lyx_mirror/src/TexRow.cpp
Jean-Marc Lasgouttes fff28c5756 Always qualify calls to std::move()
This quashes a new warning in clang++ 15, when std::move() (the
one-parameter version) is used as simply move(). There is a strong
recommendation from WG21 to avoid that.

Details here: https://reviews.llvm.org/D119670

It might be that we should not use that many move()s. I am not
competent to decide on that.

I also used this occasion to get rid of a spacial casing for C++11
that does not seem necessary after all.
2022-10-21 14:11:36 +02:00

682 lines
15 KiB
C++

/**
* \file TexRow.cpp
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Matthias Ettrich
* \author Lars Gullik Bjønnes
* \author John Levon
* \author Guillaume Munch
*
* Full author contact details are available in file CREDITS.
*/
#include <config.h>
#include "TexRow.h"
#include "Buffer.h"
#include "Cursor.h"
#include "FuncRequest.h"
#include "Paragraph.h"
#include "mathed/InsetMath.h"
#include "support/convert.h"
#include "support/debug.h"
#include "support/docstring_list.h"
#include "support/lassert.h"
#include <algorithm>
#include <iterator>
#include <sstream>
using namespace std;
namespace lyx {
TexString::TexString(docstring s)
: str(std::move(s)), texrow(TexRow())
{
texrow.setRows(1 + count(str.begin(), str.end(), '\n'));
}
TexString::TexString(docstring s, TexRow t)
: str(std::move(s)), texrow(std::move(t))
{
validate();
}
void TexString::validate()
{
size_t lines = 1 + count(str.begin(), str.end(), '\n');
size_t rows = texrow.rows();
bool valid = lines == rows;
if (!valid)
LYXERR0("TexString has " << lines << " lines but " << rows << " rows." );
// Assert in devel mode. This is important to catch bugs early, otherwise
// they might be hard to notice and find. Recover gracefully in release
// mode.
LASSERT(valid, texrow.setRows(lines));
}
bool TexRow::RowEntryList::addEntry(RowEntry entry)
{
switch (entry.type) {
case text_entry:
if (isNone(text_entry_))
text_entry_ = entry.text;
else if (!v_.empty() && TexRow::sameParOrInsetMath(v_.back(), entry))
return false;
break;
default:
break;
}
forceAddEntry(entry);
return true;
}
void TexRow::RowEntryList::forceAddEntry(RowEntry entry)
{
if (v_.empty() || !(v_.back() == entry))
v_.push_back(entry);
}
TexRow::TextEntry TexRow::RowEntryList::getTextEntry() const
{
if (!isNone(text_entry_))
return text_entry_;
return TexRow::text_none;
}
void TexRow::RowEntryList::append(RowEntryList row)
{
if (isNone(text_entry_))
text_entry_ = row.text_entry_;
move(row.begin(), row.end(), back_inserter(v_));
}
TexRow::TexRow()
{
reset();
}
TexRow::TextEntry const TexRow::text_none = { -1, 0 };
TexRow::RowEntry const TexRow::row_none = TexRow::textEntry(-1, 0);
//static
bool TexRow::isNone(TextEntry t)
{
return t.id < 0;
}
//static
bool TexRow::isNone(RowEntry r)
{
return r.type == text_entry && isNone(r.text);
}
void TexRow::reset()
{
rowlist_.clear();
newline();
}
TexRow::RowEntryList & TexRow::currentRow()
{
return rowlist_.back();
}
//static
TexRow::RowEntry TexRow::textEntry(int id, pos_type pos)
{
RowEntry entry;
entry.type = text_entry;
entry.text.pos = pos;
entry.text.id = id;
return entry;
}
//static
TexRow::RowEntry TexRow::mathEntry(uid_type id, idx_type cell)
{
RowEntry entry;
entry.type = math_entry;
entry.math.cell = cell;
entry.math.id = id;
return entry;
}
//static
TexRow::RowEntry TexRow::beginDocument()
{
RowEntry entry;
entry.type = begin_document;
entry.begindocument = {};
return entry;
}
bool operator==(TexRow::RowEntry entry1, TexRow::RowEntry entry2)
{
if (entry1.type != entry2.type)
return false;
switch (entry1.type) {
case TexRow::text_entry:
return entry1.text.id == entry2.text.id
&& entry1.text.pos == entry2.text.pos;
case TexRow::math_entry:
return entry1.math.id == entry2.math.id
&& entry1.math.cell == entry2.math.cell;
case TexRow::begin_document:
return true;
default:
return false;
}
}
bool TexRow::start(RowEntry entry)
{
return currentRow().addEntry(entry);
}
bool TexRow::start(int id, pos_type pos)
{
return start(textEntry(id,pos));
}
void TexRow::forceStart(int id, pos_type pos)
{
return currentRow().forceAddEntry(textEntry(id,pos));
}
void TexRow::startMath(uid_type id, idx_type cell)
{
start(mathEntry(id,cell));
}
void TexRow::newline()
{
rowlist_.push_back(RowEntryList());
}
void TexRow::newlines(size_t num_lines)
{
while (num_lines--)
newline();
}
void TexRow::append(TexRow other)
{
RowList::iterator it = other.rowlist_.begin();
RowList::iterator const end = other.rowlist_.end();
LASSERT(it != end, return);
currentRow().append(std::move(*it++));
move(it, end, back_inserter(rowlist_));
}
pair<TexRow::TextEntry, TexRow::TextEntry>
TexRow::getEntriesFromRow(int const row) const
{
// FIXME: Take math entries into account, take table cells into account and
// get rid of the ad hoc special text entry for each row.
//
// FIXME: A yellow note alone on its paragraph makes the reverse-search on
// the subsequent line inaccurate. Get rid of text entries that
// correspond to no output by delaying their addition, at the level
// of otexrowstream, until a character is actually output.
//
LYXERR(Debug::OUTFILE, "getEntriesFromRow: row " << row << " requested");
// check bounds for row - 1, our target index
if (row <= 0)
return {text_none, text_none};
size_t const i = static_cast<size_t>(row - 1);
if (i >= rowlist_.size())
return {text_none, text_none};
// find the start entry
TextEntry const start = [&]() {
for (size_t j = i; j > 0; --j) {
if (!isNone(rowlist_[j].getTextEntry()))
return rowlist_[j].getTextEntry();
// Check the absence of begin_document at row j. The begin_document row
// entry is used to prevent mixing of body and preamble.
for (RowEntry entry : rowlist_[j])
if (entry.type == begin_document)
return text_none;
}
return text_none;
} ();
// find the end entry
TextEntry end = [&]() {
if (isNone(start))
return text_none;
// select up to the last position of the starting paragraph as a
// fallback
TextEntry last_pos = {start.id, -1};
// find the next occurence of paragraph start.id
for (size_t j = i + 1; j < rowlist_.size(); ++j) {
for (RowEntry entry : rowlist_[j]) {
if (entry.type == begin_document)
// what happens in the preamble remains in the preamble
return last_pos;
if (entry.type == text_entry && entry.text.id == start.id)
return entry.text;
}
}
return last_pos;
} ();
// The following occurs for a displayed math inset for instance (for good
// reasons involving subtleties of the algorithm in getRowFromDocIterator).
// We want this inset selected.
if (start.id == end.id && start.pos == end.pos)
++end.pos;
return {start, end};
}
pair<DocIterator, DocIterator> TexRow::getDocIteratorsFromRow(
int const row,
Buffer const & buf) const
{
TextEntry start, end;
tie(start,end) = getEntriesFromRow(row);
return getDocIteratorsFromEntries(start, end, buf);
}
//static
pair<DocIterator, DocIterator> TexRow::getDocIteratorsFromEntries(
TextEntry start,
TextEntry end,
Buffer const & buf)
{
auto set_pos = [](DocIterator & dit, pos_type pos) {
dit.pos() = (pos >= 0) ? min(pos, dit.lastpos())
// negative pos values are counted from the end
: max(dit.lastpos() + pos + 1, pos_type(0));
};
// Finding start
DocIterator dit_start = buf.getParFromID(start.id);
if (dit_start)
set_pos(dit_start, start.pos);
// Finding end
DocIterator dit_end = buf.getParFromID(end.id);
if (dit_end) {
set_pos(dit_end, end.pos);
// Step backwards to prevent selecting the beginning of another
// paragraph.
if (dit_end.pos() == 0 && !dit_end.top().at_cell_begin()) {
CursorSlice end_top = dit_end.top();
end_top.backwardPos();
if (dit_start && end_top != dit_start.top())
dit_end.top() = end_top;
}
dit_end.boundary(true);
}
return {dit_start, dit_end};
}
//static
FuncRequest TexRow::goToFunc(TextEntry start, TextEntry end)
{
return {LFUN_PARAGRAPH_GOTO,
convert<string>(start.id) + " " + convert<string>(start.pos) + " " +
convert<string>(end.id) + " " + convert<string>(end.pos)};
}
FuncRequest TexRow::goToFuncFromRow(int const row) const
{
TextEntry start, end;
tie(start,end) = getEntriesFromRow(row);
LYXERR(Debug::OUTFILE,
"goToFuncFromRow: for row " << row << ", TexRow has found "
"start (id=" << start.id << ",pos=" << start.pos << "), "
"end (id=" << end.id << ",pos=" << end.pos << ")");
return goToFunc(start, end);
}
//static
TexRow::RowEntry TexRow::rowEntryFromCursorSlice(CursorSlice const & slice)
{
RowEntry entry;
InsetMath * insetMath = slice.asInsetMath();
if (insetMath) {
entry.type = math_entry;
entry.math.id = insetMath->id();
entry.math.cell = slice.idx();
} else if (slice.text()) {
entry.type = text_entry;
entry.text.id = slice.paragraph().id();
entry.text.pos = slice.pos();
} else
LASSERT(false, return row_none);
return entry;
}
//static
bool TexRow::sameParOrInsetMath(RowEntry entry1, RowEntry entry2)
{
if (entry1.type != entry2.type)
return false;
switch (entry1.type) {
case TexRow::text_entry:
return entry1.text.id == entry2.text.id;
case TexRow::math_entry:
return entry1.math.id == entry2.math.id;
case TexRow::begin_document:
return true;
default:
return false;
}
}
//static
int TexRow::comparePos(RowEntry entry1, RowEntry entry2)
{
// assume it is sameParOrInsetMath
switch (entry1.type /* equal to entry2.type */) {
case TexRow::text_entry:
return entry2.text.pos - entry1.text.pos;
case TexRow::math_entry:
return entry2.math.cell - entry1.math.cell;
case TexRow::begin_document:
return 0;
default:
return 0;
}
}
// An iterator on RowList that goes top-down, left-right
//
// We assume that the end of RowList does not change, which makes things simpler
//
// Records a pair of iterators on the RowEntryList (row_it_, row_end_) and a
// pair of iterators on the current row (it_, it_end_).
//
// it_ always points to a valid position unless row_it_ == row_end_.
//
// We could turn this into a proper bidirectional iterator, but we don't need as
// much.
//
class TexRow::RowListIterator
{
public:
RowListIterator(RowList::const_iterator r,
RowList::const_iterator r_end)
: row_it_(r), row_end_(r_end),
it_(r == r_end ? RowEntryList::const_iterator() : r->begin()),
it_end_(r == r_end ? RowEntryList::const_iterator() : r->end())
{
normalize();
}
RowListIterator() :
row_it_(RowList::const_iterator()),
row_end_(RowList::const_iterator()),
it_(RowEntryList::const_iterator()),
it_end_(RowEntryList::const_iterator()) { }
RowEntry const & operator*()
{
return *it_;
}
RowListIterator & operator++()
{
++it_;
normalize();
return *this;
}
bool atEnd() const
{
return row_it_ == row_end_;
}
bool operator==(RowListIterator const & a) const
{
return row_it_ == a.row_it_ && ((atEnd() && a.atEnd()) || it_ == a.it_);
}
bool operator!=(RowListIterator const & a) const { return !operator==(a); }
// Current row.
RowList::const_iterator const & row() const
{
return row_it_;
}
private:
// ensures that it_ points to a valid value unless row_it_ == row_end_
void normalize()
{
if (row_it_ == row_end_)
return;
while (it_ == it_end_) {
++row_it_;
if (row_it_ != row_end_) {
it_ = row_it_->begin();
it_end_ = row_it_->end();
} else
return;
}
}
//
RowList::const_iterator row_it_;
//
RowList::const_iterator row_end_;
//
RowEntryList::const_iterator it_;
//
RowEntryList::const_iterator it_end_;
};
TexRow::RowListIterator TexRow::begin() const
{
return RowListIterator(rowlist_.begin(), rowlist_.end());
}
TexRow::RowListIterator TexRow::end() const
{
return RowListIterator(rowlist_.end(), rowlist_.end());
}
pair<int,int> TexRow::rowFromDocIterator(DocIterator const & dit) const
{
// Do not change anything in this algorithm if unsure.
bool beg_found = false;
bool end_is_next = true;
int end_offset = 1;
size_t best_slice = 0;
RowEntry best_entry = row_none;
size_t const n = dit.depth();
// this loop finds a pair (best_beg_row,best_end_row) where best_beg_row is
// the first row of the topmost possible CursorSlice, and best_end_row is
// the one just before the first row matching the next CursorSlice.
RowListIterator const begin = this->begin();//necessary disambiguation
RowListIterator const end = this->end();
RowListIterator best_beg_entry;
//best last entry with same pos as the beg_entry, or first entry with pos
//immediately following the beg_entry
RowListIterator best_end_entry;
RowListIterator it = begin;
for (; it != end; ++it) {
// Compute the best end row.
if (beg_found
&& (!sameParOrInsetMath(*it, *best_end_entry)
|| comparePos(*it, *best_end_entry) <= 0)
&& sameParOrInsetMath(*it, best_entry)) {
switch (comparePos(*it, best_entry)) {
case 0:
// Either it is the last one that matches pos...
best_end_entry = it;
end_is_next = false;
end_offset = 1;
break;
case -1: {
// ...or it is the row preceding the first that matches pos+1
if (!end_is_next) {
end_is_next = true;
if (it.row() != best_end_entry.row())
end_offset = 0;
best_end_entry = it;
}
break;
}
}
}
// Compute the best begin row. It is better than the previous one if it
// matches either at a deeper level, or at the same level but not
// before.
for (size_t i = best_slice; i < n; ++i) {
RowEntry entry_i = rowEntryFromCursorSlice(dit[i]);
if (sameParOrInsetMath(*it, entry_i)) {
if (comparePos(*it, entry_i) >= 0
&& (i > best_slice
|| !beg_found
|| !sameParOrInsetMath(*it, *best_beg_entry)
|| (comparePos(*it, *best_beg_entry) <= 0
&& comparePos(entry_i, *best_beg_entry) != 0)
)
) {
beg_found = true;
end_is_next = false;
end_offset = 1;
best_slice = i;
best_entry = entry_i;
best_beg_entry = best_end_entry = it;
}
//found CursorSlice
break;
}
}
}
if (!beg_found)
return make_pair(-1,-1);
int const best_beg_row = distance(rowlist_.begin(),
best_beg_entry.row()) + 1;
int const best_end_row = distance(rowlist_.begin(),
best_end_entry.row()) + end_offset;
return make_pair(best_beg_row, best_end_row);
}
pair<int,int> TexRow::rowFromCursor(Cursor const & cur) const
{
DocIterator beg = cur.selectionBegin();
pair<int,int> beg_rows = rowFromDocIterator(beg);
if (cur.selection()) {
DocIterator end = cur.selectionEnd();
if (!cur.selIsMultiCell() && !end.top().at_cell_begin())
end.top().backwardPos();
pair<int,int> end_rows = rowFromDocIterator(end);
return make_pair(min(beg_rows.first, end_rows.first),
max(beg_rows.second, end_rows.second));
} else
return make_pair(beg_rows.first, beg_rows.second);
}
size_t TexRow::rows() const
{
return rowlist_.size();
}
void TexRow::setRows(size_t r)
{
rowlist_.resize(r, RowEntryList());
}
// debugging functions
///
docstring TexRow::asString(RowEntry entry)
{
odocstringstream os;
switch (entry.type) {
case TexRow::text_entry:
os << "(par " << entry.text.id << "," << entry.text.pos << ")";
break;
case TexRow::math_entry:
os << "(" << entry.math.id << "," << entry.math.cell << ")";
break;
case TexRow::begin_document:
os << "(begin_document)";
break;
default:
break;
}
return os.str();
}
///prepends the texrow to the source given by tex, for debugging purpose
void TexRow::prepend(docstring_list & tex) const
{
size_type const prefix_length = 25;
if (tex.size() < rowlist_.size())
tex.resize(rowlist_.size());
auto it = rowlist_.cbegin();
auto const beg = rowlist_.cbegin();
auto const end = rowlist_.cend();
for (; it < end; ++it) {
docstring entry;
for (RowEntry const & e : *it)
entry += asString(e);
if (entry.length() < prefix_length)
entry = entry + docstring(prefix_length - entry.length(), ' ');
ptrdiff_t i = it - beg;
tex[i] = entry + " " + tex[i];
}
}
} // namespace lyx