp()
{
return par_->idxUp(idx_, pos_);
}
bool MathCursorPos::idxDown()
{
return par_->idxDown(idx_, pos_);
}
bool MathCursorPos::idxLeft()
{
return par_->idxLeft(idx_, pos_);
}
bool MathCursorPos::idxRight()
{
return par_->idxRight(idx_, pos_);
}