lyx_mirror/src/cursor.C

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/**
* \file cursor.C
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Alejandro Aguilar Sierra
* \author Alfredo Braunstein
* \author Andr<EFBFBD> P<EFBFBD>nitz
*
* Full author contact details are available in file CREDITS.
*/
#include <config.h>
#include "buffer.h"
#include "BufferView.h"
#include "cursor.h"
#include "debug.h"
#include "dispatchresult.h"
#include "funcrequest.h"
#include "iterators.h"
#include "lfuns.h"
#include "lyxfunc.h" // only for setMessage()
#include "lyxrc.h"
#include "lyxrow.h"
#include "lyxtext.h"
#include "paragraph.h"
#include "insets/updatableinset.h"
#include "insets/insettabular.h"
#include "insets/insettext.h"
#include "mathed/math_data.h"
#include "mathed/math_hullinset.h"
#include "mathed/math_support.h"
#include "support/limited_stack.h"
#include "support/std_sstream.h"
#include "frontends/LyXView.h"
#include <boost/assert.hpp>
using std::string;
using std::vector;
using std::endl;
#ifndef CXX_GLOBAL_CSTD
using std::isalpha;
#endif
using std::min;
using std::swap;
// our own cut buffer
limited_stack<string> theCutBuffer;
LCursor::LCursor(BufferView & bv)
: cursor_(1), anchor_(1), bv_(&bv), current_(0),
cached_y_(0), x_target_(-1),
selection_(false), mark_(false)
{}
void LCursor::reset()
{
cursor_.clear();
anchor_.clear();
cursor_.push_back(CursorSlice());
anchor_.push_back(CursorSlice());
current_ = 0;
cached_y_ = 0;
clearTargetX();
selection_ = false;
mark_ = false;
}
DispatchResult LCursor::dispatch(FuncRequest const & cmd0)
{
lyxerr << "\nLCursor::dispatch: cmd: " << cmd0 << endl << *this << endl;
BOOST_ASSERT(pos() <= lastpos());
BOOST_ASSERT(idx() <= lastidx());
BOOST_ASSERT(par() <= lastpar());
FuncRequest cmd = cmd0;
disp_.update(true);
disp_.val(NONE);
for (current_ = cursor_.size() - 1; current_ >= 1; --current_) {
// the inset's dispatch() is supposed to reset the update and
// val flags if necessary
inset()->dispatch(*this, cmd);
// "Mutate" the request for semi-handled requests that need
// additional handling in outer levels.
switch (disp_.val()) {
case NONE:
// the inset handled the event fully
current_ = cursor_.size() - 1;
return DispatchResult(true, true);
case FINISHED_LEFT:
// the inset handled the event partially
cmd = FuncRequest(LFUN_FINISHED_LEFT);
break;
case FINISHED_RIGHT:
cmd = FuncRequest(LFUN_FINISHED_RIGHT);
break;
case FINISHED_UP:
cmd = FuncRequest(LFUN_FINISHED_UP);
break;
case FINISHED_DOWN:
cmd = FuncRequest(LFUN_FINISHED_DOWN);
break;
default:
//lyxerr << "not handled on level " << current_
// << " val: " << disp_.val() << endl;
break;
}
}
BOOST_ASSERT(current_ == 0);
bv_->text()->dispatch(*this, cmd);
//lyxerr << " result: " << res.val() << endl;
current_ = cursor_.size() - 1;
return disp_;
}
bool LCursor::getStatus(FuncRequest const & cmd, FuncStatus & status)
{
lyxerr << "\nLCursor::getStatus: cmd: " << cmd << endl << *this << endl;
BOOST_ASSERT(pos() <= lastpos());
BOOST_ASSERT(idx() <= lastidx());
BOOST_ASSERT(par() <= lastpar());
for (current_ = cursor_.size() - 1; current_ >= 1; --current_) {
// the inset's getStatus() will return 'true' if it made
// a definitive decision on whether it want to handle the
// request or not. The result of this decision is put into
// the 'status' parameter.
bool const res = inset()->getStatus(*this, cmd, status);
if (res) {
current_ = cursor_.size() - 1;
return true;
}
}
BOOST_ASSERT(current_ == 0);
bool const res = bv_->text()->getStatus(*this, cmd, status);
current_ = cursor_.size() - 1;
return res;
}
void LCursor::push(InsetBase * inset)
{
lyxerr << "LCursor::push() inset: " << inset << endl;
cursor_.push_back(CursorSlice(inset));
anchor_.push_back(CursorSlice(inset));
++current_;
updatePos();
}
void LCursor::pop(int depth)
{
while (int(cursor_.size()) > depth + 1)
pop();
lyxerr << "LCursor::pop() result: " << *this << endl;
}
void LCursor::pop()
{
BOOST_ASSERT(cursor_.size() >= 1);
cursor_.pop_back();
anchor_.pop_back();
current_ = cursor_.size() - 1;
}
void LCursor::pushLeft(InsetBase * p)
{
BOOST_ASSERT(!cursor_.empty());
//lyxerr << "Entering inset " << t << " left" << endl;
push(p);
p->idxFirst(*this);
}
bool LCursor::popLeft()
{
BOOST_ASSERT(!cursor_.empty());
//lyxerr << "Leaving inset to the left" << endl;
if (depth() <= 1) {
if (depth() == 1)
inset()->notifyCursorLeaves(idx());
return false;
}
inset()->notifyCursorLeaves(idx());
pop();
return true;
}
bool LCursor::popRight()
{
BOOST_ASSERT(!cursor_.empty());
//lyxerr << "Leaving inset to the right" << endl;
if (depth() <= 1) {
if (depth() == 1)
inset()->notifyCursorLeaves(idx());
return false;
}
inset()->notifyCursorLeaves(idx());
pop();
++pos();
return true;
}
CursorSlice & LCursor::current()
{
BOOST_ASSERT(!cursor_.empty());
//lyxerr << "accessing cursor slice " << current_
// << ": " << cursor_[current_] << endl;
return cursor_[current_];
}
CursorSlice const & LCursor::current() const
{
//lyxerr << "accessing cursor slice " << current_
// << ": " << cursor_[current_] << endl;
return cursor_[current_];
}
int LCursor::currentMode()
{
BOOST_ASSERT(!cursor_.empty());
for (int i = cursor_.size() - 1; i >= 1; --i) {
int res = cursor_[i].inset()->currentMode();
if (res != MathInset::UNDECIDED_MODE)
return res;
}
return MathInset::TEXT_MODE;
}
LyXText * LCursor::innerText() const
{
BOOST_ASSERT(!cursor_.empty());
if (cursor_.size() > 1) {
// go up until first non-0 text is hit
// (innermost text is 0 in mathed)
for (int i = cursor_.size() - 1; i >= 1; --i)
if (cursor_[i].text())
return cursor_[i].text();
}
return bv_->text();
}
CursorSlice const & LCursor::innerTextSlice() const
{
BOOST_ASSERT(!cursor_.empty());
if (cursor_.size() > 1) {
// go up until first non-0 text is hit
// (innermost text is 0 in mathed)
for (int i = cursor_.size() - 1; i >= 1; --i)
if (cursor_[i].text())
return cursor_[i];
}
return cursor_[0];
}
void LCursor::updatePos()
{
BOOST_ASSERT(!cursor_.empty());
if (cursor_.size() > 1)
cached_y_ = bv_->top_y() + cursor_.back().inset()->yo();
//cached_y_ = cursor_.back().inset()->yo();
}
void LCursor::getDim(int & asc, int & des) const
{
BOOST_ASSERT(!cursor_.empty());
if (inMathed()) {
BOOST_ASSERT(inset());
BOOST_ASSERT(inset()->asMathInset());
//inset()->asMathInset()->getCursorDim(asc, des);
asc = 10;
des = 10;
} else {
Row const & row = textRow();
asc = row.baseline();
des = row.height() - asc;
}
}
void LCursor::getPos(int & x, int & y) const
{
BOOST_ASSERT(!cursor_.empty());
x = 0;
y = 0;
if (cursor_.size() == 1) {
x = bv_->text()->cursorX(cursor_.front());
y = bv_->text()->cursorY(cursor_.front());
} else {
if (!inset()) {
lyxerr << "#### LCursor::getPos: " << *this << endl;
BOOST_ASSERT(inset());
}
inset()->getCursorPos(cursor_.back(), x, y);
// getCursorPos gives _screen_ coordinates. We need to add
// top_y to get document coordinates. This is hidden in cached_y_.
//y += cached_y_ - inset()->yo();
// The rest is non-obvious. The reason we have to have these
// extra computation is that the getCursorPos() calls rely
// on the inset's own knowledge of its screen position.
// If we scroll up or down in a big enough increment,
// inset->draw() is not called: this doesn't update
// inset.yo_, so getCursor() returns an old value.
// Ugly as you like.
}
//lyxerr << "#### LCursor::getPos: " << *this
// << " x: " << x << " y: " << y << endl;
}
void LCursor::paste(string const & data)
{
dispatch(FuncRequest(LFUN_PASTE, data));
}
InsetBase * LCursor::innerInsetOfType(int code) const
{
for (int i = cursor_.size() - 1; i >= 1; --i)
if (cursor_[i].inset_->lyxCode() == code)
return cursor_[i].inset_;
return 0;
}
InsetTabular * LCursor::innerInsetTabular() const
{
return static_cast<InsetTabular *>(innerInsetOfType(InsetBase::TABULAR_CODE));
}
void LCursor::resetAnchor()
{
anchor_ = cursor_;
}
BufferView & LCursor::bv() const
{
return *bv_;
}
MathAtom const & LCursor::prevAtom() const
{
BOOST_ASSERT(pos() > 0);
return cell()[pos() - 1];
}
MathAtom & LCursor::prevAtom()
{
BOOST_ASSERT(pos() > 0);
return cell()[pos() - 1];
}
MathAtom const & LCursor::nextAtom() const
{
BOOST_ASSERT(pos() < lastpos());
return cell()[pos()];
}
MathAtom & LCursor::nextAtom()
{
BOOST_ASSERT(pos() < lastpos());
return cell()[pos()];
}
bool LCursor::posLeft()
{
if (pos() == 0)
return false;
--pos();
return true;
}
bool LCursor::posRight()
{
if (pos() == lastpos())
return false;
++pos();
return true;
}
CursorSlice & LCursor::anchor()
{
return anchor_.back();
}
CursorSlice const & LCursor::anchor() const
{
return anchor_.back();
}
CursorSlice const & LCursor::selBegin() const
{
if (!selection())
return cursor_.back();
return anchor() < cursor_.back() ? anchor() : cursor_.back();
}
CursorSlice & LCursor::selBegin()
{
if (!selection())
return cursor_.back();
// can't use std::min as this returns a const ref
return anchor() < cursor_.back() ? anchor() : cursor_.back();
}
CursorSlice const & LCursor::selEnd() const
{
if (!selection())
return cursor_.back();
return anchor() > cursor_.back() ? anchor() : cursor_.back();
}
CursorSlice & LCursor::selEnd()
{
if (!selection())
return cursor_.back();
// can't use std::min as this returns a const ref
return anchor() > cursor_.back() ? anchor() : cursor_.back();
}
void LCursor::setSelection()
{
selection() = true;
// a selection with no contents is not a selection
if (par() == anchor().par() && pos() == anchor().pos())
selection() = false;
}
void LCursor::setSelection(CursorBase const & where, size_t n)
{
selection() = true;
cursor_ = where;
anchor_ = where;
pos() += n;
}
void LCursor::clearSelection()
{
selection() = false;
mark() = false;
resetAnchor();
bv().unsetXSel();
}
int & LCursor::x_target()
{
return x_target_;
}
int LCursor::x_target() const
{
return x_target_;
}
void LCursor::clearTargetX()
{
x_target_ = -1;
}
LyXText * LCursor::text() const
{
return current_ ? current().text() : bv_->text();
}
Paragraph & LCursor::paragraph()
{
BOOST_ASSERT(inTexted());
return current_ ? current().paragraph() : *bv_->text()->getPar(par());
}
Paragraph const & LCursor::paragraph() const
{
BOOST_ASSERT(inTexted());
return current_ ? current().paragraph() : *bv_->text()->getPar(par());
}
Row & LCursor::textRow()
{
return *paragraph().getRow(pos());
}
Row const & LCursor::textRow() const
{
return *paragraph().getRow(pos());
}
LCursor::par_type LCursor::lastpar() const
{
return inMathed() ? 0 : text()->paragraphs().size() - 1;
}
LCursor::pos_type LCursor::lastpos() const
{
InsetBase * inset = current().inset();
return inset && inset->asMathInset() ? cell().size() : paragraph().size();
}
LCursor::row_type LCursor::crow() const
{
return paragraph().row(pos());
}
LCursor::row_type LCursor::lastcrow() const
{
return paragraph().rows.size();
}
LCursor::idx_type LCursor::lastidx() const
{
return current_ ? current().lastidx() : 0;
}
size_t LCursor::nargs() const
{
// assume 1x1 grid for 'plain text'
return current_ ? current().nargs() : 1;
}
size_t LCursor::ncols() const
{
// assume 1x1 grid for 'plain text'
return current_ ? current().ncols() : 1;
}
size_t LCursor::nrows() const
{
// assume 1x1 grid for 'plain text'
return current_ ? current().nrows() : 1;
}
LCursor::row_type LCursor::row() const
{
BOOST_ASSERT(current_ > 0);
return current().row();
}
LCursor::col_type LCursor::col() const
{
BOOST_ASSERT(current_ > 0);
return current().col();
}
MathArray const & LCursor::cell() const
{
BOOST_ASSERT(current_ > 0);
return current().cell();
}
MathArray & LCursor::cell()
{
BOOST_ASSERT(current_ > 0);
return current().cell();
}
void LCursor::info(std::ostream & os) const
{
for (int i = 1, n = depth(); i < n; ++i) {
cursor_[i].inset()->infoize(os);
os << " ";
}
if (pos() != 0)
prevInset()->infoize2(os);
// overwite old message
os << " ";
}
namespace {
void region(CursorSlice const & i1, CursorSlice const & i2,
LCursor::row_type & r1, LCursor::row_type & r2,
LCursor::col_type & c1, LCursor::col_type & c2)
{
InsetBase * p = i1.inset();
c1 = p->col(i1.idx_);
c2 = p->col(i2.idx_);
if (c1 > c2)
swap(c1, c2);
r1 = p->row(i1.idx_);
r2 = p->row(i2.idx_);
if (r1 > r2)
swap(r1, r2);
}
}
string LCursor::grabSelection()
{
if (!selection())
return string();
CursorSlice i1 = selBegin();
CursorSlice i2 = selEnd();
if (i1.idx_ == i2.idx_) {
if (i1.inset()->asMathInset()) {
MathArray::const_iterator it = i1.cell().begin();
return asString(MathArray(it + i1.pos_, it + i2.pos_));
} else {
return "unknown selection 1";
}
}
row_type r1, r2;
col_type c1, c2;
region(i1, i2, r1, r2, c1, c2);
string data;
if (i1.inset()->asMathInset()) {
for (row_type row = r1; row <= r2; ++row) {
if (row > r1)
data += "\\\\";
for (col_type col = c1; col <= c2; ++col) {
if (col > c1)
data += '&';
data += asString(i1.asMathInset()->cell(i1.asMathInset()->index(row, col)));
}
}
} else {
data = "unknown selection 2";
}
return data;
}
void LCursor::eraseSelection()
{
//lyxerr << "LCursor::eraseSelection" << endl;
CursorSlice const & i1 = selBegin();
CursorSlice const & i2 = selEnd();
#warning FIXME
if (i1.inset()->asMathInset()) {
if (i1.idx_ == i2.idx_) {
i1.cell().erase(i1.pos_, i2.pos_);
} else {
MathInset * p = i1.asMathInset();
row_type r1, r2;
col_type c1, c2;
region(i1, i2, r1, r2, c1, c2);
for (row_type row = r1; row <= r2; ++row)
for (col_type col = c1; col <= c2; ++col)
p->cell(p->index(row, col)).clear();
}
current() = i1;
} else {
lyxerr << "can't erase this selection 1" << endl;
}
//lyxerr << "LCursor::eraseSelection end" << endl;
}
string LCursor::grabAndEraseSelection()
{
if (!selection())
return string();
string res = grabSelection();
eraseSelection();
selection() = false;
return res;
}
void LCursor::selClear()
{
resetAnchor();
clearSelection();
}
void LCursor::selCopy()
{
if (selection()) {
theCutBuffer.push(grabSelection());
selection() = false;
} else {
//theCutBuffer.erase();
}
}
void LCursor::selCut()
{
theCutBuffer.push(grabAndEraseSelection());
}
void LCursor::selDel()
{
//lyxerr << "LCursor::selDel" << endl;
if (selection()) {
eraseSelection();
selection() = false;
}
}
void LCursor::selPaste(size_t n)
{
selClearOrDel();
if (n < theCutBuffer.size())
paste(theCutBuffer[n]);
//grabSelection();
selection() = false;
}
void LCursor::selHandle(bool sel)
{
//lyxerr << "LCursor::selHandle" << endl;
if (sel == selection())
return;
resetAnchor();
selection() = sel;
}
void LCursor::selClearOrDel()
{
//lyxerr << "LCursor::selClearOrDel" << endl;
if (lyxrc.auto_region_delete)
selDel();
else
selection() = false;
}
std::ostream & operator<<(std::ostream & os, LCursor const & cur)
{
for (size_t i = 0, n = cur.cursor_.size(); i != n; ++i)
os << " " << cur.cursor_[i] << " | " << cur.anchor_[i] << "\n";
os << " current: " << cur.current_ << endl;
os << " selection: " << cur.selection_ << endl;
return os;
}
//
// CursorBase
//
void increment(CursorBase & it)
{
CursorSlice & top = it.back();
MathArray & ar = top.asMathInset()->cell(top.idx_);
// move into the current inset if possible
// it is impossible for pos() == size()!
MathInset * n = 0;
if (top.pos() != top.lastpos())
n = (ar.begin() + top.pos_)->nucleus();
if (n && n->isActive()) {
it.push_back(CursorSlice(n));
return;
}
// otherwise move on one cell back if possible
if (top.pos() < top.lastpos()) {
// pos() == lastpos() is valid!
++top.pos_;
return;
}
// otherwise try to move on one cell if possible
while (top.idx() < top.lastidx()) {
++top.idx_;
if (top.asMathInset()->validCell(top.idx_)) {
top.pos_ = 0;
return;
}
}
// otherwise leave array, move on one back
// this might yield pos() == size(), but that's a ok.
it.pop_back();
// it certainly invalidates top
++it.back().pos_;
}
CursorBase ibegin(InsetBase * p)
{
CursorBase it;
it.push_back(CursorSlice(p));
return it;
}
CursorBase iend(InsetBase * p)
{
CursorBase it;
it.push_back(CursorSlice(p));
CursorSlice & cur = it.back();
cur.idx() = cur.lastidx();
cur.pos() = cur.lastpos();
return it;
}
///////////////////////////////////////////////////////////////////
//
// The part below is the non-integrated rest of the original math
// cursor. This should be either generalized for texted or moved
// back to the math insets.
//
///////////////////////////////////////////////////////////////////
#include "mathed/math_braceinset.h"
#include "mathed/math_charinset.h"
#include "mathed/math_commentinset.h"
#include "mathed/math_factory.h"
#include "mathed/math_gridinset.h"
#include "mathed/math_macroarg.h"
#include "mathed/math_macrotemplate.h"
#include "mathed/math_mathmlstream.h"
#include "mathed/math_scriptinset.h"
#include "mathed/math_spaceinset.h"
#include "mathed/math_support.h"
#include "mathed/math_unknowninset.h"
//#define FILEDEBUG 1
bool LCursor::isInside(InsetBase const * p)
{
for (unsigned i = 0; i < depth(); ++i)
if (cursor_[i].inset() == p)
return true;
return false;
}
bool LCursor::openable(MathAtom const & t) const
{
if (!t->isActive())
return false;
if (t->lock())
return false;
if (!selection())
return true;
// we can't move into anything new during selection
if (depth() == anchor_.size())
return false;
if (!ptr_cmp(t.nucleus(), anchor_[depth()].inset()))
return false;
return true;
}
bool LCursor::inNucleus()
{
return inset()->asMathInset()->asScriptInset() && idx() == 2;
}
bool LCursor::left()
{
autocorrect() = false;
clearTargetX();
if (inMacroMode()) {
macroModeClose();
return true;
}
if (pos() != 0 && openable(prevAtom())) {
posLeft();
push(nextAtom().nucleus());
inset()->idxLast(*this);
return true;
}
return posLeft() || idxLeft() || popLeft() || selection();
}
bool LCursor::right()
{
autocorrect() = false;
clearTargetX();
if (inMacroMode()) {
macroModeClose();
return true;
}
if (pos() != lastpos() && openable(nextAtom())) {
pushLeft(nextAtom().nucleus());
inset()->idxFirst(*this);
return true;
}
return posRight() || idxRight() || popRight() || selection();
}
bool positionable(CursorBase const & cursor, CursorBase const & anchor)
{
// avoid deeper nested insets when selecting
if (cursor.size() > anchor.size())
return false;
// anchor might be deeper, should have same path then
for (size_t i = 0; i < cursor.size(); ++i)
if (cursor[i].inset() != anchor[i].inset())
return false;
// position should be ok.
return true;
}
void LCursor::setScreenPos(int x, int y)
{
bool res = bruteFind(x, y, formula()->xlow(), formula()->xhigh(),
formula()->ylow(), formula()->yhigh());
if (!res) {
// this can happen on creation of "math-display"
idx() = 0;
pos() = 0;
}
clearTargetX();
}
bool LCursor::home()
{
autocorrect() = false;
macroModeClose();
if (!inset()->idxHome(*this))
return popLeft();
clearTargetX();
return true;
}
bool LCursor::end()
{
autocorrect() = false;
macroModeClose();
if (!inset()->idxEnd(*this))
return popRight();
clearTargetX();
return true;
}
void LCursor::plainErase()
{
cell().erase(pos());
}
void LCursor::markInsert()
{
cell().insert(pos(), MathAtom(new MathCharInset(0)));
}
void LCursor::markErase()
{
cell().erase(pos());
}
void LCursor::plainInsert(MathAtom const & t)
{
cell().insert(pos(), t);
++pos();
}
void LCursor::insert(string const & str)
{
lyxerr << "LCursor::insert str '" << str << "'" << endl;
selClearOrDel();
#if 0
for (string::const_iterator it = str.begin(); it != str.end(); ++it)
plainInsert(MathAtom(new MathCharInset(*it)));
#else
MathArray ar;
asArray(str, ar);
insert(ar);
#endif
}
void LCursor::insert(char c)
{
//lyxerr << "LCursor::insert char '" << c << "'" << endl;
selClearOrDel();
plainInsert(MathAtom(new MathCharInset(c)));
}
void LCursor::insert(MathAtom const & t)
{
//lyxerr << "LCursor::insert MathAtom: " << endl;
macroModeClose();
selClearOrDel();
plainInsert(t);
}
void LCursor::insert(InsetBase * inset)
{
if (inMathed())
insert(MathAtom(inset));
else
text()->insertInset(*this, inset);
}
void LCursor::niceInsert(string const & t)
{
MathArray ar;
asArray(t, ar);
if (ar.size() == 1)
niceInsert(ar[0]);
else
insert(ar);
}
void LCursor::niceInsert(MathAtom const & t)
{
macroModeClose();
string safe = grabAndEraseSelection();
plainInsert(t);
// enter the new inset and move the contents of the selection if possible
if (t->isActive()) {
posLeft();
// be careful here: don't use 'pushLeft(t)' as this we need to
// push the clone, not the original
pushLeft(nextAtom().nucleus());
paste(safe);
}
}
void LCursor::insert(MathArray const & ar)
{
macroModeClose();
if (selection())
eraseSelection();
cell().insert(pos(), ar);
pos() += ar.size();
}
bool LCursor::backspace()
{
autocorrect() = false;
if (selection()) {
selDel();
return true;
}
if (pos() == 0) {
if (inset()->nargs() == 1 && depth() == 1 && lastpos() == 0)
return false;
pullArg();
return true;
}
if (inMacroMode()) {
MathUnknownInset * p = activeMacro();
if (p->name().size() > 1) {
p->setName(p->name().substr(0, p->name().size() - 1));
return true;
}
}
if (pos() != 0 && prevAtom()->nargs() > 0) {
// let's require two backspaces for 'big stuff' and
// highlight on the first
selection() = true;
left();
} else {
--pos();
plainErase();
}
return true;
}
bool LCursor::erase()
{
autocorrect() = false;
if (inMacroMode())
return true;
if (selection()) {
selDel();
return true;
}
// delete empty cells if possible
if (pos() == lastpos() && inset()->idxDelete(idx()))
return true;
// special behaviour when in last position of cell
if (pos() == lastpos()) {
bool one_cell = inset()->nargs() == 1;
if (one_cell && depth() == 1 && lastpos() == 0)
return false;
// remove markup
if (one_cell)
pullArg();
else
inset()->idxGlue(idx());
return true;
}
if (pos() != lastpos() && inset()->nargs() > 0) {
selection() = true;
right();
} else {
plainErase();
}
return true;
}
bool LCursor::up()
{
macroModeClose();
CursorBase save = cursor_;
if (goUpDown(true))
return true;
cursor_ = save;
autocorrect() = false;
return selection();
}
bool LCursor::down()
{
macroModeClose();
CursorBase save = cursor_;
if (goUpDown(false))
return true;
cursor_ = save;
autocorrect() = false;
return selection();
}
void LCursor::macroModeClose()
{
if (!inMacroMode())
return;
MathUnknownInset * p = activeMacro();
p->finalize();
string s = p->name();
--pos();
cell().erase(pos());
// do nothing if the macro name is empty
if (s == "\\")
return;
string const name = s.substr(1);
// prevent entering of recursive macros
if (formula()->lyxCode() == InsetOld::MATHMACRO_CODE
&& formula()->getInsetName() == name)
lyxerr << "can't enter recursive macro" << endl;
niceInsert(createMathInset(name));
}
string LCursor::macroName()
{
return inMacroMode() ? activeMacro()->name() : string();
}
void LCursor::handleNest(MathAtom const & a, int c)
{
//lyxerr << "LCursor::handleNest: " << c << endl;
MathAtom t = a;
asArray(grabAndEraseSelection(), t.nucleus()->cell(c));
insert(t);
posLeft();
pushLeft(nextAtom().nucleus());
}
int LCursor::targetX() const
{
if (x_target() != -1)
return x_target();
int x = 0;
int y = 0;
getPos(x, y);
return x;
}
MathHullInset * LCursor::formula() const
{
for (int i = cursor_.size() - 1; i >= 1; --i) {
MathInset * inset = cursor_[i].inset()->asMathInset();
if (inset && inset->asHullInset())
return static_cast<MathHullInset *>(inset);
}
return 0;
}
void LCursor::adjust(pos_type from, int diff)
{
if (pos() > from)
pos() += diff;
if (anchor().pos_ > from)
anchor().pos_ += diff;
// just to be on the safe side
// theoretically unecessary
normalize();
}
bool LCursor::inMacroMode() const
{
if (!pos() != 0)
return false;
MathUnknownInset const * p = prevAtom()->asUnknownInset();
return p && !p->final();
}
MathUnknownInset * LCursor::activeMacro()
{
return inMacroMode() ? prevAtom().nucleus()->asUnknownInset() : 0;
}
bool LCursor::inMacroArgMode() const
{
return pos() > 0 && prevAtom()->getChar() == '#';
}
MathGridInset * LCursor::enclosingGrid(idx_type & idx) const
{
for (MathInset::difference_type i = depth() - 1; i >= 0; --i) {
MathInset * m = cursor_[i].inset()->asMathInset();
if (!m)
return 0;
MathGridInset * p = m->asGridInset();
if (p) {
idx = cursor_[i].idx_;
return p;
}
}
return 0;
}
void LCursor::pullArg()
{
#warning Look here
MathArray ar = cell();
if (popLeft() && inMathed()) {
plainErase();
cell().insert(pos(), ar);
resetAnchor();
} else {
//formula()->mutateToText();
}
}
void LCursor::touch()
{
#warning look here
#if 0
CursorBase::const_iterator it = cursor_.begin();
CursorBase::const_iterator et = cursor_.end();
for ( ; it != et; ++it)
it->cell().touch();
#endif
}
void LCursor::normalize()
{
if (idx() >= nargs()) {
lyxerr << "this should not really happen - 1: "
<< idx() << ' ' << nargs()
<< " in: " << inset() << endl;
}
idx() = min(idx(), lastidx());
if (pos() > lastpos()) {
lyxerr << "this should not really happen - 2: "
<< pos() << ' ' << lastpos() << " in idx: " << idx()
<< " in atom: '";
WriteStream wi(lyxerr, false, true);
inset()->asMathInset()->write(wi);
lyxerr << endl;
}
pos() = min(pos(), lastpos());
}
char LCursor::valign()
{
idx_type idx;
MathGridInset * p = enclosingGrid(idx);
return p ? p->valign() : '\0';
}
char LCursor::halign()
{
idx_type idx;
MathGridInset * p = enclosingGrid(idx);
return p ? p->halign(idx % p->ncols()) : '\0';
}
bool LCursor::goUpDown(bool up)
{
// Be warned: The 'logic' implemented in this function is highly
// fragile. A distance of one pixel or a '<' vs '<=' _really
// matters. So fiddle around with it only if you think you know
// what you are doing!
int xo = 0;
int yo = 0;
getPos(xo, yo);
// check if we had something else in mind, if not, this is the future goal
if (x_target() == -1)
x_target() = xo;
else
xo = x_target();
// try neigbouring script insets
if (!selection()) {
// try left
if (pos() != 0) {
MathScriptInset const * p = prevAtom()->asScriptInset();
if (p && p->has(up)) {
--pos();
push(inset());
idx() = up; // the superscript has index 1
pos() = lastpos();
//lyxerr << "updown: handled by scriptinset to the left" << endl;
return true;
}
}
// try right
if (pos() != lastpos()) {
MathScriptInset const * p = nextAtom()->asScriptInset();
if (p && p->has(up)) {
push(inset());
idx() = up;
pos() = 0;
//lyxerr << "updown: handled by scriptinset to the right" << endl;
return true;
}
}
}
// try current cell for e.g. text insets
if (inset()->idxUpDown2(*this, up))
return true;
//xarray().boundingBox(xlow, xhigh, ylow, yhigh);
//if (up)
// yhigh = yo - 4;
//else
// ylow = yo + 4;
//if (bruteFind(xo, yo, xlow, xhigh, ylow, yhigh)) {
// lyxerr << "updown: handled by brute find in the same cell" << endl;
// return true;
//}
// try to find an inset that knows better then we
while (1) {
//lyxerr << "updown: We are in " << inset() << " idx: " << idx() << endl;
// ask inset first
if (inset()->idxUpDown(*this, up)) {
// try to find best position within this inset
if (!selection())
bruteFind2(xo, yo);
return true;
}
// no such inset found, just take something "above"
//lyxerr << "updown: handled by strange case" << endl;
if (!popLeft()) {
return
bruteFind(xo, yo,
formula()->xlow(),
formula()->xhigh(),
up ? formula()->ylow() : yo + 4,
up ? yo - 4 : formula()->yhigh()
);
}
// any improvement so far?
int xnew, ynew;
getPos(xnew, ynew);
if (up ? ynew < yo : ynew > yo)
return true;
}
}
bool LCursor::bruteFind(int x, int y, int xlow, int xhigh, int ylow, int yhigh)
{
CursorBase best_cursor;
double best_dist = 1e10;
CursorBase it = ibegin(formula());
CursorBase et = iend(formula());
while (1) {
// avoid invalid nesting when selecting
if (!selection() || positionable(it, anchor_)) {
int xo, yo;
CursorSlice & cur = it.back();
cur.inset()->getCursorPos(cur, xo, yo);
if (xlow <= xo && xo <= xhigh && ylow <= yo && yo <= yhigh) {
double d = (x - xo) * (x - xo) + (y - yo) * (y - yo);
//lyxerr << "x: " << x << " y: " << y << " d: " << endl;
// '<=' in order to take the last possible position
// this is important for clicking behind \sum in e.g. '\sum_i a'
if (d <= best_dist) {
best_dist = d;
best_cursor = it;
}
}
}
if (it == et)
break;
increment(it);
}
if (best_dist < 1e10)
cursor_ = best_cursor;
return best_dist < 1e10;
}
void LCursor::bruteFind2(int x, int y)
{
double best_dist = 1e10;
CursorBase it = cursor_;
it.back().pos() = 0;
CursorBase et = cursor_;
et.back().pos() = et.back().asMathInset()->cell(et.back().idx_).size();
for (int i = 0; ; ++i) {
int xo, yo;
CursorSlice & cur = it.back();
cur.inset()->getCursorPos(cur, xo, yo);
double d = (x - xo) * (x - xo) + (y - yo) * (y - yo);
// '<=' in order to take the last possible position
// this is important for clicking behind \sum in e.g. '\sum_i a'
lyxerr << "i: " << i << " d: " << d << " best: " << best_dist << endl;
if (d <= best_dist) {
best_dist = d;
cursor_ = it;
}
if (it == et)
break;
increment(it);
}
}
bool LCursor::idxLineLast()
{
idx() -= idx() % ncols();
idx() += ncols() - 1;
pos() = lastpos();
return true;
}
bool LCursor::idxLeft()
{
return inset()->idxLeft(*this);
}
bool LCursor::idxRight()
{
return inset()->idxRight(*this);
}
bool LCursor::script(bool up)
{
// Hack to get \\^ and \\_ working
lyxerr << "handling script: up: " << up << endl;
if (inMacroMode() && macroName() == "\\") {
if (up)
niceInsert(createMathInset("mathcircumflex"));
else
interpret('_');
return true;
}
macroModeClose();
string safe = grabAndEraseSelection();
if (inNucleus()) {
// we are in a nucleus of a script inset, move to _our_ script
inset()->asMathInset()->asScriptInset()->ensure(up);
idx() = up;
pos() = 0;
} else if (pos() != 0 && prevAtom()->asScriptInset()) {
--pos();
nextAtom().nucleus()->asScriptInset()->ensure(up);
push(nextInset());
idx() = up;
pos() = lastpos();
} else if (pos() != 0) {
--pos();
cell()[pos()] = MathAtom(new MathScriptInset(nextAtom(), up));
push(nextInset());
idx() = up;
pos() = 0;
} else {
plainInsert(MathAtom(new MathScriptInset(up)));
--pos();
nextAtom().nucleus()->asScriptInset()->ensure(up);
push(nextInset());
idx() = up;
pos() = 0;
}
paste(safe);
return true;
}
bool LCursor::interpret(char c)
{
//lyxerr << "interpret 2: '" << c << "'" << endl;
clearTargetX();
if (inMacroArgMode()) {
posLeft();
plainErase();
#warning FIXME
#if 0
int n = c - '0';
MathMacroTemplate const * p = formula()->asMacroTemplate();
if (p && 1 <= n && n <= p->numargs())
insert(MathAtom(new MathMacroArgument(c - '0')));
else {
insert(createMathInset("#"));
interpret(c); // try again
}
#endif
return true;
}
// handle macroMode
if (inMacroMode()) {
string name = macroName();
//lyxerr << "interpret name: '" << name << "'" << endl;
if (isalpha(c)) {
activeMacro()->setName(activeMacro()->name() + c);
return true;
}
// handle 'special char' macros
if (name == "\\") {
// remove the '\\'
backspace();
if (c == '\\') {
if (currentMode() == MathInset::TEXT_MODE)
niceInsert(createMathInset("textbackslash"));
else
niceInsert(createMathInset("backslash"));
} else if (c == '{') {
niceInsert(MathAtom(new MathBraceInset));
} else {
niceInsert(createMathInset(string(1, c)));
}
return true;
}
// leave macro mode and try again if necessary
macroModeClose();
if (c == '{')
niceInsert(MathAtom(new MathBraceInset));
else if (c != ' ')
interpret(c);
return true;
}
// This is annoying as one has to press <space> far too often.
// Disable it.
if (0) {
// leave autocorrect mode if necessary
if (autocorrect() && c == ' ') {
autocorrect() = false;
return true;
}
}
// just clear selection on pressing the space bar
if (selection() && c == ' ') {
selection() = false;
return true;
}
selClearOrDel();
if (c == '\\') {
//lyxerr << "starting with macro" << endl;
insert(MathAtom(new MathUnknownInset("\\", false)));
return true;
}
if (c == '\n') {
if (currentMode() == MathInset::TEXT_MODE)
insert(c);
return true;
}
if (c == ' ') {
if (currentMode() == MathInset::TEXT_MODE) {
// insert spaces in text mode,
// but suppress direct insertion of two spaces in a row
// the still allows typing '<space>a<space>' and deleting the 'a', but
// it is better than nothing...
if (!pos() != 0 || prevAtom()->getChar() != ' ')
insert(c);
return true;
}
if (pos() != 0 && prevAtom()->asSpaceInset()) {
prevAtom().nucleus()->asSpaceInset()->incSpace();
return true;
}
if (popRight())
return true;
// if are at the very end, leave the formula
return pos() != lastpos();
}
if (c == '_') {
script(false);
return true;
}
if (c == '^') {
script(true);
return true;
}
if (c == '{' || c == '}' || c == '#' || c == '&' || c == '$') {
niceInsert(createMathInset(string(1, c)));
return true;
}
if (c == '%') {
niceInsert(MathAtom(new MathCommentInset));
return true;
}
// try auto-correction
//if (autocorrect() && hasPrevAtom() && math_autocorrect(prevAtom(), c))
// return true;
// no special circumstances, so insert the character without any fuss
insert(c);
autocorrect() = true;
return true;
}
void LCursor::lockToggle()
{
if (pos() != lastpos()) {
// toggle previous inset ...
nextAtom().nucleus()->lock(!nextAtom()->lock());
} else if (popLeft() && pos() != lastpos()) {
// ... or enclosing inset if we are in the last inset position
nextAtom().nucleus()->lock(!nextAtom()->lock());
++pos();
}
}
CursorSlice LCursor::normalAnchor()
{
if (anchor_.size() < depth()) {
resetAnchor();
lyxerr << "unusual Anchor size" << endl;
}
//lyx::BOOST_ASSERT(Anchor_.size() >= cursor.depth());
// use Anchor on the same level as Cursor
CursorSlice normal = anchor_[current_];
#if 0
if (depth() < anchor_.size() && !(normal < xx())) {
// anchor is behind cursor -> move anchor behind the inset
++normal.pos_;
}
#endif
return normal;
}
/*
DispatchResult dispatch(LCursor & cur, FuncRequest const & cmd)
{
// mouse clicks are somewhat special
// check
switch (cmd.action) {
case LFUN_MOUSE_PRESS:
case LFUN_MOUSE_MOTION:
case LFUN_MOUSE_RELEASE:
case LFUN_MOUSE_DOUBLE: {
CursorSlice & pos = cursor_.back();
int x = 0;
int y = 0;
getPos(x, y);
if (x < cmd.x && pos() != 0) {
DispatchResult const res = prevAtom().nucleus()->dispatch(cmd);
if (res.dispatched())
return res;
}
if (x > cmd.x && pos() != lastpos()) {
DispatchResult const res = inset()->dispatch(cmd);
if (res.dispatched())
return res;
}
}
default:
break;
}
}
*/
void LCursor::handleFont(string const & font)
{
lyxerr << "LCursor::handleFont: " << font << endl;
string safe;
if (selection()) {
macroModeClose();
safe = grabAndEraseSelection();
}
if (lastpos() != 0) {
// something left in the cell
if (pos() == 0) {
// cursor in first position
popLeft();
} else if (pos() == lastpos()) {
// cursor in last position
popRight();
} else {
// cursor in between. split cell
MathArray::iterator bt = cell().begin();
MathAtom at = createMathInset(font);
at.nucleus()->cell(0) = MathArray(bt, bt + pos());
cell().erase(bt, bt + pos());
popLeft();
plainInsert(at);
}
} else {
// nothing left in the cell
pullArg();
plainErase();
}
insert(safe);
}
bool LCursor::inMathed() const
{
return formula();
}
bool LCursor::inTexted() const
{
return !formula();
}
InsetBase * LCursor::nextInset()
{
if (pos() == lastpos())
return 0;
if (inMathed())
return nextAtom().nucleus();
return paragraph().isInset(pos()) ? paragraph().getInset(pos()) : 0;
}
InsetBase * LCursor::prevInset()
{
if (pos() == 0)
return 0;
if (inMathed())
return prevAtom().nucleus();
return paragraph().isInset(pos() - 1) ? paragraph().getInset(pos() - 1) : 0;
}
InsetBase const * LCursor::prevInset() const
{
if (pos() == 0)
return 0;
if (inMathed())
return prevAtom().nucleus();
return paragraph().isInset(pos() - 1) ? paragraph().getInset(pos() - 1) : 0;
}
void LCursor::message(string const & msg) const
{
bv().owner()->getLyXFunc().setMessage(msg);
}
void LCursor::errorMessage(string const & msg) const
{
bv().owner()->getLyXFunc().setErrorMessage(msg);
}
string LCursor::selectionAsString(bool label) const
{
if (!selection())
return string();
if (inTexted()) {
Buffer const & buffer = *bv().buffer();
// should be const ...
ParagraphList::iterator startpit = text()->getPar(selBegin());
ParagraphList::iterator endpit = text()->getPar(selEnd());
size_t const startpos = selBegin().pos();
size_t const endpos = selEnd().pos();
if (startpit == endpit)
return startpit->asString(buffer, startpos, endpos, label);
// First paragraph in selection
string result =
startpit->asString(buffer, startpos, startpit->size(), label) + "\n\n";
// The paragraphs in between (if any)
ParagraphList::iterator pit = startpit;
for (++pit; pit != endpit; ++pit)
result += pit->asString(buffer, 0, pit->size(), label) + "\n\n";
// Last paragraph in selection
result += endpit->asString(buffer, 0, endpos, label);
return result;
}
#warning an mathed?
return string();
}
string LCursor::currentState()
{
if (inMathed()) {
std::ostringstream os;
info(os);
return os.str();
}
return text() ? text()->currentState(*this) : string();
}
// only used by the spellchecker
void LCursor::replaceWord(string const & replacestring)
{
LyXText * t = text();
BOOST_ASSERT(t);
t->replaceSelectionWithString(*this, replacestring);
t->setSelectionRange(*this, replacestring.length());
// Go back so that replacement string is also spellchecked
for (string::size_type i = 0; i < replacestring.length() + 1; ++i)
t->cursorLeft(*this);
}
void LCursor::update()
{
bv().update();
}
string LCursor::getPossibleLabel()
{
return inMathed() ? "eq:" : text()->getPossibleLabel(*this);
}
void LCursor::notdispatched()
{
disp_.dispatched(false);
}
void LCursor::dispatched(dispatch_result_t res)
{
disp_.val(res);
}
void LCursor::noupdate()
{
disp_.update(false);
}