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tdelibs/tdecore/kcompletion.cpp

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/* This file is part of the KDE libraries
Copyright (C) 1999,2000,2001 Carsten Pfeiffer <pfeiffer@kde.org>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public License
along with this library; see the file COPYING.LIB. If not, write to
the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301, USA.
*/
#include <kapplication.h>
#include <kdebug.h>
#include <klocale.h>
#include <knotifyclient.h>
#include <kglobal.h>
#include <tqptrvector.h>
#include "kcompletion.h"
#include "kcompletion_private.h"
class KCompletionPrivate
{
public:
// not a member to avoid #including kcompletion_private.h from kcompletion.h
// list used for nextMatch() and previousMatch()
KCompletionMatchesWrapper matches;
};
KCompletion::KCompletion()
{
d = new KCompletionPrivate;
myCompletionMode = KGlobalSettings::completionMode();
myTreeRoot = new KCompTreeNode;
myBeep = true;
myIgnoreCase = false;
myHasMultipleMatches = false;
myRotationIndex = 0;
setOrder( Insertion );
}
KCompletion::~KCompletion()
{
delete d;
delete myTreeRoot;
}
void KCompletion::setOrder( CompOrder order )
{
myOrder = order;
d->matches.setSorting( order == Weighted );
}
void KCompletion::setIgnoreCase( bool ignoreCase )
{
myIgnoreCase = ignoreCase;
}
void KCompletion::setItems( const TQStringList& items )
{
clear();
insertItems( items );
}
void KCompletion::insertItems( const TQStringList& items )
{
bool weighted = (myOrder == Weighted);
TQStringList::ConstIterator it;
if ( weighted ) { // determine weight
for ( it = items.begin(); it != items.end(); ++it )
addWeightedItem( *it );
}
else {
for ( it = items.begin(); it != items.end(); ++it )
addItem( *it, 0 );
}
}
TQStringList KCompletion::items() const
{
KCompletionMatchesWrapper list; // unsorted
bool addWeight = (myOrder == Weighted);
extractStringsFromNode( myTreeRoot, TQString::null, &list, addWeight );
return list.list();
}
bool KCompletion::isEmpty() const
{
return (myTreeRoot->childrenCount() == 0);
}
void KCompletion::addItem( const TQString& item )
{
d->matches.clear();
myRotationIndex = 0;
myLastString = TQString::null;
addItem( item, 0 );
}
void KCompletion::addItem( const TQString& item, uint weight )
{
if ( item.isEmpty() )
return;
KCompTreeNode *node = myTreeRoot;
uint len = item.length();
bool sorted = (myOrder == Sorted);
bool weighted = ((myOrder == Weighted) && weight > 1);
// knowing the weight of an item, we simply add this weight to all of its
// nodes.
for ( uint i = 0; i < len; i++ ) {
node = node->insert( item.at(i), sorted );
if ( weighted )
node->confirm( weight -1 ); // node->insert() sets weighting to 1
}
// add 0x0-item as delimiter with evtl. weight
node = node->insert( 0x0, true );
if ( weighted )
node->confirm( weight -1 );
// qDebug("*** added: %s (%i)", item.latin1(), node->weight());
}
void KCompletion::addWeightedItem( const TQString& item )
{
if ( myOrder != Weighted ) {
addItem( item, 0 );
return;
}
uint len = item.length();
uint weight = 0;
// find out the weighting of this item (appended to the string as ":num")
int index = item.findRev(':');
if ( index > 0 ) {
bool ok;
weight = item.mid( index + 1 ).toUInt( &ok );
if ( !ok )
weight = 0;
len = index; // only insert until the ':'
}
addItem( item.left( len ), weight );
return;
}
void KCompletion::removeItem( const TQString& item )
{
d->matches.clear();
myRotationIndex = 0;
myLastString = TQString::null;
myTreeRoot->remove( item );
}
void KCompletion::clear()
{
d->matches.clear();
myRotationIndex = 0;
myLastString = TQString::null;
delete myTreeRoot;
myTreeRoot = new KCompTreeNode;
}
TQString KCompletion::makeCompletion( const TQString& string )
{
if ( myCompletionMode == KGlobalSettings::CompletionNone )
return TQString::null;
//kdDebug(0) << "KCompletion: completing: " << string << endl;
d->matches.clear();
myRotationIndex = 0;
myHasMultipleMatches = false;
myLastMatch = myCurrentMatch;
// in Shell-completion-mode, emit all matches when we get the same
// complete-string twice
if ( myCompletionMode == KGlobalSettings::CompletionShell &&
string == myLastString ) {
// Don't use d->matches since calling postProcessMatches()
// on d->matches here would interfere with call to
// postProcessMatch() during rotation
findAllCompletions( string, &d->matches, myHasMultipleMatches );
TQStringList l = d->matches.list();
postProcessMatches( &l );
emit matches( l );
if ( l.isEmpty() )
doBeep( NoMatch );
return TQString::null;
}
TQString completion;
// in case-insensitive popup mode, we search all completions at once
if ( myCompletionMode == KGlobalSettings::CompletionPopup ||
myCompletionMode == KGlobalSettings::CompletionPopupAuto ) {
findAllCompletions( string, &d->matches, myHasMultipleMatches );
if ( !d->matches.isEmpty() )
completion = d->matches.first();
}
else
completion = findCompletion( string );
if ( myHasMultipleMatches )
emit multipleMatches();
myLastString = string;
myCurrentMatch = completion;
postProcessMatch( &completion );
if ( !string.isEmpty() ) { // only emit match when string is not empty
//kdDebug(0) << "KCompletion: Match: " << completion << endl;
emit match( completion );
}
if ( completion.isNull() )
doBeep( NoMatch );
return completion;
}
TQStringList KCompletion::substringCompletion( const TQString& string ) const
{
// get all items in the tree, possibly in sorted order
bool sorted = (myOrder == Weighted);
KCompletionMatchesWrapper allItems( sorted );
extractStringsFromNode( myTreeRoot, TQString::null, &allItems, false );
TQStringList list = allItems.list();
// subStringMatches is invoked manually, via a shortcut, so we should
// beep here, if necessary.
if ( list.isEmpty() ) {
doBeep( NoMatch );
return list;
}
if ( string.isEmpty() ) { // shortcut
postProcessMatches( &list );
return list;
}
TQStringList matches;
TQStringList::ConstIterator it = list.begin();
for( ; it != list.end(); ++it ) {
TQString item = *it;
if ( item.find( string, 0, false ) != -1 ) { // always case insensitive
matches.append( item );
}
}
postProcessMatches( &matches );
if ( matches.isEmpty() )
doBeep( NoMatch );
return matches;
}
void KCompletion::setCompletionMode( KGlobalSettings::Completion mode )
{
myCompletionMode = mode;
}
TQStringList KCompletion::allMatches()
{
// Don't use d->matches since calling postProcessMatches()
// on d->matches here would interfere with call to
// postProcessMatch() during rotation
KCompletionMatchesWrapper matches( myOrder == Weighted );
bool dummy;
findAllCompletions( myLastString, &matches, dummy );
TQStringList l = matches.list();
postProcessMatches( &l );
return l;
}
KCompletionMatches KCompletion::allWeightedMatches()
{
// Don't use d->matches since calling postProcessMatches()
// on d->matches here would interfere with call to
// postProcessMatch() during rotation
KCompletionMatchesWrapper matches( myOrder == Weighted );
bool dummy;
findAllCompletions( myLastString, &matches, dummy );
KCompletionMatches ret( matches );
postProcessMatches( &ret );
return ret;
}
TQStringList KCompletion::allMatches( const TQString &string )
{
KCompletionMatchesWrapper matches( myOrder == Weighted );
bool dummy;
findAllCompletions( string, &matches, dummy );
TQStringList l = matches.list();
postProcessMatches( &l );
return l;
}
KCompletionMatches KCompletion::allWeightedMatches( const TQString &string )
{
KCompletionMatchesWrapper matches( myOrder == Weighted );
bool dummy;
findAllCompletions( string, &matches, dummy );
KCompletionMatches ret( matches );
postProcessMatches( &ret );
return ret;
}
/////////////////////////////////////////////////////
///////////////// tree operations ///////////////////
TQString KCompletion::nextMatch()
{
TQString completion;
myLastMatch = myCurrentMatch;
if ( d->matches.isEmpty() ) {
findAllCompletions( myLastString, &d->matches, myHasMultipleMatches );
completion = d->matches.first();
myCurrentMatch = completion;
myRotationIndex = 0;
postProcessMatch( &completion );
emit match( completion );
return completion;
}
TQStringList matches = d->matches.list();
myLastMatch = matches[ myRotationIndex++ ];
if ( myRotationIndex == matches.count() -1 )
doBeep( Rotation ); // indicate last matching item -> rotating
else if ( myRotationIndex == matches.count() )
myRotationIndex = 0;
completion = matches[ myRotationIndex ];
myCurrentMatch = completion;
postProcessMatch( &completion );
emit match( completion );
return completion;
}
TQString KCompletion::previousMatch()
{
TQString completion;
myLastMatch = myCurrentMatch;
if ( d->matches.isEmpty() ) {
findAllCompletions( myLastString, &d->matches, myHasMultipleMatches );
completion = d->matches.last();
myCurrentMatch = completion;
myRotationIndex = 0;
postProcessMatch( &completion );
emit match( completion );
return completion;
}
TQStringList matches = d->matches.list();
myLastMatch = matches[ myRotationIndex ];
if ( myRotationIndex == 1 )
doBeep( Rotation ); // indicate first item -> rotating
else if ( myRotationIndex == 0 )
myRotationIndex = matches.count();
myRotationIndex--;
completion = matches[ myRotationIndex ];
myCurrentMatch = completion;
postProcessMatch( &completion );
emit match( completion );
return completion;
}
// tries to complete "string" from the tree-root
TQString KCompletion::findCompletion( const TQString& string )
{
TQChar ch;
TQString completion;
const KCompTreeNode *node = myTreeRoot;
// start at the tree-root and try to find the search-string
for( uint i = 0; i < string.length(); i++ ) {
ch = string.at( i );
node = node->find( ch );
if ( node )
completion += ch;
else
return TQString::null; // no completion
}
// Now we have the last node of the to be completed string.
// Follow it as long as it has exactly one child (= longest possible
// completion)
while ( node->childrenCount() == 1 ) {
node = node->firstChild();
if ( !node->isNull() )
completion += *node;
}
// if multiple matches and auto-completion mode
// -> find the first complete match
if ( node && node->childrenCount() > 1 ) {
myHasMultipleMatches = true;
if ( myCompletionMode == KGlobalSettings::CompletionAuto ) {
myRotationIndex = 1;
if (myOrder != Weighted) {
while ( (node = node->firstChild()) ) {
if ( !node->isNull() )
completion += *node;
else
break;
}
}
else {
// don't just find the "first" match, but the one with the
// highest priority
const KCompTreeNode* temp_node = 0L;
while(1) {
int count = node->childrenCount();
temp_node = node->firstChild();
uint weight = temp_node->weight();
const KCompTreeNode* hit = temp_node;
for( int i = 1; i < count; i++ ) {
temp_node = node->childAt(i);
if( temp_node->weight() > weight ) {
hit = temp_node;
weight = hit->weight();
}
}
// 0x0 has the highest priority -> we have the best match
if ( hit->isNull() )
break;
node = hit;
completion += *node;
}
}
}
else
doBeep( PartialMatch ); // partial match -> beep
}
return completion;
}
void KCompletion::findAllCompletions(const TQString& string,
KCompletionMatchesWrapper *matches,
bool& hasMultipleMatches) const
{
//kdDebug(0) << "*** finding all completions for " << string << endl;
if ( string.isEmpty() )
return;
if ( myIgnoreCase ) { // case insensitive completion
extractStringsFromNodeCI( myTreeRoot, TQString::null, string, matches );
hasMultipleMatches = (matches->count() > 1);
return;
}
TQChar ch;
TQString completion;
const KCompTreeNode *node = myTreeRoot;
// start at the tree-root and try to find the search-string
for( uint i = 0; i < string.length(); i++ ) {
ch = string.at( i );
node = node->find( ch );
if ( node )
completion += ch;
else
return; // no completion -> return empty list
}
// Now we have the last node of the to be completed string.
// Follow it as long as it has exactly one child (= longest possible
// completion)
while ( node->childrenCount() == 1 ) {
node = node->firstChild();
if ( !node->isNull() )
completion += *node;
// kdDebug() << completion << node->latin1();
}
// there is just one single match)
if ( node->childrenCount() == 0 )
matches->append( node->weight(), completion );
else {
// node has more than one child
// -> recursively find all remaining completions
hasMultipleMatches = true;
extractStringsFromNode( node, completion, matches );
}
}
void KCompletion::extractStringsFromNode( const KCompTreeNode *node,
const TQString& beginning,
KCompletionMatchesWrapper *matches,
bool addWeight ) const
{
if ( !node || !matches )
return;
// kDebug() << "Beginning: " << beginning << endl;
const KCompTreeChildren *list = node->children();
TQString string;
TQString w;
// loop thru all children
for ( KCompTreeNode *cur = list->begin(); cur ; cur = cur->next) {
string = beginning;
node = cur;
if ( !node->isNull() )
string += *node;
while ( node && node->childrenCount() == 1 ) {
node = node->firstChild();
if ( node->isNull() )
break;
string += *node;
}
if ( node && node->isNull() ) { // we found a leaf
if ( addWeight ) {
// add ":num" to the string to store the weighting
string += ':';
w.setNum( node->weight() );
string.append( w );
}
matches->append( node->weight(), string );
}
// recursively find all other strings.
if ( node && node->childrenCount() > 1 )
extractStringsFromNode( node, string, matches, addWeight );
}
}
void KCompletion::extractStringsFromNodeCI( const KCompTreeNode *node,
const TQString& beginning,
const TQString& restString,
KCompletionMatchesWrapper *matches ) const
{
if ( restString.isEmpty() ) {
extractStringsFromNode( node, beginning, matches, false /*noweight*/ );
return;
}
TQChar ch1 = restString.at(0);
TQString newRest = restString.mid(1);
KCompTreeNode *child1, *child2;
child1 = node->find( ch1 ); // the correct match
if ( child1 )
extractStringsFromNodeCI( child1, beginning + *child1, newRest,
matches );
// append the case insensitive matches, if available
if ( ch1.isLetter() ) {
// find out if we have to lower or upper it. Is there a better way?
TQChar ch2 = ch1.lower();
if ( ch1 == ch2 )
ch2 = ch1.upper();
if ( ch1 != ch2 ) {
child2 = node->find( ch2 );
if ( child2 )
extractStringsFromNodeCI( child2, beginning + *child2, newRest,
matches );
}
}
}
void KCompletion::doBeep( BeepMode mode ) const
{
if ( !myBeep )
return;
TQString text, event;
switch ( mode ) {
case Rotation:
event = TQString::fromLatin1("Textcompletion: rotation");
text = i18n("You reached the end of the list\nof matching items.\n");
break;
case PartialMatch:
if ( myCompletionMode == KGlobalSettings::CompletionShell ||
myCompletionMode == KGlobalSettings::CompletionMan ) {
event = TQString::fromLatin1("Textcompletion: partial match");
text = i18n("The completion is ambiguous, more than one\nmatch is available.\n");
}
break;
case NoMatch:
if ( myCompletionMode == KGlobalSettings::CompletionShell ) {
event = TQString::fromLatin1("Textcompletion: no match");
text = i18n("There is no matching item available.\n");
}
break;
}
if ( !text.isEmpty() )
KNotifyClient::event( event, text );
}
/////////////////////////////////
/////////
// Implements the tree. Every node is a TQChar and has a list of children, which
// are Nodes as well.
// TQChar( 0x0 ) is used as the delimiter of a string; the last child of each
// inserted string is 0x0.
KCompTreeNode::~KCompTreeNode()
{
// delete all children
KCompTreeNode *cur = myChildren.begin();
while (cur) {
KCompTreeNode * next = cur->next;
delete myChildren.remove(cur);
cur = next;
}
}
// Adds a child-node "ch" to this node. If such a node is already existant,
// it will not be created. Returns the new/existing node.
KCompTreeNode * KCompTreeNode::insert( const TQChar& ch, bool sorted )
{
KCompTreeNode *child = find( ch );
if ( !child ) {
child = new KCompTreeNode( ch );
// FIXME, first (slow) sorted insertion implementation
if ( sorted ) {
KCompTreeNode * prev = 0;
KCompTreeNode * cur = myChildren.begin();
while ( cur ) {
if ( ch > *cur ) {
prev = cur;
cur = cur->next;
} else
break;
}
if (prev)
myChildren.insert( prev, child );
else
myChildren.prepend(child);
}
else
myChildren.append( child );
}
// implicit weighting: the more often an item is inserted, the higher
// priority it gets.
child->confirm();
return child;
}
// Iteratively removes a string from the tree. The nicer recursive
// version apparently was a little memory hungry (see #56757)
void KCompTreeNode::remove( const TQString& str )
{
TQString string = str;
string += TQChar(0x0);
TQPtrVector<KCompTreeNode> deletables( string.length() + 1 );
KCompTreeNode *child = 0L;
KCompTreeNode *parent = this;
deletables.insert( 0, parent );
uint i = 0;
for ( ; i < string.length(); i++ )
{
child = parent->find( string.at( i ) );
if ( child )
deletables.insert( i + 1, child );
else
break;
parent = child;
}
for ( ; i >= 1; i-- )
{
parent = deletables.at( i - 1 );
child = deletables.at( i );
if ( child->myChildren.count() == 0 )
delete parent->myChildren.remove( child );
}
}
TQStringList KCompletionMatchesWrapper::list() const
{
if ( sortedList && dirty ) {
sortedList->sort();
dirty = false;
stringList.clear();
// high weight == sorted last -> reverse the sorting here
TQValueListConstIterator<KSortableItem<TQString> > it;
for ( it = sortedList->begin(); it != sortedList->end(); ++it )
stringList.prepend( (*it).value() );
}
return stringList;
}
KCompletionMatches::KCompletionMatches( bool sort_P )
: _sorting( sort_P )
{
}
KCompletionMatches::KCompletionMatches( const KCompletionMatchesWrapper& matches )
: _sorting( matches.sorting())
{
if( matches.sortedList != 0L )
KCompletionMatchesList::operator=( *matches.sortedList );
else {
TQStringList l = matches.list();
for( TQStringList::ConstIterator it = l.begin();
it != l.end();
++it )
prepend( KSortableItem<TQString, int>( 1, *it ) );
}
}
KCompletionMatches::~KCompletionMatches()
{
}
TQStringList KCompletionMatches::list( bool sort_P ) const
{
if( _sorting && sort_P )
const_cast< KCompletionMatches* >( this )->sort();
TQStringList stringList;
// high weight == sorted last -> reverse the sorting here
for ( ConstIterator it = begin(); it != end(); ++it )
stringList.prepend( (*it).value() );
return stringList;
}
void KCompletionMatches::removeDuplicates()
{
Iterator it1, it2;
for ( it1 = begin(); it1 != end(); ++it1 ) {
for ( (it2 = it1), ++it2; it2 != end();) {
if( (*it1).value() == (*it2).value()) {
// use the max height
(*it1).first = kMax( (*it1).index(), (*it2).index());
it2 = remove( it2 );
continue;
}
++it2;
}
}
}
void KCompTreeNodeList::append(KCompTreeNode *item)
{
m_count++;
if (!last) {
last = item;
last->next = 0;
first = item;
return;
}
last->next = item;
item->next = 0;
last = item;
}
void KCompTreeNodeList::prepend(KCompTreeNode *item)
{
m_count++;
if (!last) {
last = item;
last->next = 0;
first = item;
return;
}
item->next = first;
first = item;
}
void KCompTreeNodeList::insert(KCompTreeNode *after, KCompTreeNode *item)
{
if (!after) {
append(item);
return;
}
m_count++;
item->next = after->next;
after->next = item;
if (after == last)
last = item;
}
KCompTreeNode *KCompTreeNodeList::remove(KCompTreeNode *item)
{
if (!first || !item)
return 0;
KCompTreeNode *cur = 0;
if (item == first)
first = first->next;
else {
cur = first;
while (cur && cur->next != item) cur = cur->next;
if (!cur)
return 0;
cur->next = item->next;
}
if (item == last)
last = cur;
m_count--;
return item;
}
KCompTreeNode *KCompTreeNodeList::at(uint index) const
{
KCompTreeNode *cur = first;
while (index-- && cur) cur = cur->next;
return cur;
}
KZoneAllocator KCompTreeNode::alloc(8192);
void KCompletion::virtual_hook( int, void* )
{ /*BASE::virtual_hook( id, data );*/ }
void KCompletionBase::virtual_hook( int, void* )
{ /*BASE::virtual_hook( id, data );*/ }
#include "kcompletion.moc"