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FBX Export: implement basic animation export.

pull/1857/head
Tommy 2018-03-26 18:30:47 +02:00
parent 2dff6e2d5b
commit 57bd125839
1 changed files with 434 additions and 5 deletions
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439
code/FBXExporter.cpp
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@ -525,8 +525,9 @@ void FBXExporter::WriteDefinitions ()
total_count += count; total_count += count;
// AnimationStack / FbxAnimStack // AnimationStack / FbxAnimStack
// this seems to always be here in Maya exports // this seems to always be here in Maya exports,
count = 0; // but no harm seems to come of leaving it out.
count = mScene->mNumAnimations;
if (count) { if (count) {
n = FBX::Node("ObjectType", Property("AnimationStack")); n = FBX::Node("ObjectType", Property("AnimationStack"));
n.AddChild("Count", count); n.AddChild("Count", count);
@ -544,8 +545,11 @@ void FBXExporter::WriteDefinitions ()
} }
// AnimationLayer / FbxAnimLayer // AnimationLayer / FbxAnimLayer
// this seems to always be here in Maya exports // this seems to always be here in Maya exports,
count = 0; // but no harm seems to come of leaving it out.
// Assimp doesn't support animation layers,
// so there will be one per aiAnimation
count = mScene->mNumAnimations;
if (count) { if (count) {
n = FBX::Node("ObjectType", Property("AnimationLayer")); n = FBX::Node("ObjectType", Property("AnimationLayer"));
n.AddChild("Count", count); n.AddChild("Count", count);
@ -821,7 +825,7 @@ void FBXExporter::WriteDefinitions ()
} }
// AnimationCurveNode / FbxAnimCurveNode // AnimationCurveNode / FbxAnimCurveNode
count = 0; count = mScene->mNumAnimations * 3;
if (count) { if (count) {
n = FBX::Node("ObjectType", Property("AnimationCurveNode")); n = FBX::Node("ObjectType", Property("AnimationCurveNode"));
n.AddChild("Count", count); n.AddChild("Count", count);
@ -834,6 +838,15 @@ void FBXExporter::WriteDefinitions ()
total_count += count; total_count += count;
} }
// AnimationCurve / FbxAnimCurve
count = mScene->mNumAnimations * 9;
if (count) {
n = FBX::Node("ObjectType", Property("AnimationCurve"));
n.AddChild("Count", count);
object_nodes.push_back(n);
total_count += count;
}
// Pose // Pose
count = 0; count = 0;
for (size_t i = 0; i < mScene->mNumMeshes; ++i) { for (size_t i = 0; i < mScene->mNumMeshes; ++i) {
@ -911,6 +924,12 @@ aiMatrix4x4 get_world_transform(const aiNode* node, const aiScene* scene)
return transform; return transform;
} }
int64_t to_ktime(double ticks, const aiAnimation* anim) {
if (anim->mTicksPerSecond <= 0) {
return ticks * FBX::SECOND;
}
return (ticks / anim->mTicksPerSecond) * FBX::SECOND;
}
void FBXExporter::WriteObjects () void FBXExporter::WriteObjects ()
{ {
@ -1849,6 +1868,416 @@ void FBXExporter::WriteObjects ()
outstream, mScene->mRootNode, 0, limbnodes outstream, mScene->mRootNode, 0, limbnodes
); );
// animations
//
// in FBX there are:
// * AnimationStack - corresponds to an aiAnimation
// * AnimationLayer - a combinable animation component
// * AnimationCurveNode - links the property to be animated
// * AnimationCurve - defines animation data for a single property value
//
// the CurveNode also provides the default value for a property,
// such as the X, Y, Z coordinates for animatable translation.
//
// the Curve only specifies values for one component of the property,
// so there will be a separate AnimationCurve for X, Y, and Z.
//
// Assimp has:
// * aiAnimation - basically corresponds to an AnimationStack
// * aiNodeAnim - defines all animation for one aiNode
// * aiVectorKey/aiQuatKey - define the keyframe data for T/R/S
//
// assimp has no equivalent for AnimationLayer,
// and these are flattened on FBX import.
// we can assume there will be one per AnimationStack.
//
// the aiNodeAnim contains all animation data for a single aiNode,
// which will correspond to three AnimationCurveNode's:
// one each for translation, rotation and scale.
// The data for each of these will be put in 9 AnimationCurve's,
// T.X, T.Y, T.Z, R.X, R.Y, R.Z, etc.
// AnimationStack / aiAnimation
std::vector<int64_t> animation_stack_uids(mScene->mNumAnimations);
for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) {
int64_t animstack_uid = generate_uid();
animation_stack_uids[ai] = animstack_uid;
const aiAnimation* anim = mScene->mAnimations[ai];
FBX::Node asnode("AnimationStack");
std::string name = anim->mName.C_Str() + FBX::SEPARATOR + "AnimStack";
asnode.AddProperties(animstack_uid, name, "");
FBX::Node p("Properties70");
p.AddP70time("LocalStart", 0);
p.AddP70time("LocalStop", 0);
p.AddP70time("ReferenceStart", 0);
p.AddP70time("ReferenceStop", 0);
asnode.AddChild(p);
// this node absurdly always pretends it has children
asnode.Begin(outstream);
asnode.DumpProperties(outstream);
asnode.EndProperties(outstream);
asnode.DumpChildren(outstream);
asnode.End(outstream, true);
// note: animation stacks are not connected to anything
}
// AnimationLayer - one per aiAnimation
std::vector<int64_t> animation_layer_uids(mScene->mNumAnimations);
for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) {
int64_t animlayer_uid = generate_uid();
animation_layer_uids[ai] = animlayer_uid;
FBX::Node alnode("AnimationLayer");
alnode.AddProperties(animlayer_uid, FBX::SEPARATOR + "AnimLayer", "");
// this node absurdly always pretends it has children
alnode.Begin(outstream);
alnode.DumpProperties(outstream);
alnode.EndProperties(outstream);
alnode.DumpChildren(outstream);
alnode.End(outstream, true);
// connect to the relevant animstack
FBX::Node c("C");
c.AddProperties("OO", animlayer_uid, animation_stack_uids[ai]);
connections.push_back(c); // TODO: emplace_back
}
// AnimCurveNode - three per aiNodeAnim
std::vector<std::vector<std::array<int64_t,3>>> curve_node_uids;
for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) {
const aiAnimation* anim = mScene->mAnimations[ai];
const int64_t layer_uid = animation_layer_uids[ai];
std::vector<std::array<int64_t,3>> nodeanim_uids;
for (size_t nai = 0; nai < anim->mNumChannels; ++nai) {
const aiNodeAnim* na = anim->mChannels[nai];
// get the corresponding aiNode
const aiNode* node = mScene->mRootNode->FindNode(na->mNodeName);
// and its transform
const aiMatrix4x4 node_xfm = get_world_transform(node, mScene);
aiVector3D T, R, S;
node_xfm.Decompose(S, R, T);
// generate uids for all AnimationCurveNode
std::array<int64_t,3> ids;
ids[0] = generate_uid(); // T
ids[1] = generate_uid(); // R
ids[2] = generate_uid(); // S
// translation
FBX::Node t("AnimationCurveNode");
t.AddProperties(ids[0], "T" + FBX::SEPARATOR + "AnimCurveNode", "");
FBX::Node tp("Properties70");
tp.AddP70numberA("d|X", T.x);
tp.AddP70numberA("d|Y", T.y);
tp.AddP70numberA("d|Z", T.z);
t.AddChild(tp);
t.Dump(outstream);
// connect to layer
FBX::Node tcl("C");
tcl.AddProperties("OO", ids[0], layer_uid);
connections.push_back(tcl); // TODO: emplace_back
// connect to bone
FBX::Node tcb("C");
tcb.AddProperties("OP", ids[0], node_uids[node], "Lcl Translation");
connections.push_back(tcb); // TODO: emplace_back
// rotation
FBX::Node r("AnimationCurveNode");
r.AddProperties(ids[1], "R" + FBX::SEPARATOR + "AnimCurveNode", "");
FBX::Node rp("Properties70");
rp.AddP70numberA("d|X", DEG*R.x);
rp.AddP70numberA("d|Y", DEG*R.y);
rp.AddP70numberA("d|Z", DEG*R.z);
r.AddChild(rp);
r.Dump(outstream);
// connect to layer
FBX::Node rcl("C");
rcl.AddProperties("OO", ids[1], layer_uid);
connections.push_back(rcl); // TODO: emplace_back
// connect to bone
FBX::Node rcb("C");
rcb.AddProperties("OP", ids[1], node_uids[node], "Lcl Rotation");
connections.push_back(rcb); // TODO: emplace_back
// scale
FBX::Node s("AnimationCurveNode");
s.AddProperties(ids[2], "S" + FBX::SEPARATOR + "AnimCurveNode", "");
FBX::Node sp("Properties70");
sp.AddP70numberA("d|X", S.x);
sp.AddP70numberA("d|Y", S.y);
sp.AddP70numberA("d|Z", S.z);
s.AddChild(sp);
s.Dump(outstream);
// connect to layer
FBX::Node scl("C");
scl.AddProperties("OO", ids[2], layer_uid);
connections.push_back(scl); // TODO: emplace_back
// connect to bone
FBX::Node scb("C");
scb.AddProperties("OP", ids[2], node_uids[node], "Lcl Scaling");
connections.push_back(scb); // TODO: emplace_back
nodeanim_uids.push_back(ids);
}
curve_node_uids.push_back(nodeanim_uids);
}
// AnimCurve - defines actual keyframe data.
// there's a separate curve for every component of every vector,
// for example a transform curvenode will have separate X/Y/Z AnimCurve's
for (size_t ai = 0; ai < mScene->mNumAnimations; ++ai) {
const aiAnimation* anim = mScene->mAnimations[ai];
for (size_t nai = 0; nai < anim->mNumChannels; ++nai) {
const aiNodeAnim* na = anim->mChannels[nai];
// get the corresponding aiNode
const aiNode* node = mScene->mRootNode->FindNode(na->mNodeName);
// and its transform
const aiMatrix4x4 node_xfm = get_world_transform(node, mScene);
aiVector3D T, R, S;
node_xfm.Decompose(S, R, T);
const std::array<int64_t,3>& ids = curve_node_uids[ai][nai];
int64_t curve_uid;
std::vector<int64_t> times;
std::vector<float> values;
// TODO: compress code (it's a bit annoying)
// translation x
FBX::Node tx("AnimationCurve");
curve_uid = generate_uid();
tx.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
tx.AddChild("Default", double(T.x)); // default value
tx.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumPositionKeys; ++pki) {
const aiVectorKey& k = na->mPositionKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.x);
}
tx.AddChild("KeyTime", times);
tx.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
tx.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
tx.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
tx.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
tx.Dump(outstream);
FBX::Node txc("C");
txc.AddProperties("OP", curve_uid, ids[0], "d|X");
connections.push_back(txc); // TODO: emplace_back
// translation y
FBX::Node ty("AnimationCurve");
curve_uid = generate_uid();
ty.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
ty.AddChild("Default", double(T.y)); // default value
ty.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumPositionKeys; ++pki) {
const aiVectorKey& k = na->mPositionKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.y);
}
ty.AddChild("KeyTime", times);
ty.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
ty.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
ty.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
ty.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
ty.Dump(outstream);
FBX::Node tyc("C");
tyc.AddProperties("OP", curve_uid, ids[0], "d|Y");
connections.push_back(tyc); // TODO: emplace_back
// translation z
FBX::Node tz("AnimationCurve");
curve_uid = generate_uid();
tz.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
tz.AddChild("Default", double(T.z)); // default value
tz.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumPositionKeys; ++pki) {
const aiVectorKey& k = na->mPositionKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.z);
}
tz.AddChild("KeyTime", times);
tz.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
tz.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
tz.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
tz.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
tz.Dump(outstream);
FBX::Node tzc("C");
tzc.AddProperties("OP", curve_uid, ids[0], "d|Z");
connections.push_back(tzc); // TODO: emplace_back
// rotation x
FBX::Node rx("AnimationCurve");
curve_uid = generate_uid();
rx.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
rx.AddChild("Default", double(R.x)); // default value
rx.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumRotationKeys; ++pki) {
const aiQuatKey& k = na->mRotationKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
// there must be a better way...
aiMatrix4x4 m(k.mValue.GetMatrix());
aiVector3D qs, qr, qt;
m.Decompose(qs, qr, qt);
qr *= DEG;
values.push_back(qr.x);
}
rx.AddChild("KeyTime", times);
rx.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
rx.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
rx.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
rx.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
rx.Dump(outstream);
FBX::Node rxc("C");
rxc.AddProperties("OP", curve_uid, ids[1], "d|X");
connections.push_back(rxc); // TODO: emplace_back
// rotation y
FBX::Node ry("AnimationCurve");
curve_uid = generate_uid();
ry.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
ry.AddChild("Default", double(R.y)); // default value
ry.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumRotationKeys; ++pki) {
const aiQuatKey& k = na->mRotationKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
// there must be a better way...
aiMatrix4x4 m(k.mValue.GetMatrix());
aiVector3D qs, qr, qt;
m.Decompose(qs, qr, qt);
qr *= DEG;
values.push_back(qr.y);
}
ry.AddChild("KeyTime", times);
ry.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
ry.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
ry.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
ry.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
ry.Dump(outstream);
FBX::Node ryc("C");
ryc.AddProperties("OP", curve_uid, ids[1], "d|Y");
connections.push_back(ryc); // TODO: emplace_back
// rotation z
FBX::Node rz("AnimationCurve");
curve_uid = generate_uid();
rz.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
rz.AddChild("Default", double(R.z)); // default value
rz.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumRotationKeys; ++pki) {
const aiQuatKey& k = na->mRotationKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
// there must be a better way...
aiMatrix4x4 m(k.mValue.GetMatrix());
aiVector3D qs, qr, qt;
m.Decompose(qs, qr, qt);
qr *= DEG;
values.push_back(qr.z);
}
rz.AddChild("KeyTime", times);
rz.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
rz.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
rz.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
rz.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
rz.Dump(outstream);
FBX::Node rzc("C");
rzc.AddProperties("OP", curve_uid, ids[1], "d|Z");
connections.push_back(rzc); // TODO: emplace_back
// scale x
FBX::Node sx("AnimationCurve");
curve_uid = generate_uid();
sx.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
sx.AddChild("Default", double(S.x)); // default value
sx.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumScalingKeys; ++pki) {
const aiVectorKey& k = na->mScalingKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.x);
}
sx.AddChild("KeyTime", times);
sx.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
sx.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
sx.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
sx.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
sx.Dump(outstream);
FBX::Node sxc("C");
sxc.AddProperties("OP", curve_uid, ids[2], "d|X");
connections.push_back(sxc); // TODO: emplace_back
// scale y
FBX::Node sy("AnimationCurve");
curve_uid = generate_uid();
sy.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
sy.AddChild("Default", double(S.y)); // default value
sy.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumScalingKeys; ++pki) {
const aiVectorKey& k = na->mScalingKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.y);
}
sy.AddChild("KeyTime", times);
sy.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
sy.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
sy.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
sy.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
sy.Dump(outstream);
FBX::Node syc("C");
syc.AddProperties("OP", curve_uid, ids[2], "d|Y");
connections.push_back(syc); // TODO: emplace_back
// scale z
FBX::Node sz("AnimationCurve");
curve_uid = generate_uid();
sz.AddProperties(curve_uid, FBX::SEPARATOR + "AnimCurve", "");
sz.AddChild("Default", double(S.z)); // default value
sz.AddChild("KeyVer", int32_t(4009));
times.clear();
values.clear();
for (size_t pki = 0; pki < na->mNumScalingKeys; ++pki) {
const aiVectorKey& k = na->mScalingKeys[pki];
times.push_back(to_ktime(k.mTime, anim));
values.push_back(k.mValue.z);
}
sz.AddChild("KeyTime", times);
sz.AddChild("KeyValueFloat", values);
// TODO: keyframe flags (STUB for now)
sz.AddChild("KeyAttrFlags", std::vector<int32_t>{0});
sz.AddChild("KeyAttrDataFloat", std::vector<float>{0,0,0,0});
sz.AddChild("KeyAttrRefCount", std::vector<int32_t>{static_cast<int32_t>(times.size())});
sz.Dump(outstream);
FBX::Node szc("C");
szc.AddProperties("OP", curve_uid, ids[2], "d|Z");
connections.push_back(szc); // TODO: emplace_back
}
}
object_node.End(outstream, true); object_node.End(outstream, true);
} }