/**************************************************************************** ** ** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the QtGui module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage ** This file contains pre-release code and may not be distributed. ** You may use this file in accordance with the terms and conditions ** contained in the Technology Preview License Agreement accompanying ** this package. ** ** GNU Lesser General Public License Usage ** Alternatively, this file may be used under the terms of the GNU Lesser ** General Public License version 2.1 as published by the Free Software ** Foundation and appearing in the file LICENSE.LGPL included in the ** packaging of this file. Please review the following information to ** ensure the GNU Lesser General Public License version 2.1 requirements ** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain ** additional rights. These rights are described in the Nokia Qt LGPL ** Exception version 1.1, included in the file LGPL_EXCEPTION.txt in this ** package. ** ** If you have questions regarding the use of this file, please contact ** Nokia at qt-info@nokia.com. ** ** ** ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qlcdnumber.h" #ifndef QT_NO_LCDNUMBER #include "qbitarray.h" #include "qpainter.h" #include "private/qframe_p.h" QT_BEGIN_NAMESPACE class QLCDNumberPrivate : public QFramePrivate { Q_DECLARE_PUBLIC(QLCDNumber) public: void init(); void internalSetString(const QString& s); void drawString(const QString& s, QPainter &, QBitArray * = 0, bool = true); //void drawString(const QString &, QPainter &, QBitArray * = 0) const; void drawDigit(const QPoint &, QPainter &, int, char, char = ' '); void drawSegment(const QPoint &, char, QPainter &, int, bool = false); int ndigits; double val; uint base : 2; uint smallPoint : 1; uint fill : 1; uint shadow : 1; QString digitStr; QBitArray points; }; /*! \class QLCDNumber \brief The QLCDNumber widget displays a number with LCD-like digits. \ingroup basicwidgets It can display a number in just about any size. It can display decimal, hexadecimal, octal or binary numbers. It is easy to connect to data sources using the display() slot, which is overloaded to take any of five argument types. There are also slots to change the base with setMode() and the decimal point with setSmallDecimalPoint(). QLCDNumber emits the overflow() signal when it is asked to display something beyond its range. The range is set by setNumDigits(), but setSmallDecimalPoint() also influences it. If the display is set to hexadecimal, octal or binary, the integer equivalent of the value is displayed. These digits and other symbols can be shown: 0/O, 1, 2, 3, 4, 5/S, 6, 7, 8, 9/g, minus, decimal point, A, B, C, D, E, F, h, H, L, o, P, r, u, U, Y, colon, degree sign (which is specified as single quote in the string) and space. QLCDNumber substitutes spaces for illegal characters. It is not possible to retrieve the contents of a QLCDNumber object, although you can retrieve the numeric value with value(). If you really need the text, we recommend that you connect the signals that feed the display() slot to another slot as well and store the value there. Incidentally, QLCDNumber is the very oldest part of Qt, tracing its roots back to a BASIC program on the \link http://www.nvg.ntnu.no/sinclair/computers/zxspectrum/zxspectrum.htm Sinclair Spectrum\endlink. \table \row \o \inlineimage motif-lcdnumber.png Screenshot of a Motif style LCD number widget \inlineimage cde-lcdnumber.png Screenshot of a CDE style LCD number widget \inlineimage windows-lcdnumber.png Screenshot of a Windows style LCD number widget \inlineimage windowsxp-lcdnumber.png Screenshot of a Windows XP style LCD number widget \inlineimage macintosh-lcdnumber.png Screenshot of a Macintosh style LCD number widget \inlineimage plastique-lcdnumber.png Screenshot of a Plastique style LCD number widget \row \o LCD number widgets shown in various widget styles (from left to right): \l{Motif Style Widget Gallery}{Motif}, \l{CDE Style Widget Gallery}{CDE}, \l{Windows Style Widget Gallery}{Windows}, \l{Windows XP Style Widget Gallery}{Windows XP}, \l{Macintosh Style Widget Gallery}{Macintosh}, \l{Plastique Style Widget Gallery}{Plastique}. \endtable \sa QLabel, QFrame, {Digital Clock Example}, {Tetrix Example} */ /*! \enum QLCDNumber::Mode This type determines how numbers are shown. \value Hex Hexadecimal \value Dec Decimal \value Oct Octal \value Bin Binary \omitvalue HEX \omitvalue DEC \omitvalue OCT \omitvalue BIN If the display is set to hexadecimal, octal or binary, the integer equivalent of the value is displayed. */ /*! \enum QLCDNumber::SegmentStyle This type determines the visual appearance of the QLCDNumber widget. \value Outline gives raised segments filled with the background color. \value Filled gives raised segments filled with the windowText color. \value Flat gives flat segments filled with the windowText color. */ /*! \fn void QLCDNumber::overflow() This signal is emitted whenever the QLCDNumber is asked to display a too-large number or a too-long string. It is never emitted by setNumDigits(). */ static QString int2string(int num, int base, int ndigits, bool *oflow) { QString s; bool negative; if (num < 0) { negative = true; num = -num; } else { negative = false; } switch(base) { case QLCDNumber::Hex: s.sprintf("%*x", ndigits, num); break; case QLCDNumber::Dec: s.sprintf("%*i", ndigits, num); break; case QLCDNumber::Oct: s.sprintf("%*o", ndigits, num); break; case QLCDNumber::Bin: { char buf[42]; char *p = &buf[41]; uint n = num; int len = 0; *p = '\0'; do { *--p = (char)((n&1)+'0'); n >>= 1; len++; } while (n != 0); len = ndigits - len; if (len > 0) s.fill(QLatin1Char(' '), len); s += QString::fromLatin1(p); } break; } if (negative) { for (int i=0; i<(int)s.length(); i++) { if (s[i] != QLatin1Char(' ')) { if (i != 0) { s[i-1] = QLatin1Char('-'); } else { s.insert(0, QLatin1Char('-')); } break; } } } if (oflow) *oflow = (int)s.length() > ndigits; return s; } static QString double2string(double num, int base, int ndigits, bool *oflow) { QString s; if (base != QLCDNumber::Dec) { bool of = num >= 2147483648.0 || num < -2147483648.0; if (of) { // oops, integer overflow if (oflow) *oflow = true; return s; } s = int2string((int)num, base, ndigits, 0); } else { // decimal base int nd = ndigits; do { s.sprintf("%*.*g", ndigits, nd, num); int i = s.indexOf(QLatin1Char('e')); if (i > 0 && s[i+1]==QLatin1Char('+')) { s[i] = QLatin1Char(' '); s[i+1] = QLatin1Char('e'); } } while (nd-- && (int)s.length() > ndigits); } if (oflow) *oflow = (int)s.length() > ndigits; return s; } static const char *getSegments(char ch) // gets list of segments for ch { static const char segments[30][8] = { { 0, 1, 2, 4, 5, 6,99, 0}, // 0 0 / O { 2, 5,99, 0, 0, 0, 0, 0}, // 1 1 { 0, 2, 3, 4, 6,99, 0, 0}, // 2 2 { 0, 2, 3, 5, 6,99, 0, 0}, // 3 3 { 1, 2, 3, 5,99, 0, 0, 0}, // 4 4 { 0, 1, 3, 5, 6,99, 0, 0}, // 5 5 / S { 0, 1, 3, 4, 5, 6,99, 0}, // 6 6 { 0, 2, 5,99, 0, 0, 0, 0}, // 7 7 { 0, 1, 2, 3, 4, 5, 6,99}, // 8 8 { 0, 1, 2, 3, 5, 6,99, 0}, // 9 9 / g { 3,99, 0, 0, 0, 0, 0, 0}, // 10 - { 7,99, 0, 0, 0, 0, 0, 0}, // 11 . { 0, 1, 2, 3, 4, 5,99, 0}, // 12 A { 1, 3, 4, 5, 6,99, 0, 0}, // 13 B { 0, 1, 4, 6,99, 0, 0, 0}, // 14 C { 2, 3, 4, 5, 6,99, 0, 0}, // 15 D { 0, 1, 3, 4, 6,99, 0, 0}, // 16 E { 0, 1, 3, 4,99, 0, 0, 0}, // 17 F { 1, 3, 4, 5,99, 0, 0, 0}, // 18 h { 1, 2, 3, 4, 5,99, 0, 0}, // 19 H { 1, 4, 6,99, 0, 0, 0, 0}, // 20 L { 3, 4, 5, 6,99, 0, 0, 0}, // 21 o { 0, 1, 2, 3, 4,99, 0, 0}, // 22 P { 3, 4,99, 0, 0, 0, 0, 0}, // 23 r { 4, 5, 6,99, 0, 0, 0, 0}, // 24 u { 1, 2, 4, 5, 6,99, 0, 0}, // 25 U { 1, 2, 3, 5, 6,99, 0, 0}, // 26 Y { 8, 9,99, 0, 0, 0, 0, 0}, // 27 : { 0, 1, 2, 3,99, 0, 0, 0}, // 28 ' {99, 0, 0, 0, 0, 0, 0, 0} }; // 29 empty if (ch >= '0' && ch <= '9') return segments[ch - '0']; if (ch >= 'A' && ch <= 'F') return segments[ch - 'A' + 12]; if (ch >= 'a' && ch <= 'f') return segments[ch - 'a' + 12]; int n; switch (ch) { case '-': n = 10; break; case 'O': n = 0; break; case 'g': n = 9; break; case '.': n = 11; break; case 'h': n = 18; break; case 'H': n = 19; break; case 'l': case 'L': n = 20; break; case 'o': n = 21; break; case 'p': case 'P': n = 22; break; case 'r': case 'R': n = 23; break; case 's': case 'S': n = 5; break; case 'u': n = 24; break; case 'U': n = 25; break; case 'y': case 'Y': n = 26; break; case ':': n = 27; break; case '\'': n = 28; break; default: n = 29; break; } return segments[n]; } #ifdef QT3_SUPPORT /*! \obsolete Constructs an LCD number, sets the number of digits to 5, the base to decimal, the decimal point mode to 'small' and the frame style to a raised box. The segmentStyle() is set to \c Outline. The \a parent and \a name arguments are passed to the QFrame constructor. \sa setNumDigits(), setSmallDecimalPoint() */ QLCDNumber::QLCDNumber(QWidget *parent, const char *name) : QFrame(*new QLCDNumberPrivate, parent) { setObjectName(QString::fromAscii(name)); Q_D(QLCDNumber); d->ndigits = 5; d->init(); } /*! \obsolete Constructs an LCD number, sets the number of digits to \a numDigits, the base to decimal, the decimal point mode to 'small' and the frame style to a raised box. The segmentStyle() is set to \c Outline. The \a parent and \a name arguments are passed to the QFrame constructor. \sa setNumDigits(), setSmallDecimalPoint() */ QLCDNumber::QLCDNumber(uint numDigits, QWidget *parent, const char *name) : QFrame(*new QLCDNumberPrivate, parent) { setObjectName(QString::fromAscii(name)); Q_D(QLCDNumber); d->ndigits = numDigits; d->init(); } #endif //QT3_SUPPORT /*! Constructs an LCD number, sets the number of digits to 5, the base to decimal, the decimal point mode to 'small' and the frame style to a raised box. The segmentStyle() is set to \c Outline. The \a parent argument is passed to the QFrame constructor. \sa setNumDigits(), setSmallDecimalPoint() */ QLCDNumber::QLCDNumber(QWidget *parent) : QFrame(*new QLCDNumberPrivate, parent) { Q_D(QLCDNumber); d->ndigits = 5; d->init(); } /*! Constructs an LCD number, sets the number of digits to \a numDigits, the base to decimal, the decimal point mode to 'small' and the frame style to a raised box. The segmentStyle() is set to \c Filled. The \a parent argument is passed to the QFrame constructor. \sa setNumDigits(), setSmallDecimalPoint() */ QLCDNumber::QLCDNumber(uint numDigits, QWidget *parent) : QFrame(*new QLCDNumberPrivate, parent) { Q_D(QLCDNumber); d->ndigits = numDigits; d->init(); } void QLCDNumberPrivate::init() { Q_Q(QLCDNumber); q->setFrameStyle(QFrame::Box | QFrame::Raised); val = 0; base = QLCDNumber::Dec; smallPoint = false; q->setNumDigits(ndigits); q->setSegmentStyle(QLCDNumber::Filled); q->setSizePolicy(QSizePolicy(QSizePolicy::Minimum, QSizePolicy::Minimum)); } /*! Destroys the LCD number. */ QLCDNumber::~QLCDNumber() { } /*! \property QLCDNumber::numDigits \brief the current number of digits displayed Corresponds to the current number of digits. If \l QLCDNumber::smallDecimalPoint is false, the decimal point occupies one digit position. By default, this property contains a value of 5. \sa smallDecimalPoint */ void QLCDNumber::setNumDigits(int numDigits) { Q_D(QLCDNumber); if (numDigits > 99) { qWarning("QLCDNumber::setNumDigits: (%s) Max 99 digits allowed", objectName().toLocal8Bit().constData()); numDigits = 99; } if (numDigits < 0) { qWarning("QLCDNumber::setNumDigits: (%s) Min 0 digits allowed", objectName().toLocal8Bit().constData()); numDigits = 0; } if (d->digitStr.isNull()) { // from constructor d->ndigits = numDigits; d->digitStr.fill(QLatin1Char(' '), d->ndigits); d->points.fill(0, d->ndigits); d->digitStr[d->ndigits - 1] = QLatin1Char('0'); // "0" is the default number } else { bool doDisplay = d->ndigits == 0; if (numDigits == d->ndigits) // no change return; register int i; int dif; if (numDigits > d->ndigits) { // expand dif = numDigits - d->ndigits; QString buf; buf.fill(QLatin1Char(' '), dif); d->digitStr.insert(0, buf); d->points.resize(numDigits); for (i=numDigits-1; i>=dif; i--) d->points.setBit(i, d->points.testBit(i-dif)); for (i=0; ipoints.clearBit(i); } else { // shrink dif = d->ndigits - numDigits; d->digitStr = d->digitStr.right(numDigits); QBitArray tmpPoints = d->points; d->points.resize(numDigits); for (i=0; i<(int)numDigits; i++) d->points.setBit(i, tmpPoints.testBit(i+dif)); } d->ndigits = numDigits; if (doDisplay) display(value()); update(); } } int QLCDNumber::numDigits() const { Q_D(const QLCDNumber); return d->ndigits; } /*! \overload Returns true if \a num is too big to be displayed in its entirety; otherwise returns false. \sa display(), numDigits(), smallDecimalPoint() */ bool QLCDNumber::checkOverflow(int num) const { Q_D(const QLCDNumber); bool of; int2string(num, d->base, d->ndigits, &of); return of; } /*! Returns true if \a num is too big to be displayed in its entirety; otherwise returns false. \sa display(), numDigits(), smallDecimalPoint() */ bool QLCDNumber::checkOverflow(double num) const { Q_D(const QLCDNumber); bool of; double2string(num, d->base, d->ndigits, &of); return of; } /*! \property QLCDNumber::mode \brief the current display mode (number base) Corresponds to the current display mode, which is one of \c Bin, \c Oct, \c Dec (the default) and \c Hex. \c Dec mode can display floating point values, the other modes display the integer equivalent. \sa smallDecimalPoint(), setHexMode(), setDecMode(), setOctMode(), setBinMode() */ QLCDNumber::Mode QLCDNumber::mode() const { Q_D(const QLCDNumber); return (QLCDNumber::Mode) d->base; } void QLCDNumber::setMode(Mode m) { Q_D(QLCDNumber); d->base = m; display(d->val); } /*! \property QLCDNumber::value \brief the displayed value This property corresponds to the current value displayed by the LCDNumber. If the displayed value is not a number, the property has a value of 0. By default, this property contains a value of 0. */ double QLCDNumber::value() const { Q_D(const QLCDNumber); return d->val; } /*! \overload Displays the number \a num. */ void QLCDNumber::display(double num) { Q_D(QLCDNumber); d->val = num; bool of; QString s = double2string(d->val, d->base, d->ndigits, &of); if (of) emit overflow(); else d->internalSetString(s); } /*! \property QLCDNumber::intValue \brief the displayed value rounded to the nearest integer This property corresponds to the nearest integer to the current value displayed by the LCDNumber. This is the value used for hexadecimal, octal and binary modes. If the displayed value is not a number, the property has a value of 0. By default, this property contains a value of 0. */ int QLCDNumber::intValue() const { Q_D(const QLCDNumber); return qRound(d->val); } /*! \overload Displays the number \a num. */ void QLCDNumber::display(int num) { Q_D(QLCDNumber); d->val = (double)num; bool of; QString s = int2string(num, d->base, d->ndigits, &of); if (of) emit overflow(); else d->internalSetString(s); } /*! Displays the number represented by the string \a s. This version of the function disregards mode() and smallDecimalPoint(). These digits and other symbols can be shown: 0/O, 1, 2, 3, 4, 5/S, 6, 7, 8, 9/g, minus, decimal point, A, B, C, D, E, F, h, H, L, o, P, r, u, U, Y, colon, degree sign (which is specified as single quote in the string) and space. QLCDNumber substitutes spaces for illegal characters. */ void QLCDNumber::display(const QString &s) { Q_D(QLCDNumber); d->val = 0; bool ok = false; double v = s.toDouble(&ok); if (ok) d->val = v; d->internalSetString(s); } /*! Calls setMode(Hex). Provided for convenience (e.g. for connecting buttons to it). \sa setMode(), setDecMode(), setOctMode(), setBinMode(), mode() */ void QLCDNumber::setHexMode() { setMode(Hex); } /*! Calls setMode(Dec). Provided for convenience (e.g. for connecting buttons to it). \sa setMode(), setHexMode(), setOctMode(), setBinMode(), mode() */ void QLCDNumber::setDecMode() { setMode(Dec); } /*! Calls setMode(Oct). Provided for convenience (e.g. for connecting buttons to it). \sa setMode(), setHexMode(), setDecMode(), setBinMode(), mode() */ void QLCDNumber::setOctMode() { setMode(Oct); } /*! Calls setMode(Bin). Provided for convenience (e.g. for connecting buttons to it). \sa setMode(), setHexMode(), setDecMode(), setOctMode(), mode() */ void QLCDNumber::setBinMode() { setMode(Bin); } /*! \property QLCDNumber::smallDecimalPoint \brief the style of the decimal point If true the decimal point is drawn between two digit positions. Otherwise it occupies a digit position of its own, i.e. is drawn in a digit position. The default is false. The inter-digit space is made slightly wider when the decimal point is drawn between the digits. \sa mode */ void QLCDNumber::setSmallDecimalPoint(bool b) { Q_D(QLCDNumber); d->smallPoint = b; update(); } bool QLCDNumber::smallDecimalPoint() const { Q_D(const QLCDNumber); return d->smallPoint; } /*!\reimp */ void QLCDNumber::paintEvent(QPaintEvent *) { Q_D(QLCDNumber); QPainter p(this); drawFrame(&p); p.setRenderHint(QPainter::Antialiasing); if (d->shadow) p.translate(0.5, 0.5); if (d->smallPoint) d->drawString(d->digitStr, p, &d->points, false); else d->drawString(d->digitStr, p, 0, false); } void QLCDNumberPrivate::internalSetString(const QString& s) { Q_Q(QLCDNumber); QString buffer; int i; int len = s.length(); QBitArray newPoints(ndigits); if (!smallPoint) { if (len == ndigits) buffer = s; else buffer = s.right(ndigits).rightJustified(ndigits, QLatin1Char(' ')); } else { int index = -1; bool lastWasPoint = true; newPoints.clearBit(0); for (i=0; i=0; i--) { buffer[ndigits - 1 - index + i] = buffer[i]; newPoints.setBit(ndigits - 1 - index + i, newPoints.testBit(i)); } for(i=0; iupdate(); } /*! \internal */ void QLCDNumberPrivate::drawString(const QString &s, QPainter &p, QBitArray *newPoints, bool newString) { Q_Q(QLCDNumber); QPoint pos; int digitSpace = smallPoint ? 2 : 1; int xSegLen = q->width()*5/(ndigits*(5 + digitSpace) + digitSpace); int ySegLen = q->height()*5/12; int segLen = ySegLen > xSegLen ? xSegLen : ySegLen; int xAdvance = segLen*(5 + digitSpace)/5; int xOffset = (q->width() - ndigits*xAdvance + segLen/5)/2; int yOffset = (q->height() - segLen*2)/2; for (int i=0; itestBit(i) ? '.' : ' '; if (newString) { char oldPoint = points.testBit(i) ? '.' : ' '; drawDigit(pos, p, segLen, newPoint, oldPoint); } else { drawDigit(pos, p, segLen, newPoint); } } } if (newString) { digitStr = s; digitStr.truncate(ndigits); if (newPoints) points = *newPoints; } } /*! \internal */ void QLCDNumberPrivate::drawDigit(const QPoint &pos, QPainter &p, int segLen, char newCh, char oldCh) { // Draws and/or erases segments to change display of a single digit // from oldCh to newCh char updates[18][2]; // can hold 2 times number of segments, only // first 9 used if segment table is correct int nErases; int nUpdates; const char *segs; int i,j; const char erase = 0; const char draw = 1; const char leaveAlone = 2; segs = getSegments(oldCh); for (nErases=0; segs[nErases] != 99; nErases++) { updates[nErases][0] = erase; // get segments to erase to updates[nErases][1] = segs[nErases]; // remove old char } nUpdates = nErases; segs = getSegments(newCh); for(i = 0 ; segs[i] != 99 ; i++) { for (j=0; jpalette(); QColor lightColor,darkColor,fgColor; if (erase){ lightColor = pal.color(q->backgroundRole()); darkColor = lightColor; fgColor = lightColor; } else { lightColor = pal.light().color(); darkColor = pal.dark().color(); fgColor = pal.color(q->foregroundRole()); } #define LINETO(X,Y) addPoint(a, QPoint(pt.x() + (X),pt.y() + (Y))) #define LIGHT #define DARK if (fill) { QPolygon a(0); //The following is an exact copy of the switch below. //don't make any changes here switch (segmentNo) { case 0 : ppt = pt; LIGHT; LINETO(segLen - 1,0); DARK; LINETO(segLen - width - 1,width); LINETO(width,width); LINETO(0,0); break; case 1 : pt += QPoint(0 , 1); ppt = pt; LIGHT; LINETO(width,width); DARK; LINETO(width,segLen - width/2 - 2); LINETO(0,segLen - 2); LIGHT; LINETO(0,0); break; case 2 : pt += QPoint(segLen - 1 , 1); ppt = pt; DARK; LINETO(0,segLen - 2); LINETO(-width,segLen - width/2 - 2); LIGHT; LINETO(-width,width); LINETO(0,0); break; case 3 : pt += QPoint(0 , segLen); ppt = pt; LIGHT; LINETO(width,-width/2); LINETO(segLen - width - 1,-width/2); LINETO(segLen - 1,0); DARK; if (width & 1) { // adjust for integer division error LINETO(segLen - width - 3,width/2 + 1); LINETO(width + 2,width/2 + 1); } else { LINETO(segLen - width - 1,width/2); LINETO(width,width/2); } LINETO(0,0); break; case 4 : pt += QPoint(0 , segLen + 1); ppt = pt; LIGHT; LINETO(width,width/2); DARK; LINETO(width,segLen - width - 2); LINETO(0,segLen - 2); LIGHT; LINETO(0,0); break; case 5 : pt += QPoint(segLen - 1 , segLen + 1); ppt = pt; DARK; LINETO(0,segLen - 2); LINETO(-width,segLen - width - 2); LIGHT; LINETO(-width,width/2); LINETO(0,0); break; case 6 : pt += QPoint(0 , segLen*2); ppt = pt; LIGHT; LINETO(width,-width); LINETO(segLen - width - 1,-width); LINETO(segLen - 1,0); DARK; LINETO(0,0); break; case 7 : if (smallPoint) // if smallpoint place'.' between other digits pt += QPoint(segLen + width/2 , segLen*2); else pt += QPoint(segLen/2 , segLen*2); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; case 8 : pt += QPoint(segLen/2 - width/2 + 1 , segLen/2 + width); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; case 9 : pt += QPoint(segLen/2 - width/2 + 1 , 3*segLen/2 + width); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; default : qWarning("QLCDNumber::drawSegment: (%s) Illegal segment id: %d\n", q->objectName().toLocal8Bit().constData(), segmentNo); } // End exact copy p.setPen(Qt::NoPen); p.setBrush(fgColor); p.drawPolygon(a); p.setBrush(Qt::NoBrush); pt = pos; } #undef LINETO #undef LIGHT #undef DARK #define LINETO(X,Y) p.drawLine(ppt.x(), ppt.y(), pt.x()+(X), pt.y()+(Y)); \ ppt = QPoint(pt.x()+(X), pt.y()+(Y)) #define LIGHT p.setPen(lightColor) #define DARK p.setPen(darkColor) if (shadow) switch (segmentNo) { case 0 : ppt = pt; LIGHT; LINETO(segLen - 1,0); DARK; LINETO(segLen - width - 1,width); LINETO(width,width); LINETO(0,0); break; case 1 : pt += QPoint(0,1); ppt = pt; LIGHT; LINETO(width,width); DARK; LINETO(width,segLen - width/2 - 2); LINETO(0,segLen - 2); LIGHT; LINETO(0,0); break; case 2 : pt += QPoint(segLen - 1 , 1); ppt = pt; DARK; LINETO(0,segLen - 2); LINETO(-width,segLen - width/2 - 2); LIGHT; LINETO(-width,width); LINETO(0,0); break; case 3 : pt += QPoint(0 , segLen); ppt = pt; LIGHT; LINETO(width,-width/2); LINETO(segLen - width - 1,-width/2); LINETO(segLen - 1,0); DARK; if (width & 1) { // adjust for integer division error LINETO(segLen - width - 3,width/2 + 1); LINETO(width + 2,width/2 + 1); } else { LINETO(segLen - width - 1,width/2); LINETO(width,width/2); } LINETO(0,0); break; case 4 : pt += QPoint(0 , segLen + 1); ppt = pt; LIGHT; LINETO(width,width/2); DARK; LINETO(width,segLen - width - 2); LINETO(0,segLen - 2); LIGHT; LINETO(0,0); break; case 5 : pt += QPoint(segLen - 1 , segLen + 1); ppt = pt; DARK; LINETO(0,segLen - 2); LINETO(-width,segLen - width - 2); LIGHT; LINETO(-width,width/2); LINETO(0,0); break; case 6 : pt += QPoint(0 , segLen*2); ppt = pt; LIGHT; LINETO(width,-width); LINETO(segLen - width - 1,-width); LINETO(segLen - 1,0); DARK; LINETO(0,0); break; case 7 : if (smallPoint) // if smallpoint place'.' between other digits pt += QPoint(segLen + width/2 , segLen*2); else pt += QPoint(segLen/2 , segLen*2); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; case 8 : pt += QPoint(segLen/2 - width/2 + 1 , segLen/2 + width); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; case 9 : pt += QPoint(segLen/2 - width/2 + 1 , 3*segLen/2 + width); ppt = pt; DARK; LINETO(width,0); LINETO(width,-width); LIGHT; LINETO(0,-width); LINETO(0,0); break; default : qWarning("QLCDNumber::drawSegment: (%s) Illegal segment id: %d\n", q->objectName().toLocal8Bit().constData(), segmentNo); } #undef LINETO #undef LIGHT #undef DARK } /*! \property QLCDNumber::segmentStyle \brief the style of the LCDNumber \table \header \i Style \i Result \row \i \c Outline \i Produces raised segments filled with the background color \row \i \c Filled (this is the default). \i Produces raised segments filled with the foreground color. \row \i \c Flat \i Produces flat segments filled with the foreground color. \endtable \c Outline and \c Filled will additionally use QPalette::light() and QPalette::dark() for shadow effects. */ void QLCDNumber::setSegmentStyle(SegmentStyle s) { Q_D(QLCDNumber); d->fill = (s == Flat || s == Filled); d->shadow = (s == Outline || s == Filled); update(); } QLCDNumber::SegmentStyle QLCDNumber::segmentStyle() const { Q_D(const QLCDNumber); Q_ASSERT(d->fill || d->shadow); if (!d->fill && d->shadow) return Outline; if (d->fill && d->shadow) return Filled; return Flat; } /*!\reimp */ QSize QLCDNumber::sizeHint() const { return QSize(10 + 9 * (numDigits() + (smallDecimalPoint() ? 0 : 1)), 23); } /*! \reimp */ bool QLCDNumber::event(QEvent *e) { return QFrame::event(e); } /*! \fn void QLCDNumber::setMargin(int margin) Sets the width of the margin around the contents of the widget to \a margin. Use QWidget::setContentsMargins() instead. \sa margin(), QWidget::setContentsMargins() */ /*! \fn int QLCDNumber::margin() const Returns the width of the margin around the contents of the widget. Use QWidget::getContentsMargins() instead. \sa setMargin(), QWidget::getContentsMargins() */ QT_END_NAMESPACE #endif // QT_NO_LCDNUMBER