/*! assign (named) vec3i parameter to an object */
void ISPCDevice::setVec3i(OSPObject _object,
const char *bufName,
const vec3i &v)
{
ManagedObject *object = (ManagedObject *)_object;
object->setParam(bufName, v);
}
/*! assign (named) float parameter to an object */
void ISPCDevice::setFloat(OSPObject _object,
const char *bufName,
const float f)
{
ManagedObject *object = (ManagedObject *)_object;
object->setParam(bufName, f);
}
/*! assign (named) float parameter to an object */
void ISPCDevice::setBool(OSPObject _object,
const char *bufName,
const bool b)
{
ManagedObject *object = (ManagedObject *)_object;
object->setParam(bufName, b);
}
/*! assign (named) string parameter to an object */
void ISPCDevice::setVoidPtr(OSPObject _object,
const char *bufName,
void *v)
{
ManagedObject *object = (ManagedObject *)_object;
object->setParam(bufName, v);
}
/*! assign (named) data item as a parameter to an object */
void ISPCDevice::setObject(OSPObject _target,
const char *bufName,
OSPObject _value)
{
ManagedObject *target = (ManagedObject *)_target;
ManagedObject *value = (ManagedObject *)_value;
target->setParam(bufName, value);
}
/*! it's up to the proper init
routine to decide which processes call this function and which
ones don't. This function will not return.
\internal We ssume that mpi::worker and mpi::app have already been set up
*/
void runWorker(int *_ac, const char **_av)
{
ospray::init(_ac,&_av);
// initialize embree. (we need to do this here rather than in
// ospray::init() because in mpi-mode the latter is also called
// in the host-stubs, where it shouldn't.
// std::stringstream embreeConfig;
// if (debugMode)
// embreeConfig << " threads=1";
// rtcInit(embreeConfig.str().c_str());
// assert(rtcGetError() == RTC_NO_ERROR);
rtcSetErrorFunction(embreeErrorFunc);
std::stringstream embreeConfig;
if (debugMode)
embreeConfig << " threads=1,verbose=2";
rtcInit(embreeConfig.str().c_str());
if (rtcGetError() != RTC_NO_ERROR) {
// why did the error function not get called !?
std::cerr << "#osp:init: embree internal error number " << (int)rtcGetError() << std::endl;
assert(rtcGetError() == RTC_NO_ERROR);
}
CommandStream cmd;
char hostname[HOST_NAME_MAX];
gethostname(hostname,HOST_NAME_MAX);
printf("#w: running MPI worker process %i/%i on pid %i@%s\n",
worker.rank,worker.size,getpid(),hostname);
int rc;
// TiledLoadBalancer::instance = new mpi::DynamicLoadBalancer_Slave;
TiledLoadBalancer::instance = new mpi::staticLoadBalancer::Slave;
while (1) {
const int command = cmd.get_int32();
switch (command) {
case api::MPIDevice::CMD_NEW_RENDERER: {
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new renderer \"" << type << "\" ID " << handle << endl;
Renderer *renderer = Renderer::createRenderer(type);
cmd.free(type);
Assert(renderer);
handle.assign(renderer);
} break;
case api::MPIDevice::CMD_NEW_CAMERA: {
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new camera \"" << type << "\" ID " << (void*)(int64)handle << endl;
Camera *camera = Camera::createCamera(type);
cmd.free(type);
Assert(camera);
handle.assign(camera);
// cout << "#w: new camera " << handle << endl;
} break;
case api::MPIDevice::CMD_NEW_VOLUME: {
// Assert(type != NULL && "invalid volume type identifier");
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new volume \"" << type << "\" ID " << (void*)(int64)handle << endl;
Volume *volume = Volume::createInstance(type);
if (!volume)
throw std::runtime_error("unknown volume type '"+std::string(type)+"'");
volume->refInc();
cmd.free(type);
Assert(volume);
handle.assign(volume);
// cout << "#w: new volume " << handle << endl;
} break;
case api::MPIDevice::CMD_NEW_TRANSFERFUNCTION: {
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new transfer function \"" << type << "\" ID " << (void*)(int64)handle << endl;
TransferFunction *transferFunction = TransferFunction::createInstance(type);
if (!transferFunction) {
throw std::runtime_error("unknown transfer function type '"+std::string(type)+"'");
}
transferFunction->refInc();
cmd.free(type);
handle.assign(transferFunction);
} break;
case api::MPIDevice::CMD_NEW_MATERIAL: {
// Assert(type != NULL && "invalid volume type identifier");
const mpi::Handle rendererHandle = cmd.get_handle();
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new material \"" << type << "\" ID " << (void*)(int64)handle << endl;
Renderer *renderer = (Renderer *)rendererHandle.lookup();
Material *material = NULL;
if (renderer) {
material = renderer->createMaterial(type);
if (material) {
material->refInc();
}
}
if (material == NULL)
// no renderer present, or renderer didn't intercept this material.
material = Material::createMaterial(type);
int myFail = (material == NULL);
int sumFail = 0;
rc = MPI_Allreduce(&myFail,&sumFail,1,MPI_INT,MPI_SUM,worker.comm);
if (sumFail == 0) {
material->refInc();
cmd.free(type);
Assert(material);
handle.assign(material);
if (worker.rank == 0) {
if (logLevel > 2)
cout << "#w: new material " << handle << " "
<< material->toString() << endl;
MPI_Send(&sumFail,1,MPI_INT,0,0,mpi::app.comm);
}
} else {
// at least one client could not load/create material ...
if (material) material->refDec();
if (worker.rank == 0) {
if (logLevel > 2)
cout << "#w: could not create material " << handle << " "
<< material->toString() << endl;
MPI_Send(&sumFail,1,MPI_INT,0,0,mpi::app.comm);
}
}
} break;
case api::MPIDevice::CMD_NEW_LIGHT: {
const mpi::Handle rendererHandle = cmd.get_handle();
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new light \"" << type << "\" ID " << (void*)(int64)handle << endl;
Renderer *renderer = (Renderer *)rendererHandle.lookup();
Light *light = NULL;
if (renderer) {
light = renderer->createLight(type);
if (light) {
light->refInc();
}
}
if (light == NULL)
// no renderer present, or renderer didn't intercept this light.
light = Light::createLight(type);
int myFail = (light == NULL);
int sumFail = 0;
rc = MPI_Allreduce(&myFail,&sumFail,1,MPI_INT,MPI_SUM,worker.comm);
if (sumFail == 0) {
light->refInc();
cmd.free(type);
Assert(light);
handle.assign(light);
if (worker.rank == 0) {
if (logLevel > 2)
cout << "#w: new light " << handle << " "
<< light->toString() << endl;
MPI_Send(&sumFail,1,MPI_INT,0,0,mpi::app.comm);
}
} else {
// at least one client could not load/create light ...
if (light) light->refDec();
if (worker.rank == 0) {
if (logLevel > 2)
cout << "#w: could not create light " << handle << " "
<< light->toString() << endl;
MPI_Send(&sumFail,1,MPI_INT,0,0,mpi::app.comm);
}
}
} break;
case api::MPIDevice::CMD_NEW_GEOMETRY: {
// Assert(type != NULL && "invalid volume type identifier");
const mpi::Handle handle = cmd.get_handle();
const char *type = cmd.get_charPtr();
if (worker.rank == 0)
if (logLevel > 2)
cout << "creating new geometry \"" << type << "\" ID " << (void*)(int64)handle << endl;
Geometry *geometry = Geometry::createGeometry(type);
if (!geometry)
throw std::runtime_error("unknown geometry type '"+std::string(type)+"'");
geometry->refInc();
cmd.free(type);
Assert(geometry);
handle.assign(geometry);
if (worker.rank == 0)
if (logLevel > 2)
cout << "#w: new geometry " << handle << " " << geometry->toString() << endl;
} break;
case api::MPIDevice::CMD_FRAMEBUFFER_CREATE: {
const mpi::Handle handle = cmd.get_handle();
const vec2i size = cmd.get_vec2i();
const OSPFrameBufferFormat mode = (OSPFrameBufferFormat)cmd.get_int32();
const uint32 channelFlags = cmd.get_int32();
bool hasDepthBuffer = (channelFlags & OSP_FB_DEPTH);
bool hasAccumBuffer = (channelFlags & OSP_FB_ACCUM);
FrameBuffer *fb = new LocalFrameBuffer(size,mode,hasDepthBuffer,hasAccumBuffer);
handle.assign(fb);
} break;
case api::MPIDevice::CMD_FRAMEBUFFER_CLEAR: {
const mpi::Handle handle = cmd.get_handle();
const uint32 channelFlags = cmd.get_int32();
FrameBuffer *fb = (FrameBuffer*)handle.lookup();
fb->clear(channelFlags);
} break;
case api::MPIDevice::CMD_RENDER_FRAME: {
const mpi::Handle fbHandle = cmd.get_handle();
// const mpi::Handle swapChainHandle = cmd.get_handle();
const mpi::Handle rendererHandle = cmd.get_handle();
const uint32 channelFlags = cmd.get_int32();
FrameBuffer *fb = (FrameBuffer*)fbHandle.lookup();
// SwapChain *sc = (SwapChain*)swapChainHandle.lookup();
// Assert(sc);
Renderer *renderer = (Renderer*)rendererHandle.lookup();
Assert(renderer);
renderer->renderFrame(fb,channelFlags); //sc->getBackBuffer());
// sc->advance();
} break;
case api::MPIDevice::CMD_FRAMEBUFFER_MAP: {
FATAL("should never get called on worker!?");
// const mpi::Handle handle = cmd.get_handle();
// FrameBuffer *fb = (FrameBuffer*)handle.lookup();
// // SwapChain *sc = (SwapChain*)handle.lookup();
// // Assert(sc);
// if (worker.rank == 0) {
// // FrameBuffer *fb = sc->getBackBuffer();
// void *ptr = (void*)fb->map();
// // void *ptr = (void*)sc->map();
// rc = MPI_Send(ptr,fb->size.x*fb->size.y,MPI_INT,0,0,mpi::app.comm);
// Assert(rc == MPI_SUCCESS);
// fb->unmap(ptr);
// }
} break;
case api::MPIDevice::CMD_NEW_MODEL: {
const mpi::Handle handle = cmd.get_handle();
Model *model = new Model;
Assert(model);
handle.assign(model);
if (logLevel > 2)
cout << "#w: new model " << handle << endl;
} break;
case api::MPIDevice::CMD_NEW_TRIANGLEMESH: {
const mpi::Handle handle = cmd.get_handle();
TriangleMesh *triangleMesh = new TriangleMesh;
Assert(triangleMesh);
handle.assign(triangleMesh);
} break;
case api::MPIDevice::CMD_NEW_DATA: {
const mpi::Handle handle = cmd.get_handle();
Data *data = NULL;
size_t nitems = cmd.get_size_t();
OSPDataType format = (OSPDataType)cmd.get_int32();
int flags = cmd.get_int32();
data = new Data(nitems,format,NULL,flags & ~OSP_DATA_SHARED_BUFFER);
Assert(data);
handle.assign(data);
size_t hasInitData = cmd.get_size_t();
if (hasInitData) {
cmd.get_data(nitems*sizeOf(format),data->data);
if (format==OSP_OBJECT) {
/* translating handles to managedobject pointers: if a
data array has 'object' or 'data' entry types, then
what the host sends are _handles_, not pointers, but
what the core expects are pointers; to make the core
happy we translate all data items back to pointers at
this stage */
mpi::Handle *asHandle = (mpi::Handle *)data->data;
ManagedObject **asObjPtr = (ManagedObject **)data->data;
for (int i=0;i<nitems;i++) {
if (asHandle[i] != NULL_HANDLE) {
asObjPtr[i] = asHandle[i].lookup();
asObjPtr[i]->refInc();
}
}
}
}
} break;
case api::MPIDevice::CMD_NEW_TEXTURE2D: {
const mpi::Handle handle = cmd.get_handle();
Texture2D *texture2D = NULL;
int32 width = cmd.get_int32();
int32 height = cmd.get_int32();
int32 type = cmd.get_int32();
int32 flags = cmd.get_int32();
size_t size = cmd.get_size_t();
void *data = malloc(size);
cmd.get_data(size,data);
texture2D = Texture2D::createTexture(width,height,(OSPDataType)type,data,flags);
assert(texture2D);
handle.assign(texture2D);
} break;
case api::MPIDevice::CMD_ADD_GEOMETRY: {
const mpi::Handle modelHandle = cmd.get_handle();
const mpi::Handle geomHandle = cmd.get_handle();
Model *model = (Model*)modelHandle.lookup();
Assert(model);
Geometry *geom = (Geometry*)geomHandle.lookup();
Assert(geom);
model->geometry.push_back(geom);
} break;
case api::MPIDevice::CMD_ADD_VOLUME: {
const mpi::Handle modelHandle = cmd.get_handle();
const mpi::Handle volumeHandle = cmd.get_handle();
Model *model = (Model *) modelHandle.lookup();
Assert(model);
Volume *volume = (Volume *) volumeHandle.lookup();
Assert(volume);
model->volumes.push_back(volume);
} break;
case api::MPIDevice::CMD_COMMIT: {
const mpi::Handle handle = cmd.get_handle();
ManagedObject *obj = handle.lookup();
Assert(obj);
// printf("#w%i:c%i obj %lx\n",worker.rank,(int)handle,obj);
if (logLevel > 2)
cout << "#w: committing " << handle << " " << obj->toString() << endl;
obj->commit();
// hack, to stay compatible with earlier version
Model *model = dynamic_cast<Model *>(obj);
if (model)
model->finalize();
} break;
case api::MPIDevice::CMD_SET_OBJECT: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const mpi::Handle val = cmd.get_handle();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->setParam(name,val.lookup());
cmd.free(name);
} break;
case api::MPIDevice::CMD_RELEASE: {
const mpi::Handle handle = cmd.get_handle();
ManagedObject *obj = handle.lookup();
Assert(obj);
handle.freeObject();
} break;
case api::MPIDevice::CMD_SET_MATERIAL: {
const mpi::Handle geoHandle = cmd.get_handle();
const mpi::Handle matHandle = cmd.get_handle();
Geometry *geo = (Geometry*)geoHandle.lookup();
Material *mat = (Material*)matHandle.lookup();
geo->setMaterial(mat);
} break;
case api::MPIDevice::CMD_SET_STRING: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const char *val = cmd.get_charPtr();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
cmd.free(val);
} break;
case api::MPIDevice::CMD_SET_INT: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const int val = cmd.get_int();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
} break;
case api::MPIDevice::CMD_SET_FLOAT: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const float val = cmd.get_float();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
} break;
case api::MPIDevice::CMD_SET_VEC3F: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const vec3f val = cmd.get_vec3f();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
} break;
case api::MPIDevice::CMD_SET_VEC2F: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const vec2f val = cmd.get_vec2f();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
} break;
case api::MPIDevice::CMD_SET_VEC3I: {
const mpi::Handle handle = cmd.get_handle();
const char *name = cmd.get_charPtr();
const vec3i val = cmd.get_vec3i();
ManagedObject *obj = handle.lookup();
Assert(obj);
obj->findParam(name,1)->set(val);
cmd.free(name);
} break;
case api::MPIDevice::CMD_LOAD_MODULE: {
const char *name = cmd.get_charPtr();
#if THIS_IS_MIC
// embree automatically puts this into "lib<name>.so" format
std::string libName = "ospray_module_"+std::string(name)+"_mic";
#else
std::string libName = "ospray_module_"+std::string(name)+"";
#endif
loadLibrary(libName);
std::string initSymName = "ospray_init_module_"+std::string(name);
void*initSym = getSymbol(initSymName);
if (!initSym)
throw std::runtime_error("could not find module initializer "+initSymName);
void (*initMethod)() = (void(*)())initSym;
initMethod();
cmd.free(name);
} break;
default:
std::stringstream err;
err << "unknown cmd tag " << command;
throw std::runtime_error(err.str());
}
};
}
