mirror of
https://git.lyx.org/repos/lyx.git
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fc5b22a2f1
These uses are inefficient (a loop really) and require that pit_type is ptrdiff_t. Instead, RandomAccesslist::constIterator is renamed to iterator_at and a version adding a non-const iterator is added. Additionally, the method retirns end() when position is equal to the size of the container (see #11861). lyx::next and lyx::prev are removed, and std::prev is used in the few places where the code requires it (for no good reason IMO).
894 lines
22 KiB
C++
894 lines
22 KiB
C++
/**
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* \file Compare.cpp
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* This file is part of LyX, the document processor.
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* Licence details can be found in the file COPYING.
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*
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* \author Vincent van Ravesteijn
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*
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* Full author contact details are available in file CREDITS.
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*/
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#include <config.h>
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#include "Compare.h"
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#include "Author.h"
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#include "BufferParams.h"
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#include "Changes.h"
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#include "CutAndPaste.h"
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#include "ErrorList.h"
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#include "Font.h"
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#include "insets/InsetText.h"
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#include "support/docstream.h"
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#include "support/lassert.h"
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#include "support/lyxalgo.h"
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#include "support/qstring_helpers.h"
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using namespace std;
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using namespace lyx::support;
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namespace lyx {
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enum Direction {
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Forward = 0,
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Backward
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};
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static void step(DocIterator & dit, Direction direction)
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{
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if (direction == Forward)
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dit.top().forwardPos();
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else
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dit.top().backwardPos();
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}
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static void step(DocIterator & dit, DocIterator const & end, Direction direction)
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{
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if (dit != end)
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step(dit, direction);
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}
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/**
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* A pair of two DocIterators that form a range.
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*/
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class DocRange {
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public:
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DocRange(DocIterator const & from_, DocIterator const & to_)
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: from(from_), to(to_)
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{}
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DocRange(Buffer const * buf) :
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from(doc_iterator_begin(buf)),
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to(doc_iterator_end(buf))
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{
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to.backwardPos();
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}
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///
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Text * text() const { return from.text(); }
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///
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bool empty() const { return to <= from; }
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///
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size_t length() const;
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/// The begin of the range
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DocIterator from;
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/// The end of the range
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DocIterator to;
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};
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size_t DocRange::length() const
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{
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ParagraphList const & ps = from.text()->paragraphs();
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size_t length = 0;
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pit_type pit = from.pit();
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pit_type const endpit = to.pit();
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for (; pit < endpit; ++pit)
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length += ps[pit].size() + 1;
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length += to.pos() - from.pos();
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return length;
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}
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class DocPair {
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public:
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DocPair()
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{}
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DocPair(DocIterator o_, DocIterator n_)
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: o(o_), n(n_)
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{}
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bool operator!=(DocPair const & rhs)
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{
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// this might not be intuitive but correct for our purpose
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return o != rhs.o && n != rhs.n;
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}
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DocPair & operator++()
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{
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step(o, Forward);
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step(n, Forward);
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return *this;
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}
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DocPair & operator--()
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{
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step(o, Backward);
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step(n, Backward);
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return *this;
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}
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///
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DocIterator o;
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///
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DocIterator n;
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};
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/**
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* A pair of two DocRanges.
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*/
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class DocRangePair {
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public:
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DocRangePair(DocRange const & o_, DocRange const & n_)
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: o(o_), n(n_)
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{}
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DocRangePair(DocPair const & from, DocPair const & to)
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: o(from.o, to.o), n(from.n, to.n)
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{}
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DocRangePair(Buffer const * o_buf, Buffer const * n_buf)
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: o(o_buf), n(n_buf)
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{}
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/// Returns the from pair
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DocPair from() const
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{
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return DocPair(o.from, n.from);
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}
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/// Returns the to pair
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DocPair to() const
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{
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return DocPair(o.to, n.to);
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}
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DocRange o;
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DocRange n;
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};
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static DocRangePair stepIntoInset(DocPair const & inset_location)
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{
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DocRangePair rp(inset_location, inset_location);
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rp.o.from.forwardPos();
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rp.n.from.forwardPos();
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step(rp.o.to, Forward);
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step(rp.n.to, Forward);
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rp.o.to.backwardPos();
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rp.n.to.backwardPos();
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return rp;
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}
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/**
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* This class is designed to hold a vector that has both positive as
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* negative indices. It is internally represented as two vectors, one
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* for non-zero indices and one for negative indices. In this way, the
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* vector can grow in both directions.
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* If an index is not available in the vector, the default value is
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* returned. If an object is put in the vector beyond its size, the
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* empty spots in between are also filled with the default value.
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*/
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template<class T>
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class compl_vector {
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public:
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compl_vector()
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{}
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void reset(T const & def)
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{
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default_ = def;
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Vp_.clear();
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Vn_.clear();
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}
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/// Gets the value at index. If it is not in the vector
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/// the default value is inserted and returned.
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T & operator[](int index) {
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vector<T> & V = index >= 0 ? Vp_ : Vn_;
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unsigned int const ii = index >= 0 ? index : -index - 1;
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while (ii >= V.size())
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V.push_back(default_);
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return V[ii];
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}
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private:
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/// The vector for positive indices
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vector<T> Vp_;
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/// The vector for negative indices
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vector<T> Vn_;
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/// The default value that is inserted in the vector
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/// if more space is needed
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T default_;
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};
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/**
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* The implementation of the algorithm that does the comparison
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* between two documents.
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*/
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class Compare::Impl {
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public:
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///
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Impl(Compare const & compare)
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: abort_(false), n_(0), m_(0), offset_reverse_diagonal_(0),
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odd_offset_(0), compare_(compare),
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old_buf_(nullptr), new_buf_(nullptr), dest_buf_(nullptr),
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dest_pars_(nullptr), recursion_level_(0), nested_inset_level_(0), D_(0)
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{}
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///
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~Impl()
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{}
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// Algorithm to find the shortest edit string. This algorithm
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// only needs a linear amount of memory (linear with the sum
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// of the number of characters in the two paragraph-lists).
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bool diff(Buffer const * new_buf, Buffer const * old_buf,
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Buffer const * dest_buf);
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/// Set to true to cancel the algorithm
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bool abort_;
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///
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QString status()
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{
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QString status;
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status += toqstr("recursion level:") + " " + QString::number(recursion_level_)
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+ " " + toqstr("differences:") + " " + QString::number(D_);
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return status;
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}
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private:
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/// Finds the middle snake and returns the length of the
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/// shortest edit script.
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int findMiddleSnake(DocRangePair const & rp, DocPair & middle_snake);
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enum SnakeResult {
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NoSnake,
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SingleSnake,
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NormalSnake
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};
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/// Retrieve the middle snake when there is overlap between
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/// the forward and backward path.
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SnakeResult retrieveMiddleSnake(int k, int D, Direction direction,
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DocPair & middle_snake);
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/// Find the furthest reaching D-path (number of horizontal
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/// and vertical steps; differences between the old and new
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/// document) in the k-diagonal (vertical minus horizontal steps).
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void furthestDpathKdiagonal(int D, int k,
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DocRangePair const & rp, Direction direction);
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/// Is there overlap between the forward and backward path
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bool overlap(int k, int D);
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/// This function is called recursively by a divide and conquer
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/// algorithm. Each time, the string is divided into two split
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/// around the middle snake.
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void diff_i(DocRangePair const & rp);
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/// Processes the split chunks. It either adds them as deleted,
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/// as added, or call diff_i for further processing.
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void diffPart(DocRangePair const & rp);
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/// Runs the algorithm for the inset located at /c it and /c it_n
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/// and adds the result to /c pars.
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void diffInset(Inset * inset, DocPair const & p);
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/// Adds the snake to the destination buffer. The algorithm will
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/// recursively be applied to any InsetTexts that are within the snake.
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void processSnake(DocRangePair const & rp);
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/// Writes the range to the destination buffer
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void writeToDestBuffer(DocRange const & range,
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Change::Type type = Change::UNCHANGED);
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/// Writes the paragraph list to the destination buffer
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void writeToDestBuffer(ParagraphList const & copy_pars) const;
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/// The length of the old chunk currently processed
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int n_;
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/// The length of the new chunk currently processed
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int m_;
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/// The offset diagonal of the reverse path of the
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/// currently processed chunk
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int offset_reverse_diagonal_;
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/// Is the offset odd or even ?
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bool odd_offset_;
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/// The thread object, used to emit signals to the GUI
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Compare const & compare_;
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/// The buffer containing text that will be marked as old
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Buffer const * old_buf_;
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/// The buffer containing text that will be marked as new
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Buffer const * new_buf_;
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/// The buffer containing text that will be marked as new
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Buffer const * dest_buf_;
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/// The paragraph list of the destination buffer
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ParagraphList * dest_pars_;
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/// The level of recursion
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int recursion_level_;
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/// The number of nested insets at this level
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int nested_inset_level_;
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/// The position/snake in the old/new document
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/// of the forward/reverse search
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compl_vector<DocIterator> ofp;
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compl_vector<DocIterator> nfp;
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compl_vector<DocIterator> ofs;
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compl_vector<DocIterator> nfs;
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compl_vector<DocIterator> orp;
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compl_vector<DocIterator> nrp;
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compl_vector<DocIterator> ors;
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compl_vector<DocIterator> nrs;
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/// The number of differences in the path the algorithm
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/// is currently processing.
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int D_;
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};
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/////////////////////////////////////////////////////////////////////
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//
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// Compare
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//
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/////////////////////////////////////////////////////////////////////
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Compare::Compare(Buffer const * new_buf, Buffer const * old_buf,
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Buffer * const dest_buf, CompareOptions const & options)
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: new_buffer(new_buf), old_buffer(old_buf), dest_buffer(dest_buf),
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options_(options), pimpl_(new Impl(*this))
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{
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connect(&status_timer_, SIGNAL(timeout()),
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this, SLOT(doStatusMessage()));
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status_timer_.start(1000);
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}
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void Compare::doStatusMessage()
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{
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statusMessage(pimpl_->status());
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}
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void Compare::run()
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{
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if (!dest_buffer || !new_buffer || !old_buffer)
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return;
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// Copy the buffer params to the destination buffer
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dest_buffer->params() = options_.settings_from_new
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? new_buffer->params() : old_buffer->params();
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// Copy extra authors to the destination buffer
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AuthorList const & extra_authors = options_.settings_from_new ?
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old_buffer->params().authors() : new_buffer->params().authors();
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AuthorList::Authors::const_iterator it = extra_authors.begin();
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for (; it != extra_authors.end(); ++it)
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dest_buffer->params().authors().record(*it);
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// We will need this later
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DocumentClassConstPtr const olddc =
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dest_buffer->params().documentClassPtr();
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// We do not want to share the DocumentClass with the other Buffer.
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// See bug #10295.
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dest_buffer->params().makeDocumentClass();
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doStatusMessage();
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// Do the real work
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if (!doCompare())
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return;
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// The comparison routine simply copies the paragraphs over into the
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// new buffer with the document class from wherever they came from.
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// So we need to reset the document class of all the paragraphs.
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// See bug #10295.
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ErrorList el;
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cap::switchBetweenClasses(
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olddc, dest_buffer->params().documentClassPtr(),
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static_cast<InsetText &>(dest_buffer->inset()), el);
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finished(pimpl_->abort_);
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return;
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}
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int Compare::doCompare()
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{
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return pimpl_->diff(new_buffer, old_buffer, dest_buffer);
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}
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void Compare::abort()
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{
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pimpl_->abort_ = true;
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condition_.wakeOne();
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wait();
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pimpl_->abort_ = false;
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}
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static void getParagraphList(DocRange const & range,
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ParagraphList & pars)
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{
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// Clone the paragraphs within the selection.
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pit_type startpit = range.from.pit();
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pit_type endpit = range.to.pit();
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ParagraphList const & ps_ = range.text()->paragraphs();
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ParagraphList tmp_pars(ps_.iterator_at(startpit),
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ps_.iterator_at(endpit + 1));
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// Remove the end of the last paragraph; afterwards, remove the
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// beginning of the first paragraph. Keep this order - there may only
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// be one paragraph!
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Paragraph & back = tmp_pars.back();
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back.eraseChars(range.to.pos(), back.size(), false);
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Paragraph & front = tmp_pars.front();
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front.eraseChars(0, range.from.pos(), false);
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pars.insert(pars.begin(), tmp_pars.begin(), tmp_pars.end());
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}
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static bool equal(Inset const * i_o, Inset const * i_n)
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{
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if (!i_o || !i_n)
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return false;
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// Different types of insets
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if (i_o->lyxCode() != i_n->lyxCode())
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return false;
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// Editable insets are assumed to be the same as they are of the
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// same type. If we later on decide that we insert them in the
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// document as being unchanged, we will run the algorithm on the
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// contents of the two insets.
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// FIXME: This fails if the parameters of the insets differ.
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// FIXME: We do not recurse into InsetTabulars.
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// FIXME: We need methods inset->equivalent(inset).
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if (i_o->editable() && !i_o->asInsetMath()
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&& i_o->asInsetText())
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return true;
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ostringstream o_os;
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ostringstream n_os;
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i_o->write(o_os);
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i_n->write(n_os);
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return o_os.str() == n_os.str();
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}
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static bool equal(DocIterator & o, DocIterator & n)
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{
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// Explicitly check for this, so we won't call
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// Paragraph::getChar for the last pos.
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bool const o_lastpos = o.pos() == o.lastpos();
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bool const n_lastpos = n.pos() == n.lastpos();
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if (o_lastpos || n_lastpos)
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return o_lastpos && n_lastpos;
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Paragraph const & old_par = o.text()->getPar(o.pit());
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Paragraph const & new_par = n.text()->getPar(n.pit());
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char_type const c_o = old_par.getChar(o.pos());
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char_type const c_n = new_par.getChar(n.pos());
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if (c_o != c_n)
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return false;
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if (old_par.isInset(o.pos())) {
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Inset const * i_o = old_par.getInset(o.pos());
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Inset const * i_n = new_par.getInset(n.pos());
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if (i_o && i_n)
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return equal(i_o, i_n);
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}
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Font fo = old_par.getFontSettings(o.buffer()->params(), o.pos());
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Font fn = new_par.getFontSettings(n.buffer()->params(), n.pos());
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return fo == fn;
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}
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/// Traverses a snake in a certain direction. p points to a
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/// position in the old and new file and they are synchronously
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/// moved along the snake. The function returns true if a snake
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/// was found.
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static bool traverseSnake(DocPair & p, DocRangePair const & range,
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Direction direction)
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{
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bool ret = false;
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DocPair const & p_end =
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direction == Forward ? range.to() : range.from();
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while (p != p_end) {
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if (direction == Backward)
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--p;
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if (!equal(p.o, p.n)) {
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if (direction == Backward)
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++p;
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return ret;
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}
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if (direction == Forward)
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++p;
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ret = true;
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}
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return ret;
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}
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/////////////////////////////////////////////////////////////////////
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//
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// Compare::Impl
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//
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/////////////////////////////////////////////////////////////////////
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void Compare::Impl::furthestDpathKdiagonal(int D, int k,
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DocRangePair const & rp, Direction direction)
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{
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compl_vector<DocIterator> & op = direction == Forward ? ofp : orp;
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compl_vector<DocIterator> & np = direction == Forward ? nfp : nrp;
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compl_vector<DocIterator> & os = direction == Forward ? ofs : ors;
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compl_vector<DocIterator> & ns = direction == Forward ? nfs : nrs;
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// A vertical step means stepping one character in the new document.
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bool vertical_step = k == -D;
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if (!vertical_step && k != D) {
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vertical_step = direction == Forward
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? op[k - 1] < op[k + 1] : op[k - 1] > op[k + 1];
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|
}
|
|
|
|
// Where do we take the step from ?
|
|
int const kk = vertical_step ? k + 1 : k - 1;
|
|
DocPair p(op[kk], np[kk]);
|
|
DocPair const s(os[kk], ns[kk]);
|
|
|
|
// If D==0 we simulate a vertical step from (0,-1) by doing nothing.
|
|
if (D != 0) {
|
|
// Take a step
|
|
if (vertical_step && direction == Forward)
|
|
step(p.n, rp.n.to, direction);
|
|
else if (vertical_step && direction == Backward)
|
|
step(p.n, rp.n.from, direction);
|
|
else if (!vertical_step && direction == Forward)
|
|
step(p.o, rp.o.to, direction);
|
|
else if (!vertical_step && direction == Backward)
|
|
step(p.o, rp.o.from, direction);
|
|
}
|
|
|
|
// Traverse snake
|
|
if (traverseSnake(p, rp, direction)) {
|
|
// Record last snake
|
|
os[k] = p.o;
|
|
ns[k] = p.n;
|
|
} else {
|
|
// Copy last snake from the previous step
|
|
os[k] = s.o;
|
|
ns[k] = s.n;
|
|
}
|
|
|
|
//Record new position
|
|
op[k] = p.o;
|
|
np[k] = p.n;
|
|
}
|
|
|
|
|
|
bool Compare::Impl::overlap(int k, int D)
|
|
{
|
|
// To generalize for the forward and reverse checks
|
|
int kk = offset_reverse_diagonal_ - k;
|
|
|
|
// Can we have overlap ?
|
|
if (kk <= D && kk >= -D) {
|
|
// Do we have overlap ?
|
|
if (odd_offset_)
|
|
return ofp[k] >= orp[kk] && nfp[k] >= nrp[kk];
|
|
else
|
|
return ofp[kk] >= orp[k] && nfp[kk] >= nrp[k];
|
|
}
|
|
return false;
|
|
}
|
|
|
|
|
|
Compare::Impl::SnakeResult Compare::Impl::retrieveMiddleSnake(
|
|
int k, int D, Direction direction, DocPair & middle_snake)
|
|
{
|
|
compl_vector<DocIterator> & os = direction == Forward ? ofs : ors;
|
|
compl_vector<DocIterator> & ns = direction == Forward ? nfs : nrs;
|
|
compl_vector<DocIterator> & os_r = direction == Forward ? ors : ofs;
|
|
compl_vector<DocIterator> & ns_r = direction == Forward ? nrs : nfs;
|
|
|
|
// The diagonal while doing the backward search
|
|
int kk = -k + offset_reverse_diagonal_;
|
|
|
|
// Did we find a snake ?
|
|
if (os[k].empty() && os_r[kk].empty()) {
|
|
// No, there is no snake at all, in which case
|
|
// the length of the shortest edit script is M+N.
|
|
LATTEST(2 * D - odd_offset_ == m_ + n_);
|
|
return NoSnake;
|
|
}
|
|
|
|
if (os[k].empty()) {
|
|
// Yes, but there is only 1 snake and we found it in the
|
|
// reverse path.
|
|
middle_snake.o = os_r[kk];
|
|
middle_snake.n = ns_r[kk];
|
|
return SingleSnake;
|
|
}
|
|
|
|
middle_snake.o = os[k];
|
|
middle_snake.n = ns[k];
|
|
return NormalSnake;
|
|
}
|
|
|
|
|
|
int Compare::Impl::findMiddleSnake(DocRangePair const & rp,
|
|
DocPair & middle_snake)
|
|
{
|
|
// The lengths of the old and new chunks.
|
|
n_ = rp.o.length();
|
|
m_ = rp.n.length();
|
|
|
|
// Forward paths are centered around the 0-diagonal; reverse paths
|
|
// are centered around the diagonal N - M. (Delta in the article)
|
|
offset_reverse_diagonal_ = n_ - m_;
|
|
|
|
// If the offset is odd, only check for overlap while extending forward
|
|
// paths, otherwise only check while extending reverse paths.
|
|
odd_offset_ = (offset_reverse_diagonal_ % 2 != 0);
|
|
|
|
ofp.reset(rp.o.from);
|
|
nfp.reset(rp.n.from);
|
|
ofs.reset(DocIterator());
|
|
nfs.reset(DocIterator());
|
|
orp.reset(rp.o.to);
|
|
nrp.reset(rp.n.to);
|
|
ors.reset(DocIterator());
|
|
nrs.reset(DocIterator());
|
|
|
|
// In the formula below, the "+ 1" ensures we round like ceil()
|
|
int const D_max = (m_ + n_ + 1)/2;
|
|
// D is the number of horizontal and vertical steps, i.e.
|
|
// different characters in the old and new chunk.
|
|
for (int D = 0; D <= D_max; ++D) {
|
|
// to be used in the status messages
|
|
D_ = D;
|
|
|
|
// Forward and reverse paths
|
|
for (int f = 0; f < 2; ++f) {
|
|
Direction direction = f == 0 ? Forward : Backward;
|
|
|
|
// Diagonals between -D and D can be reached by a D-path
|
|
for (int k = -D; k <= D; k += 2) {
|
|
// Find the furthest reaching D-path on this diagonal
|
|
furthestDpathKdiagonal(D, k, rp, direction);
|
|
|
|
// Only check for overlap for forward paths if the offset is odd
|
|
// and only for reverse paths if the offset is even.
|
|
if (odd_offset_ == (direction == Forward)) {
|
|
|
|
// Do the forward and backward paths overlap ?
|
|
if (overlap(k, D - odd_offset_)) {
|
|
retrieveMiddleSnake(k, D, direction, middle_snake);
|
|
return 2 * D - odd_offset_;
|
|
}
|
|
}
|
|
if (abort_)
|
|
return 0;
|
|
}
|
|
}
|
|
}
|
|
// This should never be reached
|
|
return -2;
|
|
}
|
|
|
|
|
|
bool Compare::Impl::diff(Buffer const * new_buf, Buffer const * old_buf,
|
|
Buffer const * dest_buf)
|
|
{
|
|
if (!new_buf || !old_buf || !dest_buf)
|
|
return false;
|
|
|
|
old_buf_ = old_buf;
|
|
new_buf_ = new_buf;
|
|
dest_buf_ = dest_buf;
|
|
dest_pars_ = &dest_buf->inset().asInsetText()->paragraphs();
|
|
dest_pars_->clear();
|
|
|
|
recursion_level_ = 0;
|
|
nested_inset_level_ = 0;
|
|
|
|
DocRangePair rp(old_buf_, new_buf_);
|
|
|
|
DocPair from = rp.from();
|
|
traverseSnake(from, rp, Forward);
|
|
DocRangePair const snake(rp.from(), from);
|
|
processSnake(snake);
|
|
|
|
// Start the recursive algorithm
|
|
DocRangePair rp_new(from, rp.to());
|
|
if (!rp_new.o.empty() || !rp_new.n.empty())
|
|
diff_i(rp_new);
|
|
|
|
for (pit_type p = 0; p < (pit_type)dest_pars_->size(); ++p) {
|
|
(*dest_pars_)[p].setInsetBuffers(const_cast<Buffer &>(*dest_buf));
|
|
(*dest_pars_)[p].setInsetOwner(&dest_buf_->inset());
|
|
}
|
|
|
|
return true;
|
|
}
|
|
|
|
|
|
void Compare::Impl::diff_i(DocRangePair const & rp)
|
|
{
|
|
if (abort_)
|
|
return;
|
|
|
|
// The middle snake
|
|
DocPair middle_snake;
|
|
|
|
// Divides the problem into two smaller problems, split around
|
|
// the snake in the middle.
|
|
int const L_ses = findMiddleSnake(rp, middle_snake);
|
|
|
|
// Set maximum of progress bar
|
|
if (++recursion_level_ == 1)
|
|
compare_.progressMax(L_ses);
|
|
|
|
// There are now three possibilities: the strings were the same,
|
|
// the strings were completely different, or we found a middle
|
|
// snake and we can split the string into two parts to process.
|
|
if (L_ses == 0)
|
|
// Two the same strings (this must be a very rare case, because
|
|
// usually this will be part of a snake adjacent to these strings).
|
|
writeToDestBuffer(rp.o);
|
|
|
|
else if (middle_snake.o.empty()) {
|
|
// Two totally different strings
|
|
writeToDestBuffer(rp.o, Change::DELETED);
|
|
writeToDestBuffer(rp.n, Change::INSERTED);
|
|
|
|
} else {
|
|
// Retrieve the complete snake
|
|
DocPair first_part_end = middle_snake;
|
|
traverseSnake(first_part_end, rp, Backward);
|
|
DocRangePair first_part(rp.from(), first_part_end);
|
|
|
|
DocPair second_part_begin = middle_snake;
|
|
traverseSnake(second_part_begin, rp, Forward);
|
|
DocRangePair second_part(second_part_begin, rp.to());
|
|
|
|
// Split the string in three parts:
|
|
// 1. in front of the snake
|
|
diffPart(first_part);
|
|
|
|
// 2. the snake itself, and
|
|
DocRangePair const snake(first_part.to(), second_part.from());
|
|
processSnake(snake);
|
|
|
|
// 3. behind the snake.
|
|
diffPart(second_part);
|
|
}
|
|
--recursion_level_;
|
|
}
|
|
|
|
|
|
void Compare::Impl::diffPart(DocRangePair const & rp)
|
|
{
|
|
// Is there a finite length string in both buffers, if not there
|
|
// is an empty string and we write the other one to the buffer.
|
|
if (!rp.o.empty() && !rp.n.empty())
|
|
diff_i(rp);
|
|
|
|
else if (!rp.o.empty())
|
|
writeToDestBuffer(rp.o, Change::DELETED);
|
|
|
|
else if (!rp.n.empty())
|
|
writeToDestBuffer(rp.n, Change::INSERTED);
|
|
}
|
|
|
|
|
|
void Compare::Impl::diffInset(Inset * inset, DocPair const & p)
|
|
{
|
|
// Find the dociterators for the beginning and the
|
|
// end of the inset, for the old and new document.
|
|
DocRangePair const rp = stepIntoInset(p);
|
|
|
|
// Recurse into the inset. Temporarily replace the dest_pars
|
|
// paragraph list by the paragraph list of the nested inset.
|
|
ParagraphList * backup_dest_pars = dest_pars_;
|
|
dest_pars_ = &inset->asInsetText()->text().paragraphs();
|
|
dest_pars_->clear();
|
|
|
|
++nested_inset_level_;
|
|
diff_i(rp);
|
|
--nested_inset_level_;
|
|
|
|
dest_pars_ = backup_dest_pars;
|
|
}
|
|
|
|
|
|
void Compare::Impl::processSnake(DocRangePair const & rp)
|
|
{
|
|
ParagraphList pars;
|
|
getParagraphList(rp.o, pars);
|
|
|
|
// Find insets in this paragaph list
|
|
DocPair it = rp.from();
|
|
for (; it.o < rp.o.to; ++it) {
|
|
Inset * inset = it.o.text()->getPar(it.o.pit()).getInset(it.o.pos());
|
|
if (inset && inset->editable() && inset->asInsetText()) {
|
|
// Find the inset in the paragraph list that will be pasted into
|
|
// the final document. The contents of the inset will be replaced
|
|
// by the output of the algorithm below.
|
|
pit_type const pit = it.o.pit() - rp.o.from.pit();
|
|
pos_type const pos = pit ? it.o.pos() : it.o.pos() - rp.o.from.pos();
|
|
inset = pars[pit].getInset(pos);
|
|
LASSERT(inset, continue);
|
|
diffInset(inset, it);
|
|
}
|
|
}
|
|
writeToDestBuffer(pars);
|
|
}
|
|
|
|
|
|
void Compare::Impl::writeToDestBuffer(DocRange const & range,
|
|
Change::Type type)
|
|
{
|
|
ParagraphList pars;
|
|
getParagraphList(range, pars);
|
|
|
|
pos_type size = 0;
|
|
|
|
// Set the change
|
|
ParagraphList::iterator it = pars.begin();
|
|
for (; it != pars.end(); ++it) {
|
|
it->setChange(Change(type));
|
|
size += it->size();
|
|
}
|
|
|
|
writeToDestBuffer(pars);
|
|
|
|
if (nested_inset_level_ == 0)
|
|
compare_.progress(size);
|
|
}
|
|
|
|
|
|
void Compare::Impl::writeToDestBuffer(ParagraphList const & pars) const
|
|
{
|
|
pit_type const pit = dest_pars_->size() - 1;
|
|
dest_pars_->insert(dest_pars_->end(), pars.begin(), pars.end());
|
|
if (pit >= 0)
|
|
mergeParagraph(dest_buf_->params(), *dest_pars_, pit);
|
|
}
|
|
|
|
|
|
#include "moc_Compare.cpp"
|
|
|
|
} // namespace lyx
|