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201 lines
4.9 KiB
C++
201 lines
4.9 KiB
C++
//========= Copyright Valve Corporation, All rights reserved. ============//
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#include "movieobjects/timeutils.h"
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#include "tier0/dbg.h"
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#include "mathlib/mathlib.h"
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#include <math.h>
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////////////////////////////////////////////////////////////////////////////////////////
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//
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// DmeFramerate_t
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//
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// exact (rational) representation of common framerates - any integral or ntsc framerate
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//
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////////////////////////////////////////////////////////////////////////////////////////
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DmeFramerate_t::DmeFramerate_t( float fps )
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{
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SetFramerate( fps );
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}
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DmeFramerate_t::DmeFramerate_t( int fps /*= 0*/ ) :
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m_num( fps ), m_den( 10000 )
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{
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}
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DmeFramerate_t::DmeFramerate_t( int nNumerator, int nDenominator ) :
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m_num( nNumerator ), m_den( nDenominator * 10000 )
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{
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}
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void DmeFramerate_t::SetFramerate( float flFrameRate )
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{
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if ( IsIntegralValue( flFrameRate ) )
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{
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SetFramerate( RoundFloatToInt( flFrameRate ) );
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}
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else if ( IsIntegralValue( flFrameRate * 1001.0f / 1000.0f ) ) // 1001 is the ntsc divisor (30*1000/1001 = 29.97, etc)
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{
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SetFramerateNTSC( RoundFloatToInt( flFrameRate * 1001.0f / 1000.0f ) );
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}
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else
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{
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Assert( 0 );
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SetFramerate( RoundFloatToInt( flFrameRate ) );
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}
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}
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void DmeFramerate_t::SetFramerate( int fps )
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{
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m_num = fps;
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m_den = 10000;
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}
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// other (uncommon) options besides 30(29.97 - ntsc video) are 24 (23.976 - ntsc film) and 60 (59.94 - ntsc progressive)
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void DmeFramerate_t::SetFramerateNTSC( int multiplier /*= 30*/ )
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{
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// ntsc = 30 fps * 1000 / 1001
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// = ( 30 / 10000 fptms ) * 1000 / 1001
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// = 30 / 10010
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m_num = multiplier;
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m_den = 10010;
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}
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float DmeFramerate_t::GetFramesPerSecond() const
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{
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return 10000.0f * m_num / float( m_den );
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}
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////////////////////////////////////////////////////////////////////////////////////////
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//
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// DmeTime_t
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//
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// representing time as integral tenths of a millisecond (tms)
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//
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////////////////////////////////////////////////////////////////////////////////////////
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DmeTime_t::DmeTime_t( int frame, DmeFramerate_t framerate )
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{
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int64 num = int64( framerate.m_num );
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int64 prod = frame * int64( framerate.m_den );
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// add signed offset to force integer truncation (towards 0) to give us truncation towards -inf
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if ( frame < 0 )
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{
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prod -= num - 1;
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}
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m_tms = int( prod / num ); // round tms towards 0
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}
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// float operators - comment these out to find potentially incorrect uses of DmeTime_t
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DmeTime_t DmeTime_t::operator*=( float f )
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{
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m_tms = int( floor( m_tms * f + 0.5f ) );
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return *this;
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}
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DmeTime_t DmeTime_t::operator/=( float f )
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{
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m_tms = int( floor( m_tms / f + 0.5f ) );
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return *this;
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}
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// helper methods
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void DmeTime_t::Clamp( DmeTime_t lo, DmeTime_t hi )
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{
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m_tms = clamp( m_tms, lo.m_tms, hi.m_tms );
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}
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bool DmeTime_t::IsInRange( DmeTime_t lo, DmeTime_t hi ) const
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{
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return m_tms >= lo.m_tms && m_tms < hi.m_tms;
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}
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// helper functions
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float GetFractionOfTimeBetween( DmeTime_t t, DmeTime_t start, DmeTime_t end, bool bClamp /*= false*/ )
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{
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return GetFractionOfTime( t - start, end - start, bClamp );
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}
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float GetFractionOfTime( DmeTime_t t, DmeTime_t duration, bool bClamp /*= false*/ )
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{
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if ( duration == DMETIME_ZERO )
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return 0.0f;
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if ( bClamp )
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{
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t.Clamp( DMETIME_ZERO, duration );
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}
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return t.m_tms / float( duration.m_tms );
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}
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int FrameForTime( DmeTime_t t, DmeFramerate_t framerate )
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{
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return t.CurrentFrame( framerate );
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}
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// framerate-dependent conversions to/from frames
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int DmeTime_t::CurrentFrame( DmeFramerate_t framerate, bool bRoundDown ) const
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{
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int64 den = int64( framerate.m_den );
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int64 num = int64( framerate.m_num );
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int64 prod = int64( m_tms ) * num;
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// times within this range are considered on a frame: (frame*den/num - 1, frame*den/num]
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// this follows from the truncation towards -inf behavior of the frame,framerate constructor above
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// the following logic is there to ensure the above rule,
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// while working around the truncation towards 0 behavior of integer divide
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if ( m_tms < 0 )
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{
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if ( bRoundDown )
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prod -= den - num;
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}
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else
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{
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if ( bRoundDown )
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prod += num - 1;
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else
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prod += den - 1;
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}
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return int( prod / den );
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}
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DmeTime_t DmeTime_t::TimeAtCurrentFrame( DmeFramerate_t framerate, bool bRoundDown ) const
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{
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int frame = CurrentFrame( framerate, bRoundDown );
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return DmeTime_t( frame, framerate );
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}
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DmeTime_t DmeTime_t::TimeAtNextFrame( DmeFramerate_t framerate ) const
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{
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// since we always round towards -inf, go to next frame whether we're on a frame or not
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int frame = CurrentFrame( framerate, true );
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return DmeTime_t( frame + 1, framerate );
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}
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DmeTime_t DmeTime_t::TimeAtPrevFrame( DmeFramerate_t framerate ) const
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{
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int frame = CurrentFrame( framerate, false );
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return DmeTime_t( frame - 1, framerate ); // we're exactly on a frame
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}
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int DmeTime_t::RoundSecondsToTMS( float sec )
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{
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return floor( 10000.0f * sec + 0.5f ); // round at half-tms boundary
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}
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int DmeTime_t::RoundSecondsToTMS( double sec )
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{
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return floor( 10000.0 * sec + 0.5 ); // round at half-tms boundary
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}
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