animation update

updated how animations are handled from assimp
gltf timing now correct
This commit is contained in:
marauder2k7 2024-12-10 11:54:13 +00:00
parent 5f1c2a63e5
commit 28fcb8d68b
6 changed files with 161 additions and 160 deletions

View file

@ -135,115 +135,104 @@ MatrixF AssimpAppNode::getTransform(F32 time)
void AssimpAppNode::getAnimatedTransform(MatrixF& mat, F32 t, aiAnimation* animSeq) void AssimpAppNode::getAnimatedTransform(MatrixF& mat, F32 t, aiAnimation* animSeq)
{ {
// Find the channel for this node // Convert time `t` (in seconds) to a frame index
const F32 frameTime = (t * animSeq->mTicksPerSecond + 0.5f) + 1.0f;
// Loop through animation channels to find the matching node
for (U32 k = 0; k < animSeq->mNumChannels; ++k) for (U32 k = 0; k < animSeq->mNumChannels; ++k)
{ {
if (dStrcmp(mName, animSeq->mChannels[k]->mNodeName.C_Str()) == 0) const aiNodeAnim* nodeAnim = animSeq->mChannels[k];
if (dStrcmp(mName, nodeAnim->mNodeName.C_Str()) != 0)
continue;
Point3F translation(Point3F::Zero);
QuatF rotation(QuatF::Identity);
Point3F scale(Point3F::One);
// Interpolate Translation Keys
if (nodeAnim->mNumPositionKeys > 0)
{ {
aiNodeAnim *nodeAnim = animSeq->mChannels[k]; translation = interpolateVectorKey(nodeAnim->mPositionKeys, nodeAnim->mNumPositionKeys, frameTime);
Point3F trans(Point3F::Zero); }
Point3F scale(Point3F::One);
QuatF rot;
rot.identity();
// T is in seconds, convert to frames.
F32 frame = (t * animSeq->mTicksPerSecond + 0.5f) + 1.0f;
// Transform // Interpolate Rotation Keys
if (nodeAnim->mNumPositionKeys == 1) if (nodeAnim->mNumRotationKeys > 0)
trans.set(nodeAnim->mPositionKeys[0].mValue.x, nodeAnim->mPositionKeys[0].mValue.y, nodeAnim->mPositionKeys[0].mValue.z); {
else rotation = interpolateQuaternionKey(nodeAnim->mRotationKeys, nodeAnim->mNumRotationKeys, frameTime);
{ }
Point3F curPos, lastPos;
F32 lastT = 0.0;
for (U32 key = 0; key < nodeAnim->mNumPositionKeys; ++key)
{
F32 curT = sTimeMultiplier * (F32)nodeAnim->mPositionKeys[key].mTime;
curPos.set(nodeAnim->mPositionKeys[key].mValue.x, nodeAnim->mPositionKeys[key].mValue.y, nodeAnim->mPositionKeys[key].mValue.z);
if ((curT > frame) && (key > 0))
{
F32 factor = (frame - lastT) / (curT - lastT);
trans.interpolate(lastPos, curPos, factor);
break;
}
else if ((curT >= frame) || (key == nodeAnim->mNumPositionKeys - 1))
{
trans = curPos;
break;
}
lastT = curT; // Interpolate Scaling Keys
lastPos = curPos; if (nodeAnim->mNumScalingKeys > 0)
} {
} scale = interpolateVectorKey(nodeAnim->mScalingKeys, nodeAnim->mNumScalingKeys, frameTime);
}
// Rotation // Apply the interpolated transform components to the matrix
if (nodeAnim->mNumRotationKeys == 1) rotation.setMatrix(&mat);
rot.set(nodeAnim->mRotationKeys[0].mValue.x, nodeAnim->mRotationKeys[0].mValue.y, mat.inverse();
nodeAnim->mRotationKeys[0].mValue.z, nodeAnim->mRotationKeys[0].mValue.w); mat.setPosition(translation);
else mat.scale(scale);
{
QuatF curRot, lastRot;
F32 lastT = 0.0;
for (U32 key = 0; key < nodeAnim->mNumRotationKeys; ++key)
{
F32 curT = sTimeMultiplier * (F32)nodeAnim->mRotationKeys[key].mTime;
curRot.set(nodeAnim->mRotationKeys[key].mValue.x, nodeAnim->mRotationKeys[key].mValue.y,
nodeAnim->mRotationKeys[key].mValue.z, nodeAnim->mRotationKeys[key].mValue.w);
if ((curT > frame) && (key > 0))
{
F32 factor = (frame - lastT) / (curT - lastT);
rot.interpolate(lastRot, curRot, factor);
break;
}
else if ((curT >= frame) || (key == nodeAnim->mNumRotationKeys - 1))
{
rot = curRot;
break;
}
lastT = curT; return; // Exit after processing the matching node
lastRot = curRot; }
}
}
// Scale // Default to the static node transformation if no animation data is found
if (nodeAnim->mNumScalingKeys == 1) mat = mNodeTransform;
scale.set(nodeAnim->mScalingKeys[0].mValue.x, nodeAnim->mScalingKeys[0].mValue.y, nodeAnim->mScalingKeys[0].mValue.z); }
else
{
Point3F curScale, lastScale;
F32 lastT = 0.0;
for (U32 key = 0; key < nodeAnim->mNumScalingKeys; ++key)
{
F32 curT = sTimeMultiplier * (F32)nodeAnim->mScalingKeys[key].mTime;
curScale.set(nodeAnim->mScalingKeys[key].mValue.x, nodeAnim->mScalingKeys[key].mValue.y, nodeAnim->mScalingKeys[key].mValue.z);
if ((curT > frame) && (key > 0))
{
F32 factor = (frame - lastT) / (curT - lastT);
scale.interpolate(lastScale, curScale, factor);
break;
}
else if ((curT >= frame) || (key == nodeAnim->mNumScalingKeys - 1))
{
scale = curScale;
break;
}
lastT = curT; Point3F AssimpAppNode::interpolateVectorKey(const aiVectorKey* keys, U32 numKeys, F32 frameTime)
lastScale = curScale; {
} if (numKeys == 1) // Single keyframe: use it directly
} return Point3F(keys[0].mValue.x, keys[0].mValue.y, keys[0].mValue.z);
rot.setMatrix(&mat); // Clamp frameTime to the bounds of the keyframes
mat.inverse(); if (frameTime <= keys[0].mTime) {
mat.setPosition(trans); // Before the first keyframe, return the first key
mat.scale(scale); return Point3F(keys[0].mValue.x, keys[0].mValue.y, keys[0].mValue.z);
return; }
if (frameTime >= keys[numKeys - 1].mTime) {
// After the last keyframe, return the last key
return Point3F(keys[numKeys - 1].mValue.x, keys[numKeys - 1].mValue.y, keys[numKeys - 1].mValue.z);
}
// Interpolate between the two nearest keyframes
for (U32 i = 1; i < numKeys; ++i)
{
if (frameTime < keys[i].mTime)
{
const F32 factor = (frameTime - keys[i - 1].mTime) / (keys[i].mTime - keys[i - 1].mTime);
Point3F start(keys[i - 1].mValue.x, keys[i - 1].mValue.y, keys[i - 1].mValue.z);
Point3F end(keys[i].mValue.x, keys[i].mValue.y, keys[i].mValue.z);
Point3F result;
result.interpolate(start, end, factor);
return result;
} }
} }
// Node not found in the animation channels // Default to the last keyframe
mat = mNodeTransform; return Point3F(keys[numKeys - 1].mValue.x, keys[numKeys - 1].mValue.y, keys[numKeys - 1].mValue.z);
}
QuatF AssimpAppNode::interpolateQuaternionKey(const aiQuatKey* keys, U32 numKeys, F32 frameTime)
{
if (numKeys == 1) // Single keyframe: use it directly
return QuatF(keys[0].mValue.x, keys[0].mValue.y, keys[0].mValue.z, keys[0].mValue.w);
for (U32 i = 1; i < numKeys; ++i)
{
if (frameTime < keys[i].mTime)
{
const F32 factor = (frameTime - keys[i - 1].mTime) / (keys[i].mTime - keys[i - 1].mTime);
QuatF start(keys[i - 1].mValue.x, keys[i - 1].mValue.y, keys[i - 1].mValue.z, keys[i - 1].mValue.w);
QuatF end(keys[i].mValue.x, keys[i].mValue.y, keys[i].mValue.z, keys[i].mValue.w);
QuatF result;
result.interpolate(start, end, factor);
return result;
}
}
// Default to the last keyframe
return QuatF(keys[numKeys - 1].mValue.x, keys[numKeys - 1].mValue.y, keys[numKeys - 1].mValue.z, keys[numKeys - 1].mValue.w);
} }
bool AssimpAppNode::animatesTransform(const AppSequence* appSeq) bool AssimpAppNode::animatesTransform(const AppSequence* appSeq)

View file

@ -45,6 +45,8 @@ class AssimpAppNode : public AppNode
MatrixF getTransform(F32 time); MatrixF getTransform(F32 time);
void getAnimatedTransform(MatrixF& mat, F32 t, aiAnimation* animSeq); void getAnimatedTransform(MatrixF& mat, F32 t, aiAnimation* animSeq);
Point3F interpolateVectorKey(const aiVectorKey* keys, U32 numKeys, F32 frameTime);
QuatF interpolateQuaternionKey(const aiQuatKey* keys, U32 numKeys, F32 frameTime);
void buildMeshList() override; void buildMeshList() override;
void buildChildList() override; void buildChildList() override;

View file

@ -12,94 +12,103 @@
#include "ts/assimp/assimpAppSequence.h" #include "ts/assimp/assimpAppSequence.h"
#include "ts/assimp/assimpAppNode.h" #include "ts/assimp/assimpAppNode.h"
AssimpAppSequence::AssimpAppSequence(aiAnimation *a) : AssimpAppSequence::AssimpAppSequence(aiAnimation* a)
seqStart(0.0f), : seqStart(0.0f), seqEnd(0.0f), mTimeMultiplier(1.0f)
seqEnd(0.0f)
{ {
fps = 30.0f;
// Deep copy animation structure
mAnim = new aiAnimation(*a); mAnim = new aiAnimation(*a);
// Deep copy channels
mAnim->mChannels = new aiNodeAnim * [a->mNumChannels]; mAnim->mChannels = new aiNodeAnim * [a->mNumChannels];
for (U32 i = 0; i < a->mNumChannels; ++i) { for (U32 i = 0; i < a->mNumChannels; ++i) {
mAnim->mChannels[i] = new aiNodeAnim(*a->mChannels[i]); mAnim->mChannels[i] = new aiNodeAnim(*a->mChannels[i]);
} }
// Deep copy meshes
mAnim->mMeshChannels = new aiMeshAnim * [a->mNumMeshChannels]; mAnim->mMeshChannels = new aiMeshAnim * [a->mNumMeshChannels];
for (U32 i = 0; i < a->mNumMeshChannels; ++i) { for (U32 i = 0; i < a->mNumMeshChannels; ++i) {
mAnim->mMeshChannels[i] = new aiMeshAnim(*a->mMeshChannels[i]); mAnim->mMeshChannels[i] = new aiMeshAnim(*a->mMeshChannels[i]);
} }
// Deep copy name
mAnim->mName = a->mName; mAnim->mName = a->mName;
mSequenceName = mAnim->mName.C_Str(); mSequenceName = mAnim->mName.C_Str();
if (mSequenceName.isEmpty()) if (mSequenceName.isEmpty())
mSequenceName = "ambient"; mSequenceName = "ambient";
Con::printf("\n[Assimp] Adding %s animation", mSequenceName.c_str());
fps = (a->mTicksPerSecond > 0) ? a->mTicksPerSecond : 30.0f; Con::printf("\n[Assimp] Adding animation: %s", mSequenceName.c_str());
if (a->mDuration > 0) // Determine the FPS and Time Multiplier
{ determineTimeMultiplier(a);
// torques seqEnd is in seconds, this then gets generated into frames in generateSequences()
seqEnd = (F32)a->mDuration / fps;
}
else
{
for (U32 i = 0; i < a->mNumChannels; ++i)
{
aiNodeAnim* nodeAnim = a->mChannels[i];
// Determine the maximum keyframe time for this animation
F32 maxKeyTime = 0.0f;
for (U32 k = 0; k < nodeAnim->mNumPositionKeys; k++) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mPositionKeys[k].mTime);
}
for (U32 k = 0; k < nodeAnim->mNumRotationKeys; k++) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mRotationKeys[k].mTime);
}
for (U32 k = 0; k < nodeAnim->mNumScalingKeys; k++) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mScalingKeys[k].mTime);
}
seqEnd = getMax(seqEnd, maxKeyTime);
}
}
mTimeMultiplier = 1.0f;
S32 timeFactor = ColladaUtils::getOptions().animTiming;
S32 fpsRequest = (S32)a->mTicksPerSecond;
if (timeFactor == 0)
{ // Timing specified in frames
fps = mClamp(fpsRequest, 5 /*TSShapeLoader::MinFrameRate*/, TSShapeLoader::MaxFrameRate);
mTimeMultiplier = 1.0f / fps;
}
else
{ // Timing specified in seconds or ms depending on format
if (seqEnd > 1000.0f || a->mDuration > 1000.0f)
timeFactor = 1000.0f; // If it's more than 1000 seconds, assume it's ms.
timeFactor = mClamp(timeFactor, 1, 1000);
mTimeMultiplier = 1.0f / timeFactor;
}
// Calculate sequence end time based on keyframes and multiplier
calculateSequenceEnd(a);
} }
AssimpAppSequence::~AssimpAppSequence() AssimpAppSequence::~AssimpAppSequence()
{ {
} }
void AssimpAppSequence::determineTimeMultiplier(aiAnimation* a)
{
// Set fps from the file or use default
fps = (a->mTicksPerSecond > 0) ? a->mTicksPerSecond : 30.0f;
if (fps >= 1000.0f) { // Indicates milliseconds (GLTF or similar formats)
mTimeMultiplier = 1.0f / 1000.0f; // Convert milliseconds to seconds
Con::printf("[Assimp] Detected milliseconds timing (FPS >= 1000). Time Multiplier: %f", mTimeMultiplier);
}
else if (fps > 0.0f) { // Standard FPS
fps = mClamp(fps, 5 /*TSShapeLoader::MinFrameRate*/, TSShapeLoader::MaxFrameRate);
mTimeMultiplier = 1.0f / fps;
Con::printf("[Assimp] Standard FPS detected. Time Multiplier: %f", mTimeMultiplier);
}
else {
// Fall back to 30 FPS as default
mTimeMultiplier = 1.0f / 30.0f;
Con::printf("[Assimp] FPS not specified. Using default 30 FPS. Time Multiplier: %f", mTimeMultiplier);
}
}
void AssimpAppSequence::calculateSequenceEnd(aiAnimation* a)
{
for (U32 i = 0; i < a->mNumChannels; ++i) {
aiNodeAnim* nodeAnim = a->mChannels[i];
F32 maxKeyTime = 0.0f;
// Calculate the maximum time across all keyframes for this channel
for (U32 k = 0; k < nodeAnim->mNumPositionKeys; ++k) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mPositionKeys[k].mTime);
}
for (U32 k = 0; k < nodeAnim->mNumRotationKeys; ++k) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mRotationKeys[k].mTime);
}
for (U32 k = 0; k < nodeAnim->mNumScalingKeys; ++k) {
maxKeyTime = getMax(maxKeyTime, (F32)nodeAnim->mScalingKeys[k].mTime);
}
// Use the multiplier to convert to real sequence time
seqEnd = mTimeMultiplier * getMax(seqEnd, maxKeyTime);
}
Con::printf("[Assimp] Sequence End Time: %f seconds", seqEnd);
}
void AssimpAppSequence::setActive(bool active) void AssimpAppSequence::setActive(bool active)
{ {
if (active) if (active)
{ {
AssimpAppNode::sActiveSequence = mAnim; AssimpAppNode::sActiveSequence = mAnim;
AssimpAppNode::sTimeMultiplier = mTimeMultiplier; AssimpAppNode::sTimeMultiplier = mTimeMultiplier;
Con::printf("[Assimp] Activating sequence: %s with Time Multiplier: %f", mSequenceName.c_str(), mTimeMultiplier);
} }
else else
{ {
if (AssimpAppNode::sActiveSequence == mAnim) if (AssimpAppNode::sActiveSequence == mAnim)
{
AssimpAppNode::sActiveSequence = NULL; AssimpAppNode::sActiveSequence = NULL;
Con::printf("[Assimp] Deactivating sequence: %s", mSequenceName.c_str());
}
} }
} }

View file

@ -27,11 +27,14 @@ class AssimpAppSequence : public AppSequence
F32 seqEnd; F32 seqEnd;
F32 mTimeMultiplier; // The factor needed to convert the sequence data timestamp to seconds F32 mTimeMultiplier; // The factor needed to convert the sequence data timestamp to seconds
void determineTimeMultiplier(aiAnimation* a);
void calculateSequenceEnd(aiAnimation* a);
public: public:
AssimpAppSequence(aiAnimation *a); AssimpAppSequence(aiAnimation *a);
~AssimpAppSequence(); ~AssimpAppSequence();
aiAnimation *mAnim; aiAnimation *mAnim;
void setActive(bool active) override; void setActive(bool active) override;

View file

@ -349,12 +349,16 @@ void AssimpShapeLoader::processAnimations()
Vector<aiNodeAnim*> ambientChannels; Vector<aiNodeAnim*> ambientChannels;
F32 duration = 0.0f; F32 duration = 0.0f;
F32 ticks = 0.0f;
if (mScene->mNumAnimations > 0) if (mScene->mNumAnimations > 0)
{ {
for (U32 i = 0; i < mScene->mNumAnimations; ++i) for (U32 i = 0; i < mScene->mNumAnimations; ++i)
{ {
aiAnimation* anim = mScene->mAnimations[i]; aiAnimation* anim = mScene->mAnimations[i];
duration = anim->mDuration;
ticks = anim->mTicksPerSecond;
duration = 0.0f;
for (U32 j = 0; j < anim->mNumChannels; j++) for (U32 j = 0; j < anim->mNumChannels; j++)
{ {
aiNodeAnim* nodeAnim = anim->mChannels[j]; aiNodeAnim* nodeAnim = anim->mChannels[j];
@ -379,7 +383,7 @@ void AssimpShapeLoader::processAnimations()
ambientSeq->mNumChannels = ambientChannels.size(); ambientSeq->mNumChannels = ambientChannels.size();
ambientSeq->mChannels = ambientChannels.address(); ambientSeq->mChannels = ambientChannels.address();
ambientSeq->mDuration = duration; ambientSeq->mDuration = duration;
ambientSeq->mTicksPerSecond = 24.0; ambientSeq->mTicksPerSecond = ticks;
AssimpAppSequence* defaultAssimpSeq = new AssimpAppSequence(ambientSeq); AssimpAppSequence* defaultAssimpSeq = new AssimpAppSequence(ambientSeq);
appSequences.push_back(defaultAssimpSeq); appSequences.push_back(defaultAssimpSeq);

View file

@ -57,9 +57,7 @@ IMPLEMENT_CALLBACK(TSShapeConstructor, onUnload, void, (), (),
ImplementEnumType(TSShapeConstructorUpAxis, ImplementEnumType(TSShapeConstructorUpAxis,
"Axis to use for upwards direction when importing from Collada.\n\n" "Axis to use for upwards direction when importing from Collada.\n\n"
"@ingroup TSShapeConstructor") "@ingroup TSShapeConstructor")
{ { UPAXISTYPE_X_UP, "X_AXIS" },
UPAXISTYPE_X_UP, "X_AXIS"
},
{ UPAXISTYPE_Y_UP, "Y_AXIS" }, { UPAXISTYPE_Y_UP, "Y_AXIS" },
{ UPAXISTYPE_Z_UP, "Z_AXIS" }, { UPAXISTYPE_Z_UP, "Z_AXIS" },
{ UPAXISTYPE_COUNT, "DEFAULT" } { UPAXISTYPE_COUNT, "DEFAULT" }
@ -68,9 +66,7 @@ EndImplementEnumType;
ImplementEnumType(TSShapeConstructorLodType, ImplementEnumType(TSShapeConstructorLodType,
"\n\n" "\n\n"
"@ingroup TSShapeConstructor") "@ingroup TSShapeConstructor")
{ { ColladaUtils::ImportOptions::DetectDTS, "DetectDTS" },
ColladaUtils::ImportOptions::DetectDTS, "DetectDTS"
},
{ ColladaUtils::ImportOptions::SingleSize, "SingleSize" }, { ColladaUtils::ImportOptions::SingleSize, "SingleSize" },
{ ColladaUtils::ImportOptions::TrailingNumber, "TrailingNumber" }, { ColladaUtils::ImportOptions::TrailingNumber, "TrailingNumber" },
EndImplementEnumType; EndImplementEnumType;
@ -78,9 +74,7 @@ ImplementEnumType(TSShapeConstructorLodType,
ImplementEnumType(TSShapeConstructorAnimType, ImplementEnumType(TSShapeConstructorAnimType,
"\n\n" "\n\n"
"@ingroup TSShapeConstructor") "@ingroup TSShapeConstructor")
{ { ColladaUtils::ImportOptions::FrameCount, "Frames" },
ColladaUtils::ImportOptions::FrameCount, "Frames"
},
{ ColladaUtils::ImportOptions::Seconds, "Seconds" }, { ColladaUtils::ImportOptions::Seconds, "Seconds" },
{ ColladaUtils::ImportOptions::Milliseconds, "Milliseconds" }, { ColladaUtils::ImportOptions::Milliseconds, "Milliseconds" },
EndImplementEnumType; EndImplementEnumType;