public void OnEnable()
{
dnaRange = target as DNARangeAsset;
if (dnaRange.dnaConverter != null)
{
dnaSource = dnaRange.dnaConverter.DNAType.GetConstructor(System.Type.EmptyTypes).Invoke(null) as UMADnaBase;
if (dnaSource != null)
entryCount = dnaSource.Count;
}
}
public IDNAConverter GetConverter(UMADnaBase DNA)
{
/*foreach (DnaConverterBehaviour dcb in _dnaConverterList)
* {
* if (dcb.DNATypeHash == DNA.DNATypeHash)
* return dcb;
* }*/
for (int i = 0; i < _dnaConverterList.Count; i++)
{
if (_dnaConverterList[i].DNATypeHash == DNA.DNATypeHash)
{
return(_dnaConverterList[i]);
}
}
return(null);
}
public float GetUmaDNAValue(string DNATypeName, UMADnaBase umaDnaIn)
{
if (umaDnaIn == null)
{
return(0.5f);
}
DynamicUMADnaBase umaDna = (DynamicUMADnaBase)umaDnaIn;
float val = 0.5f;
if (DNATypeName == "None" || umaDna == null)
{
return(val);
}
val = umaDna.GetValue(DNATypeName, true); //implimented a 'failSilently' option here because recipes may have dna in that the dna asset no longer has
return(val);
}
//TODO methods for screwing with the reducer dnas? Better if we can use fancy properties with indexers
public void ApplyDNA(UMAData umaData, UMASkeleton skeleton, UMADnaBase activeDNA, float masterWeight = 1f)
{
_liveShapeWeight = _startingShapeWeight;
//dna weight superceeds startingWeight if it exists
if (_modifyingDNA.UsedDNANames.Count > 0)
{
_liveShapeWeight = _modifyingDNA.Evaluate(activeDNA);
}
_liveShapeWeight = _liveShapeWeight * masterWeight;
//In Unity 2018.3+ blendshapes can have negative values too, so in that case allow the value to go to -1
#if !UNITY_2018_3_OR_NEWER
_liveShapeWeight = Mathf.Clamp(_liveShapeWeight, 0f, 1f);
#endif
umaData.SetBlendShape(_blendshapeToApply, _liveShapeWeight);
}
public void ApplyDNA(UMAData umaData, UMASkeleton skeleton, UMADnaBase activeDNA, float masterWeight = 1f)
{
if (_poseToApply == null)
{
if (Debug.isDebugBuild)
{
Debug.LogWarning(umaData.gameObject.name + " had an invalid or empty pose set in its BonePoseDNAConverters in its DNAConverterController");
}
return;
}
_livePoseWeight = _startingPoseWeight;
//dna weight superceeds startingWeight if it exists
if (_modifyingDNA.UsedDNANames.Count > 0)
{
_livePoseWeight = _modifyingDNA.Evaluate(activeDNA);
}
_livePoseWeight = _livePoseWeight * masterWeight;
_livePoseWeight = Mathf.Clamp(_livePoseWeight, 0f, 1f);
_poseToApply.ApplyPose(skeleton, _livePoseWeight);
}
/// <summary>
/// Uniformly randomizes each value in the DNA.
/// </summary>
/// <param name="data">UMA data.</param>
public void RandomizeDNA(UMAData data)
{
if (dnaConverter == null)
{
return;
}
UMADnaBase dna = data.GetDna(dnaConverter.DNATypeHash);
if (dna == null)
{
return;
}
int entryCount = dna.Count;
for (int i = 0; i < means.Length; i++)
{
dna.SetValue(i, means[i] + (Random.value - 0.5f) * spreads[i]);
}
}
/// <summary>
/// Finds the set dna name in the supplied dna list and applies the evaluator and multiplier to it.
/// Tip: if you are already looping through the dna to find the name/value just use Evaluate(float dnaValue) instead for efficiency
/// </summary>
/// <param name="dna">The dna to search</param>
/// <returns>The evaluated value</returns>
public float Evaluate(UMADnaBase dna)
{
//using lastIndex building dna takes apprx 00:00:00.0027695
//Using lastIndex modifying dna takes apprx 00:00:00.0004993
//notusing lastIndex building dna takes apprx 00:00:00.0035695
//notusing lastIndex modifying dna takes apprx 00:00:00.0008447
//using lastIndex is about 1/3 faster at the cost of being less robust because the dnaNames could in theory be changed at runtime and lastIndex would then fail
//could make the difference between being able to use things like color dna for wrinkle maps etc?
if (_lastIndex != -1)
{
return(Evaluate(dna.GetValue(_lastIndex)));
}
else
{
_lastIndex = System.Array.IndexOf(dna.Names, _dnaName);
if (_lastIndex > -1)
{
return(Evaluate(dna.GetValue(_lastIndex)));
}
}
return(defaultDNAValue);
}
/// <summary>
/// Uniformly randomizes each value in the DNA.
/// </summary>
/// <param name="data">UMA data.</param>
public void RandomizeDNA(UMAData data)
{
if (dnaConverter == null)
{
return;
}
UMADnaBase dna = data.GetDna(dnaConverter.DNATypeHash);
if (dna == null)
{
return;
}
int entryCount = dna.Count;
if (means.Length != entryCount)
{
if (Debug.isDebugBuild)
{
Debug.LogWarning("Range settings out of sync with DNA, cannot apply!");
}
return;
}
if ((values == null) || (values.Length != entryCount))
{
values = new float[entryCount];
}
for (int i = 0; i < entryCount; i++)
{
values[i] = means[i] + (Random.value - 0.5f) * spreads[i];
}
dna.Values = values;
}
/// <summary>
/// Randomizes each value in the DNA using a Gaussian distribution.
/// </summary>
/// <param name="data">UMA data.</param>
public void RandomizeDNAGaussian(UMAData data)
{
if (dnaConverter == null)
{
return;
}
UMADnaBase dna = data.GetDna(dnaConverter.DNATypeHash);
if (dna == null)
{
return;
}
int entryCount = dna.Count;
if (means.Length != entryCount)
{
if (Debug.isDebugBuild)
{
Debug.LogWarning("Range settings out of sync with DNA, cannot apply!");
}
return;
}
if (values == null)
{
values = new float[entryCount];
}
for (int i = 0; i < entryCount; i++)
{
values[i] = UMAUtils.GaussianRandom(means[i], deviations[i]);
}
dna.Values = values;
}
//TODO check if this still screws up the incoming dnas values
public UMADnaBase GetWeightedDNA(UMADnaBase incomingDna)
{
if (_masterWeightType == MasterWeightType.UseGlobalValue)
{
return(incomingDna);
}
var masterWeight = GetWeight(incomingDna);
var weightedDNA = new DynamicUMADna();
if (masterWeight > 0)
{
weightedDNA._names = new string[incomingDna.Names.Length];
Array.Copy(incomingDna.Names, weightedDNA._names, incomingDna.Names.Length);
weightedDNA._values = new float[incomingDna.Values.Length];
Array.Copy(incomingDna.Values, weightedDNA._values, incomingDna.Values.Length);
for (int i = 0; i < incomingDna.Count; i++)
{
weightedDNA.SetValue(i, weightedDNA.GetValue(i) * masterWeight);
}
}
return(weightedDNA);
}
/// <summary>
/// Calls ApplyDNA on all this convertersControllers plugins (aka converters) that apply dna during the pre-pass
/// </summary>
/// <param name="umaData">The umaData on the avatar</param>
/// <param name="skeleton">The avatars skeleton</param>
/// <param name="dnaTypeHash">The dnaTypeHash that this converters behaviour is using</param>
public void ApplyDNAPrepass(UMAData umaData, UMASkeleton skeleton)
{
if (!_prepared)
{
Prepare();
}
UMADnaBase umaDna = umaData.GetDna(DNATypeHash);
//Make the DNAAssets match if they dont already, can happen when some parts are in bundles and others arent
if (((DynamicUMADnaBase)umaDna).dnaAsset != DNAAsset && DNAAsset != null)
{
((DynamicUMADnaBase)umaDna).dnaAsset = DNAAsset;
}
if (_applyDNAPrepassPlugins.Count > 0)
{
for (int i = 0; i < _applyDNAPrepassPlugins.Count; i++)
{
_applyDNAPrepassPlugins[i].ApplyDNA(umaData, skeleton, DNATypeHash);
}
}
}
/// <summary>
/// Convert a recipes UMADnaHumanoid values to DynamicUMADna values. This will need to be done if the user switches a races converter from a HumanoidDNAConverterBehaviour to a DynamicDNAConverterBehaviour
/// </summary>
/// <param name="umaDna"></param>
public override int ImportUMADnaValues(UMADnaBase umaDna)
{
int dnaImported = 0;
string[] dnaNames = umaDna.Names;
for (int i = 0; i < umaDna.Count; i++)
{
var thisValueName = dnaNames[i];
for (int ii = 0; ii < Names.Length; ii++)
{
//if (Names[ii].Equals(thisValueName, StringComparison.OrdinalIgnoreCase))
//actually I think they should be exactly equal
if (Names[ii] == thisValueName)
{
Values[ii] = umaDna.Values[i];
dnaImported++;
}
}
}
return(dnaImported);
}
public void ApplyDNA(UMAData data, UMASkeleton skeleton)
{
UMADnaBase activeDNA = data.GetDna(this.dnaTypeHash);
if (activeDNA == null)
{
Debug.LogError("Could not get DNA values for: " + this.name);
return;
}
if (startingPose != null)
{
startingPose.ApplyPose(skeleton, 1f);
}
if (activeDNA.Count == dnaPoses.Length)
{
float[] dnaValues = activeDNA.Values;
for (int i = 0; i < dnaValues.Length; i++)
{
float dnaValue = dnaValues[i];
if ((dnaValue > 0.5f) && (dnaPoses[i].poseOne != null))
{
float poseWeight = (dnaValue - 0.5f) * 2f;
dnaPoses[i].poseOne.ApplyPose(skeleton, poseWeight);
}
else if ((dnaValue < 0.5f) && (dnaPoses[i].poseZero != null))
{
float poseWeight = (0.5f - dnaValue) * 2f;
dnaPoses[i].poseOne.ApplyPose(skeleton, poseWeight);
}
}
}
else
{
Debug.LogWarning("DNA length mismatch, trying names. This is SLOW!");
string[] dnaNames = activeDNA.Names;
for (int i = 0; i < dnaPoses.Length; i++)
{
if ((dnaPoses[i].dnaEntryName == null) || (dnaPoses[i].dnaEntryName.Length == 0))
{
continue;
}
int dnaIndex = System.Array.IndexOf(dnaNames, dnaPoses[i].dnaEntryName);
if (dnaIndex < 0)
{
continue;
}
float dnaValue = activeDNA.GetValue(dnaIndex);
if ((dnaValue > 0.5f) && (dnaPoses[i].poseOne != null))
{
float poseWeight = (dnaValue - 0.5f) * 2f;
dnaPoses[i].poseOne.ApplyPose(skeleton, poseWeight);
}
else if ((dnaValue < 0.5f) && (dnaPoses[i].poseZero != null))
{
float poseWeight = (0.5f - dnaValue) * 2f;
dnaPoses[i].poseOne.ApplyPose(skeleton, poseWeight);
}
}
}
}
public abstract int ImportUMADnaValues(UMADnaBase umaDna);
public override void ApplyDNA(UMAData umaData, UMASkeleton skeleton, int dnaTypeHash)
{
//Add the reset listeners if we havent already
//we need this because if 'fastGeneration' is false we may still get another loop
//and we should not do this again if _dnaAppliedTo contains umaData.gameObject
if (!_listenersAddedTo.Contains(umaData.gameObject))
{
umaData.CharacterUpdated.AddListener(ResetOnCharaterUpdated);
_listenersAddedTo.Add(umaData.gameObject);
}
if (_dnaAppliedTo.Contains(umaData.gameObject))
{
return;
}
UMADnaBase activeDNA = umaData.GetDna(dnaTypeHash);
if (activeDNA == null)
{
Debug.LogError("Could not get DNA values for: " + this.name);
return;
}
var masterWeightCalc = masterWeight.GetWeight(activeDNA);
if (masterWeightCalc == 0f)
{
return;
}
bool needsUpdate = false;
for (int i = 0; i < _colorSets.Length; i++)
{
if (_colorSets[i].modifyingDNA.UsedDNANames.Count == 0 || string.IsNullOrEmpty(_colorSets[i].targetName))
{
continue;
}
var targetOverlays = new List <OverlayData>();
for (int si = 0; si < umaData.umaRecipe.slotDataList.Length; si++)
{
var overlays = umaData.umaRecipe.slotDataList[si].GetOverlayList();
for (int oi = 0; oi < overlays.Count; oi++)
{
if (overlays[oi] != null)
{
//we can target specific Overlays or SharedColors now
if ((overlays[oi].colorData.IsASharedColor && overlays[oi].colorData.name == _colorSets[i].targetName) || overlays[oi].overlayName == _colorSets[i].targetName)
{
if (!targetOverlays.Contains(overlays[oi]))
{
targetOverlays.Add(overlays[oi]);
}
}
}
}
}
if (targetOverlays.Count == 0)
{
continue;
}
if (_colorSets[i].EvaluateAndApplyAdjustments(activeDNA, masterWeightCalc, targetOverlays))
{
needsUpdate = true;
}
}
if (needsUpdate)
{
umaData.isTextureDirty = true;
umaData.isAtlasDirty = true;
}
_dnaAppliedTo.Add(umaData.gameObject);
}
public void ApplyDNA(UMAData data, UMASkeleton skeleton)
{
if (morphSet == null)
{
if (Debug.isDebugBuild)
{
Debug.LogError("Missing morph set asset for: " + this.name);
}
return;
}
UMADnaBase activeDNA = data.GetDna(this.dnaTypeHash);
if (activeDNA == null)
{
if (Debug.isDebugBuild)
{
Debug.LogError("Could not get DNA values for: " + this.name);
}
return;
}
if (morphSet.startingPose != null)
{
morphSet.startingPose.ApplyPose(skeleton, 1f);
}
if (!String.IsNullOrEmpty(morphSet.startingBlendShape))
{
data.SetBlendShape(morphSet.startingBlendShape, 1f);
}
if (activeDNA.Count == morphSet.dnaMorphs.Length)
{
float[] dnaValues = activeDNA.Values;
for (int i = 0; i < dnaValues.Length; i++)
{
float dnaValue = dnaValues[i];
MorphSetDnaAsset.DNAMorphSet morph = morphSet.dnaMorphs[i];
ApplyMorph(dnaValue, data, skeleton, morph);
}
}
else
{
if (Debug.isDebugBuild)
{
Debug.LogWarning("DNA length mismatch, trying names. This is SLOW!");
}
string[] dnaNames = activeDNA.Names;
for (int i = 0; i < morphSet.dnaMorphs.Length; i++)
{
if (String.IsNullOrEmpty(morphSet.dnaMorphs[i].dnaEntryName))
{
continue;
}
int dnaIndex = System.Array.IndexOf(dnaNames, morphSet.dnaMorphs[i].dnaEntryName);
if (dnaIndex < 0)
{
continue;
}
float dnaValue = activeDNA.GetValue(dnaIndex);
MorphSetDnaAsset.DNAMorphSet morph = morphSet.dnaMorphs[i];
ApplyMorph(dnaValue, data, skeleton, morph);
}
}
}
public float CalculateValue(UMADnaBase umaDNA)
{
float thisVal = value;
float modifierVal = 0;
float tempModifierVal = 0;
string dnaCombineMethod = "";
bool inModifierPair = false;
if (modifiers.Count > 0)
{
for (int i = 0; i < modifiers.Count; i++)
{
if (modifiers[i].DNATypeName != "None" && (modifiers[i].modifier == spValModifier.spValModifierType.AddDNA ||
modifiers[i].modifier == spValModifier.spValModifierType.DivideDNA ||
modifiers[i].modifier == spValModifier.spValModifierType.MultiplyDNA ||
modifiers[i].modifier == spValModifier.spValModifierType.SubtractDNA))
{
tempModifierVal = GetUmaDNAValue(modifiers[i].DNATypeName, umaDNA);
tempModifierVal -= 0.5f;
inModifierPair = true;
if (modifiers[i].modifier == spValModifier.spValModifierType.AddDNA)
{
dnaCombineMethod = "Add";
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.DivideDNA)
{
dnaCombineMethod = "Divide";
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.MultiplyDNA)
{
dnaCombineMethod = "Multiply";
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.SubtractDNA)
{
dnaCombineMethod = "Subtract";
}
}
else
{
if (modifiers[i].modifier == spValModifier.spValModifierType.Add)
{
modifierVal += (tempModifierVal + modifiers[i].modifierValue);
tempModifierVal = 0;
inModifierPair = false;
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.Divide)
{
modifierVal += (tempModifierVal / modifiers[i].modifierValue);
tempModifierVal = 0;
inModifierPair = false;
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.Multiply)
{
modifierVal += (tempModifierVal * modifiers[i].modifierValue);
tempModifierVal = 0;
inModifierPair = false;
}
else if (modifiers[i].modifier == spValModifier.spValModifierType.Subtract)
{
modifierVal += (tempModifierVal - modifiers[i].modifierValue);
tempModifierVal = 0;
inModifierPair = false;
}
}
if (modifierVal != 0 && inModifierPair == false)
{
if (dnaCombineMethod == "Add")
{
thisVal += modifierVal;
}
if (dnaCombineMethod == "Subtract")
{
thisVal -= modifierVal;
}
if (dnaCombineMethod == "Multiply")
{
thisVal *= modifierVal;
}
if (dnaCombineMethod == "Divide")
{
thisVal /= modifierVal;
}
modifierVal = 0;
dnaCombineMethod = "";
}
}
//in the case of left/Right(Up)LegAdjust the umadna is subtracted from the result without being multiplied by anything
//this accounts for the scenario where umaDna is left trailing with no correcponding add/subtract/multiply/divide multiplier
if (tempModifierVal != 0 && inModifierPair != false)
{
if (dnaCombineMethod == "Add")
{
thisVal += tempModifierVal;
}
if (dnaCombineMethod == "Subtract")
{
thisVal -= tempModifierVal;
}
if (dnaCombineMethod == "Multiply")
{
thisVal *= tempModifierVal;
}
if (dnaCombineMethod == "Divide")
{
thisVal /= tempModifierVal;
}
dnaCombineMethod = "";
modifierVal = 0;
tempModifierVal = 0;
inModifierPair = false;
}
}
return(thisVal);
}
public void AddDna(UMADnaBase dna)
{
umaDna.Add(dna.GetType(), dna);
}
public override void OnInspectorGUI()
{
bool dirty = false;
DnaConverterBehaviour newSource = EditorGUILayout.ObjectField("DNA Converter", dnaRange.dnaConverter, typeof(DnaConverterBehaviour), true) as DnaConverterBehaviour;
if (newSource != dnaRange.dnaConverter)
{
dnaRange.dnaConverter = newSource;
dnaSource = null;
if (dnaRange.dnaConverter != null)
{
dnaSource = dnaRange.dnaConverter.DNAType.GetConstructor(System.Type.EmptyTypes).Invoke(null) as UMADnaBase;
}
if (dnaSource == null)
{
entryCount = 0;
}
else
{
entryCount = dnaSource.Count;
}
dnaRange.means = new float[entryCount];
dnaRange.deviations = new float[entryCount];
dnaRange.spreads = new float[entryCount];
for (int i = 0; i < entryCount; i++)
{
dnaRange.means[i] = 0.5f;
dnaRange.deviations[i] = 0.16f;
dnaRange.spreads[i] = 0.5f;
}
dirty = true;
}
GUILayout.Box("", GUILayout.ExpandWidth(true), GUILayout.Height(1));
if (dnaRange.dnaConverter != null)
{
GUILayout.Space(2f);
GUIStyle headerStyle = new GUIStyle();
headerStyle.alignment = TextAnchor.MiddleCenter;
headerStyle.normal.textColor = Color.white;
headerStyle.fontSize = 12;
EditorGUILayout.LabelField(dnaRange.dnaConverter.DNAType.Name, headerStyle);
string[] dnaNames = dnaSource.Names;
for (int i = 0; i < entryCount; i++)
{
float currentMin = dnaRange.means[i] - dnaRange.spreads[i];
float currentMax = dnaRange.means[i] + dnaRange.spreads[i];
float min = currentMin;
float max = currentMax;
EditorGUILayout.PrefixLabel(dnaNames[i]);
EditorGUILayout.MinMaxSlider(ref min, ref max, 0f, 1f);
if ((min != currentMin) || (max != currentMax))
{
dnaRange.means[i] = (min + max) / 2f;
dnaRange.spreads[i] = (max - min) / 2f;
dnaRange.deviations[i] = dnaRange.spreads[i] / 3f;
dirty = true;
}
}
}
if (dirty)
{
EditorUtility.SetDirty(dnaRange);
AssetDatabase.SaveAssets();
}
}
public bool EvaluateAndApplyAdjustments(UMADnaBase activeDNA, float masterWeight, List <OverlayData> targetOverlays)
{
var dnaVal = modifyingDNA.Evaluate(activeDNA);
float rAdj = 0f;
float gAdj = 0f;
float bAdj = 0f;
float aAdj = 0f;
float rCurr = 0f;
float gCurr = 0f;
float bCurr = 0f;
float aCurr = 0f;
OverlayColorData ocd;
for (int oi = 0; oi < targetOverlays.Count; oi++)
{
ocd = targetOverlays[oi].colorData;
if (colorModifier.R.enable)
{
rCurr = colorModifier.R.Additive ? ocd.channelAdditiveMask[textureChannel].r : ocd.channelMask[textureChannel].r;
rAdj = colorModifier.R.EvaluateAdjustment(dnaVal, rCurr);
if (colorModifier.R.Absolute)
{
rAdj = Mathf.Lerp(rCurr, rAdj, masterWeight);
}
else
{
rAdj = rAdj * masterWeight;
}
if ((colorModifier.R.Absolute && rAdj != 0) || (!colorModifier.R.Absolute && rAdj != rCurr))
{
targetOverlays[oi].colorComponentAdjusters.Add(new OverlayData.ColorComponentAdjuster(textureChannel, 0, rAdj, colorModifier.R.adjustmentType));
}
}
if (colorModifier.G.enable)
{
gCurr = colorModifier.G.Additive ? ocd.channelAdditiveMask[textureChannel].g : ocd.channelMask[textureChannel].g;
gAdj = colorModifier.G.EvaluateAdjustment(dnaVal, gCurr);
if (colorModifier.G.Absolute)
{
gAdj = Mathf.Lerp(gCurr, gAdj, masterWeight);
}
else
{
gAdj = gAdj * masterWeight;
}
if ((colorModifier.G.Absolute && gAdj != 0) || (!colorModifier.G.Absolute && gAdj != gCurr))
{
targetOverlays[oi].colorComponentAdjusters.Add(new OverlayData.ColorComponentAdjuster(textureChannel, 1, gAdj, colorModifier.G.adjustmentType));
}
}
if (colorModifier.B.enable)
{
bCurr = colorModifier.B.Additive ? ocd.channelAdditiveMask[textureChannel].b : ocd.channelMask[textureChannel].b;
bAdj = colorModifier.B.EvaluateAdjustment(dnaVal, bCurr);
if (colorModifier.B.Absolute)
{
bAdj = Mathf.Lerp(bCurr, bAdj, masterWeight);
}
else
{
bAdj = bAdj * masterWeight;
}
if ((colorModifier.B.Absolute && bAdj != 0) || (!colorModifier.B.Absolute && bAdj != bCurr))
{
targetOverlays[oi].colorComponentAdjusters.Add(new OverlayData.ColorComponentAdjuster(textureChannel, 2, bAdj, colorModifier.B.adjustmentType));
}
}
if (colorModifier.A.enable)
{
aCurr = colorModifier.A.Additive ? ocd.channelAdditiveMask[textureChannel].a : ocd.channelMask[textureChannel].a;
aAdj = colorModifier.A.EvaluateAdjustment(dnaVal, aCurr);
if (colorModifier.A.Absolute)
{
aAdj = Mathf.Lerp(aCurr, aAdj, masterWeight);
}
else if (colorModifier.A.adjustmentType == AdjustmentType.BlendFactor) //BlendFactor is different and only used on the alpha channel
{
aAdj = Mathf.Lerp(aCurr, aAdj * masterWeight, masterWeight);
}
else
{
aAdj = aAdj * masterWeight;
}
if ((colorModifier.A.Absolute && aAdj != 0) || (!colorModifier.A.Absolute && aAdj != aCurr))
{
targetOverlays[oi].colorComponentAdjusters.Add(new OverlayData.ColorComponentAdjuster(textureChannel, 3, aAdj, colorModifier.A.adjustmentType));
}
}
}
return(true);
}
private float GetAggregateValueNew(UMADnaBase dna, float result = 0f)
{
float tempResult = 0f;
if (_aggregationMethod == AggregationMethodOpts.Average)
{
var aveCount = result != 0f ? 1 : 0;
for (int i = 0; i < _dnaEvaluators.Count; i++)
{
if (!string.IsNullOrEmpty(_dnaEvaluators[i].dnaName))
{
aveCount++;
result += _dnaEvaluators[i].Evaluate(dna);
}
}
if (aveCount > 0)
{
result = result / aveCount;
}
}
else if (_aggregationMethod == AggregationMethodOpts.Maximum)
{
for (int i = 0; i < _dnaEvaluators.Count; i++)
{
tempResult = 0f;
if (!string.IsNullOrEmpty(_dnaEvaluators[i].dnaName))
{
tempResult = _dnaEvaluators[i].Evaluate(dna);
if (tempResult > result)
{
result = tempResult;
}
}
}
}
else if (_aggregationMethod == AggregationMethodOpts.Minimum)
{
for (int i = 0; i < _dnaEvaluators.Count; i++)
{
tempResult = 0f;
if (!string.IsNullOrEmpty(_dnaEvaluators[i].dnaName))
{
tempResult = _dnaEvaluators[i].Evaluate(dna);
if (tempResult < result)
{
result = tempResult;
}
}
}
}
else if (aggregationMethod == AggregationMethodOpts.Cumulative)
{
for (int i = 0; i < _dnaEvaluators.Count; i++)
{
tempResult = 0f;
if (!string.IsNullOrEmpty(_dnaEvaluators[i].dnaName))
{
tempResult = _dnaEvaluators[i].Evaluate(dna);
if (_dnaEvaluators[i].calcOption == DNAEvaluator.CalcOption.Add)
{
result += tempResult;
}
else if (_dnaEvaluators[i].calcOption == DNAEvaluator.CalcOption.Subtract)
{
result -= tempResult;
}
else if (_dnaEvaluators[i].calcOption == DNAEvaluator.CalcOption.Multiply)
{
result *= tempResult;
}
else if (_dnaEvaluators[i].calcOption == DNAEvaluator.CalcOption.Divide && tempResult != 0)
{
result /= tempResult;
}
}
}
}
return(result);
}
