bool AlembicCustomAttributesEx::defineCustomAttributes(INode* node, Abc::OCompoundProperty& compoundProp, const AbcA::MetaData& metadata, unsigned int animatedTs)
{
Modifier* pMod = FindModifier(node, (char*)this->modName.c_str());
if(!pMod){
return false;
}
ICustAttribContainer* cont = pMod->GetCustAttribContainer();
if(!cont){
return false;
}
for(int i=0; i<cont->GetNumCustAttribs(); i++)
{
CustAttrib* ca = cont->GetCustAttrib(i);
std::string name = EC_MCHAR_to_UTF8( ca->GetName() );
pblock = ca->GetParamBlockByID(0);
break;
}
if(!pblock){
return false;
}
for(int i=0, nNumParams = pblock->NumParams(); i<nNumParams; i++){
ParamID id = pblock->IndextoID(i);
MSTR name = pblock->GetLocalName(id, 0);
std::stringstream propName;
propName<<EC_MSTR_to_UTF8(name);
ParamType2 type = pblock->GetParameterType(id);
if(type == TYPE_STRING){
customProps[propName.str()] = new Abc::OStringProperty(compoundProp, propName.str().c_str(), metadata, animatedTs );
}
else if(type == TYPE_FLOAT){
customProps[propName.str()] = new Abc::OFloatProperty(compoundProp, propName.str().c_str(), metadata, animatedTs );
}
else if(type == TYPE_INT){
customProps[propName.str()] = new Abc::OInt32Property(compoundProp, propName.str().c_str(), metadata, animatedTs );
}
}
return true;
}
static bool IsDxMaterialEnabled(MtlBase * map)
{
bool enabled = false;
ICustAttribContainer * cont = map->GetCustAttribContainer();
if(cont)
{
for(int i=0; i< cont->GetNumCustAttribs(); i++)
{
CustAttrib * ca = cont->GetCustAttrib(i);
if(ca->GetInterface(VIEWPORT_SHADER_MANAGER_INTERFACE2)){
IViewportShaderManager2 * vsm = (IViewportShaderManager2*)ca->GetInterface(VIEWPORT_SHADER_MANAGER_INTERFACE2);
return vsm->IsDxStdMtlEnabled();
}
}
}
return enabled;
}
void HavokImport::HandleRagdollOnNonAccum(INode* accumChild, INode* ragdollParent)
{
const int MaxChar = 512;
char buffer[MaxChar];
//Fix for nonaccumNodes
//TSTR name(A2THelper(buffer, parent->GetName().c_str(), _countof(buffer)));
ragdollParent->SetName(FormatText(TEXT("Ragdoll_%s"), accumChild->GetName()));
Object *Obj = ragdollParent->GetObjectRef();
if (Obj->SuperClassID() == GEN_DERIVOB_CLASS_ID)
{
while (Obj->SuperClassID() == GEN_DERIVOB_CLASS_ID) {
IDerivedObject *DerObj = static_cast<IDerivedObject *> (Obj);
const int nMods = DerObj->NumModifiers();
for (int i = 0; i < nMods; i++)
{
Modifier *Mod = DerObj->GetModifier(i);
if (Mod->ClassID() == HK_RIGIDBODY_MODIFIER_CLASS_ID)
{
ICustAttribContainer* cc = Mod->GetCustAttribContainer();
if (cc)
{
//reset
Mod->DeleteCustAttribContainer();
}
Mod->AllocCustAttribContainer();
cc = Mod->GetCustAttribContainer();
CustAttrib* c = (CustAttrib*)CreateInstance(CUST_ATTRIB_CLASS_ID, Class_ID(0x6e663460, 0x32682c72));
IParamBlock2* custModParameters = c->GetParamBlock(0);
custModParameters->SetValue(0, 0, accumChild, 0);
cc->InsertCustAttrib(0, c);
}
}
Obj = DerObj->GetObjRef();
}
}
}
RefResult StdDualVSImp::NotifyRefChanged(const Interval& changeInt, RefTargetHandle hTarget, PartID& partID, RefMessage message, BOOL propagate)
{
switch (message)
{
case REFMSG_TARGET_DELETED:
{
int i = FindNodeIndex((INode*)hTarget);
assert(i >= 0);
callb->DeleteRenderMeshCache(caches[i]->GetNode());
delete caches[i];
caches[i] = NULL;
// NH 07|11|02 The cache is no longer dynamic - it will only grow but not shrink,
// so there could be null entries. This was causing a problem in SetReference
// caches.Delete(i,1);
// caches.Shrink();
}
break;
case REFMSG_NODE_MATERIAL_CHANGED:
{
int i = FindNodeIndex((INode*)hTarget);
assert(i >= 0);
DeleteReference(i);
}
break;
case REFMSG_NODE_WSCACHE_UPDATED:
{
int i = FindNodeIndex((INode*)hTarget);
//NH:06|11|02 I removed this, as in an undo situation the node reference may not be restored yet
// as the viewport shader has not been initialised and thus not set the node. In this case -1 is valid
// assert(i >= 0);
if(i >= 0)
caches[i]->SetValid(false);
}
break;
case REFMSG_SUBANIM_STRUCTURE_CHANGED:
case REFMSG_REF_DELETED:
{
BOOL del = TRUE;
int i = FindNodeIndex((INode*)hTarget);
INode * n = (INode*)hTarget;
Mtl * m = n->GetMtl();
if(m)
{
// NH|06|11|02 check for the Viewport Manager - if the Effect is the same as the callback then keep it
ICustAttribContainer *cont = m->GetCustAttribContainer();
if (cont && cont->GetNumCustAttribs()) {
IDXShaderManagerInterface *sm = GetDXShaderManager();
if (!sm)
{
break;
}
for (int kk = 0; kk < cont->GetNumCustAttribs(); kk++) {
CustAttrib *ca = cont->GetCustAttrib(kk);
IViewportShaderManager *manager = (IViewportShaderManager*)ca->GetInterface(VIEWPORT_SHADER_MANAGER_INTERFACE);
if (manager) {
ReferenceTarget *rt = manager->GetActiveEffect();
if(rt == callb->GetRefTarg())
del = FALSE;
}
}
}
}
// Check, if there's still a reference path from the node to the MtlBase
if(!DependsOn(hTarget,callb->GetRefTarg()) && del)
{
DeleteReference(i);
}
forceInvalid = true;
}
}
return REF_SUCCEED;
}
void HavokImport::createRagdollRigidBody(INode* n, INode* parent, INode* ragdollParent, bhkRigidBodyRef rbody) {
const int MaxChar = 512;
char buffer[MaxChar];
//TSTR name(A2THelper(buffer, parent->GetName().c_str(), _countof(buffer)));
n->SetName(FormatText(TEXT("Ragdoll_%s"), parent->GetName()));
Object *pObj = n->GetObjectRef();
IDerivedObject *dobj = nullptr;
if (n->SuperClassID() == GEN_DERIVOB_CLASS_ID)
dobj = static_cast<IDerivedObject*>(pObj);
else {
dobj = CreateDerivedObject(pObj);
}
MotionSystem msys = rbody->GetMotionSystem(); //?
MotionQuality qtype = rbody->GetQualityType();
float mass = rbody->GetMass();
float lindamp = rbody->GetLinearDamping();
float angdamp = rbody->GetAngularDamping();
float frict = rbody->GetFriction();
float resti = rbody->GetRestitution();
float maxlinvel = rbody->GetMaxLinearVelocity();
float maxangvel = rbody->GetMaxAngularVelocity();
float pendepth = rbody->GetPenetrationDepth();
InertiaMatrix im = rbody->GetInertia();
Modifier* rbMod = (Modifier*)CreateInstance(OSM_CLASS_ID, HK_RIGIDBODY_MODIFIER_CLASS_ID);
if (IParamBlock2* rbParameters = rbMod->GetParamBlockByID(PB_RB_MOD_PBLOCK)) {
//These are fundamental parameters
rbParameters->SetValue(PA_RB_MOD_MASS, 0, mass, 0);
rbParameters->SetValue(PA_RB_MOD_RESTITUTION, 0, resti, 0);
rbParameters->SetValue(PA_RB_MOD_FRICTION, 0, frict, 0);
rbParameters->SetValue(PA_RB_MOD_INERTIA_TENSOR, 0, Point3(im[0][0],im[1][1],im[2][2]), 0);
rbParameters->SetValue(PA_RB_MOD_LINEAR_DAMPING, 0, lindamp, 0);
rbParameters->SetValue(PA_RB_MOD_CHANGE_ANGULAR_DAMPING, 0, angdamp, 0);
rbParameters->SetValue(PA_RB_MOD_MAX_LINEAR_VELOCITY, 0, maxlinvel, 0);
rbParameters->SetValue(PA_RB_MOD_MAX_ANGULAR_VELOCITY, 0, maxangvel, 0);
rbParameters->SetValue(PA_RB_MOD_ALLOWED_PENETRATION_DEPTH, 0, pendepth, 0);
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_FIXED, 0);
rbParameters->SetValue(PA_RB_MOD_SOLVER_DEACTIVATION, 0, SD_LOW, 0);
rbParameters->SetValue(PA_RB_MOD_DEACTIVATOR_TYPE, 0, DT_LOW, 0);
/*body->SetMotionSystem(MotionSystem::MO_SYS_BOX);
body->SetDeactivatorType(DeactivatorType::DEACTIVATOR_NEVER);
body->SetSolverDeactivation(SolverDeactivation::SOLVER_DEACTIVATION_LOW);
body->SetQualityType(MO_QUAL_FIXED);*/
/*switch (qtype) {
case MO_QUAL_INVALID:
break;
case MO_QUAL_FIXED:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_FIXED, 0);
break;
case MO_QUAL_KEYFRAMED:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_KEYFRAMED, 0);
break;
case MO_QUAL_DEBRIS:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_DEBRIS, 0);
break;
case MO_QUAL_MOVING:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_MOVING, 0);
break;
case MO_QUAL_CRITICAL:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_CRITICAL, 0);
break;
case MO_QUAL_BULLET:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_BULLET, 0);
break;
case MO_QUAL_USER:
break;
case MO_QUAL_CHARACTER:
break;
case MO_QUAL_KEYFRAMED_REPORT:
rbParameters->SetValue(PA_RB_MOD_QUALITY_TYPE, 0, QT_KEYFRAMED_REPORTING, 0);
break;
}*/
}
//Link Rigid Body to parent Rigid Body
ICustAttribContainer* cc = rbMod->GetCustAttribContainer();
if (!cc)
{
rbMod->AllocCustAttribContainer();
cc = rbMod->GetCustAttribContainer();
}
CustAttrib* c = (CustAttrib*)CreateInstance(CUST_ATTRIB_CLASS_ID, Class_ID(0x6e663460, 0x32682c72));
IParamBlock2* custModParameters = c->GetParamBlock(0);
custModParameters->SetValue(0, 0, parent, 0);
cc->InsertCustAttrib(0, c);
Modifier* constraintMod = nullptr;
vector< bhkSerializableRef > constraints = rbody->GetConstraints();
//Rigid Body constraints
if (ragdollParent) {
for (vector< bhkSerializableRef >::iterator it = constraints.begin(); it != constraints.end(); ) {
bhkConstraintRef constraint = bhkConstraintRef(*it);
if (constraint->IsDerivedType(bhkLimitedHingeConstraint::TYPE)) {
bhkLimitedHingeConstraintRef limitedHingeConstraint = bhkLimitedHingeConstraintRef(*it);
LimitedHingeDescriptor lh = limitedHingeConstraint->GetLimitedHinge();
constraintMod = (Modifier*)CreateInstance(OSM_CLASS_ID, HK_CONSTRAINT_HINGE_CLASS_ID);
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_CONSTRAINT_MOD_COMMON_SPACES_PARAMS)) {
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_NODE, 0, ragdollParent, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_ROTATION_LOCK, 0, 0, 0);
Point3 origin(0, 0, 0);
Matrix3 parentRotation(TOPOINT3(lh.perp2AxleInA1), TOPOINT3(lh.perp2AxleInA2), TOPOINT3(lh.axleA), origin);
Matrix3 childRotation(TOPOINT3(lh.perp2AxleInB1), TOPOINT3(lh.perp2AxleInB2), TOPOINT3(lh.axleB), origin);
//Matrix3 parentRotation(true);
//MatrixFromNormal(TOPOINT3(lh.axleA), parentRotation);
//Matrix3 childRotation(true);
//MatrixFromNormal(TOPOINT3(lh.axleB), childRotation);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_ROTATION, 0, childRotation, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_ROTATION, 0, parentRotation, 0);
}
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_HINGE_MOD_PBLOCK)) {
constraintParameters->SetValue(PA_HINGE_MOD_IS_LIMITED, 0, 1, 0);
constraintParameters->SetValue(PA_HINGE_MOD_LIMIT_MIN, 0, TODEG(lh.minAngle), 0);
constraintParameters->SetValue(PA_HINGE_MOD_LIMIT_MAX, 0, TODEG(lh.maxAngle), 0);
constraintParameters->SetValue(PA_HINGE_MOD_MAX_FRICTION_TORQUE, 0, lh.maxFriction, 0);
// constraintParameters->SetValue(PA_HINGE_MOD_MOTOR_TYPE, 0, lh.motor., 0);
}
}
else if (constraint->IsDerivedType(bhkRagdollConstraint::TYPE)) {
bhkRagdollConstraintRef ragdollConstraint = bhkRagdollConstraintRef(*it);
RagdollDescriptor rag = ragdollConstraint->GetRagdoll();
constraintMod = (Modifier*)CreateInstance(OSM_CLASS_ID, HK_CONSTRAINT_RAGDOLL_CLASS_ID);
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_CONSTRAINT_MOD_COMMON_SPACES_PARAMS)) {
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_NODE, 0, ragdollParent, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_ROTATION_LOCK, 0, 0, 0);
//TOVECTOR3(rag.twistA);
//MatrixFromNormal(TOPOINT3(rag.twistA), parentRotation);
Point3 origin(0,0,0);
Matrix3 parentRotation(TOPOINT3(rag.planeA),TOPOINT3(rag.motorA),TOPOINT3(rag.twistA),origin);
//TOVECTOR3(rag.twistB);
//MatrixFromNormal(TOPOINT3(rag.twistB), childRotation);
Matrix3 childRotation(TOPOINT3(rag.planeB), TOPOINT3(rag.motorB), TOPOINT3(rag.twistB), origin);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_TRANSLATION, 0, TOPOINT3(rag.pivotB), 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_ROTATION, 0, childRotation, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_TRANSLATION, 0, TOPOINT3(rag.pivotA), 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_ROTATION, 0, parentRotation, 0);
}
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_RAGDOLL_MOD_PBLOCK)) {
constraintParameters->SetValue(PA_RAGDOLL_MOD_CONE_ANGLE, 0, TODEG(rag.coneMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_PLANE_MIN, 0, TODEG(rag.planeMinAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_PLANE_MAX, 0, TODEG(rag.planeMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_TWIST_MIN, 0, TODEG(rag.twistMinAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_TWIST_MAX, 0, TODEG(rag.twistMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_MAX_FRICTION_TORQUE, 0, rag.maxFriction, 0);
}
}
else if (constraint->IsDerivedType(bhkMalleableConstraint::TYPE)) {
bhkMalleableConstraintRef malleableConstraint = bhkMalleableConstraintRef(*it);
if (malleableConstraint->GetConstraintType() == (unsigned int)2) {
LimitedHingeDescriptor lh = malleableConstraint->GetLimitedHinge();
constraintMod = (Modifier*)CreateInstance(OSM_CLASS_ID, HK_CONSTRAINT_HINGE_CLASS_ID);
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_CONSTRAINT_MOD_COMMON_SPACES_PARAMS)) {
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_NODE, 0, ragdollParent, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_ROTATION_LOCK, 0, 0, 0);
Point3 origin(0, 0, 0);
Matrix3 parentRotation(TOPOINT3(lh.perp2AxleInA1), TOPOINT3(lh.perp2AxleInA2), TOPOINT3(lh.axleA), origin);
Matrix3 childRotation(TOPOINT3(lh.perp2AxleInB1), TOPOINT3(lh.perp2AxleInB2), TOPOINT3(lh.axleB), origin);
//Matrix3 parentRotation(true);
//MatrixFromNormal(TOPOINT3(lh.axleA), parentRotation);
//Matrix3 childRotation(true);
//MatrixFromNormal(TOPOINT3(lh.axleB), childRotation);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_ROTATION, 0, childRotation, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_ROTATION, 0, parentRotation, 0);
}
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_HINGE_MOD_PBLOCK)) {
constraintParameters->SetValue(PA_HINGE_MOD_IS_LIMITED, 0, 1, 0);
constraintParameters->SetValue(PA_HINGE_MOD_LIMIT_MIN, 0, TODEG(lh.minAngle), 0);
constraintParameters->SetValue(PA_HINGE_MOD_LIMIT_MAX, 0, TODEG(lh.maxAngle), 0);
constraintParameters->SetValue(PA_HINGE_MOD_MAX_FRICTION_TORQUE, 0, lh.maxFriction, 0);
// constraintParameters->SetValue(PA_HINGE_MOD_MOTOR_TYPE, 0, lh.motor., 0);
}
}
else if (malleableConstraint->GetConstraintType() == (unsigned int)7) {
RagdollDescriptor rag = malleableConstraint->GetRagdoll();
constraintMod = (Modifier*)CreateInstance(OSM_CLASS_ID, HK_CONSTRAINT_RAGDOLL_CLASS_ID);
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_CONSTRAINT_MOD_COMMON_SPACES_PARAMS)) {
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_NODE, 0, ragdollParent, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_ROTATION_LOCK, 0, 0, 0);
//TOVECTOR3(rag.twistA);
//MatrixFromNormal(TOPOINT3(rag.twistA), parentRotation);
Point3 origin(0, 0, 0);
Matrix3 parentRotation(TOPOINT3(rag.planeA), TOPOINT3(rag.motorA), TOPOINT3(rag.twistA), origin);
//TOVECTOR3(rag.twistB);
//MatrixFromNormal(TOPOINT3(rag.twistB), childRotation);
Matrix3 childRotation(TOPOINT3(rag.planeB), TOPOINT3(rag.motorB), TOPOINT3(rag.twistB), origin);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_TRANSLATION, 0, TOPOINT3(rag.pivotB), 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_CHILD_SPACE_ROTATION, 0, childRotation, 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_TRANSLATION, 0, TOPOINT3(rag.pivotA), 0);
constraintParameters->SetValue(PA_CONSTRAINT_MOD_PARENT_SPACE_ROTATION, 0, parentRotation, 0);
}
if (IParamBlock2* constraintParameters = constraintMod->GetParamBlockByID(PB_RAGDOLL_MOD_PBLOCK)) {
constraintParameters->SetValue(PA_RAGDOLL_MOD_CONE_ANGLE, 0, TODEG(rag.coneMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_PLANE_MIN, 0, TODEG(rag.planeMinAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_PLANE_MAX, 0, TODEG(rag.planeMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_TWIST_MIN, 0, TODEG(rag.twistMinAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_TWIST_MAX, 0, TODEG(rag.twistMaxAngle), 0);
constraintParameters->SetValue(PA_RAGDOLL_MOD_MAX_FRICTION_TORQUE, 0, rag.maxFriction, 0);
}
}
}
++it;
}
}
dobj->SetAFlag(A_LOCK_TARGET);
dobj->AddModifier(rbMod);
if (constraintMod)
dobj->AddModifier(constraintMod);
dobj->ClearAFlag(A_LOCK_TARGET);
n->SetObjectRef(dobj);
}
void MaxAWDExporter::ExportUserAttributes(Animatable *obj, AWDAttrElement *elem)
{
if (!opts->ExportAttributes())
return;
ICustAttribContainer *attributes = obj->GetCustAttribContainer();
if (attributes) {
int a=0;
int numAttribs=0;
numAttribs = attributes->GetNumCustAttribs();
for (a=0; a<numAttribs; a++) {
int k=0;
CustAttrib *attr = attributes->GetCustAttrib(a);
for (k=0; k<attr->NumParamBlocks(); k++) {
int p=0;
IParamBlock2 *block = attr->GetParamBlock(k);
if (block!=NULL){
char * blockName_ptr=W2A(block->GetLocalName());
if (ATTREQ(blockName_ptr,"AWDObjectSettingsParams") ){ }
// the next three should not occur yet, as we do not read Custom-properties on materials yet
else if (ATTREQ(blockName_ptr,"AWD_MaterialSettingsparams") ){ }
else if (ATTREQ(blockName_ptr,"AWD_EffectMethodsparams") ){ }
else if (ATTREQ(blockName_ptr,"AWDShadingParams") ){ }
else{
for (p=0; p<block->NumParams(); p++) {
ParamID pid = block->IndextoID(p);
Color col;
AColor acol;
Interval valid = FOREVER;
awd_uint16 len = 0;
AWD_field_type type = AWD_FIELD_FLOAT32;
AWD_field_ptr ptr;
ptr.v = NULL;
switch (block->GetParameterType(pid)) {
case TYPE_ANGLE:
case TYPE_PCNT_FRAC:
case TYPE_WORLD:
case TYPE_FLOAT:
type = AWD_FIELD_FLOAT64;
len = sizeof(awd_float64);
ptr.v = malloc(len);
*ptr.f64 = block->GetFloat(pid);
break;
case TYPE_TIMEVALUE:
case TYPE_INT:
type = AWD_FIELD_INT32;
len = sizeof(awd_int32);
ptr.v = malloc(len);
*ptr.i32 = block->GetInt(pid);
break;
case TYPE_BOOL:
type = AWD_FIELD_BOOL;
len = sizeof(awd_bool);
ptr.v = malloc(len);
*ptr.b = (0 != block->GetInt(pid));
break;
case TYPE_FILENAME:
case TYPE_STRING:
type = AWD_FIELD_STRING;
ptr.str = (char*)block->GetStr(pid);
len = strlen(ptr.str);
break;
case TYPE_RGBA:
type = AWD_FIELD_COLOR;
len = sizeof(awd_color);
col = block->GetColor(pid);
ptr.v = malloc(len);
*ptr.col = awdutil_float_color(col.r, col.g, col.b, 1.0);
break;
case TYPE_FRGBA:
type = AWD_FIELD_COLOR;
len = sizeof(awd_color);
acol = block->GetAColor(pid);
ptr.v = malloc(len);
*ptr.col = awdutil_float_color(acol.r, acol.g, acol.b, acol.a);
break;
}
if (ptr.v != NULL) {
ParamDef def = block->GetParamDef(pid);
if (ns == NULL) {
// Namespace has not yet been created; ns is a class
// variable that will be created only once and then
// reused for all user attributes.
char * ns_ptr=opts->AttributeNamespace();//dont free, as this will get freed in the opts delete
ns = new AWDNamespace(ns_ptr, strlen(ns_ptr));
awd->add_namespace(ns);
}
char * thisName=W2A(def.int_name);
elem->set_attr(ns, thisName, strlen(thisName)+1, ptr, len, type);
free(thisName);
}
}
}
free(blockName_ptr);
}
}
}
}
}
CustomAttributes_struct MaxAWDExporter::GetCustomAWDObjectSettings(IDerivedObject * node_der,Animatable *obj)
{
CustomAttributes_struct returnData;
returnData.export_this=true;
returnData.export_this_children=true;
if(node_der!=NULL){
int nMods = node_der->NumModifiers();
for (int m = 0; m<nMods; m++){
Modifier* node_mod = node_der->GetModifier(m);
if (node_mod->IsEnabled()){
MSTR className;
node_mod->GetClassName(className);
char * className_ptr=W2A(className);
if (ATTREQ(className_ptr,"AWDObjectSettings")){
IParamBlock2* pb = GetParamBlock2ByIndex((ReferenceMaker*)node_mod, 0);
if(pb!=NULL){
int numBlockparams=pb->NumParams();
int p=0;
for (p=0; p<numBlockparams; p++) {
ParamID pid = pb->IndextoID(p);
ParamDef def = pb->GetParamDef(pid);
ParamType2 paramtype = pb->GetParameterType(pid);
char * paramName_ptr=W2A(def.int_name);
if (ATTREQ(paramName_ptr, "thisAWDID")){
//if (paramtype==TYPE_STRING)
// skeletonMod_ptr=W2A(pb->GetStr(pid));
}
if (ATTREQ(paramName_ptr, "Export")){
if (paramtype==TYPE_BOOL)
returnData.export_this=(0 != pb->GetInt(pid));
}
if (ATTREQ(paramName_ptr, "ExportChildren")){
if (paramtype==TYPE_BOOL)
returnData.export_this_children=(0 != pb->GetInt(pid));
}
}
}
free (className_ptr);
return returnData;
}
free (className_ptr);
}
}
Object * thisOBJ=(Object *)node_der->GetObjRef();
if(thisOBJ!=NULL){
if((thisOBJ->SuperClassID() == GEN_DERIVOB_CLASS_ID) || (thisOBJ->SuperClassID() == WSM_DERIVOB_CLASS_ID) || (thisOBJ->SuperClassID() == DERIVOB_CLASS_ID )){
IDerivedObject* thisDerObj=( IDerivedObject* ) thisOBJ;
if(thisDerObj!=NULL){
int nMods = thisDerObj->NumModifiers();
for (int m = 0; m<nMods; m++){
Modifier* node_mod = thisDerObj->GetModifier(m);
if (node_mod->IsEnabled()){
MSTR className;
node_mod->GetClassName(className);
char * className_ptr=W2A(className);
if (ATTREQ(className_ptr,"AWDObjectSettings")){
IParamBlock2* pb = GetParamBlock2ByIndex((ReferenceMaker*)node_mod, 0);
if(pb!=NULL){
int numBlockparams=pb->NumParams();
int p=0;
for (p=0; p<numBlockparams; p++) {
ParamID pid = pb->IndextoID(p);
ParamDef def = pb->GetParamDef(pid);
ParamType2 paramtype = pb->GetParameterType(pid);
char * paramName_ptr=W2A(def.int_name);
if (ATTREQ(paramName_ptr, "thisAWDID")){
//if (paramtype==TYPE_STRING)
// skeletonMod_ptr=W2A(pb->GetStr(pid));
}
if (ATTREQ(paramName_ptr, "export")){
if (paramtype==TYPE_BOOL)
returnData.export_this=(0 != pb->GetInt(pid));
}
if (ATTREQ(paramName_ptr, "exportChildren")){
if (paramtype==TYPE_BOOL)
returnData.export_this_children=(0 != pb->GetInt(pid));
}
}
}
free (className_ptr);
return returnData;
}
free (className_ptr);
}
}
}
}
}
}
while(obj->SuperClassID() != BASENODE_CLASS_ID) {
if (obj->SuperClassID() == GEN_DERIVOB_CLASS_ID) {
IDerivedObject *dobj = (IDerivedObject *)obj;
obj = dobj->GetObjRef(); // Get next object down mod-stack.
}
else {
break; // Failed.
}
}
ICustAttribContainer *attributes = obj->GetCustAttribContainer();
if (attributes) {
int a=0;
int numAttribs=0;
numAttribs = attributes->GetNumCustAttribs();
for (a=0; a<numAttribs; a++) {
int p=0;
int t=0;
CustAttrib *attr = attributes->GetCustAttrib(a);
for (t=0; t<attr->NumParamBlocks(); t++) {
IParamBlock2 *block = attr->GetParamBlock(t);
char * localName_ptr=W2A(block->GetLocalName());
if (ATTREQ(localName_ptr,"AWD_Export") ){
for (p=0; p<block->NumParams(); p++) {
ParamID pid = block->IndextoID(p);
ParamDef def = block->GetParamDef(pid);
char * paramName_ptr=W2A(def.int_name);
if (block->GetParameterType(pid)==TYPE_BOOL){
if (ATTREQ(paramName_ptr,"Export") )
returnData.export_this= (0 != block->GetInt(pid));
else if (ATTREQ(paramName_ptr,"ExportChildren") )
returnData.export_this_children= (0 != block->GetInt(pid));
}
free(paramName_ptr);
}
}
free(localName_ptr);
}
}
}
return returnData;
}
void SaveMetaData(INode* node, AlembicObject* object)
{
if (object == NULL) {
return;
}
if (object->GetNumSamples() > 0) {
return;
}
Modifier* pMod = FindModifier(node, Class_ID(0xd81fc3e, 0x1e4eacf5));
bool bReadCustAttribs = false;
if (!pMod) {
pMod = FindModifier(node, "Metadata");
bReadCustAttribs = true;
}
if (!pMod) {
return;
}
std::vector<std::string> metaData;
if (bReadCustAttribs) {
ICustAttribContainer* cont = pMod->GetCustAttribContainer();
if (!cont) {
return;
}
for (int i = 0; i < cont->GetNumCustAttribs(); i++) {
CustAttrib* ca = cont->GetCustAttrib(i);
std::string name = EC_MCHAR_to_UTF8(ca->GetName());
IParamBlock2* pblock = ca->GetParamBlockByID(0);
if (pblock) {
int nNumParams = pblock->NumParams();
for (int i = 0; i < nNumParams; i++) {
ParamID id = pblock->IndextoID(i);
// MSTR name = pblock->GetLocalName(id, 0);
MSTR value = pblock->GetStr(id, 0);
metaData.push_back(EC_MSTR_to_UTF8(value));
}
}
}
}
else {
IParamBlock2* pblock = pMod->GetParamBlockByID(0);
if (pblock && pblock->NumParams() == 1) {
ParamID id = pblock->IndextoID(0);
MSTR name = pblock->GetLocalName(id, 0);
int nSize = pblock->Count(id);
for (int i = 0; i < nSize; i++) {
MSTR value = pblock->GetStr(id, 0, i);
metaData.push_back(EC_MSTR_to_UTF8(value));
}
}
}
if (metaData.size() > 0) {
Abc::OStringArrayProperty metaDataProperty = Abc::OStringArrayProperty(
object->GetCompound(), ".metadata", object->GetCompound().getMetaData(),
object->GetCurrentJob()->GetAnimatedTs());
Abc::StringArraySample metaDataSample(&metaData.front(), metaData.size());
metaDataProperty.set(metaDataSample);
}
}
