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/*************************************************************************
*
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* Copyright 2008 by Sun Microsystems, Inc.
*
* OpenOffice.org - a multi-platform office productivity suite
*
* $RCSfile: simplecontinuousactivitybase.cxx,v $
* $Revision: 1.11 $
*
* This file is part of OpenOffice.org.
*
* OpenOffice.org is free software: you can redistribute it and/or modify
* it under the terms of the GNU Lesser General Public License version 3
* only, as published by the Free Software Foundation.
*
* OpenOffice.org is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU Lesser General Public License version 3 for more details
* (a copy is included in the LICENSE file that accompanied this code).
*
* You should have received a copy of the GNU Lesser General Public License
* version 3 along with OpenOffice.org. If not, see
* <http://www.openoffice.org/license.html>
* for a copy of the LGPLv3 License.
*
************************************************************************/
// MARKER(update_precomp.py): autogen include statement, do not remove
#include "precompiled_slideshow.hxx"
// must be first
#include <canvas/debug.hxx>
#include <canvas/verbosetrace.hxx>
#include <simplecontinuousactivitybase.hxx>
namespace slideshow
{
namespace internal
{
SimpleContinuousActivityBase::SimpleContinuousActivityBase(
const ActivityParameters& rParms ) :
ActivityBase( rParms ),
maTimer( rParms.mrActivitiesQueue.getTimer() ),
mnMinSimpleDuration( rParms.mnMinDuration ),
mnMinNumberOfFrames( rParms.mnMinNumberOfFrames ),
mnCurrPerformCalls( 0 )
{
}
void SimpleContinuousActivityBase::startAnimation()
{
// init timer. We measure animation time only when we're
// actually started.
maTimer.reset();
}
double SimpleContinuousActivityBase::calcTimeLag() const
{
ActivityBase::calcTimeLag();
if (! isActive())
return 0.0;
// retrieve locally elapsed time
const double nCurrElapsedTime( maTimer.getElapsedTime() );
// log time
VERBOSE_TRACE( "SimpleContinuousActivityBase::calcTimeLag(): "
"next step is based on time: %f", nCurrElapsedTime );
// go to great length to ensure a proper animation
// run. Since we don't know how often we will be called
// here, try to spread the animator calls uniquely over
// the [0,1] parameter range. Be aware of the fact that
// perform will be called at least mnMinNumberOfTurns
// times.
// fraction of time elapsed
const double nFractionElapsedTime(
nCurrElapsedTime / mnMinSimpleDuration );
// fraction of minimum calls performed
const double nFractionRequiredCalls(
double(mnCurrPerformCalls) / mnMinNumberOfFrames );
// okay, so now, the decision is easy:
//
// If the fraction of time elapsed is smaller than the
// number of calls required to be performed, then we calc
// the position on the animation range according to
// elapsed time. That is, we're so to say ahead of time.
//
// In contrary, if the fraction of time elapsed is larger,
// then we're lagging, and we thus calc the position on
// the animation time line according to the fraction of
// calls performed. Thus, the animation is forced to slow
// down, and take the required minimal number of steps,
// sufficiently equally distributed across the animation
// time line.
if( nFractionElapsedTime < nFractionRequiredCalls )
{
VERBOSE_TRACE( "SimpleContinuousActivityBase::calcTimeLag(): "
"t=%f is based on time", nFractionElapsedTime );
return 0.0;
}
else
{
VERBOSE_TRACE( "SimpleContinuousActivityBase::perform(): "
"t=%f is based on number of calls",
nFractionRequiredCalls );
// lag global time, so all other animations lag, too:
return ((nFractionElapsedTime - nFractionRequiredCalls)
* mnMinSimpleDuration);
}
}
bool SimpleContinuousActivityBase::perform()
{
// call base class, for start() calls and end handling
if( !ActivityBase::perform() )
return false; // done, we're ended
// get relative animation position
// ===============================
const double nCurrElapsedTime( maTimer.getElapsedTime() );
double nT( nCurrElapsedTime / mnMinSimpleDuration );
// one of the stop criteria reached?
// =================================
// will be set to true below, if one of the termination criteria
// matched.
bool bActivityEnding( false );
if( isRepeatCountValid() )
{
// Finite duration
// ===============
// When we've autoreverse on, the repeat count
// doubles
const double nRepeatCount( getRepeatCount() );
const double nEffectiveRepeat( isAutoReverse() ?
2.0*nRepeatCount :
nRepeatCount );
// time (or frame count) elapsed?
if( nEffectiveRepeat <= nT )
{
// okee. done for now. Will not exit right here,
// to give animation the chance to render the last
// frame below
bActivityEnding = true;
// clamp animation to max permissible value
nT = nEffectiveRepeat;
}
}
// need to do auto-reverse?
// ========================
double nRepeats;
double nRelativeSimpleTime;
// TODO(Q3): Refactor this mess
if( isAutoReverse() )
{
// divert active duration into repeat and
// fractional part.
const double nFractionalActiveDuration( modf(nT, &nRepeats) );
// for auto-reverse, map ranges [1,2), [3,4), ...
// to ranges [0,1), [1,2), etc.
if( ((int)nRepeats) % 2 )
{
// we're in an odd range, reverse sweep
nRelativeSimpleTime = 1.0 - nFractionalActiveDuration;
}
else
{
// we're in an even range, pass on as is
nRelativeSimpleTime = nFractionalActiveDuration;
}
// effective repeat count for autoreverse is half of
// the input time's value (each run of an autoreverse
// cycle is half of a repeat)
nRepeats /= 2;
}
else
{
// determine repeat
// ================
// calc simple time and number of repeats from nT
// Now, that's easy, since the fractional part of
// nT gives the relative simple time, and the
// integer part the number of full repeats:
nRelativeSimpleTime = modf(nT, &nRepeats);
// clamp repeats to max permissible value (maRepeats.getValue() - 1.0)
if( isRepeatCountValid() &&
nRepeats >= getRepeatCount() )
{
// Note that this code here only gets
// triggered if maRepeats.getValue() is an
// _integer_. Otherwise, nRepeats will never
// reach nor exceed
// maRepeats.getValue(). Thus, the code below
// does not need to handle cases of fractional
// repeats, and can always assume that a full
// animation run has ended (with
// nRelativeSimpleTime=1.0 for
// non-autoreversed activities).
// with modf, nRelativeSimpleTime will never
// become 1.0, since nRepeats is incremented and
// nRelativeSimpleTime set to 0.0 then.
//
// For the animation to reach its final value,
// nRepeats must although become
// maRepeats.getValue()-1.0, and
// nRelativeSimpleTime=1.0.
nRelativeSimpleTime = 1.0;
nRepeats -= 1.0;
}
}
// actually perform something
// ==========================
simplePerform( nRelativeSimpleTime,
// nRepeats is already integer-valued
static_cast<sal_uInt32>( nRepeats ) );
// delayed endActivity() call from end condition check
// below. Issued after the simplePerform() call above, to
// give animations the chance to correctly reach the
// animation end value, without spurious bail-outs because
// of isActive() returning false.
if( bActivityEnding )
endActivity();
// one more frame successfully performed
++mnCurrPerformCalls;
return isActive();
}
}
}
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