483 lines
14 KiB
C++
483 lines
14 KiB
C++
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/*
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File: CAVolumeCurve.cpp
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Abstract: CAVolumeCurve.h
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Version: 1.1
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Disclaimer: IMPORTANT: This Apple software is supplied to you by Apple
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Inc. ("Apple") in consideration of your agreement to the following
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terms, and your use, installation, modification or redistribution of
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this Apple software constitutes acceptance of these terms. If you do
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not agree with these terms, please do not use, install, modify or
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redistribute this Apple software.
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In consideration of your agreement to abide by the following terms, and
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subject to these terms, Apple grants you a personal, non-exclusive
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license, under Apple's copyrights in this original Apple software (the
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"Apple Software"), to use, reproduce, modify and redistribute the Apple
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Software, with or without modifications, in source and/or binary forms;
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provided that if you redistribute the Apple Software in its entirety and
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without modifications, you must retain this notice and the following
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text and disclaimers in all such redistributions of the Apple Software.
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Neither the name, trademarks, service marks or logos of Apple Inc. may
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be used to endorse or promote products derived from the Apple Software
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without specific prior written permission from Apple. Except as
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expressly stated in this notice, no other rights or licenses, express or
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implied, are granted by Apple herein, including but not limited to any
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patent rights that may be infringed by your derivative works or by other
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works in which the Apple Software may be incorporated.
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The Apple Software is provided by Apple on an "AS IS" basis. APPLE
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MAKES NO WARRANTIES, EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION
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THE IMPLIED WARRANTIES OF NON-INFRINGEMENT, MERCHANTABILITY AND FITNESS
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FOR A PARTICULAR PURPOSE, REGARDING THE APPLE SOFTWARE OR ITS USE AND
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OPERATION ALONE OR IN COMBINATION WITH YOUR PRODUCTS.
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IN NO EVENT SHALL APPLE BE LIABLE FOR ANY SPECIAL, INDIRECT, INCIDENTAL
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OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
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SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
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INTERRUPTION) ARISING IN ANY WAY OUT OF THE USE, REPRODUCTION,
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MODIFICATION AND/OR DISTRIBUTION OF THE APPLE SOFTWARE, HOWEVER CAUSED
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AND WHETHER UNDER THEORY OF CONTRACT, TORT (INCLUDING NEGLIGENCE),
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STRICT LIABILITY OR OTHERWISE, EVEN IF APPLE HAS BEEN ADVISED OF THE
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POSSIBILITY OF SUCH DAMAGE.
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Copyright (C) 2014 Apple Inc. All Rights Reserved.
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*/
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//=============================================================================
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// Includes
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//=============================================================================
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#include "CAVolumeCurve.h"
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#include "CADebugMacros.h"
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#include <math.h>
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//=============================================================================
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// CAVolumeCurve
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//=============================================================================
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CAVolumeCurve::CAVolumeCurve()
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:
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mTag(0),
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mCurveMap(),
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mIsApplyingTransferFunction(true),
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mTransferFunction(kPow2Over1Curve),
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mRawToScalarExponentNumerator(2.0f),
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mRawToScalarExponentDenominator(1.0f)
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{
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}
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CAVolumeCurve::~CAVolumeCurve()
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{
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}
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SInt32 CAVolumeCurve::GetMinimumRaw() const
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{
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SInt32 theAnswer = 0;
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if(!mCurveMap.empty())
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{
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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theAnswer = theIterator->first.mMinimum;
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}
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return theAnswer;
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}
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SInt32 CAVolumeCurve::GetMaximumRaw() const
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{
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SInt32 theAnswer = 0;
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if(!mCurveMap.empty())
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{
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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std::advance(theIterator, static_cast<int>(mCurveMap.size() - 1));
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theAnswer = theIterator->first.mMaximum;
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}
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return theAnswer;
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}
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Float32 CAVolumeCurve::GetMinimumDB() const
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{
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Float32 theAnswer = 0;
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if(!mCurveMap.empty())
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{
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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theAnswer = theIterator->second.mMinimum;
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}
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return theAnswer;
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}
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Float32 CAVolumeCurve::GetMaximumDB() const
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{
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Float32 theAnswer = 0;
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if(!mCurveMap.empty())
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{
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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std::advance(theIterator, static_cast<int>(mCurveMap.size() - 1));
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theAnswer = theIterator->second.mMaximum;
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}
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return theAnswer;
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}
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void CAVolumeCurve::SetTransferFunction(UInt32 inTransferFunction)
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{
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mTransferFunction = inTransferFunction;
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// figure out the co-efficients
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switch(inTransferFunction)
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{
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case kLinearCurve:
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mIsApplyingTransferFunction = false;
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mRawToScalarExponentNumerator = 1.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow1Over3Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 1.0f;
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mRawToScalarExponentDenominator = 3.0f;
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break;
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case kPow1Over2Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 1.0f;
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mRawToScalarExponentDenominator = 2.0f;
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break;
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case kPow3Over4Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 3.0f;
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mRawToScalarExponentDenominator = 4.0f;
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break;
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case kPow3Over2Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 3.0f;
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mRawToScalarExponentDenominator = 2.0f;
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break;
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case kPow2Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 2.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow3Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 3.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow4Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 4.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow5Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 5.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow6Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 6.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow7Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 7.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow8Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 8.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow9Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 9.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow10Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 10.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow11Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 11.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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case kPow12Over1Curve:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 12.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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default:
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mIsApplyingTransferFunction = true;
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mRawToScalarExponentNumerator = 2.0f;
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mRawToScalarExponentDenominator = 1.0f;
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break;
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};
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}
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void CAVolumeCurve::AddRange(SInt32 inMinRaw, SInt32 inMaxRaw, Float32 inMinDB, Float32 inMaxDB)
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{
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CARawPoint theRaw(inMinRaw, inMaxRaw);
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CADBPoint theDB(inMinDB, inMaxDB);
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bool isOverlapped = false;
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bool isDone = false;
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CurveMap::iterator theIterator = mCurveMap.begin();
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while((theIterator != mCurveMap.end()) && !isOverlapped && !isDone)
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{
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isOverlapped = CARawPoint::Overlap(theRaw, theIterator->first);
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isDone = theRaw >= theIterator->first;
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if(!isOverlapped && !isDone)
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{
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std::advance(theIterator, 1);
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}
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}
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if(!isOverlapped)
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{
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mCurveMap.insert(CurveMap::value_type(theRaw, theDB));
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}
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else
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{
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DebugMessage("CAVolumeCurve::AddRange: new point overlaps");
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}
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}
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void CAVolumeCurve::ResetRange()
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{
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mCurveMap.clear();
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}
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bool CAVolumeCurve::CheckForContinuity() const
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{
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bool theAnswer = true;
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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if(theIterator != mCurveMap.end())
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{
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SInt32 theRaw = theIterator->first.mMinimum;
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Float32 theDB = theIterator->second.mMinimum;
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do
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{
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SInt32 theRawMin = theIterator->first.mMinimum;
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SInt32 theRawMax = theIterator->first.mMaximum;
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SInt32 theRawRange = theRawMax - theRawMin;
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Float32 theDBMin = theIterator->second.mMinimum;
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Float32 theDBMax = theIterator->second.mMaximum;
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Float32 theDBRange = theDBMax - theDBMin;
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theAnswer = theRaw == theRawMin;
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theAnswer = theAnswer && (theDB == theDBMin);
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theRaw += theRawRange;
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theDB += theDBRange;
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std::advance(theIterator, 1);
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}
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while((theIterator != mCurveMap.end()) && theAnswer);
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}
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return theAnswer;
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}
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SInt32 CAVolumeCurve::ConvertDBToRaw(Float32 inDB) const
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{
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// clamp the value to the dB range
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Float32 theOverallDBMin = GetMinimumDB();
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Float32 theOverallDBMax = GetMaximumDB();
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if(inDB < theOverallDBMin) inDB = theOverallDBMin;
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if(inDB > theOverallDBMax) inDB = theOverallDBMax;
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// get the first entry in the curve map;
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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// initialize the answer to the minimum raw of the first item in the curve map
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SInt32 theAnswer = theIterator->first.mMinimum;
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// iterate through the curve map until we run out of dB
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bool isDone = false;
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while(!isDone && (theIterator != mCurveMap.end()))
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{
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SInt32 theRawMin = theIterator->first.mMinimum;
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SInt32 theRawMax = theIterator->first.mMaximum;
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SInt32 theRawRange = theRawMax - theRawMin;
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Float32 theDBMin = theIterator->second.mMinimum;
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Float32 theDBMax = theIterator->second.mMaximum;
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Float32 theDBRange = theDBMax - theDBMin;
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Float32 theDBPerRaw = theDBRange / static_cast<Float32>(theRawRange);
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// figure out how many steps we are into this entry in the curve map
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if(inDB > theDBMax)
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{
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// we're past the end of this one, so add in the whole range for this entry
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theAnswer += theRawRange;
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}
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else
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{
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// it's somewhere within the current entry
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// figure out how many steps it is
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Float32 theNumberRawSteps = inDB - theDBMin;
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theNumberRawSteps /= theDBPerRaw;
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// only move in whole steps
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theNumberRawSteps = roundf(theNumberRawSteps);
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// add this many steps to the answer
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theAnswer += static_cast<SInt32>(theNumberRawSteps);
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// mark that we are done
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isDone = true;
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}
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// go to the next entry in the curve map
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std::advance(theIterator, 1);
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}
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return theAnswer;
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}
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Float32 CAVolumeCurve::ConvertRawToDB(SInt32 inRaw) const
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{
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Float32 theAnswer = 0;
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// clamp the raw value
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SInt32 theOverallRawMin = GetMinimumRaw();
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SInt32 theOverallRawMax = GetMaximumRaw();
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if(inRaw < theOverallRawMin) inRaw = theOverallRawMin;
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if(inRaw > theOverallRawMax) inRaw = theOverallRawMax;
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// figure out how many raw steps need to be taken from the first one
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SInt32 theNumberRawSteps = inRaw - theOverallRawMin;
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// get the first item in the curve map
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CurveMap::const_iterator theIterator = mCurveMap.begin();
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// initialize the answer to the minimum dB of the first item in the curve map
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theAnswer = theIterator->second.mMinimum;
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// iterate through the curve map until we run out of steps
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while((theNumberRawSteps > 0) && (theIterator != mCurveMap.end()))
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{
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// compute some values
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SInt32 theRawMin = theIterator->first.mMinimum;
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SInt32 theRawMax = theIterator->first.mMaximum;
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SInt32 theRawRange = theRawMax - theRawMin;
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Float32 theDBMin = theIterator->second.mMinimum;
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Float32 theDBMax = theIterator->second.mMaximum;
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Float32 theDBRange = theDBMax - theDBMin;
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Float32 theDBPerRaw = theDBRange / static_cast<Float32>(theRawRange);
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// there might be more steps than the current map entry accounts for
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SInt32 theRawStepsToAdd = std::min(theRawRange, theNumberRawSteps);
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// add this many steps worth of db to the answer;
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theAnswer += theRawStepsToAdd * theDBPerRaw;
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// figure out how many steps are left
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theNumberRawSteps -= theRawStepsToAdd;
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// go to the next map entry
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std::advance(theIterator, 1);
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}
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return theAnswer;
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}
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Float32 CAVolumeCurve::ConvertRawToScalar(SInt32 inRaw) const
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{
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// get some important values
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Float32 theDBMin = GetMinimumDB();
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Float32 theDBMax = GetMaximumDB();
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Float32 theDBRange = theDBMax - theDBMin;
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SInt32 theRawMin = GetMinimumRaw();
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SInt32 theRawMax = GetMaximumRaw();
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SInt32 theRawRange = theRawMax - theRawMin;
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// range the raw value
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if(inRaw < theRawMin) inRaw = theRawMin;
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if(inRaw > theRawMax) inRaw = theRawMax;
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// calculate the distance in the range inRaw is
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Float32 theAnswer = static_cast<Float32>(inRaw - theRawMin) / static_cast<Float32>(theRawRange);
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// only apply a curve to the scalar values if the dB range is greater than 30
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if(mIsApplyingTransferFunction && (theDBRange > 30.0f))
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{
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theAnswer = powf(theAnswer, mRawToScalarExponentNumerator / mRawToScalarExponentDenominator);
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}
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return theAnswer;
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}
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||
|
Float32 CAVolumeCurve::ConvertDBToScalar(Float32 inDB) const
|
||
|
{
|
||
|
SInt32 theRawValue = ConvertDBToRaw(inDB);
|
||
|
Float32 theAnswer = ConvertRawToScalar(theRawValue);
|
||
|
return theAnswer;
|
||
|
}
|
||
|
|
||
|
SInt32 CAVolumeCurve::ConvertScalarToRaw(Float32 inScalar) const
|
||
|
{
|
||
|
// range the scalar value
|
||
|
inScalar = std::min(1.0f, std::max(0.0f, inScalar));
|
||
|
|
||
|
// get some important values
|
||
|
Float32 theDBMin = GetMinimumDB();
|
||
|
Float32 theDBMax = GetMaximumDB();
|
||
|
Float32 theDBRange = theDBMax - theDBMin;
|
||
|
SInt32 theRawMin = GetMinimumRaw();
|
||
|
SInt32 theRawMax = GetMaximumRaw();
|
||
|
SInt32 theRawRange = theRawMax - theRawMin;
|
||
|
|
||
|
// have to undo the curve if the dB range is greater than 30
|
||
|
if(mIsApplyingTransferFunction && (theDBRange > 30.0f))
|
||
|
{
|
||
|
inScalar = powf(inScalar, mRawToScalarExponentDenominator / mRawToScalarExponentNumerator);
|
||
|
}
|
||
|
|
||
|
// now we can figure out how many raw steps this is
|
||
|
Float32 theNumberRawSteps = inScalar * static_cast<Float32>(theRawRange);
|
||
|
theNumberRawSteps = roundf(theNumberRawSteps);
|
||
|
|
||
|
// the answer is the minimum raw value plus the number of raw steps
|
||
|
SInt32 theAnswer = theRawMin + static_cast<SInt32>(theNumberRawSteps);
|
||
|
|
||
|
return theAnswer;
|
||
|
}
|
||
|
|
||
|
Float32 CAVolumeCurve::ConvertScalarToDB(Float32 inScalar) const
|
||
|
{
|
||
|
SInt32 theRawValue = ConvertScalarToRaw(inScalar);
|
||
|
Float32 theAnswer = ConvertRawToDB(theRawValue);
|
||
|
return theAnswer;
|
||
|
}
|