OpenVDB 11.0.0
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NanoVDB Hello World Examples

The first example shows how to convert an OpenVDB level set sphere into a NanoVDB level set, use accessors to print out multiple values from both grids, and save the NanoVDB grid to file. Note that this example depends on both OpenVDB and NanoVDB.

#include <openvdb/tools/LevelSetSphere.h> // replace with your own dependencies for generating the OpenVDB grid
#include <nanovdb/util/CreateNanoGrid.h> // converter from OpenVDB to NanoVDB (includes NanoVDB.h and GridManager.h)
// Convert an openvdb level set sphere into a nanovdb, use accessors to print out multiple values from both
// grids and save the NanoVDB grid to file.
// Note, main depends on BOTH OpenVDB and NanoVDB.
int main()
{
try {
// Create an OpenVDB grid (here a level set surface but replace this with your own code)
auto srcGrid = openvdb::tools::createLevelSetSphere<openvdb::FloatGrid>(100.0f, openvdb::Vec3f(0.0f), 1.0f);
// Convert the OpenVDB grid, srcGrid, into a NanoVDB grid handle.
auto handle = nanovdb::createNanoGrid(*srcGrid);
// Define a (raw) pointer to the NanoVDB grid on the host. Note we match the value type of the srcGrid!
auto* dstGrid = handle.grid<float>();
if (!dstGrid)
throw std::runtime_error("GridHandle does not contain a grid with value type float");
// Get accessors for the two grids. Note that accessors only accelerate repeated access!
auto dstAcc = dstGrid->getAccessor();
auto srcAcc = srcGrid->getAccessor();
// Access and print out a cross-section of the narrow-band level set from the two grids
for (int i = 97; i < 104; ++i) {
printf("(%3i,0,0) OpenVDB cpu: % -4.2f, NanoVDB cpu: % -4.2f\n", i, srcAcc.getValue(openvdb::Coord(i, 0, 0)), dstAcc.getValue(nanovdb::Coord(i, 0, 0)));
}
nanovdb::io::writeGrid("data/sphere.nvdb", handle); // Write the NanoVDB grid to file and throw if writing fails
}
catch (const std::exception& e) {
std::cerr << "An exception occurred: \"" << e.what() << "\"" << std::endl;
}
return 0;
}
Convert any grid to a nanovdb grid of the same type, e.g. float->float.
Generate a narrow-band level set of sphere.
Signed (i, j, k) 32-bit integer coordinate class, similar to openvdb::math::Coord.
Definition NanoVDB.h:1302
Signed (x, y, z) 32-bit integer coordinates.
Definition Coord.h:25
Definition Vec3.h:24
void writeGrid(const std::string &fileName, const GridHandle< BufferT > &handle, io::Codec codec=io::Codec::NONE, int verbose=0)
Write a single grid to file (over-writing existing content of the file)
Definition IO.h:487
disable_if< BuildTraits< DstBuildT >::is_index||BuildTraits< DstBuildT >::is_Fp, GridHandle< BufferT > >::type createNanoGrid(const SrcGridT &srcGrid, StatsMode sMode=StatsMode::Default, ChecksumMode cMode=ChecksumMode::Default, int verbose=0, const BufferT &buffer=BufferT())
Freestanding function that creates a NanoGrid<T> from any source grid.
Definition CreateNanoGrid.h:1956

The second example reads a NanoVDB grid from a file (the one saved in the previous example) and prints out multiple values. Note that this example does not depend on OpenVDB (nor CUDA), only NanoVDB.

#include <nanovdb/util/IO.h> // this is required to read (and write) NanoVDB files on the host
/// @brief Read a NanoVDB grid from a file and print out multiple values.
///
/// @note Note This example does NOT depend on OpenVDB (nor CUDA), only NanoVDB.
int main()
{
try {
auto handle = nanovdb::io::readGrid("data/sphere.nvdb"); // reads first grid from file
auto* grid = handle.grid<float>(); // get a (raw) pointer to a NanoVDB grid of value type float
if (!grid)
throw std::runtime_error("File did not contain a grid with value type float");
auto acc = grid->getAccessor(); // create an accessor for fast access to multiple values
for (int i = 97; i < 104; ++i) {
printf("(%3i,0,0) NanoVDB cpu: % -4.2f\n", i, acc.getValue(nanovdb::Coord(i, 0, 0)));
}
}
catch (const std::exception& e) {
std::cerr << "An exception occurred: \"" << e.what() << "\"" << std::endl;
}
return 0;
}
GridHandle< BufferT > readGrid(const std::string &fileName, int n=0, int verbose=0, const BufferT &buffer=BufferT())
Read and return one or all grids from a file into a single GridHandle.
Definition IO.h:580

The third example reads a NanoVDB grid from a file (the one saved in the first example) and prints out multiple values on both the CPU and GPU. Note that this example does NOT depend on OpenVDB, only NanoVDB and CUDA.

#include <nanovdb/util/IO.h> // this is required to read (and write) NanoVDB files on the host
#include <nanovdb/util/cuda/CudaDeviceBuffer.h> // required for CUDA memory management
extern "C" void launch_kernels(const nanovdb::NanoGrid<float>*,
cudaStream_t stream);
/// @brief Read a NanoVDB grid from a file and print out multiple values on both the cpu and gpu.
///
/// @note Note This example does NOT depend on OpenVDB, only NanoVDB and CUDA.
int main()
{
try {
// returns a GridHandle using CUDA for memory management.
auto handle = nanovdb::io::readGrid<nanovdb::CudaDeviceBuffer>("data/sphere.nvdb");
cudaStream_t stream; // Create a CUDA stream to allow for asynchronous copy of pinned CUDA memory.
cudaStreamCreate(&stream);
handle.deviceUpload(stream, false); // Copy the NanoVDB grid to the GPU asynchronously
auto* cpuGrid = handle.grid<float>(); // get a (raw) pointer to a NanoVDB grid of value type float on the CPU
auto* deviceGrid = handle.deviceGrid<float>(); // get a (raw) pointer to a NanoVDB grid of value type float on the GPU
if (!deviceGrid || !cpuGrid)
throw std::runtime_error("GridHandle did not contain a grid with value type float");
launch_kernels(deviceGrid, cpuGrid, stream); // Call a host method to print a grid values on both the CPU and GPU
cudaStreamDestroy(stream); // Destroy the CUDA stream
}
catch (const std::exception& e) {
std::cerr << "An exception occurred: \"" << e.what() << "\"" << std::endl;
}
return 0;
}
Highest level of the data structure. Contains a tree and a world->index transform (that currently onl...
Definition NanoVDB.h:3699

NVCC requires the CUDA kernel to be defined in a separate .cu file:

#include <nanovdb/NanoVDB.h> // this defined the core tree data structure of NanoVDB accessible on both the host and device
#include <stdio.h> // for printf
// This is called by the host only
void cpu_kernel(const nanovdb::NanoGrid<float>* cpuGrid)
{
auto cpuAcc = cpuGrid->getAccessor();
for (int i = 97; i < 104; ++i) {
printf("(%3i,0,0) NanoVDB cpu: % -4.2f\n", i, cpuAcc.getValue(nanovdb::Coord(i, 0, 0)));
}
}
// This is called by the device only
__global__ void gpu_kernel(const nanovdb::NanoGrid<float>* deviceGrid)
{
if (threadIdx.x > 6)
return;
int i = 97 + threadIdx.x;
auto gpuAcc = deviceGrid->getAccessor();
printf("(%3i,0,0) NanoVDB gpu: % -4.2f\n", i, gpuAcc.getValue(nanovdb::Coord(i, 0, 0)));
}
// This is called by the client code on the host
extern "C" void launch_kernels(const nanovdb::NanoGrid<float>* deviceGrid,
const nanovdb::NanoGrid<float>* cpuGrid,
cudaStream_t stream)
{
// Launch the device kernel asynchronously
gpu_kernel<<<1, 64, 0, stream>>>(deviceGrid);
// Launch the host "kernel" (synchronously)
cpu_kernel(cpuGrid);
}
Implements a light-weight self-contained VDB data-structure in a single file! In other words,...
#define __global__
Definition NanoVDB.h:216
AccessorType getAccessor() const
Return a new instance of a ReadAccessor used to access values in this grid.
Definition NanoVDB.h:3759