lyx_mirror/src/mathed/MathData.cpp
Enrico Forestieri cb3044101e Fix bug #6739: Loading in a 1.6.5 file causes 1.6.6-1 to crash
git-svn-id: svn://svn.lyx.org/lyx/lyx-devel/branches/BRANCH_1_6_X@34580 a592a061-630c-0410-9148-cb99ea01b6c8
2010-06-01 13:34:31 +00:00

961 lines
24 KiB
C++

/**
* \file MathData.cpp
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author André Pönitz
* \author Stefan Schimanski
*
* Full author contact details are available in file CREDITS.
*/
#include <config.h>
#include "MathData.h"
#include "InsetMathBrace.h"
#include "InsetMathFont.h"
#include "InsetMathScript.h"
#include "MacroTable.h"
#include "MathMacro.h"
#include "MathStream.h"
#include "MathSupport.h"
#include "MetricsInfo.h"
#include "ReplaceData.h"
#include "Buffer.h"
#include "BufferView.h"
#include "CoordCache.h"
#include "Cursor.h"
#include "mathed/InsetMathUnknown.h"
#include "support/debug.h"
#include "support/docstream.h"
#include "frontends/FontMetrics.h"
#include "frontends/Painter.h"
#include "support/lassert.h"
#include <boost/next_prior.hpp>
#include <cstdlib>
using namespace std;
namespace lyx {
MathData::MathData(Buffer * buf, const_iterator from, const_iterator to)
: base_type(from, to), buffer_(buf)
{}
MathAtom & MathData::operator[](pos_type pos)
{
LASSERT(pos < size(), /**/);
return base_type::operator[](pos);
}
MathAtom const & MathData::operator[](pos_type pos) const
{
LASSERT(pos < size(), /**/);
return base_type::operator[](pos);
}
void MathData::insert(size_type pos, MathAtom const & t)
{
base_type::insert(begin() + pos, t);
}
void MathData::insert(size_type pos, MathData const & ar)
{
LASSERT(pos <= size(), /**/);
base_type::insert(begin() + pos, ar.begin(), ar.end());
}
void MathData::append(MathData const & ar)
{
insert(size(), ar);
}
void MathData::erase(size_type pos)
{
if (pos < size())
erase(pos, pos + 1);
}
void MathData::erase(iterator pos1, iterator pos2)
{
base_type::erase(pos1, pos2);
}
void MathData::erase(iterator pos)
{
base_type::erase(pos);
}
void MathData::erase(size_type pos1, size_type pos2)
{
base_type::erase(begin() + pos1, begin() + pos2);
}
void MathData::dump2() const
{
odocstringstream os;
NormalStream ns(os);
for (const_iterator it = begin(); it != end(); ++it)
ns << *it << ' ';
lyxerr << to_utf8(os.str());
}
void MathData::dump() const
{
odocstringstream os;
NormalStream ns(os);
for (const_iterator it = begin(); it != end(); ++it)
ns << '<' << *it << '>';
lyxerr << to_utf8(os.str());
}
void MathData::validate(LaTeXFeatures & features) const
{
for (const_iterator it = begin(); it != end(); ++it)
(*it)->validate(features);
}
bool MathData::match(MathData const & ar) const
{
return size() == ar.size() && matchpart(ar, 0);
}
bool MathData::matchpart(MathData const & ar, pos_type pos) const
{
if (size() < ar.size() + pos)
return false;
const_iterator it = begin() + pos;
for (const_iterator jt = ar.begin(); jt != ar.end(); ++jt, ++it)
if (asString(*it) != asString(*jt))
return false;
return true;
}
void MathData::replace(ReplaceData & rep)
{
for (size_type i = 0; i < size(); ++i) {
if (find1(rep.from, i)) {
// match found
lyxerr << "match found!" << endl;
erase(i, i + rep.from.size());
insert(i, rep.to);
}
}
// FIXME: temporarily disabled
// for (const_iterator it = begin(); it != end(); ++it)
// it->nucleus()->replace(rep);
}
bool MathData::find1(MathData const & ar, size_type pos) const
{
lyxerr << "finding '" << ar << "' in '" << *this << "'" << endl;
for (size_type i = 0, n = ar.size(); i < n; ++i)
if (asString(operator[](pos + i)) != asString(ar[i]))
return false;
return true;
}
MathData::size_type MathData::find(MathData const & ar) const
{
for (int i = 0, last = size() - ar.size(); i < last; ++i)
if (find1(ar, i))
return i;
return size();
}
MathData::size_type MathData::find_last(MathData const & ar) const
{
for (int i = size() - ar.size(); i >= 0; --i)
if (find1(ar, i))
return i;
return size();
}
bool MathData::contains(MathData const & ar) const
{
if (find(ar) != size())
return true;
for (const_iterator it = begin(); it != end(); ++it)
if ((*it)->contains(ar))
return true;
return false;
}
void MathData::touch() const
{
}
namespace {
bool isInside(DocIterator const & it, MathData const & ar,
pos_type p1, pos_type p2)
{
for (size_t i = 0; i != it.depth(); ++i) {
CursorSlice const & sl = it[i];
if (sl.inset().inMathed() && &sl.cell() == &ar)
return p1 <= sl.pos() && sl.pos() < p2;
}
return false;
}
}
void MathData::metrics(MetricsInfo & mi, Dimension & dim) const
{
frontend::FontMetrics const & fm = theFontMetrics(mi.base.font);
dim = fm.dimension('I');
int xascent = fm.dimension('x').ascent();
if (xascent >= dim.asc)
xascent = (2 * dim.asc) / 3;
minasc_ = xascent;
mindes_ = (3 * xascent) / 4;
slevel_ = (4 * xascent) / 5;
sshift_ = xascent / 4;
kerning_ = 0;
if (empty()) {
// Cache the dimension.
mi.base.bv->coordCache().arrays().add(this, dim);
return;
}
Cursor & cur = mi.base.bv->cursor();
const_cast<MathData*>(this)->updateMacros(&cur, mi.macrocontext);
DocIterator const & inlineCompletionPos = mi.base.bv->inlineCompletionPos();
MathData const * inlineCompletionData = 0;
if (inlineCompletionPos.inMathed())
inlineCompletionData = &inlineCompletionPos.cell();
dim.asc = 0;
dim.wid = 0;
Dimension d;
CoordCacheBase<Inset> & coords = mi.base.bv->coordCache().insets();
for (pos_type i = 0, n = size(); i != n; ++i) {
MathAtom const & at = operator[](i);
at->metrics(mi, d);
coords.add(at.nucleus(), d);
dim += d;
if (i == n - 1)
kerning_ = at->kerning(mi.base.bv);
// HACK to draw completion suggestion inline
if (inlineCompletionData != this
|| size_t(inlineCompletionPos.pos()) != i + 1)
continue;
docstring const & completion = mi.base.bv->inlineCompletion();
if (completion.length() == 0)
continue;
dim.wid += mathed_string_width(mi.base.font, completion);
}
// Cache the dimension.
mi.base.bv->coordCache().arrays().add(this, dim);
}
void MathData::draw(PainterInfo & pi, int x, int y) const
{
//lyxerr << "MathData::draw: x: " << x << " y: " << y << endl;
BufferView & bv = *pi.base.bv;
setXY(bv, x, y);
Dimension const & dim = bv.coordCache().getArrays().dim(this);
if (empty()) {
pi.pain.rectangle(x, y - dim.ascent(), dim.width(), dim.height(), Color_mathline);
return;
}
// don't draw outside the workarea
if (y + dim.descent() <= 0
|| y - dim.ascent() >= bv.workHeight()
|| x + dim.width() <= 0
|| x >= bv. workWidth())
return;
DocIterator const & inlineCompletionPos = bv.inlineCompletionPos();
MathData const * inlineCompletionData = 0;
if (inlineCompletionPos.inMathed())
inlineCompletionData = &inlineCompletionPos.cell();
CoordCacheBase<Inset> & coords = pi.base.bv->coordCache().insets();
for (size_t i = 0, n = size(); i != n; ++i) {
MathAtom const & at = operator[](i);
coords.add(at.nucleus(), x, y);
at->drawSelection(pi, x, y);
at->draw(pi, x, y);
x += coords.dim(at.nucleus()).wid;
// Is the inline completion here?
if (inlineCompletionData != this
|| size_t(inlineCompletionPos.pos()) != i + 1)
continue;
docstring const & completion = bv.inlineCompletion();
if (completion.length() == 0)
continue;
FontInfo f = pi.base.font;
// draw the unique and the non-unique completion part
// Note: this is not time-critical as it is
// only done once per screen.
size_t uniqueTo = bv.inlineCompletionUniqueChars();
docstring s1 = completion.substr(0, uniqueTo);
docstring s2 = completion.substr(uniqueTo);
if (s1.size() > 0) {
f.setColor(Color_inlinecompletion);
pi.pain.text(x, y, s1, f);
x += mathed_string_width(f, s1);
}
if (s2.size() > 0) {
f.setColor(Color_nonunique_inlinecompletion);
pi.pain.text(x, y, s2, f);
x += mathed_string_width(f, s2);
}
}
}
void MathData::metricsT(TextMetricsInfo const & mi, Dimension & dim) const
{
dim.clear();
Dimension d;
for (const_iterator it = begin(); it != end(); ++it) {
(*it)->metricsT(mi, d);
dim += d;
}
}
void MathData::drawT(TextPainter & pain, int x, int y) const
{
//lyxerr << "x: " << x << " y: " << y << ' ' << pain.workAreaHeight() << endl;
// FIXME: Abdel 16/10/2006
// This drawT() method is never used, this is dead code.
for (const_iterator it = begin(), et = end(); it != et; ++it) {
(*it)->drawT(pain, x, y);
//x += (*it)->width_;
x += 2;
}
}
void MathData::updateMacros(Cursor * cur, MacroContext const & mc)
{
// If we are editing a macro, we cannot update it immediately,
// otherwise wrong undo steps will be recorded (bug 6208).
InsetMath const * inmath = cur ? cur->inset().asInsetMath() : 0;
MathMacro const * inmacro = inmath ? inmath->asMacro() : 0;
docstring const edited_name = inmacro ? inmacro->name() : docstring();
// go over the array and look for macros
for (size_t i = 0; i < size(); ++i) {
MathMacro * macroInset = operator[](i).nucleus()->asMacro();
if (!macroInset || macroInset->name_.empty()
|| macroInset->name_[0] == '^'
|| macroInset->name_[0] == '_'
|| (macroInset->name() == edited_name
&& macroInset->displayMode() ==
MathMacro::DISPLAY_UNFOLDED))
continue;
// get macro
macroInset->updateMacro(mc);
size_t macroNumArgs = 0;
size_t macroOptionals = 0;
MacroData const * macro = macroInset->macro();
if (macro) {
macroNumArgs = macro->numargs();
macroOptionals = macro->optionals();
}
// store old and compute new display mode
MathMacro::DisplayMode newDisplayMode;
MathMacro::DisplayMode oldDisplayMode = macroInset->displayMode();
newDisplayMode = macroInset->computeDisplayMode();
// arity changed or other reason to detach?
if (oldDisplayMode == MathMacro::DISPLAY_NORMAL
&& (macroInset->arity() != macroNumArgs
|| macroInset->optionals() != macroOptionals
|| newDisplayMode == MathMacro::DISPLAY_UNFOLDED)) {
detachMacroParameters(cur, i);
// FIXME: proper anchor handling, this removes the selection
if (cur)
cur->clearSelection();
}
// the macro could have been copied while resizing this
macroInset = operator[](i).nucleus()->asMacro();
// Cursor in \label?
if (newDisplayMode != MathMacro::DISPLAY_UNFOLDED
&& oldDisplayMode == MathMacro::DISPLAY_UNFOLDED) {
// put cursor in front of macro
if (cur) {
int macroSlice = cur->find(macroInset);
if (macroSlice != -1)
cur->cutOff(macroSlice - 1);
}
}
// update the display mode
size_t appetite = macroInset->appetite();
macroInset->setDisplayMode(newDisplayMode);
// arity changed?
if (newDisplayMode == MathMacro::DISPLAY_NORMAL
&& (macroInset->arity() != macroNumArgs
|| macroInset->optionals() != macroOptionals)) {
// is it a virgin macro which was never attached to parameters?
bool fromInitToNormalMode
= (oldDisplayMode == MathMacro::DISPLAY_INIT
|| oldDisplayMode == MathMacro::DISPLAY_INTERACTIVE_INIT)
&& newDisplayMode == MathMacro::DISPLAY_NORMAL;
// if the macro was entered interactively (i.e. not by paste or during
// loading), it should not be greedy, but the cursor should
// automatically jump into the macro when behind
bool interactive = (oldDisplayMode == MathMacro::DISPLAY_INTERACTIVE_INIT);
// attach parameters
attachMacroParameters(cur, i, macroNumArgs, macroOptionals,
fromInitToNormalMode, interactive, appetite);
if (cur) {
// FIXME: proper anchor handling, this removes the selection
cur->updateInsets(&cur->bottom().inset());
cur->clearSelection();
}
}
// Give macro the chance to adapt to new situation.
// The macroInset could be invalid now because it was put into a script
// inset and therefore "deep" copied. So get it again from the MathData.
InsetMath * inset = operator[](i).nucleus();
if (inset->asScriptInset())
inset = inset->asScriptInset()->nuc()[0].nucleus();
LASSERT(inset->asMacro(), /**/);
inset->asMacro()->updateRepresentation();
}
}
void MathData::detachMacroParameters(DocIterator * cur, const size_type macroPos)
{
MathMacro * macroInset = operator[](macroPos).nucleus()->asMacro();
// detach all arguments
vector<MathData> detachedArgs;
if (macroPos + 1 == size())
// strip arguments if we are at the MathData end
macroInset->detachArguments(detachedArgs, true);
else
macroInset->detachArguments(detachedArgs, false);
// find cursor slice
int curMacroSlice = -1;
if (cur)
curMacroSlice = cur->find(macroInset);
idx_type curMacroIdx = -1;
pos_type curMacroPos = -1;
vector<CursorSlice> argSlices;
if (curMacroSlice != -1) {
curMacroPos = (*cur)[curMacroSlice].pos();
curMacroIdx = (*cur)[curMacroSlice].idx();
cur->cutOff(curMacroSlice, argSlices);
cur->pop_back();
}
// only [] after the last non-empty argument can be dropped later
size_t lastNonEmptyOptional = 0;
for (size_t l = 0; l < detachedArgs.size() && l < macroInset->optionals(); ++l) {
if (!detachedArgs[l].empty())
lastNonEmptyOptional = l;
}
// optional arguments to be put back?
pos_type p = macroPos + 1;
size_t j = 0;
for (; j < detachedArgs.size() && j < macroInset->optionals(); ++j) {
// another non-empty parameter follows?
bool canDropEmptyOptional = j >= lastNonEmptyOptional;
// then we can drop empty optional parameters
if (detachedArgs[j].empty() && canDropEmptyOptional) {
if (curMacroIdx == j)
(*cur)[curMacroSlice - 1].pos() = macroPos + 1;
continue;
}
// Otherwise we don't drop an empty optional, put it back normally
MathData optarg;
asArray(from_ascii("[]"), optarg);
MathData & arg = detachedArgs[j];
// look for "]", i.e. put a brace around?
InsetMathBrace * brace = 0;
for (size_t q = 0; q < arg.size(); ++q) {
if (arg[q]->getChar() == ']') {
// put brace
brace = new InsetMathBrace(buffer_);
break;
}
}
// put arg between []
if (brace) {
brace->cell(0) = arg;
optarg.insert(1, MathAtom(brace));
} else
optarg.insert(1, arg);
// insert it into the array
insert(p, optarg);
p += optarg.size();
// cursor in macro?
if (curMacroSlice == -1)
continue;
// cursor in optional argument of macro?
if (curMacroIdx == j) {
if (brace) {
cur->append(0, curMacroPos);
(*cur)[curMacroSlice - 1].pos() = macroPos + 2;
} else
(*cur)[curMacroSlice - 1].pos() = macroPos + 2 + curMacroPos;
cur->append(argSlices);
} else if ((*cur)[curMacroSlice - 1].pos() >= int(p))
// cursor right of macro
(*cur)[curMacroSlice - 1].pos() += optarg.size();
}
// put them back into the MathData
for (; j < detachedArgs.size(); ++j, ++p) {
MathData const & arg = detachedArgs[j];
if (arg.size() == 1
&& !arg[0]->asScriptInset()
&& !(arg[0]->asMacro() && arg[0]->asMacro()->arity() > 0))
insert(p, arg[0]);
else
insert(p, MathAtom(new InsetMathBrace(arg)));
// cursor in macro?
if (curMacroSlice == -1)
continue;
// cursor in j-th argument of macro?
if (curMacroIdx == j) {
if (operator[](p).nucleus()->asBraceInset()) {
(*cur)[curMacroSlice - 1].pos() = p;
cur->append(0, curMacroPos);
cur->append(argSlices);
} else {
(*cur)[curMacroSlice - 1].pos() = p; // + macroPos;
cur->append(argSlices);
}
} else if ((*cur)[curMacroSlice - 1].pos() >= int(p))
++(*cur)[curMacroSlice - 1].pos();
}
if (cur)
cur->updateInsets(&cur->bottom().inset());
}
void MathData::attachMacroParameters(Cursor * cur,
const size_type macroPos, const size_type macroNumArgs,
const int macroOptionals, const bool fromInitToNormalMode,
const bool interactiveInit, const size_t appetite)
{
MathMacro * macroInset = operator[](macroPos).nucleus()->asMacro();
// start at atom behind the macro again, maybe with some new arguments
// from the detach phase above, to add them back into the macro inset
size_t p = macroPos + 1;
vector<MathData> detachedArgs;
MathAtom scriptToPutAround;
// find cursor slice again of this MathData
int thisSlice = -1;
if (cur)
thisSlice = cur->find(*this);
int thisPos = -1;
if (thisSlice != -1)
thisPos = (*cur)[thisSlice].pos();
// find arguments behind the macro
if (!interactiveInit) {
collectOptionalParameters(cur, macroOptionals, detachedArgs, p,
scriptToPutAround, macroPos, thisPos, thisSlice);
}
collectParameters(cur, macroNumArgs, detachedArgs, p,
scriptToPutAround, macroPos, thisPos, thisSlice, appetite);
// attach arguments back to macro inset
macroInset->attachArguments(detachedArgs, macroNumArgs, macroOptionals);
// found tail script? E.g. \foo{a}b^x
if (scriptToPutAround.nucleus()) {
InsetMathScript * scriptInset =
scriptToPutAround.nucleus()->asScriptInset();
// In the math parser we remove empty braces in the base
// of a script inset, but we have to restore them here.
if (scriptInset->nuc().empty()) {
MathData ar;
scriptInset->nuc().push_back(
MathAtom(new InsetMathBrace(ar)));
}
// put macro into a script inset
scriptInset->nuc()[0] = operator[](macroPos);
operator[](macroPos) = scriptToPutAround;
// go into the script inset nucleus
if (cur && thisPos == int(macroPos))
cur->append(0, 0);
// get pointer to "deep" copied macro inset
scriptInset = operator[](macroPos).nucleus()->asScriptInset();
macroInset = scriptInset->nuc()[0].nucleus()->asMacro();
}
// remove them from the MathData
erase(begin() + macroPos + 1, begin() + p);
// cursor outside this MathData?
if (thisSlice == -1)
return;
// fix cursor if right of p
if (thisPos >= int(p))
(*cur)[thisSlice].pos() -= p - (macroPos + 1);
// was the macro inset just inserted interactively and was now folded
// and the cursor is just behind?
if ((*cur)[thisSlice].pos() == int(macroPos + 1)
&& interactiveInit
&& fromInitToNormalMode
&& macroInset->arity() > 0
&& thisSlice + 1 == int(cur->depth())) {
// then enter it if the cursor was just behind
(*cur)[thisSlice].pos() = macroPos;
cur->push_back(CursorSlice(*macroInset));
macroInset->idxFirst(*cur);
}
}
void MathData::collectOptionalParameters(Cursor * cur,
const size_type numOptionalParams, vector<MathData> & params,
size_t & pos, MathAtom & scriptToPutAround,
const pos_type macroPos, const int thisPos, const int thisSlice)
{
Buffer * buf = cur ? &cur->buffer() : 0;
// insert optional arguments?
while (params.size() < numOptionalParams
&& pos < size()
&& !scriptToPutAround.nucleus()) {
// is a [] block following which could be an optional parameter?
if (operator[](pos)->getChar() != '[')
break;
// found possible optional argument, look for "]"
size_t right = pos + 1;
for (; right < size(); ++right) {
MathAtom & cell = operator[](right);
if (cell->getChar() == ']')
// found right end
break;
// maybe "]" with a script around?
InsetMathScript * script = cell.nucleus()->asScriptInset();
if (!script)
continue;
if (script->nuc().size() != 1)
continue;
if (script->nuc()[0]->getChar() == ']') {
// script will be put around the macro later
scriptToPutAround = cell;
break;
}
}
// found?
if (right >= size()) {
// no ] found, so it's not an optional argument
break;
}
// add everything between [ and ] as optional argument
MathData optarg(buf, begin() + pos + 1, begin() + right);
// a brace?
bool brace = false;
if (optarg.size() == 1 && optarg[0]->asBraceInset()) {
brace = true;
params.push_back(optarg[0]->asBraceInset()->cell(0));
} else
params.push_back(optarg);
// place cursor in optional argument of macro
if (thisSlice != -1
&& thisPos >= int(pos) && thisPos <= int(right)) {
int paramPos = max(0, thisPos - int(pos) - 1);
vector<CursorSlice> x;
cur->cutOff(thisSlice, x);
(*cur)[thisSlice].pos() = macroPos;
if (brace) {
paramPos = x[0].pos();
x.erase(x.begin());
}
cur->append(0, paramPos);
cur->append(x);
}
pos = right + 1;
}
// fill up empty optional parameters
while (params.size() < numOptionalParams)
params.push_back(MathData());
}
void MathData::collectParameters(Cursor * cur,
const size_type numParams, vector<MathData> & params,
size_t & pos, MathAtom & scriptToPutAround,
const pos_type macroPos, const int thisPos, const int thisSlice,
const size_t appetite)
{
size_t startSize = params.size();
// insert normal arguments
while (params.size() < numParams
&& params.size() - startSize < appetite
&& pos < size()
&& !scriptToPutAround.nucleus()) {
MathAtom & cell = operator[](pos);
// fix cursor
vector<CursorSlice> argSlices;
int argPos = 0;
if (thisSlice != -1 && thisPos == int(pos))
cur->cutOff(thisSlice, argSlices);
// which kind of parameter is it? In {}? With index x^n?
InsetMathBrace const * brace = cell->asBraceInset();
if (brace) {
// found brace, convert into argument
params.push_back(brace->cell(0));
// cursor inside of the brace or just in front of?
if (thisPos == int(pos) && !argSlices.empty()) {
argPos = argSlices[0].pos();
argSlices.erase(argSlices.begin());
}
} else if (cell->asScriptInset() && params.size() + 1 == numParams) {
// last inset with scripts without braces
// -> they belong to the macro, not the argument
InsetMathScript * script = cell.nucleus()->asScriptInset();
if (script->nuc().size() == 1 && script->nuc()[0]->asBraceInset())
// nucleus in brace? Unpack!
params.push_back(script->nuc()[0]->asBraceInset()->cell(0));
else
params.push_back(script->nuc());
// script will be put around below
scriptToPutAround = cell;
// this should only happen after loading, so make cursor handling simple
if (thisPos >= int(macroPos) && thisPos <= int(macroPos + numParams)) {
argSlices.clear();
if (cur)
cur->append(0, 0);
}
} else {
// the simplest case: plain inset
MathData array;
array.insert(0, cell);
params.push_back(array);
}
// put cursor in argument again
if (thisSlice != - 1 && thisPos == int(pos)) {
cur->append(params.size() - 1, argPos);
cur->append(argSlices);
(*cur)[thisSlice].pos() = macroPos;
}
++pos;
}
}
int MathData::pos2x(BufferView const * bv, size_type pos) const
{
return pos2x(bv, pos, 0);
}
int MathData::pos2x(BufferView const * bv, size_type pos, int glue) const
{
int x = 0;
size_type target = min(pos, size());
CoordCacheBase<Inset> const & coords = bv->coordCache().getInsets();
for (size_type i = 0; i < target; ++i) {
const_iterator it = begin() + i;
if ((*it)->getChar() == ' ')
x += glue;
//lyxerr << "char: " << (*it)->getChar()
// << "width: " << (*it)->width() << endl;
x += coords.dim((*it).nucleus()).wid;
}
return x;
}
MathData::size_type MathData::x2pos(BufferView const * bv, int targetx) const
{
return x2pos(bv, targetx, 0);
}
MathData::size_type MathData::x2pos(BufferView const * bv, int targetx, int glue) const
{
const_iterator it = begin();
int lastx = 0;
int currx = 0;
CoordCacheBase<Inset> const & coords = bv->coordCache().getInsets();
// find first position after targetx
for (; currx < targetx && it < end(); ++it) {
lastx = currx;
if ((*it)->getChar() == ' ')
currx += glue;
currx += coords.dim((*it).nucleus()).wid;
}
/**
* If we are not at the beginning of the array, go to the left
* of the inset if one of the following two condition holds:
* - the current inset is editable (so that the cursor tip is
* deeper than us): in this case, we want all intermediate
* cursor slices to be before insets;
* - the mouse is closer to the left side of the inset than to
* the right one.
* See bug 1918 for details.
**/
if (it != begin() && currx >= targetx
&& ((*boost::prior(it))->asNestInset()
|| abs(lastx - targetx) < abs(currx - targetx))) {
--it;
}
return it - begin();
}
int MathData::dist(BufferView const & bv, int x, int y) const
{
return bv.coordCache().getArrays().squareDistance(this, x, y);
}
void MathData::setXY(BufferView & bv, int x, int y) const
{
//lyxerr << "setting position cache for MathData " << this << endl;
bv.coordCache().arrays().add(this, x, y);
}
Dimension const & MathData::dimension(BufferView const & bv) const
{
return bv.coordCache().getArrays().dim(this);
}
int MathData::xm(BufferView const & bv) const
{
Geometry const & g = bv.coordCache().getArrays().geometry(this);
return g.pos.x_ + g.dim.wid / 2;
}
int MathData::ym(BufferView const & bv) const
{
Geometry const & g = bv.coordCache().getArrays().geometry(this);
return g.pos.y_ + (g.dim.des - g.dim.asc) / 2;
}
int MathData::xo(BufferView const & bv) const
{
return bv.coordCache().getArrays().x(this);
}
int MathData::yo(BufferView const & bv) const
{
return bv.coordCache().getArrays().y(this);
}
ostream & operator<<(ostream & os, MathData const & ar)
{
odocstringstream oss;
NormalStream ns(oss);
ns << ar;
return os << to_utf8(oss.str());
}
odocstream & operator<<(odocstream & os, MathData const & ar)
{
NormalStream ns(os);
ns << ar;
return os;
}
} // namespace lyx