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/*
* Copyright (c) 2016-2017, NVIDIA CORPORATION. All rights reserved.
*
* NVIDIA CORPORATION and its licensors retain all intellectual property
* and proprietary rights in and to this software, related documentation
* and any modifications thereto. Any use, reproduction, disclosure or
* distribution of this software and related documentation without an express
* license agreement from NVIDIA CORPORATION is strictly prohibited.
*/
#include "NvBlastExtPxActorImpl.h"
#include "NvBlastExtPxAsset.h"
#include "NvBlastExtPxManagerImpl.h"
#include "NvBlastExtPxFamilyImpl.h"
#include "PxRigidDynamic.h"
#include "PxPhysics.h"
#include "NvBlastTkActor.h"
#include "NvBlastTkAsset.h"
#include "PxRigidBodyExt.h"
namespace Nv
{
namespace Blast
{
ExtPxActorImpl::ExtPxActorImpl(ExtPxFamilyImpl* family, TkActor* tkActor, const PxActorCreateInfo& pxActorInfo)
: m_family(family), m_tkActor(tkActor)
{
const ExtPxChunk* pxChunks = m_family->m_pxAsset.getChunks();
const ExtPxSubchunk* pxSubchunks = m_family->m_pxAsset.getSubchunks();
const NvBlastChunk* chunks = m_tkActor->getAsset()->getChunks();
uint32_t nodeCount = m_tkActor->getGraphNodeCount();
PxFilterData simulationFilterData; // Default constructor = {0,0,0,0}
// get visible chunk indices list
{
auto& chunkIndices = m_family->m_indicesScratch;
chunkIndices.resize(m_tkActor->getVisibleChunkCount());
m_tkActor->getVisibleChunkIndices(chunkIndices.begin(), static_cast<uint32_t>(chunkIndices.size()));
// fill visible chunk indices list with mapped to our asset indices
m_chunkIndices.reserve(chunkIndices.size());
for (const uint32_t chunkIndex : chunkIndices)
{
const ExtPxChunk& chunk = pxChunks[chunkIndex];
if (chunk.subchunkCount == 0)
continue;
m_chunkIndices.pushBack(chunkIndex);
}
// Single lower-support chunk actors might be leaf actors, check for this and disable contact callbacks if so
if (nodeCount <= 1)
{
PX_ASSERT(chunkIndices.size() == 1);
if (chunkIndices.size() > 0)
{
const NvBlastChunk& chunk = chunks[chunkIndices[0]];
if (chunk.firstChildIndex == chunk.childIndexStop)
{
simulationFilterData.word3 = ExtPxManager::LEAF_CHUNK; // mark as leaf chunk if chunk has no children
}
}
}
}
// create rigidDynamic and setup
PxPhysics& physics = m_family->m_manager.m_physics;
m_rigidDynamic = physics.createRigidDynamic(pxActorInfo.m_transform);
if (m_family->m_pxActorDescTemplate != nullptr)
{
m_rigidDynamic->setActorFlags(static_cast<physx::PxActorFlags>(m_family->m_pxActorDescTemplate->flags));
}
// fill rigidDynamic with shapes
PxMaterial* material = m_family->m_spawnSettings.material;
for (uint32_t i = 0; i < m_chunkIndices.size(); ++i)
{
uint32_t chunkID = m_chunkIndices[i];
const ExtPxChunk& chunk = pxChunks[chunkID];
for (uint32_t c = 0; c < chunk.subchunkCount; c++)
{
const uint32_t subchunkIndex = chunk.firstSubchunkIndex + c;
auto& subchunk = pxSubchunks[subchunkIndex];
PxShape* shape = physics.createShape(subchunk.geometry, *material);
shape->setLocalPose(subchunk.transform);
const ExtPxShapeDescTemplate* pxShapeDesc = m_family->m_pxShapeDescTemplate;
if (pxShapeDesc != nullptr)
{
shape->setFlags(static_cast<PxShapeFlags>(pxShapeDesc->flags));
shape->setSimulationFilterData(pxShapeDesc->simulationFilterData);
shape->setQueryFilterData(pxShapeDesc->queryFilterData);
shape->setContactOffset(pxShapeDesc->contactOffset);
shape->setRestOffset(pxShapeDesc->restOffset);
}
else
{
shape->setSimulationFilterData(simulationFilterData);
}
m_rigidDynamic->attachShape(*shape);
PX_ASSERT_WITH_MESSAGE(m_family->m_subchunkShapes[subchunkIndex] == nullptr, "Chunk has some shapes(live).");
m_family->m_subchunkShapes[subchunkIndex] = shape;
}
}
// search for static chunk in actor's graph (make actor static if it contains static chunk)
bool staticFound = false;
if (nodeCount > 0)
{
auto& graphChunkIndices = m_family->m_indicesScratch;
graphChunkIndices.resize(nodeCount);
m_tkActor->getGraphNodeIndices(graphChunkIndices.begin(), static_cast<uint32_t>(graphChunkIndices.size()));
const NvBlastSupportGraph graph = m_tkActor->getAsset()->getGraph();
for (uint32_t i = 0; !staticFound && i < graphChunkIndices.size(); ++i)
{
uint32_t chunkIndex = graph.chunkIndices[graphChunkIndices[i]];
const ExtPxChunk& chunk = pxChunks[chunkIndex];
staticFound = chunk.isStatic;
}
}
m_rigidDynamic->setRigidBodyFlag(PxRigidBodyFlag::eKINEMATIC, staticFound);
// store pointer to actor in px userData
m_family->m_manager.registerActor(m_rigidDynamic, this);
// store pointer to actor in blast userData
m_tkActor->userData = this;
// update mass properties
PxRigidBodyExt::updateMassAndInertia(*m_rigidDynamic, m_family->m_spawnSettings.density);
// set initial velocities
if (!(m_rigidDynamic->getRigidBodyFlags() & PxRigidBodyFlag::eKINEMATIC))
{
m_rigidDynamic->setLinearVelocity(pxActorInfo.m_linearVelocity);
m_rigidDynamic->setAngularVelocity(pxActorInfo.m_angularVelocity);
}
}
void ExtPxActorImpl::release()
{
if (m_rigidDynamic != nullptr)
{
m_family->m_manager.unregisterActor(m_rigidDynamic);
m_rigidDynamic->release();
m_rigidDynamic = nullptr;
}
const ExtPxChunk* pxChunks = m_family->m_pxAsset.getChunks();
for (uint32_t chunkID : m_chunkIndices)
{
const ExtPxChunk& chunk = pxChunks[chunkID];
for (uint32_t c = 0; c < chunk.subchunkCount; c++)
{
const uint32_t subchunkIndex = chunk.firstSubchunkIndex + c;
m_family->m_subchunkShapes[subchunkIndex] = nullptr;
}
}
m_chunkIndices.clear();
m_tkActor->userData = nullptr;
}
ExtPxFamily& ExtPxActorImpl::getFamily() const
{
return *m_family;
}
} // namespace Blast
} // namespace Nv
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