You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
tqt3/src/kernel/qfont.cpp

3357 lines
92 KiB

/****************************************************************************
**
** Implementation of TQFont, TQFontMetrics and TQFontInfo classes
**
** Created : 941207
**
** Copyright (C) 1992-2008 Trolltech ASA. All rights reserved.
**
** This file is part of the kernel module of the TQt GUI Toolkit.
**
** This file may be used under the terms of the GNU General
** Public License versions 2.0 or 3.0 as published by the Free
** Software Foundation and appearing in the files LICENSE.GPL2
** and LICENSE.GPL3 included in the packaging of this file.
** Alternatively you may (at your option) use any later version
** of the GNU General Public License if such license has been
** publicly approved by Trolltech ASA (or its successors, if any)
** and the KDE Free TQt Foundation.
**
** Please review the following information to ensure GNU General
** Public Licensing requirements will be met:
** http://trolltech.com/products/qt/licenses/licensing/opensource/.
** If you are unsure which license is appropriate for your use, please
** review the following information:
** http://trolltech.com/products/qt/licenses/licensing/licensingoverview
** or contact the sales department at sales@trolltech.com.
**
** This file may be used under the terms of the Q Public License as
** defined by Trolltech ASA and appearing in the file LICENSE.TQPL
** included in the packaging of this file. Licensees holding valid TQt
** Commercial licenses may use this file in accordance with the TQt
** Commercial License Agreement provided with the Software.
**
** This file is provided "AS IS" with NO WARRANTY OF ANY KIND,
** INCLUDING THE WARRANTIES OF DESIGN, MERCHANTABILITY AND FITNESS FOR
** A PARTICULAR PURPOSE. Trolltech reserves all rights not granted
** herein.
**
**********************************************************************/
#define QT_FATAL_ASSERT
#include "ntqfont.h"
#include "ntqfontdatabase.h"
#include "ntqfontmetrics.h"
#include "ntqfontinfo.h"
#include "ntqpainter.h"
#include "ntqdict.h"
#include "ntqcache.h"
#include "ntqdatastream.h"
#include "ntqapplication.h"
#include "ntqcleanuphandler.h"
#include "ntqstringlist.h"
#ifdef Q_WS_MAC
#include "ntqpaintdevicemetrics.h"
#endif
#include <private/qunicodetables_p.h>
#include "qfontdata_p.h"
#include "qfontengine_p.h"
#include "qpainter_p.h"
#include "qtextengine_p.h"
// #define TQFONTCACHE_DEBUG
#ifdef TQFONTCACHE_DEBUG
# define FC_DEBUG tqDebug
#else
# define FC_DEBUG if (FALSE) tqDebug
#endif
bool TQFontDef::operator==( const TQFontDef &other ) const
{
/*
TQFontDef comparison is more complicated than just simple
per-member comparisons.
When comparing point/pixel sizes, either point or pixelsize
could be -1. in This case we have to compare the non negative
size value.
This test will fail if the point-sizes differ by 1/2 point or
more or they do not round to the same value. We have to do this
since our API still uses 'int' point-sizes in the API, but store
deci-point-sizes internally.
To compare the family members, we need to parse the font names
and compare the family/foundry strings separately. This allows
us to compare e.g. "Helvetica" and "Helvetica [Adobe]" with
positive results.
*/
if (pixelSize != -1 && other.pixelSize != -1) {
if (pixelSize != other.pixelSize)
return FALSE;
} else if (pointSize != -1 && other.pointSize != -1) {
if (pointSize != other.pointSize
&& (TQABS(pointSize - other.pointSize) >= 5
|| tqRound(pointSize/10.) != tqRound(other.pointSize/10.)))
return FALSE;
} else {
return FALSE;
}
if (!ignorePitch && !other.ignorePitch && fixedPitch != other.fixedPitch)
return FALSE;
if (stretch != 0 && other.stretch != 0 && stretch != other.stretch)
return FALSE;
TQString this_family, this_foundry, other_family, other_foundry;
TQFontDatabase::parseFontName(family, this_foundry, this_family);
TQFontDatabase::parseFontName(other.family, other_foundry, other_family);
return ( styleHint == other.styleHint
&& styleStrategy == other.styleStrategy
&& weight == other.weight
&& italic == other.italic
&& this_family == other_family
&& (this_foundry.isEmpty()
|| other_foundry.isEmpty()
|| this_foundry == other_foundry)
#ifdef Q_WS_X11
&& addStyle == other.addStyle
#endif // Q_WS_X11
);
}
TQFontPrivate::TQFontPrivate()
: engineData( 0 ), paintdevice( 0 ),
rawMode( FALSE ), underline( FALSE ), overline( FALSE ), strikeOut( FALSE ),
mask( 0 )
{
#ifdef Q_WS_X11
screen = TQPaintDevice::x11AppScreen();
#else
screen = 0;
#endif // Q_WS_X11
}
TQFontPrivate::TQFontPrivate( const TQFontPrivate &other )
: TQShared(), request( other.request ), engineData( 0 ),
paintdevice( other.paintdevice ), screen( other.screen ),
rawMode( other.rawMode ), underline( other.underline ), overline( other.overline ),
strikeOut( other.strikeOut ), mask( other.mask )
{
}
TQFontPrivate::~TQFontPrivate()
{
if ( engineData )
engineData->deref();
engineData = 0;
}
void TQFontPrivate::resolve( const TQFontPrivate *other )
{
#ifdef QT_CHECK_STATE
Q_ASSERT( other != 0 );
#endif
if ( ( mask & Complete ) == Complete ) return;
// assign the unset-bits with the set-bits of the other font def
if ( ! ( mask & Family ) )
request.family = other->request.family;
if ( ! ( mask & Size ) ) {
request.pointSize = other->request.pointSize;
request.pixelSize = other->request.pixelSize;
}
if ( ! ( mask & StyleHint ) )
request.styleHint = other->request.styleHint;
if ( ! ( mask & StyleStrategy ) )
request.styleStrategy = other->request.styleStrategy;
if ( ! ( mask & Weight ) )
request.weight = other->request.weight;
if ( ! ( mask & Italic ) )
request.italic = other->request.italic;
if ( ! ( mask & FixedPitch ) )
request.fixedPitch = other->request.fixedPitch;
if ( ! ( mask & Stretch ) )
request.stretch = other->request.stretch;
if ( ! ( mask & Underline ) )
underline = other->underline;
if ( ! ( mask & Overline ) )
overline = other->overline;
if ( ! ( mask & StrikeOut ) )
strikeOut = other->strikeOut;
}
TQFontEngineData::TQFontEngineData()
: lineWidth( 1 )
{
#if defined(Q_WS_X11) || defined(Q_WS_WIN)
memset( engines, 0, TQFont::LastPrivateScript * sizeof( TQFontEngine * ) );
#else
engine = 0;
#endif // Q_WS_X11 || Q_WS_WIN
#ifndef Q_WS_MAC
memset( widthCache, 0, widthCacheSize*sizeof( uchar ) );
#endif
}
TQFontEngineData::~TQFontEngineData()
{
#if defined(Q_WS_X11) || defined(Q_WS_WIN)
for ( int i = 0; i < TQFont::LastPrivateScript; i++ ) {
if ( engines[i] )
engines[i]->deref();
engines[i] = 0;
}
#else
if ( engine )
engine->deref();
engine = 0;
#endif // Q_WS_X11 || Q_WS_WIN
}
/*!
\class TQFont ntqfont.h
\brief The TQFont class specifies a font used for drawing text.
\ingroup graphics
\ingroup appearance
\ingroup shared
\mainclass
When you create a TQFont object you specify various attributes that
you want the font to have. TQt will use the font with the specified
attributes, or if no matching font exists, TQt will use the closest
matching installed font. The attributes of the font that is
actually used are retrievable from a TQFontInfo object. If the
window system provides an exact match exactMatch() returns TRUE.
Use TQFontMetrics to get measurements, e.g. the pixel length of a
string using TQFontMetrics::width().
Use TQApplication::setFont() to set the application's default font.
If a choosen X11 font does not include all the characters that
need to be displayed, TQFont will try to find the characters in the
nearest equivalent fonts. When a TQPainter draws a character from a
font the TQFont will report whether or not it has the character; if
it does not, TQPainter will draw an unfilled square.
Create TQFonts like this:
\code
TQFont serifFont( "Times", 10, Bold );
TQFont sansFont( "Helvetica [Cronyx]", 12 );
\endcode
The attributes set in the constructor can also be set later, e.g.
setFamily(), setPointSize(), setPointSizeFloat(), setWeight() and
setItalic(). The remaining attributes must be set after
contstruction, e.g. setBold(), setUnderline(), setOverline(),
setStrikeOut() and setFixedPitch(). TQFontInfo objects should be
created \e after the font's attributes have been set. A TQFontInfo
object will not change, even if you change the font's
attributes. The corresponding "get" functions, e.g. family(),
pointSize(), etc., return the values that were set, even though
the values used may differ. The actual values are available from a
TQFontInfo object.
If the requested font family is unavailable you can influence the
\link #fontmatching font matching algorithm\endlink by choosing a
particular \l{TQFont::StyleHint} and \l{TQFont::StyleStrategy} with
setStyleHint(). The default family (corresponding to the current
style hint) is returned by defaultFamily().
The font-matching algorithm has a lastResortFamily() and
lastResortFont() in cases where a suitable match cannot be found.
You can provide substitutions for font family names using
insertSubstitution() and insertSubstitutions(). Substitutions can
be removed with removeSubstitution(). Use substitute() to retrieve
a family's first substitute, or the family name itself if it has
no substitutes. Use substitutes() to retrieve a list of a family's
substitutes (which may be empty).
Every TQFont has a key() which you can use, for example, as the key
in a cache or dictionary. If you want to store a user's font
preferences you could use TQSettings, writing the font information
with toString() and reading it back with fromString(). The
operator<<() and operator>>() functions are also available, but
they work on a data stream.
It is possible to set the height of characters shown on the screen
to a specified number of pixels with setPixelSize(); however using
setPointSize() has a similar effect and provides device
independence.
Under the X Window System you can set a font using its system
specific name with setRawName().
Loading fonts can be expensive, especially on X11. TQFont contains
extensive optimizations to make the copying of TQFont objects fast,
and to cache the results of the slow window system functions it
depends upon.
\target fontmatching
The font matching algorithm works as follows:
\list 1
\i The specified font family is searched for.
\i If not found, the styleHint() is used to select a replacement
family.
\i Each replacement font family is searched for.
\i If none of these are found or there was no styleHint(), "helvetica"
will be searched for.
\i If "helvetica" isn't found TQt will try the lastResortFamily().
\i If the lastResortFamily() isn't found TQt will try the
lastResortFont() which will always return a name of some kind.
\endlist
Once a font is found, the remaining attributes are matched in order of
priority:
\list 1
\i fixedPitch()
\i pointSize() (see below)
\i weight()
\i italic()
\endlist
If you have a font which matches on family, even if none of the
other attributes match, this font will be chosen in preference to
a font which doesn't match on family but which does match on the
other attributes. This is because font family is the dominant
search criteria.
The point size is defined to match if it is within 20% of the
requested point size. When several fonts match and are only
distinguished by point size, the font with the closest point size
to the one requested will be chosen.
The actual family, font size, weight and other font attributes
used for drawing text will depend on what's available for the
chosen family under the window system. A TQFontInfo object can be
used to determine the actual values used for drawing the text.
Examples:
\code
TQFont f("Helvetica");
\endcode
If you had both an Adobe and a Cronyx Helvetica, you might get
either.
\code
TQFont f1( "Helvetica [Cronyx]" ); // TQt 3.x
TQFont f2( "Cronyx-Helvetica" ); // TQt 2.x compatibility
\endcode
You can specify the foundry you want in the family name. Both fonts,
f1 and f2, in the above example will be set to "Helvetica
[Cronyx]".
To determine the attributes of the font actually used in the window
system, use a TQFontInfo object, e.g.
\code
TQFontInfo info( f1 );
TQString family = info.family();
\endcode
To find out font metrics use a TQFontMetrics object, e.g.
\code
TQFontMetrics fm( f1 );
int pixelWidth = fm.width( "How many pixels wide is this text?" );
int pixelHeight = fm.height();
\endcode
For more general information on fonts, see the
\link http://www.nwalsh.com/comp.fonts/FAQ/ comp.fonts FAQ.\endlink
Information on encodings can be found from
\link http://czyborra.com/ Roman Czyborra's\endlink page.
\sa TQFontMetrics TQFontInfo TQFontDatabase TQApplication::setFont()
TQWidget::setFont() TQPainter::setFont() TQFont::StyleHint
TQFont::Weight
*/
/*!
\enum TQFont::Script
This enum represents \link unicode.html Unicode \endlink allocated
scripts. For exhaustive coverage see \link
http://www.amazon.com/exec/obidos/ASIN/0201616335/trolltech/t The
Unicode Standard Version 3.0 \endlink. The following scripts are
supported:
Modern European alphabetic scripts (left to right):
\value Latin consists of most alphabets based on the original Latin alphabet.
\value Greek covers ancient and modern Greek and Coptic.
\value Cyrillic covers the Slavic and non-Slavic languages using
cyrillic alphabets.
\value Armenian contains the Armenian alphabet used with the
Armenian language.
\value Georgian covers at least the language Georgian.
\value Runic covers the known constituents of the Runic alphabets used
by the early and medieval societies in the Germanic,
Scandinavian, and Anglo-Saxon areas.
\value Ogham is an alphabetical script used to write a very early
form of Irish.
\value SpacingModifiers are small signs indicating modifications
to the preceeding letter.
\value CombiningMarks consist of diacritical marks not specific to
a particular alphabet, diacritical marks used in
combination with mathematical and technical symbols, and
glyph encodings applied to multiple letterforms.
Middle Eastern scripts (right to left):
\value Hebrew is used for writing Hebrew, Yiddish, and some other languages.
\value Arabic covers the Arabic language as well as Persian, Urdu,
Kurdish and some others.
\value Syriac is used to write the active liturgical languages and
dialects of several Middle Eastern and Southeast Indian
communities.
\value Thaana is used to write the Maledivian Dhivehi language.
South and Southeast Asian scripts (left to right with few historical exceptions):
\value Devanagari covers classical Sanskrit and modern Hindi as
well as several other languages.
\value Bengali is a relative to Devanagari employed to write the
Bengali language used in West Bengal/India and Bangladesh
as well as several minority languages.
\value Gurmukhi is another Devanagari relative used to write Punjabi.
\value Gujarati is closely related to Devanagari and used to write
the Gujarati language of the Gujarat state in India.
\value Oriya is used to write the Oriya language of Orissa state/India.
\value Tamil is used to write the Tamil language of Tamil Nadu state/India,
Sri Lanka, Singapore and parts of Malaysia as well as some
minority languages.
\value Telugu is used to write the Telugu language of Andhra
Pradesh state/India and some minority languages.
\value Kannada is another South Indian script used to write the
Kannada language of Karnataka state/India and some minority
languages.
\value Malayalam is used to write the Malayalam language of Kerala
state/India.
\value Sinhala is used for Sri Lanka's majority language Sinhala
and is also employed to write Pali, Sanskrit, and Tamil.
\value Thai is used to write Thai and other Southeast Asian languages.
\value Lao is a language and script quite similar to Thai.
\value Tibetan is the script used to write Tibetan in several
countries like Tibet, the bordering Indian regions and
Nepal. It is also used in the Buddist philosophy and
liturgy of the Mongolian cultural area.
\value Myanmar is mainly used to write the Burmese language of
Myanmar (former Burma).
\value Khmer is the official language of Kampuchea.
East Asian scripts (traditionally top-down, right to left, modern
often horizontal left to right):
\value Han consists of the CJK (Chinese, Japanese, Korean)
idiographic characters.
\value Hiragana is a cursive syllabary used to indicate phonetics
and pronounciation of Japanese words.
\value Katakana is a non-cursive syllabic script used to write
Japanese words with visual emphasis and non-Japanese words
in a phonetical manner.
\value Hangul is a Korean script consisting of alphabetic components.
\value Bopomofo is a phonetic alphabet for Chinese (mainly Mandarin).
\value Yi (also called Cuan or Wei) is a syllabary used to write
the Yi language of Southwestern China, Myanmar, Laos, and Vietnam.
Additional scripts that do not fit well into the script categories above:
\value Ethiopic is a syllabary used by several Central East African languages.
\value Cherokee is a left-to-right syllabic script used to write
the Cherokee language.
\value CanadianAboriginal consists of the syllabics used by some
Canadian aboriginal societies.
\value Mongolian is the traditional (and recently reintroduced)
script used to write Mongolian.
Symbols:
\value CurrencySymbols contains currency symbols not encoded in other scripts.
\value LetterlikeSymbols consists of symbols derived from
ordinary letters of an alphabetical script.
\value NumberForms are provided for compatibility with other
existing character sets.
\value MathematicalOperators consists of encodings for operators,
relations and other symbols like arrows used in a mathematical context.
\value TechnicalSymbols contains representations for control
codes, the space symbol, APL symbols and other symbols
mainly used in the context of electronic data processing.
\value GeometricSymbols covers block elements and geometric shapes.
\value MiscellaneousSymbols consists of a heterogeneous collection
of symbols that do not fit any other Unicode character
block, e.g. Dingbats.
\value EnclosedAndSquare is provided for compatibility with some
East Asian standards.
\value Braille is an international writing system used by blind
people. This script encodes the 256 eight-dot patterns with
the 64 six-dot patterns as a subset.
\value Tagalog
\value Hanunoo
\value Buhid
\value Tagbanwa
\value KatakanaHalfWidth
\value Limbu (Unicode 4.0)
\value TaiLe (Unicode 4.0)
\value Unicode includes all the above scripts.
*/
/*! \internal
Constructs a font for use on the paint device \a pd using the
specified font \a data.
*/
TQFont::TQFont( TQFontPrivate *data, TQPaintDevice *pd )
{
d = new TQFontPrivate( *data );
TQ_CHECK_PTR( d );
d->paintdevice = pd;
// now a single reference
d->count = 1;
}
/*! \internal
Detaches the font object from common font data.
*/
void TQFont::detach()
{
if (d->count == 1) {
if ( d->engineData )
d->engineData->deref();
d->engineData = 0;
return;
}
TQFontPrivate *old_d = d;
d = new TQFontPrivate( *old_d );
/*
if this font is a copy of the application default font, set the
fontdef mask to zero to indicate that *nothing* has been
explicitly set by the programmer.
*/
const TQFont appfont = TQApplication::font();
if ( old_d == appfont.d )
d->mask = 0;
if ( old_d->deref() )
delete old_d;
}
/*!
Constructs a font object that uses the application's default font.
\sa TQApplication::setFont(), TQApplication::font()
*/
TQFont::TQFont()
{
const TQFont appfont = TQApplication::font();
d = appfont.d;
d->ref();
}
/*!
Constructs a font object with the specified \a family, \a
pointSize, \a weight and \a italic settings.
If \a pointSize is <= 0 it is set to 1.
The \a family name may optionally also include a foundry name,
e.g. "Helvetica [Cronyx]". (The TQt 2.x syntax, i.e.
"Cronyx-Helvetica", is also supported.) If the \a family is
available from more than one foundry and the foundry isn't
specified, an arbitrary foundry is chosen. If the family isn't
available a family will be set using the \link #fontmatching font
matching\endlink algorithm.
\sa Weight, setFamily(), setPointSize(), setWeight(), setItalic(),
setStyleHint() TQApplication::font()
*/
TQFont::TQFont( const TQString &family, int pointSize, int weight, bool italic )
{
d = new TQFontPrivate;
TQ_CHECK_PTR( d );
d->mask = TQFontPrivate::Family;
if (pointSize <= 0) {
pointSize = 12;
} else {
d->mask |= TQFontPrivate::Size;
}
if (weight < 0) {
weight = Normal;
} else {
d->mask |= TQFontPrivate::Weight | TQFontPrivate::Italic;
}
d->request.family = family;
d->request.pointSize = pointSize * 10;
d->request.pixelSize = -1;
d->request.weight = weight;
d->request.italic = italic;
}
/*!
Constructs a font that is a copy of \a font.
*/
TQFont::TQFont( const TQFont &font )
{
d = font.d;
d->ref();
}
/*!
Destroys the font object and frees all allocated resources.
*/
TQFont::~TQFont()
{
if ( d->deref() )
delete d;
d = 0;
}
/*!
Assigns \a font to this font and returns a reference to it.
*/
TQFont &TQFont::operator=( const TQFont &font )
{
if ( font.d != d ) {
if ( d->deref() )
delete d;
d = font.d;
d->ref();
}
return *this;
}
/*!
Returns the requested font family name, i.e. the name set in the
constructor or the last setFont() call.
\sa setFamily() substitutes() substitute()
*/
TQString TQFont::family() const
{
return d->request.family;
}
/*!
Sets the family name of the font. The name is case insensitive and
may include a foundry name.
The \a family name may optionally also include a foundry name,
e.g. "Helvetica [Cronyx]". (The TQt 2.x syntax, i.e.
"Cronyx-Helvetica", is also supported.) If the \a family is
available from more than one foundry and the foundry isn't
specified, an arbitrary foundry is chosen. If the family isn't
available a family will be set using the \link #fontmatching font
matching\endlink algorithm.
\sa family(), setStyleHint(), TQFontInfo
*/
void TQFont::setFamily( const TQString &family )
{
detach();
d->request.family = family;
#if defined(Q_WS_X11)
d->request.addStyle = TQString::null;
#endif // Q_WS_X11
d->mask |= TQFontPrivate::Family;
}
/*!
Returns the point size in 1/10ths of a point.
The returned value will be -1 if the font size has been specified
in pixels.
\sa pointSize() pointSizeFloat()
*/
int TQFont::deciPointSize() const
{
return d->request.pointSize;
}
/*!
Returns the point size of the font. Returns -1 if the font size
was specified in pixels.
\sa setPointSize() deciPointSize() pointSizeFloat()
*/
int TQFont::pointSize() const
{
return d->request.pointSize == -1 ? -1 : (d->request.pointSize + 5) / 10;
}
/*!
Sets the point size to \a pointSize. The point size must be
greater than zero.
\sa pointSize() setPointSizeFloat()
*/
void TQFont::setPointSize( int pointSize )
{
if ( pointSize <= 0 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQFont::setPointSize: Point size <= 0 (%d)", pointSize );
#endif
return;
}
detach();
d->request.pointSize = pointSize * 10;
d->request.pixelSize = -1;
d->mask |= TQFontPrivate::Size;
}
/*!
Sets the point size to \a pointSize. The point size must be
greater than zero. The requested precision may not be achieved on
all platforms.
\sa pointSizeFloat() setPointSize() setPixelSize()
*/
void TQFont::setPointSizeFloat( float pointSize )
{
if ( pointSize <= 0.0 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQFont::setPointSize: Point size <= 0 (%f)", pointSize );
#endif
return;
}
detach();
d->request.pointSize = tqRound(pointSize * 10.0);
d->request.pixelSize = -1;
d->mask |= TQFontPrivate::Size;
}
/*!
Returns the point size of the font. Returns -1 if the font size was
specified in pixels.
\sa pointSize() setPointSizeFloat() pixelSize() TQFontInfo::pointSize() TQFontInfo::pixelSize()
*/
float TQFont::pointSizeFloat() const
{
return float( d->request.pointSize == -1 ? -10 : d->request.pointSize ) / 10.0;
}
/*!
Sets the font size to \a pixelSize pixels.
Using this function makes the font device dependent. Use
setPointSize() or setPointSizeFloat() to set the size of the font
in a device independent manner.
\sa pixelSize()
*/
void TQFont::setPixelSize( int pixelSize )
{
if ( pixelSize <= 0 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQFont::setPixelSize: Pixel size <= 0 (%d)", pixelSize );
#endif
return;
}
detach();
d->request.pixelSize = pixelSize;
d->request.pointSize = -1;
d->mask |= TQFontPrivate::Size;
}
/*!
Returns the pixel size of the font if it was set with
setPixelSize(). Returns -1 if the size was set with setPointSize()
or setPointSizeFloat().
\sa setPixelSize() pointSize() TQFontInfo::pointSize() TQFontInfo::pixelSize()
*/
int TQFont::pixelSize() const
{
return d->request.pixelSize;
}
/*! \obsolete
Sets the logical pixel height of font characters when shown on
the screen to \a pixelSize.
*/
void TQFont::setPixelSizeFloat( float pixelSize )
{
setPixelSize( (int)pixelSize );
}
/*!
Returns TRUE if italic has been set; otherwise returns FALSE.
\sa setItalic()
*/
bool TQFont::italic() const
{
return d->request.italic;
}
/*!
If \a enable is TRUE, italic is set on; otherwise italic is set
off.
\sa italic(), TQFontInfo
*/
void TQFont::setItalic( bool enable )
{
detach();
d->request.italic = enable;
d->mask |= TQFontPrivate::Italic;
}
/*!
Returns the weight of the font which is one of the enumerated
values from \l{TQFont::Weight}.
\sa setWeight(), Weight, TQFontInfo
*/
int TQFont::weight() const
{
return d->request.weight;
}
/*!
\enum TQFont::Weight
TQt uses a weighting scale from 0 to 99 similar to, but not the
same as, the scales used in Windows or CSS. A weight of 0 is
ultralight, whilst 99 will be an extremely black.
This enum contains the predefined font weights:
\value Light 25
\value Normal 50
\value DemiBold 63
\value Bold 75
\value Black 87
*/
/*!
Sets the weight the font to \a weight, which should be a value
from the \l TQFont::Weight enumeration.
\sa weight(), TQFontInfo
*/
void TQFont::setWeight( int weight )
{
if ( weight < 0 || weight > 99 ) {
#if defined(QT_CHECK_RANGE)
tqWarning( "TQFont::setWeight: Value out of range (%d)", weight );
#endif
return;
}
detach();
d->request.weight = weight;
d->mask |= TQFontPrivate::Weight;
}
/*!
\fn bool TQFont::bold() const
Returns TRUE if weight() is a value greater than \link Weight
TQFont::Normal \endlink; otherwise returns FALSE.
\sa weight(), setBold(), TQFontInfo::bold()
*/
/*!
\fn void TQFont::setBold( bool enable )
If \a enable is true sets the font's weight to \link Weight
TQFont::Bold \endlink; otherwise sets the weight to \link Weight
TQFont::Normal\endlink.
For finer boldness control use setWeight().
\sa bold(), setWeight()
*/
/*!
Returns TRUE if underline has been set; otherwise returns FALSE.
\sa setUnderline()
*/
bool TQFont::underline() const
{
return d->underline;
}
/*!
If \a enable is TRUE, sets underline on; otherwise sets underline
off.
\sa underline(), TQFontInfo
*/
void TQFont::setUnderline( bool enable )
{
detach();
d->underline = enable;
d->mask |= TQFontPrivate::Underline;
}
/*!
Returns TRUE if overline has been set; otherwise returns FALSE.
\sa setOverline()
*/
bool TQFont::overline() const
{
return d->overline;
}
/*!
If \a enable is TRUE, sets overline on; otherwise sets overline off.
\sa overline(), TQFontInfo
*/
void TQFont::setOverline( bool enable )
{
detach();
d->overline = enable;
d->mask |= TQFontPrivate::Overline;
}
/*!
Returns TRUE if strikeout has been set; otherwise returns FALSE.
\sa setStrikeOut()
*/
bool TQFont::strikeOut() const
{
return d->strikeOut;
}
/*!
If \a enable is TRUE, sets strikeout on; otherwise sets strikeout
off.
\sa strikeOut(), TQFontInfo
*/
void TQFont::setStrikeOut( bool enable )
{
detach();
d->strikeOut = enable;
d->mask |= TQFontPrivate::StrikeOut;
}
/*!
Returns TRUE if fixed pitch has been set; otherwise returns FALSE.
\sa setFixedPitch(), TQFontInfo::fixedPitch()
*/
bool TQFont::fixedPitch() const
{
return d->request.fixedPitch;
}
/*!
If \a enable is TRUE, sets fixed pitch on; otherwise sets fixed
pitch off.
\sa fixedPitch(), TQFontInfo
*/
void TQFont::setFixedPitch( bool enable )
{
detach();
d->request.fixedPitch = enable;
d->request.ignorePitch = FALSE;
d->mask |= TQFontPrivate::FixedPitch;
}
/*!
Returns the StyleStrategy.
The style strategy affects the \link #fontmatching font
matching\endlink algorithm. See \l TQFont::StyleStrategy for the
list of strategies.
\sa setStyleHint() TQFont::StyleHint
*/
TQFont::StyleStrategy TQFont::styleStrategy() const
{
return (StyleStrategy) d->request.styleStrategy;
}
/*!
Returns the StyleHint.
The style hint affects the \link #fontmatching font
matching\endlink algorithm. See \l TQFont::StyleHint for the list
of strategies.
\sa setStyleHint(), TQFont::StyleStrategy TQFontInfo::styleHint()
*/
TQFont::StyleHint TQFont::styleHint() const
{
return (StyleHint) d->request.styleHint;
}
/*!
\enum TQFont::StyleHint
Style hints are used by the \link #fontmatching font
matching\endlink algorithm to find an appropriate default family
if a selected font family is not available.
\value AnyStyle leaves the font matching algorithm to choose the
family. This is the default.
\value SansSerif the font matcher prefer sans serif fonts.
\value Helvetica is a synonym for \c SansSerif.
\value Serif the font matcher prefers serif fonts.
\value Times is a synonym for \c Serif.
\value TypeWriter the font matcher prefers fixed pitch fonts.
\value Courier a synonym for \c TypeWriter.
\value OldEnglish the font matcher prefers decorative fonts.
\value Decorative is a synonym for \c OldEnglish.
\value System the font matcher prefers system fonts.
*/
/*!
\enum TQFont::StyleStrategy
The style strategy tells the \link #fontmatching font
matching\endlink algorithm what type of fonts should be used to
find an appropriate default family.
The following strategies are available:
\value PreferDefault the default style strategy. It does not prefer
any type of font.
\value PreferBitmap prefers bitmap fonts (as opposed to outline
fonts).
\value PreferDevice prefers device fonts.
\value PreferOutline prefers outline fonts (as opposed to bitmap fonts).
\value ForceOutline forces the use of outline fonts.
\value NoAntialias don't antialias the fonts.
\value PreferAntialias antialias if possible.
\value OpenGLCompatible forces the use of OpenGL compatible
fonts.
Any of these may be OR-ed with one of these flags:
\value PreferMatch prefer an exact match. The font matcher will try to
use the exact font size that has been specified.
\value PreferQuality prefer the best quality font. The font matcher
will use the nearest standard point size that the font
supports.
*/
/*!
Sets the style hint and strategy to \a hint and \a strategy,
respectively.
If these aren't set explicitly the style hint will default to
\c AnyStyle and the style strategy to \c PreferDefault.
TQt does not support style hints on X11 since this information
is not provided by the window system.
\sa StyleHint, styleHint(), StyleStrategy, styleStrategy(), TQFontInfo
*/
void TQFont::setStyleHint( StyleHint hint, StyleStrategy strategy )
{
detach();
if ( ( d->mask & ( TQFontPrivate::StyleHint | TQFontPrivate::StyleStrategy ) ) &&
(StyleHint) d->request.styleHint == hint &&
(StyleStrategy) d->request.styleStrategy == strategy )
return;
d->request.styleHint = hint;
d->request.styleStrategy = strategy;
d->mask |= TQFontPrivate::StyleHint;
d->mask |= TQFontPrivate::StyleStrategy;
#if defined(Q_WS_X11)
d->request.addStyle = TQString::null;
#endif // Q_WS_X11
}
/*!
Sets the style strategy for the font to \a s.
\sa TQFont::StyleStrategy
*/
void TQFont::setStyleStrategy( StyleStrategy s )
{
detach();
if ( ( d->mask & TQFontPrivate::StyleStrategy ) &&
s == (StyleStrategy)d->request.styleStrategy )
return;
d->request.styleStrategy = s;
d->mask |= TQFontPrivate::StyleStrategy;
}
/*!
\enum TQFont::Stretch
Predefined stretch values that follow the CSS naming convention.
\value UltraCondensed 50
\value ExtraCondensed 62
\value Condensed 75
\value SemiCondensed 87
\value Unstretched 100
\value SemiExpanded 112
\value Expanded 125
\value ExtraExpanded 150
\value UltraExpanded 200
\sa setStretch() stretch()
*/
/*!
Returns the stretch factor for the font.
\sa setStretch()
*/
int TQFont::stretch() const
{
return d->request.stretch;
}
/*!
Sets the stretch factor for the font.
The stretch factor changes the width of all characters in the font
by \a factor percent. For example, setting \a factor to 150
results in all characters in the font being 1.5 times ( ie. 150% )
wider. The default stretch factor is 100. The minimum stretch
factor is 1, and the maximum stretch factor is 4000.
The stretch factor is only applied to outline fonts. The stretch
factor is ignored for bitmap fonts.
NOTE: TQFont cannot stretch XLFD fonts. When loading XLFD fonts on
X11, the stretch factor is matched against a predefined set of
values for the SETWIDTH_NAME field of the XLFD.
\sa stretch() TQFont::StyleStrategy
*/
void TQFont::setStretch( int factor )
{
if ( factor < 1 || factor > 4000 ) {
#ifdef QT_CHECK_RANGE
tqWarning( "TQFont::setStretch(): parameter '%d' out of range", factor );
#endif // QT_CHECK_RANGE
return;
}
detach();
if ( ( d->mask & TQFontPrivate::Stretch ) &&
d->request.stretch == (uint)factor )
return;
d->request.stretch = (uint)factor;
d->mask |= TQFontPrivate::Stretch;
}
/*!
If \a enable is TRUE, turns raw mode on; otherwise turns raw mode
off. This function only has an effect under X11.
If raw mode is enabled, TQt will search for an X font with a
complete font name matching the family name, ignoring all other
values set for the TQFont. If the font name matches several fonts,
TQt will use the first font returned by X. TQFontInfo \e cannot be
used to fetch information about a TQFont using raw mode (it will
return the values set in the TQFont for all parameters, including
the family name).
\warning Do not use raw mode unless you really, really need it! In
most (if not all) cases, setRawName() is a much better choice.
\sa rawMode(), setRawName()
*/
void TQFont::setRawMode( bool enable )
{
detach();
if ( (bool) d->rawMode == enable ) return;
d->rawMode = enable;
}
/*!
Returns TRUE if a window system font exactly matching the settings
of this font is available.
\sa TQFontInfo
*/
bool TQFont::exactMatch() const
{
TQFontEngine *engine = d->engineForScript( TQFont::NoScript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return d->rawMode ? engine->type() != TQFontEngine::Box
: d->request == engine->fontDef;
}
/*!
Returns TRUE if this font is equal to \a f; otherwise returns
FALSE.
Two TQFonts are considered equal if their font attributes are
equal. If rawMode() is enabled for both fonts, only the family
fields are compared.
\sa operator!=() isCopyOf()
*/
bool TQFont::operator==( const TQFont &f ) const
{
return f.d == d || ( f.d->request == d->request &&
f.d->underline == d->underline &&
f.d->overline == d->overline &&
f.d->strikeOut == d->strikeOut );
}
/*!
Returns TRUE if this font is different from \a f; otherwise
returns FALSE.
Two TQFonts are considered to be different if their font attributes
are different. If rawMode() is enabled for both fonts, only the
family fields are compared.
\sa operator==()
*/
bool TQFont::operator!=( const TQFont &f ) const
{
return !(operator==( f ));
}
/*!
Returns TRUE if this font and \a f are copies of each other, i.e.
one of them was created as a copy of the other and neither has
been modified since. This is much stricter than equality.
\sa operator=() operator==()
*/
bool TQFont::isCopyOf( const TQFont & f ) const
{
return d == f.d;
}
/*!
Returns TRUE if raw mode is used for font name matching; otherwise
returns FALSE.
\sa setRawMode() rawName()
*/
bool TQFont::rawMode() const
{
return d->rawMode;
}
/*!
Returns a new TQFont that has attributes copied from \a other.
*/
TQFont TQFont::resolve( const TQFont &other ) const
{
if ( *this == other && d->mask == other.d->mask )
return *this;
TQFont font( *this );
font.detach();
/*
if this font is a copy of the application default font, set the
fontdef mask to zero to indicate that *nothing* has been
explicitly set by the programmer.
*/
const TQFont appfont = TQApplication::font();
if ( d == appfont.d )
font.d->mask = 0;
font.d->resolve( other.d );
return font;
}
#ifndef QT_NO_COMPAT
/*! \obsolete
Please use TQApplication::font() instead.
*/
TQFont TQFont::defaultFont()
{
return TQApplication::font();
}
/*! \obsolete
Please use TQApplication::setFont() instead.
*/
void TQFont::setDefaultFont( const TQFont &f )
{
TQApplication::setFont( f );
}
#endif
#ifndef QT_NO_STRINGLIST
/*****************************************************************************
TQFont substitution management
*****************************************************************************/
typedef TQDict<TQStringList> TQFontSubst;
static TQFontSubst *fontSubst = 0;
static TQSingleCleanupHandler<TQFontSubst> qfont_cleanup_fontsubst;
// create substitution dict
static void initFontSubst()
{
// default substitutions
static const char *initTbl[] = {
#if defined(Q_WS_X11)
"arial", "helvetica",
"helv", "helvetica",
"tms rmn", "times",
#elif defined(Q_WS_WIN)
"times", "Times New Roman",
"courier", "Courier New",
"helvetica", "Arial",
#endif
0, 0
};
if (fontSubst)
return;
fontSubst = new TQFontSubst(17, FALSE);
TQ_CHECK_PTR( fontSubst );
fontSubst->setAutoDelete( TRUE );
qfont_cleanup_fontsubst.set(&fontSubst);
for ( int i=0; initTbl[i] != 0; i += 2 )
TQFont::insertSubstitution(TQString::fromLatin1(initTbl[i]),
TQString::fromLatin1(initTbl[i+1]));
}
/*!
Returns the first family name to be used whenever \a familyName is
specified. The lookup is case insensitive.
If there is no substitution for \a familyName, \a familyName is
returned.
To obtain a list of substitutions use substitutes().
\sa setFamily() insertSubstitutions() insertSubstitution() removeSubstitution()
*/
TQString TQFont::substitute( const TQString &familyName )
{
initFontSubst();
TQStringList *list = fontSubst->find(familyName);
if (list && list->count() > 0)
return *(list->at(0));
return familyName;
}
/*!
Returns a list of family names to be used whenever \a familyName
is specified. The lookup is case insensitive.
If there is no substitution for \a familyName, an empty list is
returned.
\sa substitute() insertSubstitutions() insertSubstitution() removeSubstitution()
*/
TQStringList TQFont::substitutes(const TQString &familyName)
{
initFontSubst();
TQStringList ret, *list = fontSubst->find(familyName);
if (list)
ret += *list;
return ret;
}
/*!
Inserts the family name \a substituteName into the substitution
table for \a familyName.
\sa insertSubstitutions() removeSubstitution() substitutions() substitute() substitutes()
*/
void TQFont::insertSubstitution(const TQString &familyName,
const TQString &substituteName)
{
initFontSubst();
TQStringList *list = fontSubst->find(familyName);
if (! list) {
list = new TQStringList;
fontSubst->insert(familyName, list);
}
if (! list->contains(substituteName))
list->append(substituteName);
}
/*!
Inserts the list of families \a substituteNames into the
substitution list for \a familyName.
\sa insertSubstitution(), removeSubstitution(), substitutions(), substitute()
*/
void TQFont::insertSubstitutions(const TQString &familyName,
const TQStringList &substituteNames)
{
initFontSubst();
TQStringList *list = fontSubst->find(familyName);
if (! list) {
list = new TQStringList;
fontSubst->insert(familyName, list);
}
TQStringList::ConstIterator it = substituteNames.begin();
while (it != substituteNames.end()) {
if (! list->contains(*it))
list->append(*it);
it++;
}
}
// ### mark: should be called removeSubstitutions()
/*!
Removes all the substitutions for \a familyName.
\sa insertSubstitutions(), insertSubstitution(), substitutions(), substitute()
*/
void TQFont::removeSubstitution( const TQString &familyName )
{ // ### function name should be removeSubstitutions() or
// ### removeSubstitutionList()
initFontSubst();
fontSubst->remove(familyName);
}
/*!
Returns a sorted list of substituted family names.
\sa insertSubstitution(), removeSubstitution(), substitute()
*/
TQStringList TQFont::substitutions()
{
initFontSubst();
TQStringList ret;
TQDictIterator<TQStringList> it(*fontSubst);
while (it.current()) {
ret.append(it.currentKey());
++it;
}
ret.sort();
return ret;
}
#endif // QT_NO_STRINGLIST
/* \internal
Internal function. Converts boolean font settings to an unsigned
8-bit number. Used for serialization etc.
*/
static TQ_UINT8 get_font_bits( const TQFontPrivate *f )
{
#ifdef QT_CHECK_STATE
Q_ASSERT( f != 0 );
#endif
TQ_UINT8 bits = 0;
if ( f->request.italic )
bits |= 0x01;
if ( f->underline )
bits |= 0x02;
if ( f->overline )
bits |= 0x40;
if ( f->strikeOut )
bits |= 0x04;
if ( f->request.fixedPitch )
bits |= 0x08;
// if ( f.hintSetByUser )
// bits |= 0x10;
if ( f->rawMode )
bits |= 0x20;
return bits;
}
#ifndef QT_NO_DATASTREAM
/* \internal
Internal function. Sets boolean font settings from an unsigned
8-bit number. Used for serialization etc.
*/
static void set_font_bits( TQ_UINT8 bits, TQFontPrivate *f )
{
#ifdef QT_CHECK_STATE
Q_ASSERT( f != 0 );
#endif
f->request.italic = (bits & 0x01) != 0;
f->underline = (bits & 0x02) != 0;
f->overline = (bits & 0x40) != 0;
f->strikeOut = (bits & 0x04) != 0;
f->request.fixedPitch = (bits & 0x08) != 0;
// f->hintSetByUser = (bits & 0x10) != 0;
f->rawMode = (bits & 0x20) != 0;
}
#endif
/*!
Returns the font's key, a textual representation of a font. It is
typically used as the key for a cache or dictionary of fonts.
\sa TQMap
*/
TQString TQFont::key() const
{
return toString();
}
/*!
Returns a description of the font. The description is a
comma-separated list of the attributes, perfectly suited for use
in TQSettings.
\sa fromString() operator<<()
*/
TQString TQFont::toString() const
{
const TQChar comma( ',' );
return family() + comma +
TQString::number( pointSizeFloat() ) + comma +
TQString::number( pixelSize() ) + comma +
TQString::number( (int) styleHint() ) + comma +
TQString::number( weight() ) + comma +
TQString::number( (int) italic() ) + comma +
TQString::number( (int) underline() ) + comma +
TQString::number( (int) strikeOut() ) + comma +
TQString::number( (int)fixedPitch() ) + comma +
TQString::number( (int) rawMode() );
}
/*!
Sets this font to match the description \a descrip. The description
is a comma-separated list of the font attributes, as returned by
toString().
\sa toString() operator>>()
*/
bool TQFont::fromString(const TQString &descrip)
{
#ifndef QT_NO_STRINGLIST
TQStringList l(TQStringList::split(',', descrip));
int count = (int)l.count();
#else
int count = 0;
TQString l[11];
int from = 0;
int to = descrip.find( ',' );
while ( to > 0 && count < 11 ) {
l[count] = descrip.mid( from, to-from );
count++;
from = to+1;
to = descrip.find( ',', from );
}
#endif // QT_NO_STRINGLIST
if ( !count || ( count > 2 && count < 9 ) || count > 11 ) {
#ifdef QT_CHECK_STATE
tqWarning("TQFont::fromString: invalid description '%s'",
descrip.isEmpty() ? "(empty)" : descrip.latin1());
#endif
return FALSE;
}
setFamily(l[0]);
if ( count > 1 && l[1].toDouble() > 0.0 )
setPointSizeFloat(l[1].toDouble());
if ( count == 9 ) {
setStyleHint((StyleHint) l[2].toInt());
setWeight(l[3].toInt());
setItalic(l[4].toInt());
setUnderline(l[5].toInt());
setStrikeOut(l[6].toInt());
setFixedPitch(l[7].toInt());
setRawMode(l[8].toInt());
} else if ( count == 10 ) {
if ( l[2].toInt() > 0 )
setPixelSize( l[2].toInt() );
setStyleHint((StyleHint) l[3].toInt());
setWeight(l[4].toInt());
setItalic(l[5].toInt());
setUnderline(l[6].toInt());
setStrikeOut(l[7].toInt());
setFixedPitch(l[8].toInt());
setRawMode(l[9].toInt());
}
return TRUE;
}
#if !defined( Q_WS_QWS )
/*! \internal
Internal function that dumps font cache statistics.
*/
void TQFont::cacheStatistics()
{
}
#endif // !Q_WS_QWS
/*****************************************************************************
TQFont stream functions
*****************************************************************************/
#ifndef QT_NO_DATASTREAM
/*!
\relates TQFont
Writes the font \a font to the data stream \a s. (toString()
writes to a text stream.)
\sa \link datastreamformat.html Format of the TQDataStream operators \endlink
*/
TQDataStream &operator<<( TQDataStream &s, const TQFont &font )
{
if ( s.version() == 1 ) {
TQCString fam( font.d->request.family.latin1() );
s << fam;
} else {
s << font.d->request.family;
}
if ( s.version() <= 3 ) {
TQ_INT16 pointSize = (TQ_INT16) font.d->request.pointSize;
if ( pointSize == -1 ) {
#ifdef Q_WS_X11
pointSize = (TQ_INT16)(font.d->request.pixelSize*720/TQPaintDevice::x11AppDpiY());
#else
pointSize = (TQ_INT16)TQFontInfo( font ).pointSize() * 10;
#endif
}
s << pointSize;
} else {
s << (TQ_INT16) font.d->request.pointSize;
s << (TQ_INT16) font.d->request.pixelSize;
}
s << (TQ_UINT8) font.d->request.styleHint;
if ( s.version() >= 5 )
s << (TQ_UINT8 ) font.d->request.styleStrategy;
return s << (TQ_UINT8) 0
<< (TQ_UINT8) font.d->request.weight
<< get_font_bits(font.d);
}
/*!
\relates TQFont
Reads the font \a font from the data stream \a s. (fromString()
reads from a text stream.)
\sa \link datastreamformat.html Format of the TQDataStream operators \endlink
*/
TQDataStream &operator>>( TQDataStream &s, TQFont &font )
{
if (font.d->deref()) delete font.d;
font.d = new TQFontPrivate;
font.d->mask = TQFontPrivate::Complete;
TQ_INT16 pointSize, pixelSize = -1;
TQ_UINT8 styleHint, styleStrategy = TQFont::PreferDefault, charSet, weight, bits;
if ( s.version() == 1 ) {
TQCString fam;
s >> fam;
font.d->request.family = TQString( fam );
} else {
s >> font.d->request.family;
}
s >> pointSize;
if ( s.version() >= 4 )
s >> pixelSize;
s >> styleHint;
if ( s.version() >= 5 )
s >> styleStrategy;
s >> charSet;
s >> weight;
s >> bits;
font.d->request.pointSize = pointSize;
font.d->request.pixelSize = pixelSize;
font.d->request.styleHint = styleHint;
font.d->request.styleStrategy = styleStrategy;
font.d->request.weight = weight;
set_font_bits( bits, font.d );
return s;
}
#endif // QT_NO_DATASTREAM
/*****************************************************************************
TQFontMetrics member functions
*****************************************************************************/
/*!
\class TQFontMetrics ntqfontmetrics.h
\brief The TQFontMetrics class provides font metrics information.
\ingroup graphics
\ingroup shared
TQFontMetrics functions calculate the size of characters and
strings for a given font. There are three ways you can create a
TQFontMetrics object:
\list 1
\i Calling the TQFontMetrics constructor with a TQFont creates a
font metrics object for a screen-compatible font, i.e. the font
cannot be a printer font<sup>*</sup>. If the font is changed
later, the font metrics object is \e not updated.
\i TQWidget::fontMetrics() returns the font metrics for a widget's
font. This is equivalent to TQFontMetrics(widget->font()). If the
widget's font is changed later, the font metrics object is \e not
updated.
\i TQPainter::fontMetrics() returns the font metrics for a
painter's current font. If the painter's font is changed later, the
font metrics object is \e not updated.
\endlist
<sup>*</sup> If you use a printer font the values returned may be
inaccurate. Printer fonts are not always accessible so the nearest
screen font is used if a printer font is supplied.
Once created, the object provides functions to access the
individual metrics of the font, its characters, and for strings
rendered in the font.
There are several functions that operate on the font: ascent(),
descent(), height(), leading() and lineSpacing() return the basic
size properties of the font. The underlinePos(), overlinePos(),
strikeOutPos() and lineWidth() functions, return the properties of
the line that underlines, overlines or strikes out the
characters. These functions are all fast.
There are also some functions that operate on the set of glyphs in
the font: minLeftBearing(), minRightBearing() and maxWidth().
These are by necessity slow, and we recommend avoiding them if
possible.
For each character, you can get its width(), leftBearing() and
rightBearing() and find out whether it is in the font using
inFont(). You can also treat the character as a string, and use
the string functions on it.
The string functions include width(), to return the width of a
string in pixels (or points, for a printer), boundingRect(), to
return a rectangle large enough to contain the rendered string,
and size(), to return the size of that rectangle.
Example:
\code
TQFont font( "times", 24 );
TQFontMetrics fm( font );
int pixelsWide = fm.width( "What's the width of this text?" );
int pixelsHigh = fm.height();
\endcode
\sa TQFont TQFontInfo TQFontDatabase
*/
/*!
Constructs a font metrics object for \a font.
The font must be screen-compatible, i.e. a font you use when
drawing text in \link TQWidget widgets\endlink or \link TQPixmap
pixmaps\endlink, not TQPicture or TQPrinter.
The font metrics object holds the information for the font that is
passed in the constructor at the time it is created, and is not
updated if the font's attributes are changed later.
Use TQPainter::fontMetrics() to get the font metrics when painting.
This will give correct results also when painting on paint device
that is not screen-compatible.
*/
TQFontMetrics::TQFontMetrics( const TQFont &font )
: d( font.d ), painter( 0 ), fscript( TQFont::NoScript )
{
d->ref();
}
/*!
\overload
Constructs a font metrics object for \a font using the given \a
script.
*/
TQFontMetrics::TQFontMetrics( const TQFont &font, TQFont::Script script )
: d( font.d ), painter( 0 ), fscript( script )
{
d->ref();
}
/*! \internal
Constructs a font metrics object for the painter's font \a p.
*/
TQFontMetrics::TQFontMetrics( const TQPainter *p )
: painter ( (TQPainter *) p ), fscript( TQFont::NoScript )
{
#if defined(CHECK_STATE)
if ( !painter->isActive() )
tqWarning( "TQFontMetrics: Get font metrics between TQPainter::begin() "
"and TQPainter::end()" );
#endif
if ( painter->testf(TQPainter::DirtyFont) )
painter->updateFont();
d = painter->pfont ? painter->pfont->d : painter->cfont.d;
#if defined(Q_WS_X11)
if ( d->screen != p->scrn ) {
TQFontPrivate *new_d = new TQFontPrivate( *d );
TQ_CHECK_PTR( new_d );
d = new_d;
d->screen = p->scrn;
d->count = 1;
} else
#endif // Q_WS_X11
d->ref();
}
/*!
Constructs a copy of \a fm.
*/
TQFontMetrics::TQFontMetrics( const TQFontMetrics &fm )
: d( fm.d ), painter( 0 ), fscript( fm.fscript )
{
d->ref();
}
/*!
Destroys the font metrics object and frees all allocated
resources.
*/
TQFontMetrics::~TQFontMetrics()
{
if ( d->deref() )
delete d;
}
/*!
Assigns the font metrics \a fm.
*/
TQFontMetrics &TQFontMetrics::operator=( const TQFontMetrics &fm )
{
if ( d != fm.d ) {
if ( d->deref() )
delete d;
d = fm.d;
d->ref();
}
painter = fm.painter;
return *this;
}
/*!
Returns the ascent of the font.
The ascent of a font is the distance from the baseline to the
highest position characters extend to. In practice, some font
designers break this rule, e.g. when they put more than one accent
on top of a character, or to accommodate an unusual character in
an exotic language, so it is possible (though rare) that this
value will be too small.
\sa descent()
*/
int TQFontMetrics::ascent() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return TQMAX(engine->ascent(), latin_engine->ascent());
}
/*!
Returns the descent of the font.
The descent is the distance from the base line to the lowest point
characters extend to. (Note that this is different from X, which
adds 1 pixel.) In practice, some font designers break this rule,
e.g. to accommodate an unusual character in an exotic language, so
it is possible (though rare) that this value will be too small.
\sa ascent()
*/
int TQFontMetrics::descent() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return TQMAX(engine->descent(), latin_engine->descent());
}
/*!
Returns the height of the font.
This is always equal to ascent()+descent()+1 (the 1 is for the
base line).
\sa leading(), lineSpacing()
*/
int TQFontMetrics::height() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return (TQMAX(engine->ascent(), latin_engine->ascent()) +
TQMAX(engine->descent(), latin_engine->descent()) + 1);
}
/*!
Returns the leading of the font.
This is the natural inter-line spacing.
\sa height(), lineSpacing()
*/
int TQFontMetrics::leading() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return TQMAX(engine->leading(), latin_engine->leading());
}
/*!
Returns the distance from one base line to the next.
This value is always equal to leading()+height().
\sa height(), leading()
*/
int TQFontMetrics::lineSpacing() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return (TQMAX(engine->leading(), latin_engine->leading()) +
TQMAX(engine->ascent(), latin_engine->ascent()) +
TQMAX(engine->descent(), latin_engine->descent()) + 1);
}
/*!
Returns the minimum left bearing of the font.
This is the smallest leftBearing(char) of all characters in the
font.
Note that this function can be very slow if the font is large.
\sa minRightBearing(), leftBearing()
*/
int TQFontMetrics::minLeftBearing() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return TQMIN(engine->minLeftBearing(), latin_engine->minLeftBearing());
}
/*!
Returns the minimum right bearing of the font.
This is the smallest rightBearing(char) of all characters in the
font.
Note that this function can be very slow if the font is large.
\sa minLeftBearing(), rightBearing()
*/
int TQFontMetrics::minRightBearing() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *latin_engine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( latin_engine != 0 );
#endif // QT_CHECK_STATE
return TQMIN(engine->minRightBearing(), latin_engine->minRightBearing());
}
/*!
Returns the width of the widest character in the font.
*/
int TQFontMetrics::maxWidth() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
TQFontEngine *lengine = d->engineForScript( TQFont::Latin );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
Q_ASSERT( lengine != 0 );
#endif // QT_CHECK_STATE
return TQMAX(engine->maxCharWidth(), lengine->maxCharWidth());
}
/*!
Returns TRUE if character \a ch is a valid character in the font;
otherwise returns FALSE.
*/
bool TQFontMetrics::inFont(TQChar ch) const
{
TQFont::Script script;
SCRIPT_FOR_CHAR( script, ch );
TQFontEngine *engine = d->engineForScript( script );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
if ( engine->type() == TQFontEngine::Box ) return FALSE;
return engine->canRender( &ch, 1 );
}
/*! \fn int TQFontMetrics::leftBearing( TQChar ch ) const
Returns the left bearing of character \a ch in the font.
The left bearing is the right-ward distance of the left-most pixel
of the character from the logical origin of the character. This
value is negative if the pixels of the character extend to the
left of the logical origin.
See width(TQChar) for a graphical description of this metric.
\sa rightBearing(), minLeftBearing(), width()
*/
#if !defined(Q_WS_WIN) && !defined(Q_WS_QWS)
int TQFontMetrics::leftBearing(TQChar ch) const
{
TQFont::Script script;
SCRIPT_FOR_CHAR( script, ch );
TQFontEngine *engine = d->engineForScript( script );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
if ( engine->type() == TQFontEngine::Box ) return 0;
glyph_t glyphs[10];
int nglyphs = 9;
engine->stringToCMap( &ch, 1, glyphs, 0, &nglyphs, FALSE );
// ### can nglyphs != 1 happen at all? Not currently I think
glyph_metrics_t gi = engine->boundingBox( glyphs[0] );
return gi.x;
}
#endif // !Q_WS_WIN
/*! \fn int TQFontMetrics::rightBearing(TQChar ch) const
Returns the right bearing of character \a ch in the font.
The right bearing is the left-ward distance of the right-most
pixel of the character from the logical origin of a subsequent
character. This value is negative if the pixels of the character
extend to the right of the width() of the character.
See width() for a graphical description of this metric.
\sa leftBearing(), minRightBearing(), width()
*/
#if !defined(Q_WS_WIN) && !defined(Q_WS_QWS)
int TQFontMetrics::rightBearing(TQChar ch) const
{
TQFont::Script script;
SCRIPT_FOR_CHAR( script, ch );
TQFontEngine *engine = d->engineForScript( script );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
if ( engine->type() == TQFontEngine::Box ) return 0;
glyph_t glyphs[10];
int nglyphs = 9;
engine->stringToCMap( &ch, 1, glyphs, 0, &nglyphs, FALSE );
// ### can nglyphs != 1 happen at all? Not currently I think
glyph_metrics_t gi = engine->boundingBox( glyphs[0] );
return gi.xoff - gi.x - gi.width;
}
#endif // !Q_WS_WIN
#ifndef Q_WS_QWS
/*!
Returns the width in pixels of the first \a len characters of \a
str. If \a len is negative (the default), the entire string is
used.
Note that this value is \e not equal to boundingRect().width();
boundingRect() returns a rectangle describing the pixels this
string will cover whereas width() returns the distance to where
the next string should be drawn.
\sa boundingRect()
*/
int TQFontMetrics::width( const TQString &str, int len ) const
{
if (len < 0)
len = str.length();
if (len == 0)
return 0;
int pos = 0;
int width = 0;
#ifndef Q_WS_MAC
const TQChar *ch = str.unicode();
while (pos < len) {
unsigned short uc = ch->unicode();
if (uc < TQFontEngineData::widthCacheSize && d->engineData && d->engineData->widthCache[uc])
width += d->engineData->widthCache[uc];
else {
TQFont::Script script;
SCRIPT_FOR_CHAR( script, *ch );
if (script >= TQFont::Arabic && script <= TQFont::Khmer)
break;
if ( ::category( *ch ) != TQChar::Mark_NonSpacing && !qIsZeroWidthChar(ch->unicode())) {
TQFontEngine *engine = d->engineForScript( script );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
glyph_t glyphs[8];
advance_t advances[8];
int nglyphs = 7;
engine->stringToCMap( ch, 1, glyphs, advances, &nglyphs, FALSE );
// ### can nglyphs != 1 happen at all? Not currently I think
if ( uc < TQFontEngineData::widthCacheSize && advances[0] > 0 && advances[0] < 0x100 )
d->engineData->widthCache[ uc ] = advances[0];
width += advances[0];
}
}
++pos;
++ch;
}
if ( pos < len ) {
#endif
TQTextEngine layout( str, d );
layout.itemize( TQTextEngine::WidthOnly );
width += layout.width( pos, len-pos );
#ifndef Q_WS_MAC
}
#endif
return width;
}
#endif
/*! \fn int TQFontMetrics::width( TQChar ch ) const
<img src="bearings.png" align=right>
Returns the logical width of character \a ch in pixels. This is a
distance appropriate for drawing a subsequent character after \a
ch.
Some of the metrics are described in the image to the right. The
central dark rectangles cover the logical width() of each
character. The outer pale rectangles cover the leftBearing() and
rightBearing() of each character. Notice that the bearings of "f"
in this particular font are both negative, while the bearings of
"o" are both positive.
\warning This function will produce incorrect results for Arabic
characters or non spacing marks in the middle of a string, as the
glyph shaping and positioning of marks that happens when
processing strings cannot be taken into account. Use charWidth()
instead if you aren't looking for the width of isolated
characters.
\sa boundingRect(), charWidth()
*/
/*! \fn int TQFontMetrics::width( char c ) const
\overload
\obsolete
Provided to aid porting from TQt 1.x.
*/
/*! \fn int TQFontMetrics::charWidth( const TQString &str, int pos ) const
Returns the width of the character at position \a pos in the
string \a str.
The whole string is needed, as the glyph drawn may change
depending on the context (the letter before and after the current
one) for some languages (e.g. Arabic).
This function also takes non spacing marks and ligatures into
account.
*/
#ifndef Q_WS_QWS
/*!
Returns the bounding rectangle of the first \a len characters of
\a str, which is the set of pixels the text would cover if drawn
at (0, 0).
If \a len is negative (the default), the entire string is used.
Note that the bounding rectangle may extend to the left of (0, 0),
e.g. for italicized fonts, and that the text output may cover \e
all pixels in the bounding rectangle.
Newline characters are processed as normal characters, \e not as
linebreaks.
Due to the different actual character heights, the height of the
bounding rectangle of e.g. "Yes" and "yes" may be different.
\sa width(), TQPainter::boundingRect()
*/
TQRect TQFontMetrics::boundingRect( const TQString &str, int len ) const
{
if (len < 0)
len = str.length();
if (len == 0)
return TQRect();
TQTextEngine layout( str, d );
layout.itemize( TQTextEngine::NoBidi|TQTextEngine::SingleLine );
glyph_metrics_t gm = layout.boundingBox( 0, len );
return TQRect( gm.x, gm.y, gm.width, gm.height );
}
#endif
/*!
Returns the rectangle that is covered by ink if the character
specified by \a ch were to be drawn at the origin of the coordinate
system.
Note that the bounding rectangle may extend to the left of (0, 0),
e.g. for italicized fonts, and that the text output may cover \e
all pixels in the bounding rectangle. For a space character the rectangle
will usually be empty.
Note that the rectangle usually extends both above and below the
base line.
\warning The width of the returned rectangle is not the advance width
of the character. Use boundingRect(const TQString &) or width() instead.
\sa width()
*/
TQRect TQFontMetrics::boundingRect( TQChar ch ) const
{
TQFont::Script script;
SCRIPT_FOR_CHAR( script, ch );
TQFontEngine *engine = d->engineForScript( script );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
glyph_t glyphs[10];
int nglyphs = 9;
engine->stringToCMap( &ch, 1, glyphs, 0, &nglyphs, FALSE );
glyph_metrics_t gi = engine->boundingBox( glyphs[0] );
return TQRect( gi.x, gi.y, gi.width, gi.height );
}
/*!
\overload
Returns the bounding rectangle of the first \a len characters of
\a str, which is the set of pixels the text would cover if drawn
at (0, 0). The drawing, and hence the bounding rectangle, is
constrained to the rectangle (\a x, \a y, \a w, \a h).
If \a len is negative (which is the default), the entire string is
used.
The \a flgs argument is the bitwise OR of the following flags:
\list
\i \c AlignAuto aligns to the left border for all languages except
Arabic and Hebrew where it aligns to the right.
\i \c AlignLeft aligns to the left border.
\i \c AlignRight aligns to the right border.
\i \c AlignJustify produces justified text.
\i \c AlignHCenter aligns horizontally centered.
\i \c AlignTop aligns to the top border.
\i \c AlignBottom aligns to the bottom border.
\i \c AlignVCenter aligns vertically centered
\i \c AlignCenter (== \c{AlignHCenter | AlignVCenter})
\i \c SingleLine ignores newline characters in the text.
\i \c ExpandTabs expands tabs (see below)
\i \c ShowPrefix interprets "&amp;x" as "<u>x</u>", i.e. underlined.
\i \c WordBreak breaks the text to fit the rectangle.
\endlist
Horizontal alignment defaults to \c AlignAuto and vertical
alignment defaults to \c AlignTop.
If several of the horizontal or several of the vertical alignment
flags are set, the resulting alignment is undefined.
These flags are defined in \c ntqnamespace.h.
If \c ExpandTabs is set in \a flgs, then: if \a tabarray is
non-null, it specifies a 0-terminated sequence of pixel-positions
for tabs; otherwise if \a tabstops is non-zero, it is used as the
tab spacing (in pixels).
Note that the bounding rectangle may extend to the left of (0, 0),
e.g. for italicized fonts, and that the text output may cover \e
all pixels in the bounding rectangle.
Newline characters are processed as linebreaks.
Despite the different actual character heights, the heights of the
bounding rectangles of "Yes" and "yes" are the same.
The bounding rectangle given by this function is somewhat larger
than that calculated by the simpler boundingRect() function. This
function uses the \link minLeftBearing() maximum left \endlink and
\link minRightBearing() right \endlink font bearings as is
necessary for multi-line text to align correctly. Also,
fontHeight() and lineSpacing() are used to calculate the height,
rather than individual character heights.
The \a intern argument should not be used.
\sa width(), TQPainter::boundingRect(), TQt::AlignmentFlags
*/
TQRect TQFontMetrics::boundingRect( int x, int y, int w, int h, int flgs,
const TQString& str, int len, int tabstops,
int *tabarray, TQTextParag **intern ) const
{
if ( len < 0 )
len = str.length();
int tabarraylen=0;
if (tabarray)
while (tabarray[tabarraylen])
tabarraylen++;
TQRect rb;
TQRect r(x, y, w, h);
qt_format_text( TQFont( d, d->paintdevice ), r, flgs|TQt::DontPrint, str, len, &rb,
tabstops, tabarray, tabarraylen, intern, 0 );
return rb;
}
/*!
Returns the size in pixels of the first \a len characters of \a
str.
If \a len is negative (the default), the entire string is used.
The \a flgs argument is the bitwise OR of the following flags:
\list
\i \c SingleLine ignores newline characters.
\i \c ExpandTabs expands tabs (see below)
\i \c ShowPrefix interprets "&amp;x" as "<u>x</u>", i.e. underlined.
\i \c WordBreak breaks the text to fit the rectangle.
\endlist
These flags are defined in \c ntqnamespace.h.
If \c ExpandTabs is set in \a flgs, then: if \a tabarray is
non-null, it specifies a 0-terminated sequence of pixel-positions
for tabs; otherwise if \a tabstops is non-zero, it is used as the
tab spacing (in pixels).
Newline characters are processed as linebreaks.
Despite the different actual character heights, the heights of the
bounding rectangles of "Yes" and "yes" are the same.
The \a intern argument should not be used.
\sa boundingRect()
*/
TQSize TQFontMetrics::size( int flgs, const TQString &str, int len, int tabstops,
int *tabarray, TQTextParag **intern ) const
{
return boundingRect(0,0,0,0,flgs,str,len,tabstops,tabarray,intern).size();
}
/*!
Returns the distance from the base line to where an underscore
should be drawn.
\sa overlinePos(), strikeOutPos(), lineWidth()
*/
int TQFontMetrics::underlinePos() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->underlinePosition();
}
/*!
Returns the distance from the base line to where an overline
should be drawn.
\sa underlinePos(), strikeOutPos(), lineWidth()
*/
int TQFontMetrics::overlinePos() const
{
int pos = ascent() + 1;
return pos > 0 ? pos : 1;
}
/*!
Returns the distance from the base line to where the strikeout
line should be drawn.
\sa underlinePos(), overlinePos(), lineWidth()
*/
int TQFontMetrics::strikeOutPos() const
{
int pos = ascent() / 3;
return pos > 0 ? pos : 1;
}
/*!
Returns the width of the underline and strikeout lines, adjusted
for the point size of the font.
\sa underlinePos(), overlinePos(), strikeOutPos()
*/
int TQFontMetrics::lineWidth() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->lineThickness();
}
/*****************************************************************************
TQFontInfo member functions
*****************************************************************************/
/*!
\class TQFontInfo ntqfontinfo.h
\brief The TQFontInfo class provides general information about fonts.
\ingroup graphics
\ingroup shared
The TQFontInfo class provides the same access functions as TQFont,
e.g. family(), pointSize(), italic(), weight(), fixedPitch(),
styleHint() etc. But whilst the TQFont access functions return the
values that were set, a TQFontInfo object returns the values that
apply to the font that will actually be used to draw the text.
For example, when the program asks for a 25pt Courier font on a
machine that has a non-scalable 24pt Courier font, TQFont will
(normally) use the 24pt Courier for rendering. In this case,
TQFont::pointSize() returns 25 and TQFontInfo::pointSize() returns
24.
There are three ways to create a TQFontInfo object.
\list 1
\i Calling the TQFontInfo constructor with a TQFont creates a font
info object for a screen-compatible font, i.e. the font cannot be
a printer font<sup>*</sup>. If the font is changed later, the font
info object is \e not updated.
\i TQWidget::fontInfo() returns the font info for a widget's font.
This is equivalent to calling TQFontInfo(widget->font()). If the
widget's font is changed later, the font info object is \e not
updated.
\i TQPainter::fontInfo() returns the font info for a painter's
current font. If the painter's font is changed later, the font
info object is \e not updated.
\endlist
<sup>*</sup> If you use a printer font the values returned may be
inaccurate. Printer fonts are not always accessible so the nearest
screen font is used if a printer font is supplied.
\sa TQFont TQFontMetrics TQFontDatabase
*/
/*!
Constructs a font info object for \a font.
The font must be screen-compatible, i.e. a font you use when
drawing text in \link TQWidget widgets\endlink or \link TQPixmap
pixmaps\endlink, not TQPicture or TQPrinter.
The font info object holds the information for the font that is
passed in the constructor at the time it is created, and is not
updated if the font's attributes are changed later.
Use TQPainter::fontInfo() to get the font info when painting.
This will give correct results also when painting on paint device
that is not screen-compatible.
*/
TQFontInfo::TQFontInfo( const TQFont &font )
: d( font.d ), painter( 0 ), fscript( TQFont::NoScript )
{
d->ref();
}
/*!
Constructs a font info object for \a font using the specified \a
script.
*/
TQFontInfo::TQFontInfo( const TQFont &font, TQFont::Script script )
: d( font.d ), painter( 0 ), fscript( script )
{
d->ref();
}
/*! \internal
Constructs a font info object from the painter's font \a p.
*/
TQFontInfo::TQFontInfo( const TQPainter *p )
: painter( 0 ), fscript( TQFont::NoScript )
{
TQPainter *painter = (TQPainter *) p;
#if defined(CHECK_STATE)
if ( !painter->isActive() )
tqWarning( "TQFontInfo: Get font info between TQPainter::begin() "
"and TQPainter::end()" );
#endif
painter->setf( TQPainter::FontInf );
if ( painter->testf(TQPainter::DirtyFont) )
painter->updateFont();
if ( painter->pfont )
d = painter->pfont->d;
else
d = painter->cfont.d;
d->ref();
}
/*!
Constructs a copy of \a fi.
*/
TQFontInfo::TQFontInfo( const TQFontInfo &fi )
: d(fi.d), painter(0), fscript( fi.fscript )
{
d->ref();
}
/*!
Destroys the font info object.
*/
TQFontInfo::~TQFontInfo()
{
if ( d->deref() )
delete d;
}
/*!
Assigns the font info in \a fi.
*/
TQFontInfo &TQFontInfo::operator=( const TQFontInfo &fi )
{
if ( d != fi.d ) {
if ( d->deref() )
delete d;
d = fi.d;
d->ref();
}
painter = 0;
fscript = fi.fscript;
return *this;
}
/*!
Returns the family name of the matched window system font.
\sa TQFont::family()
*/
TQString TQFontInfo::family() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->fontDef.family;
}
/*!
Returns the point size of the matched window system font.
\sa TQFont::pointSize()
*/
int TQFontInfo::pointSize() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return ( engine->fontDef.pointSize + 5 ) / 10;
}
/*!
Returns the pixel size of the matched window system font.
\sa TQFont::pointSize()
*/
int TQFontInfo::pixelSize() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->fontDef.pixelSize;
}
/*!
Returns the italic value of the matched window system font.
\sa TQFont::italic()
*/
bool TQFontInfo::italic() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->fontDef.italic;
}
/*!
Returns the weight of the matched window system font.
\sa TQFont::weight(), bold()
*/
int TQFontInfo::weight() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return engine->fontDef.weight;
}
/*!
\fn bool TQFontInfo::bold() const
Returns TRUE if weight() would return a value greater than \c
TQFont::Normal; otherwise returns FALSE.
\sa weight(), TQFont::bold()
*/
/*!
Returns the underline value of the matched window system font.
\sa TQFont::underline()
\internal
Here we read the underline flag directly from the TQFont.
This is OK for X11 and for Windows because we always get what we want.
*/
bool TQFontInfo::underline() const
{
return d->underline;
}
/*!
Returns the overline value of the matched window system font.
\sa TQFont::overline()
\internal
Here we read the overline flag directly from the TQFont.
This is OK for X11 and for Windows because we always get what we want.
*/
bool TQFontInfo::overline() const
{
return d->overline;
}
/*!
Returns the strikeout value of the matched window system font.
\sa TQFont::strikeOut()
\internal Here we read the strikeOut flag directly from the TQFont.
This is OK for X11 and for Windows because we always get what we want.
*/
bool TQFontInfo::strikeOut() const
{
return d->strikeOut;
}
/*!
Returns the fixed pitch value of the matched window system font.
\sa TQFont::fixedPitch()
*/
bool TQFontInfo::fixedPitch() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
#ifdef Q_OS_MAC
if (!engine->fontDef.fixedPitchComputed) {
TQChar ch[2] = { TQChar('i'), TQChar('m') };
glyph_t g[2];
int l = 2;
advance_t a[2];
engine->stringToCMap(ch, 2, g, a, &l, FALSE);
engine->fontDef.fixedPitch = a[0] == a[1];
engine->fontDef.fixedPitchComputed = TRUE;
}
#endif
return engine->fontDef.fixedPitch;
}
/*!
Returns the style of the matched window system font.
Currently only returns the style hint set in TQFont.
\sa TQFont::styleHint() TQFont::StyleHint
*/
TQFont::StyleHint TQFontInfo::styleHint() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return (TQFont::StyleHint) engine->fontDef.styleHint;
}
/*!
Returns TRUE if the font is a raw mode font; otherwise returns
FALSE.
If it is a raw mode font, all other functions in TQFontInfo will
return the same values set in the TQFont, regardless of the font
actually used.
\sa TQFont::rawMode()
*/
bool TQFontInfo::rawMode() const
{
return d->rawMode;
}
/*!
Returns TRUE if the matched window system font is exactly the same
as the one specified by the font; otherwise returns FALSE.
\sa TQFont::exactMatch()
*/
bool TQFontInfo::exactMatch() const
{
TQFontEngine *engine = d->engineForScript( (TQFont::Script) fscript );
#ifdef QT_CHECK_STATE
Q_ASSERT( engine != 0 );
#endif // QT_CHECK_STATE
return d->rawMode ? engine->type() != TQFontEngine::Box
: d->request == engine->fontDef;
}
// **********************************************************************
// TQFontCache
// **********************************************************************
#ifdef TQFONTCACHE_DEBUG
// fast timeouts for debugging
static const int fast_timeout = 1000; // 1s
static const int slow_timeout = 5000; // 5s
#else
static const int fast_timeout = 10000; // 10s
static const int slow_timeout = 300000; // 5m
#endif // TQFONTCACHE_DEBUG
TQFontCache *TQFontCache::instance = 0;
const uint TQFontCache::min_cost = 4*1024; // 4mb
static TQSingleCleanupHandler<TQFontCache> cleanup_fontcache;
TQFontCache::TQFontCache()
: TQObject( tqApp, "global font cache" ), total_cost( 0 ), max_cost( min_cost ),
current_timestamp( 0 ), fast( FALSE ), timer_id( -1 )
{
Q_ASSERT( instance == 0 );
instance = this;
cleanup_fontcache.set( &instance );
}
TQFontCache::~TQFontCache()
{
{
EngineDataCache::Iterator it = engineDataCache.begin(),
end = engineDataCache.end();
while ( it != end ) {
if ( it.data()->count == 0 )
delete it.data();
else
FC_DEBUG("TQFontCache::~TQFontCache: engineData %p still has refcount %d",
it.data(), it.data()->count);
++it;
}
}
EngineCache::Iterator it = engineCache.begin(),
end = engineCache.end();
while ( it != end ) {
if ( it.data().data->count == 0 ) {
if ( --it.data().data->cache_count == 0 ) {
FC_DEBUG("TQFontCache::~TQFontCache: deleting engine %p key=(%d / %d %d %d %d %d)",
it.data().data, it.key().script, it.key().def.pointSize,
it.key().def.pixelSize, it.key().def.weight, it.key().def.italic,
it.key().def.fixedPitch);
delete it.data().data;
}
} else {
FC_DEBUG("TQFontCache::~TQFontCache: engine = %p still has refcount %d",
it.data().data, it.data().data->count);
}
++it;
}
instance = 0;
}
#ifdef Q_WS_QWS
void TQFontCache::clear()
{
{
EngineDataCache::Iterator it = engineDataCache.begin(),
end = engineDataCache.end();
while ( it != end ) {
TQFontEngineData *data = it.data();
if ( data->engine )
data->engine->deref();
data->engine = 0;
++it;
}
}
EngineCache::Iterator it = engineCache.begin(),
end = engineCache.end();
while ( it != end ) {
if ( it.data().data->count == 0 ) {
if ( --it.data().data->cache_count == 0 ) {
FC_DEBUG("TQFontCache::~TQFontCache: deleting engine %p key=(%d / %d %d %d %d %d)",
it.data().data, it.key().script, it.key().def.pointSize,
it.key().def.pixelSize, it.key().def.weight, it.key().def.italic,
it.key().def.fixedPitch);
delete it.data().data;
}
} else {
FC_DEBUG("TQFontCache::~TQFontCache: engine = %p still has refcount %d",
it.data().data, it.data().data->count);
}
++it;
}
}
#endif
TQFontEngineData *TQFontCache::findEngineData( const Key &key ) const
{
EngineDataCache::ConstIterator it = engineDataCache.find( key ),
end = engineDataCache.end();
if ( it == end ) return 0;
// found
return it.data();
}
void TQFontCache::insertEngineData( const Key &key, TQFontEngineData *engineData )
{
FC_DEBUG( "TQFontCache: inserting new engine data %p", engineData );
engineDataCache.insert( key, engineData );
increaseCost( sizeof( TQFontEngineData ) );
}
TQFontEngine *TQFontCache::findEngine( const Key &key )
{
EngineCache::Iterator it = engineCache.find( key ),
end = engineCache.end();
if ( it == end ) return 0;
// found... update the hitcount and timestamp
it.data().hits++;
it.data().timestamp = ++current_timestamp;
FC_DEBUG( "TQFontCache: found font engine\n"
" %p: timestamp %4u hits %3u ref %2d/%2d, type '%s'",
it.data().data, it.data().timestamp, it.data().hits,
it.data().data->count, it.data().data->cache_count,
it.data().data->name() );
return it.data().data;
}
void TQFontCache::insertEngine( const Key &key, TQFontEngine *engine )
{
FC_DEBUG( "TQFontCache: inserting new engine %p", engine );
Engine data( engine );
data.timestamp = ++current_timestamp;
engineCache.insert( key, data );
// only increase the cost if this is the first time we insert the engine
if ( engine->cache_count == 0 )
increaseCost( engine->cache_cost );
++engine->cache_count;
}
void TQFontCache::increaseCost( uint cost )
{
cost = ( cost + 512 ) / 1024; // store cost in kb
cost = cost > 0 ? cost : 1;
total_cost += cost;
FC_DEBUG( " COST: increased %u kb, total_cost %u kb, max_cost %u kb",
cost, total_cost, max_cost );
if ( total_cost > max_cost) {
max_cost = total_cost;
if ( timer_id == -1 || ! fast ) {
FC_DEBUG( " TIMER: starting fast timer (%d ms)", fast_timeout );
if (timer_id != -1) killTimer( timer_id );
timer_id = startTimer( fast_timeout );
fast = TRUE;
}
}
}
void TQFontCache::decreaseCost( uint cost )
{
cost = ( cost + 512 ) / 1024; // cost is stored in kb
cost = cost > 0 ? cost : 1;
Q_ASSERT( cost <= total_cost );
total_cost -= cost;
FC_DEBUG( " COST: decreased %u kb, total_cost %u kb, max_cost %u kb",
cost, total_cost, max_cost );
}
#if defined(Q_WS_WIN ) || defined (Q_WS_QWS)
void TQFontCache::cleanupPrinterFonts()
{
FC_DEBUG( "TQFontCache::cleanupPrinterFonts" );
{
FC_DEBUG( " CLEAN engine data:" );
// clean out all unused engine datas
EngineDataCache::Iterator it = engineDataCache.begin(),
end = engineDataCache.end();
while ( it != end ) {
if ( it.key().screen == 0 ) {
++it;
continue;
}
if( it.data()->count > 0 ) {
#ifdef Q_WS_WIN
for(int i = 0; i < TQFont::LastPrivateScript; ++i) {
if( it.data()->engines[i] ) {
it.data()->engines[i]->deref();
it.data()->engines[i] = 0;
}
}
#else
if ( it.data()->engine ) {
it.data()->engine->deref();
it.data()->engine = 0;
}
#endif
++it;
} else {
EngineDataCache::Iterator rem = it++;
decreaseCost( sizeof( TQFontEngineData ) );
FC_DEBUG( " %p", rem.data() );
delete rem.data();
engineDataCache.remove( rem );
}
}
}
EngineCache::Iterator it = engineCache.begin(),
end = engineCache.end();
while( it != end ) {
if ( it.data().data->count > 0 || it.key().screen == 0) {
++it;
continue;
}
FC_DEBUG( " %p: timestamp %4u hits %2u ref %2d/%2d, type '%s'",
it.data().data, it.data().timestamp, it.data().hits,
it.data().data->count, it.data().data->cache_count,
it.data().data->name() );
if ( --it.data().data->cache_count == 0 ) {
FC_DEBUG( " DELETE: last occurence in cache" );
decreaseCost( it.data().data->cache_cost );
delete it.data().data;
}
engineCache.remove( it++ );
}
}
#endif
void TQFontCache::timerEvent( TQTimerEvent * )
{
FC_DEBUG( "TQFontCache::timerEvent: performing cache maintenance (timestamp %u)",
current_timestamp );
if ( total_cost <= max_cost && max_cost <= min_cost ) {
FC_DEBUG( " cache redused sufficiently, stopping timer" );
killTimer( timer_id );
timer_id = -1;
fast = FALSE;
return;
}
// go through the cache and count up everything in use
uint in_use_cost = 0;
{
FC_DEBUG( " SWEEP engine data:" );
// make sure the cost of each engine data is at least 1kb
const uint engine_data_cost =
sizeof( TQFontEngineData ) > 1024 ? sizeof( TQFontEngineData ) : 1024;
EngineDataCache::ConstIterator it = engineDataCache.begin(),
end = engineDataCache.end();
for ( ; it != end; ++it ) {
#ifdef TQFONTCACHE_DEBUG
FC_DEBUG( " %p: ref %2d", it.data(), it.data()->count );
# if defined(Q_WS_X11) || defined(Q_WS_WIN)
// print out all engines
for ( int i = 0; i < TQFont::LastPrivateScript; ++i ) {
if ( ! it.data()->engines[i] ) continue;
FC_DEBUG( " contains %p", it.data()->engines[i] );
}
# endif // Q_WS_X11 || Q_WS_WIN
#endif // TQFONTCACHE_DEBUG
if ( it.data()->count > 0 )
in_use_cost += engine_data_cost;
}
}
{
FC_DEBUG( " SWEEP engine:" );
EngineCache::ConstIterator it = engineCache.begin(),
end = engineCache.end();
for ( ; it != end; ++it ) {
FC_DEBUG( " %p: timestamp %4u hits %2u ref %2d/%2d, cost %u bytes",
it.data().data, it.data().timestamp, it.data().hits,
it.data().data->count, it.data().data->cache_count,
it.data().data->cache_cost );
if ( it.data().data->count > 0 )
in_use_cost += it.data().data->cache_cost / it.data().data->cache_count;
}
// attempt to make up for rounding errors
in_use_cost += (uint)engineCache.count();
}
in_use_cost = ( in_use_cost + 512 ) / 1024; // cost is stored in kb
/*
calculate the new maximum cost for the cache
NOTE: in_use_cost is *not* correct due to rounding errors in the
above algorithm. instead of worrying about getting the
calculation correct, we are more interested in speed, and use
in_use_cost as a floor for new_max_cost
*/
uint new_max_cost = TQMAX( TQMAX( max_cost / 2, in_use_cost ), min_cost );
FC_DEBUG( " after sweep, in use %u kb, total %u kb, max %u kb, new max %u kb",
in_use_cost, total_cost, max_cost, new_max_cost );
if ( new_max_cost == max_cost ) {
if ( fast ) {
FC_DEBUG( " cannot shrink cache, slowing timer" );
killTimer( timer_id );
timer_id = startTimer( slow_timeout );
fast = FALSE;
}
return;
} else if ( ! fast ) {
FC_DEBUG( " dropping into passing gear" );
killTimer( timer_id );
timer_id = startTimer( fast_timeout );
fast = TRUE;
}
max_cost = new_max_cost;
{
FC_DEBUG( " CLEAN engine data:" );
// clean out all unused engine datas
EngineDataCache::Iterator it = engineDataCache.begin(),
end = engineDataCache.end();
while ( it != end ) {
if ( it.data()->count > 0 ) {
++it;
continue;
}
EngineDataCache::Iterator rem = it++;
decreaseCost( sizeof( TQFontEngineData ) );
FC_DEBUG( " %p", rem.data() );
delete rem.data();
engineDataCache.remove( rem );
}
}
// clean out the engine cache just enough to get below our new max cost
uint current_cost;
do {
current_cost = total_cost;
EngineCache::Iterator it = engineCache.begin(),
end = engineCache.end();
// determine the oldest and least popular of the unused engines
uint oldest = ~0;
uint least_popular = ~0;
for ( ; it != end; ++it ) {
if ( it.data().data->count > 0 ) continue;
if ( it.data().timestamp < oldest &&
it.data().hits <= least_popular ) {
oldest = it.data().timestamp;
least_popular = it.data().hits;
}
}
FC_DEBUG( " oldest %u least popular %u", oldest, least_popular );
for ( it = engineCache.begin(); it != end; ++it ) {
if ( it.data().data->count == 0 &&
it.data().timestamp == oldest &&
it.data().hits == least_popular)
break;
}
if ( it != end ) {
FC_DEBUG( " %p: timestamp %4u hits %2u ref %2d/%2d, type '%s'",
it.data().data, it.data().timestamp, it.data().hits,
it.data().data->count, it.data().data->cache_count,
it.data().data->name() );
if ( --it.data().data->cache_count == 0 ) {
FC_DEBUG( " DELETE: last occurence in cache" );
decreaseCost( it.data().data->cache_cost );
delete it.data().data;
} else {
/*
this particular font engine is in the cache multiple
times... set current_cost to zero, so that we can
keep looping to get rid of all occurences
*/
current_cost = 0;
}
engineCache.remove( it );
}
} while ( current_cost != total_cost && total_cost > max_cost );
}