OSPRay API

To access the OSPRay API you first need to include the OSPRay header

#include "ospray/ospray.h"

where the API is compatible with C99 and C++.

Initialization and Shutdown

To use the API, OSPRay must be initialized with a “device”. A device is the object which implements the API. Creating and initializing a device can be done in either of two ways: command line arguments using ospInit or manually instantiating a device and setting parameters on it.

Command Line Arguments

The first is to do so by giving OSPRay the command line from main() by calling

OSPError ospInit(int *argc, const char **argv);

OSPRay parses (and removes) its known command line parameters from your application’s main function. For an example see the tutorial. For possible error codes see section Error Handling and Status Messages. It is important to note that the arguments passed to ospInit() are processed in order they are listed. The following parameters (which are prefixed by convention with “--osp:”) are understood:

Command line parameters accepted by OSPRay’s ospInit.

Parameter

Description

--osp:debug

enables various extra checks and debug output, and disables multi-threading

--osp:num-threads=<n>

use n threads instead of per default using all detected hardware threads

--osp:log-level=<str>

set logging level; valid values (in order of severity) are none, error, warning, info, and debug

--osp:warn-as-error

send warning and error messages through the error callback, otherwise send warning messages through the message callback; must have sufficient logLevel to enable warnings

--osp:verbose

shortcut for --osp:log-level=info and enable debug output on cout, error output on cerr

--osp:vv

shortcut for --osp:log-level=debug and enable debug output on cout, error output on cerr

--osp:load-modules=<name>[,...]

load one or more modules during initialization; equivalent to calling ospLoadModule(name)

--osp:log-output=<dst>

convenience for setting where status messages go; valid values for dst are cerr and cout

--osp:error-output=<dst>

convenience for setting where error messages go; valid values for dst are cerr and cout

--osp:device=<name>

use name as the type of device for OSPRay to create; e.g., --osp:device=cpu gives you the default cpu device; Note if the device to be used is defined in a module, remember to pass --osp:load-modules=<name> first

--osp:set-affinity=<n>

if 1, bind software threads to hardware threads; 0 disables binding; default is 1 on KNL and 0 otherwise

--osp:device-params=<param>:<value>[,...]

set one or more other device parameters; equivalent to calling ospDeviceSet*(param, value)

Manual Device Instantiation

The second method of initialization is to explicitly create the device and possibly set parameters. This method looks almost identical to how other objects are created and used by OSPRay (described in later sections). The first step is to create the device with

OSPDevice ospNewDevice(const char *type);

where the type string maps to a specific device implementation. OSPRay always provides the “cpu” device, which maps to a fast, local CPU implementation. Other devices can also be added through additional modules, such as distributed MPI device implementations.

Once a device is created, you can call

void ospDeviceSetParam(OSPObject, const char *id, OSPDataType type, const void *mem);

to set parameters on the device. The semantics of setting parameters is exactly the same as ospSetParam, which is documented below in the parameters section. The following parameters can be set on all devices:

Parameters shared by all devices.

Type

Name

Description

int

numThreads

number of threads which OSPRay should use

int

logLevel

logging level; valid values (in order of severity) are OSP_LOG_NONE, OSP_LOG_ERROR, OSP_LOG_WARNING, OSP_LOG_INFO, and OSP_LOG_DEBUG

string

logOutput

convenience for setting where status messages go; valid values are cerr and cout

string

errorOutput

convenience for setting where error messages go; valid values are cerr and cout

bool

debug

set debug mode; equivalent to logLevel=debug and numThreads=1

bool

warnAsError

send warning and error messages through the error callback, otherwise send warning messages through the message callback; must have sufficient logLevel to enable warnings

bool

setAffinity

bind software threads to hardware threads if set to 1; 0 disables binding omitting the parameter will let OSPRay choose

Once parameters are set on the created device, the device must be committed with

void ospDeviceCommit(OSPDevice);

To use the newly committed device, you must call

void ospSetCurrentDevice(OSPDevice);

This then sets the given device as the object which will respond to all other OSPRay API calls.

Device handle lifetimes are managed with two calls, the first which increments the internal reference count to the given OSPDevice

void ospDeviceRetain(OSPDevice)

and the second which decrements the reference count

void ospDeviceRelease(OSPDevice)

Users can change parameters on the device after initialization (from either method above), by calling

OSPDevice ospGetCurrentDevice();

This function returns the handle to the device currently used to respond to OSPRay API calls, where users can set/change parameters and recommit the device. If changes are made to the device that is already set as the current device, it does not need to be set as current again. Note this API call will increment the ref count of the returned device handle, so applications must use ospDeviceRelease when finished using the handle to avoid leaking the underlying device object. If there is no current device set, this will return an invalid NULL handle.

When a device is created, its reference count is initially 1. When a device is set as the current device, it internally has its reference count incremented. Note that ospDeviceRetain and ospDeviceRelease should only be used with reference counts that the application tracks: removing reference held by the current set device should be handled by ospShutdown. Thus, ospDeviceRelease should only decrement the reference counts that come from ospNewDevice, ospGetCurrentDevice, and the number of explicit calls to ospDeviceRetain.

OSPRay allows applications to query runtime properties of a device in order to do enhanced validation of what device was loaded at runtime. The following function can be used to get these device-specific properties (attributes about the device, not parameter values)

int64_t ospDeviceGetProperty(OSPDevice, OSPDeviceProperty);

It returns an integer value of the queried property and the following properties can be provided as parameter:

OSP_DEVICE_VERSION
OSP_DEVICE_VERSION_MAJOR
OSP_DEVICE_VERSION_MINOR
OSP_DEVICE_VERSION_PATCH
OSP_DEVICE_SO_VERSION

Environment Variables

OSPRay’s generic device parameters can be overridden via environment variables for easy changes to OSPRay’s behavior without needing to change the application (variables are prefixed by convention with “OSPRAY_”):

Environment variables interpreted by OSPRay.

Variable

Description

OSPRAY_NUM_THREADS

equivalent to --osp:num-threads

OSPRAY_LOG_LEVEL

equivalent to --osp:log-level

OSPRAY_LOG_OUTPUT

equivalent to --osp:log-output

OSPRAY_ERROR_OUTPUT

equivalent to --osp:error-output

OSPRAY_DEBUG

equivalent to --osp:debug

OSPRAY_WARN_AS_ERROR

equivalent to --osp:warn-as-error

OSPRAY_SET_AFFINITY

equivalent to --osp:set-affinity

OSPRAY_LOAD_MODULES

equivalent to --osp:load-modules, can be a comma separated list of modules which will be loaded in order

OSPRAY_DEVICE

equivalent to --osp:device:

Note that these environment variables take precedence over values specified through ospInit or manually set device parameters.

Error Handling and Status Messages

The following errors are currently used by OSPRay:

Possible error codes, i.e., valid named constants of type OSPError.

Name

Description

OSP_NO_ERROR

no error occurred

OSP_UNKNOWN_ERROR

an unknown error occurred

OSP_INVALID_ARGUMENT

an invalid argument was specified

OSP_INVALID_OPERATION

the operation is not allowed for the specified object

OSP_OUT_OF_MEMORY

there is not enough memory to execute the command

OSP_UNSUPPORTED_CPU

the CPU is not supported (minimum ISA is SSE4.1 on x86_64 and NEON on ARM64)

OSP_VERSION_MISMATCH

a module could not be loaded due to mismatching version

These error codes are either directly return by some API functions, or are recorded to be later queried by the application via

OSPError ospDeviceGetLastErrorCode(OSPDevice);

A more descriptive error message can be queried by calling

const char* ospDeviceGetLastErrorMsg(OSPDevice);

Alternatively, the application can also register a callback function of type

typedef void (*OSPErrorCallback)(void *userData, OSPError, const char* errorDetails);

via

void ospDeviceSetErrorCallback(OSPDevice, OSPErrorCallback, void *userData);

to get notified when errors occur.

Applications may be interested in messages which OSPRay emits, whether for debugging or logging events. Applications can call

void ospDeviceSetStatusCallback(OSPDevice, OSPStatusCallback, void *userData);

in order to register a callback function of type

typedef void (*OSPStatusCallback)(void *userData, const char* messageText);

which OSPRay will use to emit status messages. By default, OSPRay uses a callback which does nothing, so any output desired by an application will require that a callback is provided. Note that callbacks for C++ std::cout and std::cerr can be alternatively set through ospInit() or the OSPRAY_LOG_OUTPUT environment variable.

Applications can clear either callback by passing NULL instead of an actual function pointer.

Loading OSPRay Extensions at Runtime

OSPRay’s functionality can be extended via plugins (which we call “modules”), which are implemented in shared libraries. To load module name from libospray_module_<name>.so (on Linux and Mac OS X) or ospray_module_<name>.dll (on Windows) use

OSPError ospLoadModule(const char *name);

Modules are searched in OS-dependent paths. ospLoadModule returns OSP_NO_ERROR if the plugin could be successfully loaded.

Shutting Down OSPRay

When the application is finished using OSPRay (typically on application exit), the OSPRay API should be finalized with

void ospShutdown();

This API call ensures that the current device is cleaned up appropriately. Due to static object allocation having non-deterministic ordering, it is recommended that applications call ospShutdown() before the calling application process terminates.

Objects

All entities of OSPRay (the renderer, volumes, geometries, lights, cameras, …) are a logical specialization of OSPObject and share common mechanism to deal with parameters and lifetime.

An important aspect of object parameters is that parameters do not get passed to objects immediately. Instead, parameters are not visible at all to objects until they get explicitly committed to a given object via a call to

void ospCommit(OSPObject);

at which time all previously additions or changes to parameters are visible at the same time. If a user wants to change the state of an existing object (e.g., to change the origin of an already existing camera) it is perfectly valid to do so, as long as the changed parameters are recommitted.

The commit semantic allow for batching up multiple small changes, and specifies exactly when changes to objects will occur. This can impact performance and consistency for devices crossing a PCI bus or across a network.

Note that OSPRay uses reference counting to manage the lifetime of all objects, so one cannot explicitly “delete” any object. Instead, to indicate that the application does not need and does not access the given object anymore, call

void ospRelease(OSPObject);

This decreases its reference count and if the count reaches 0 the object will automatically get deleted. Passing NULL is not an error. Note that every handle returned via the API needs to be released when the object is no longer needed, to avoid memory leaks.

Sometimes applications may want to have more than one reference to an object, where it is desirable for the application to increment the reference count of an object. This is done with

void ospRetain(OSPObject);

It is important to note that this is only necessary if the application wants to call ospRelease on an object more than once: objects which contain other objects as parameters internally increment/decrement ref counts and should not be explicitly done by the application.

Parameters

Parameters allow to configure the behavior of and to pass data to objects. However, objects do not have an explicit interface for reasons of high flexibility and a more stable compile-time API. Instead, parameters are passed separately to objects in an arbitrary order, and unknown parameters will simply be ignored (though a warning message will be posted). The following function allows adding various types of parameters with name id to a given object:

void ospSetParam(OSPObject, const char *id, OSPDataType type, const void *mem);

The valid parameter names for all OSPObjects and what types are valid are discussed in future sections.

Note that mem must always be a pointer to the object, otherwise accidental type casting can occur. This is especially true for pointer types (OSP_VOID_PTR and OSPObject handles), as they will implicitly cast to void\ *, but be incorrectly interpreted. To help with some of these issues, there also exist variants of ospSetParam for specific types, such as ospSetInt and ospSetVec3f in the OSPRay utility library (found in ospray_util.h). Note that half precision float parameters OSP_HALF, OSP_VEC[234]H are not supported.

Users can also remove parameters that have been explicitly set from ospSetParam. Any parameters which have been removed will go back to their default value during the next commit unless a new parameter was set after the parameter was removed. To remove a parameter, use

void ospRemoveParam(OSPObject, const char *id);

Data

OSPRay consumes data arrays from the application using a specific object type, OSPData. There are several components to describing a data array: element type, 1/2/3 dimensional striding, and whether the array is shared with the application or copied into opaque, OSPRay-owned memory.

Shared data arrays require that the application’s array memory outlives the lifetime of the created OSPData, as OSPRay is referring to application memory. Where this is not preferable, applications use opaque arrays to allow the OSPData to own the lifetime of the array memory. However, opaque arrays dictate the cost of copying data into it, which should be kept in mind.

Thus, the most efficient way to specify a data array from the application is to created a shared data array, which is done with

OSPData ospNewSharedData(const void *sharedData,
    OSPDataType,
    uint64_t numItems1,
    int64_t byteStride1 = 0,
    uint64_t numItems2 = 1,
    int64_t byteStride2 = 0,
    uint64_t numItems3 = 1,
    int64_t byteStride3 = 0);

The call returns an OSPData handle to the created array. The calling program guarantees that the sharedData pointer will remain valid for the duration that this data array is being used. The number of elements numItems must be positive (there cannot be an empty data object). The data is arranged in three dimensions, with specializations to two or one dimension (if some numItems are 1). The distance between consecutive elements (per dimension) is given in bytes with byteStride and can also be negative. If byteStride is zero it will be determined automatically (e.g., as sizeof(type)). Strides do not need to be ordered, i.e., byteStride2 can be smaller than byteStride1, which is equivalent to a transpose. However, if the stride should be calculated, then an ordering in dimensions is assumed to disambiguate, i.e., byteStride1 < byteStride2 < byteStride3.

The enum type OSPDataType describes the different element types that can be represented in OSPRay; valid constants are listed in the table below.

Valid named constants for OSPDataType.

Type/Name

Description

OSP_DEVICE

API device object reference

OSP_DATA

data reference

OSP_OBJECT

generic object reference

OSP_CAMERA

camera object reference

OSP_FRAMEBUFFER

framebuffer object reference

OSP_LIGHT

light object reference

OSP_MATERIAL

material object reference

OSP_TEXTURE

texture object reference

OSP_RENDERER

renderer object reference

OSP_WORLD

world object reference

OSP_GEOMETRY

geometry object reference

OSP_VOLUME

volume object reference

OSP_TRANSFER_FUNCTION

transfer function object reference

OSP_IMAGE_OPERATION

image operation object reference

OSP_STRING

C-style zero-terminated character string

OSP_CHAR, OSP_VEC[234]C

8 bit signed character scalar and [234]-element vector

OSP_UCHAR, OSP_VEC[234]UC

8 bit unsigned character scalar and [234]-element vector

OSP_SHORT, OSP_VEC[234]S

16 bit unsigned integer scalar and [234]-element vector

OSP_USHORT, OSP_VEC[234]US

16 bit unsigned integer scalar and [234]-element vector

OSP_INT, OSP_VEC[234]I

32 bit signed integer scalar and [234]-element vector

OSP_UINT, OSP_VEC[234]UI

32 bit unsigned integer scalar and [234]-element vector

OSP_LONG, OSP_VEC[234]L

64 bit signed integer scalar and [234]-element vector

OSP_ULONG, OSP_VEC[234]UL

64 bit unsigned integer scalar and [234]-element vector

OSP_HALF, OSP_VEC[234]H

16 bit half precision floating-point scalar and [234]-element vector (IEEE 754 binary16)

OSP_FLOAT, OSP_VEC[234]F

32 bit single precision floating-point scalar and [234]-element vector

OSP_DOUBLE, OSP_VEC[234]D

64 bit double precision floating-point scalar and [234]-element vector

OSP_BOX[1234]I

32 bit integer box (lower + upper bounds)

OSP_BOX[1234]F

32 bit single precision floating-point box (lower + upper bounds)

OSP_LINEAR[23]F

32 bit single precision floating-point linear transform ([23] vectors)

OSP_AFFINE[23]F

32 bit single precision floating-point affine transform (linear transform plus translation)

OSP_QUATF

32 bit single precision floating-point quaternion, in \((i, j, k, w)\) layout

OSP_VOID_PTR

raw memory address (only found in module extensions)

If the elements of the array are handles to objects, then their reference counter is incremented.

An opaque OSPData with memory allocated by OSPRay is created with

OSPData ospNewData(OSPDataType,
    uint64_t numItems1,
    uint64_t numItems2 = 1,
    uint64_t numItems3 = 1);

To allow for (partial) copies or updates of data arrays use

void ospCopyData(const OSPData source,
    OSPData destination,
    uint64_t destinationIndex1 = 0,
    uint64_t destinationIndex2 = 0,
    uint64_t destinationIndex3 = 0);

which will copy the whole 1 content of the source array into destination at the given location destinationIndex. The OSPDataTypes of the data objects must match. The region to be copied must be valid inside the destination, i.e., in all dimensions, destinationIndex + sourceSize <= destinationSize. The affected region [destinationIndex, destinationIndex + sourceSize) is marked as dirty, which may be used by OSPRay to only process or update that sub-region (e.g., updating an acceleration structure). If the destination array is shared with OSPData by the application (created with ospNewSharedData), then

  • the source array must be shared as well (thus ospCopyData cannot be used to read opaque data)

  • if source and destination memory overlaps (aliasing), then behavior is undefined

  • except if source and destination regions are identical (including matching strides), which can be used by application to mark that region as dirty (instead of the whole OSPData)

To add a data array as parameter named id to another object call also use

void ospSetObject(OSPObject, const char *id, OSPData);

Volumes

Volumes are volumetric data sets with discretely sampled values in 3D space, typically a 3D scalar field. To create a new volume object of given type type use

OSPVolume ospNewVolume(const char *type);

Note that OSPRay’s implementation forwards type directly to Open VKL, allowing new Open VKL volume types to be usable within OSPRay without the need to change (or even recompile) OSPRay.

Structured Regular Volume

Structured volumes only need to store the values of the samples, because their addresses in memory can be easily computed from a 3D position. A common type of structured volumes are regular grids.

Structured regular volumes are created by passing the type string “structuredRegular” to ospNewVolume. Structured volumes are represented through an OSPData 3D array data (which may or may not be shared with the application). The voxel data must be laid out in xyz-order 2 and can be compact (best for performance) or can have a stride between voxels, specified through the byteStride1 parameter when creating the OSPData. Only 1D strides are supported, additional strides between scanlines (2D, byteStride2) and slices (3D, byteStride3) are not.

The parameters understood by structured volumes are summarized in the table below.

Configuration parameters for structured regular volumes.

Type

Name

Default

Description

vec3f

gridOrigin

\((0, 0, 0)\)

origin of the grid in object-space

vec3f

gridSpacing

\((1, 1, 1)\)

size of the grid cells in object-space

OSPData

data

the actual voxel 3D data

int

filter

OSP_VOLUME_FILTER_TRILINEAR

filter used for reconstructing the field, also allowed is OSP_VOLUME_FILTER_NEAREST and OSP_VOLUME_FILTER_TRICUBIC

int

gradientFilter

same as filter

filter used during gradient computations

float

background

NaN

value that is used when sampling an undefined region outside the volume domain

The size of the volume is inferred from the size of the 3D array data, as is the type of the voxel values (currently supported are: OSP_UCHAR, OSP_SHORT, OSP_USHORT, OSP_HALF, OSP_FLOAT, and OSP_DOUBLE).

Structured Spherical Volume

Structured spherical volumes are also supported, which are created by passing a type string of “structuredSpherical” to ospNewVolume. The grid dimensions and parameters are defined in terms of radial distance \(r\), inclination angle \(\theta\), and azimuthal angle \(\phi\), conforming with the ISO convention for spherical coordinate systems. The coordinate system and parameters understood by structured spherical volumes are summarized below.

Coordinate system of structured spherical volumes.

Coordinate system of structured spherical volumes.

Configuration parameters for structured spherical volumes.

Type

Name

Default

Description

vec3f

gridOrigin

\((0, 0, 0)\)

origin of the grid in units of \((r, \theta, \phi)\); angles in degrees

vec3f

gridSpacing

\((1, 1, 1)\)

size of the grid cells in units of \((r, \theta, \phi)\); angles in degrees

OSPData

data

the actual voxel 3D data

int

filter

OSP_VOLUME_FILTER_TRILINEAR

filter used for reconstructing the field, also allowed is OSP_VOLUME_FILTER_NEAREST

int

gradientFilter

same as filter

filter used during gradient computations

float

background

NaN

value that is used when sampling an undefined region outside the volume domain

The dimensions \((r, \theta, \phi)\) of the volume are inferred from the size of the 3D array data, as is the type of the voxel values (currently supported are: OSP_UCHAR, OSP_SHORT, OSP_USHORT, OSP_HALF, OSP_FLOAT, and OSP_DOUBLE).

These grid parameters support flexible specification of spheres, hemispheres, spherical shells, spherical wedges, and so forth. The grid extents (computed as [gridOrigin, gridOrigin + (dimensions - 1) * gridSpacing]) however must be constrained such that:

  • \(r \geq 0\)

  • \(0 \leq \theta \leq 180\)

  • \(0 \leq \phi \leq 360\)

Adaptive Mesh Refinement (AMR) Volume

OSPRay currently supports block-structured (Berger-Colella) AMR volumes. Volumes are specified as a list of blocks, which exist at levels of refinement in potentially overlapping regions. Blocks exist in a tree structure, with coarser refinement level blocks containing finer blocks. The cell width is equal for all blocks at the same refinement level, though blocks at a coarser level have a larger cell width than finer levels.

There can be any number of refinement levels and any number of blocks at any level of refinement. An AMR volume type is created by passing the type string “amr” to ospNewVolume.

Blocks are defined by three parameters: their bounds, the refinement level in which they reside, and the scalar data contained within each block.

Note that cell widths are defined per refinement level, not per block.

Configuration parameters for AMR volumes.

Type

Name

Default

Description

OSPAMRMethod

method

OSP_AMR_CURRENT

OSPAMRMethod sampling method. Supported methods are:

OSP_AMR_CURRENT

OSP_AMR_FINEST

OSP_AMR_OCTANT

float[]

cellWidth

NULL

array of each level’s cell width

box3i[]

block.bounds

NULL

data array of grid sizes (in voxels) for each AMR block

int[]

block.level

NULL

array of each block’s refinement level

OSPData[]

block.data

NULL

data array of OSPData containing the actual scalar voxel data, only OSP_FLOAT is supported as OSPDataType

vec3f

gridOrigin

\((0, 0, 0)\)

origin of the grid

vec3f

gridSpacing

\((1, 1, 1)\)

size of the grid cells

float

background

NaN

value that is used when sampling an undefined region outside the volume domain

Lastly, note that the gridOrigin and gridSpacing parameters act just like the structured volume equivalent, but they only modify the root (coarsest level) of refinement.

In particular, OSPRay’s / Open VKL’s AMR implementation was designed to cover Berger-Colella [1] and Chombo [2] AMR data. The method parameter above determines the interpolation method used when sampling the volume.

OSP_AMR_CURRENT

finds the finest refinement level at that cell and interpolates through this “current” level

OSP_AMR_FINEST

will interpolate at the closest existing cell in the volume-wide finest refinement level regardless of the sample cell’s level

OSP_AMR_OCTANT

interpolates through all available refinement levels at that cell. This method avoids discontinuities at refinement level boundaries at the cost of performance

Details and more information can be found in the publication for the implementation [3].

  1. M.J. Berger and P. Colella, “Local adaptive mesh refinement for shock hydrodynamics.” Journal of Computational Physics 82.1 (1989): 64-84. DOI: 10.1016/0021-9991(89)90035-1

    1. Adams, P. Colella, D.T. Graves, J.N. Johnson, N.D. Keen, T.J. Ligocki, D.F. Martin. P.W. McCorquodale, D. Modiano. P.O. Schwartz, T.D. Sternberg, and B. Van Straalen, “Chombo Software Package for AMR Applications – Design Document”, Lawrence Berkeley National Laboratory Technical Report LBNL-6616E.

    1. Wald, C. Brownlee, W. Usher, and A. Knoll, “CPU volume rendering of adaptive mesh refinement data”. SIGGRAPH Asia 2017 Symposium on Visualization – SA ’17, 18(8), 1–8. DOI: 10.1145/3139295.3139305

Unstructured Volume

Unstructured volumes can have their topology and geometry freely defined. Geometry can be composed of tetrahedral, hexahedral, wedge or pyramid cell types. The data format used is compatible with VTK and consists of multiple arrays: vertex positions and values, vertex indices, cell start indices, cell types, and cell values. An unstructured volume type is created by passing the type string “unstructured” to ospNewVolume.

Sampled cell values can be specified either per-vertex (vertex.data) or per-cell (cell.data). If both arrays are set, cell.data takes precedence.

Similar to a mesh, each cell is formed by a group of indices into the vertices. For each vertex, the corresponding (by array index) data value will be used for sampling when rendering, if specified. The index order for a tetrahedron is the same as VTK_TETRA: bottom triangle counterclockwise, then the top vertex.

For hexahedral cells, each hexahedron is formed by a group of eight indices into the vertices and data values. Vertex ordering is the same as VTK_HEXAHEDRON: four bottom vertices counterclockwise, then top four counterclockwise.

For wedge cells, each wedge is formed by a group of six indices into the vertices and data values. Vertex ordering is the same as VTK_WEDGE: three bottom vertices counterclockwise, then top three counterclockwise.

For pyramid cells, each cell is formed by a group of five indices into the vertices and data values. Vertex ordering is the same as VTK_PYRAMID: four bottom vertices counterclockwise, then the top vertex.

To maintain VTK data compatibility, the index array may be specified with cell sizes interleaved with vertex indices in the following format: \(n, id_1, ..., id_n, m, id_1, ..., id_m\). This alternative index array layout can be enabled through the indexPrefixed flag (in which case, the cell.type parameter must be omitted).

Configuration parameters for unstructured volumes.

Type

Name

Default

Description

vec3f[]

vertex.position

data array of vertex positions

float[]

vertex.data

data array of vertex data values to be sampled

uint32[] / uint64[]

index

data array of indices (into the vertex array(s)) that form cells

bool

indexPrefixed

false

indicates that the index array is compatible to VTK, where the indices of each cell are prefixed with the number of vertices

uint32[] / uint64[]

cell.index

data array of locations (into the index array), specifying the first index of each cell

float[]

cell.data

data array of cell data values to be sampled

uint8[]

cell.type

data array of cell types (VTK compatible), only set if indexPrefixed = false false. Supported types are:

OSP_TETRAHEDRON

OSP_HEXAHEDRON

OSP_WEDGE

OSP_PYRAMID

bool

hexIterative

false

hexahedron interpolation method, defaults to fast non-iterative version which could have rendering inaccuracies may appear if hex is not parallelepiped

bool

precomputedNormals

false

whether to accelerate by precomputing, at a cost of 12 bytes/face

float

background

NaN

value that is used when sampling an undefined region outside the volume domain

VDB Volume

VDB volumes implement a data structure that is very similar to the data structure outlined in Museth [1], they are created by passing the type string “vdb” to ospNewVolume.

The data structure is a hierarchical regular grid at its core: Nodes are regular grids, and each grid cell may either store a constant value (this is called a tile), or child pointers. Nodes in VDB trees are wide: Nodes on the first level have a resolution of 323 voxels, on the next level 163, and on the leaf level 83 voxels. All nodes on a given level have the same resolution. This makes it easy to find the node containing a coordinate using shift operations (see [1]). VDB leaf nodes are implicit in OSPRay / Open VKL: they are stored as pointers to user-provided data.

Topology of VDB volumes.

Topology of VDB volumes.

VDB volumes interpret input data as constant cells (which are then potentially filtered). This is in contrast to structuredRegular volumes, which have a vertex-centered interpretation.

The VDB implementation in OSPRay / Open VKL follows the following goals:

  • Efficient data structure traversal on vector architectures.

  • Enable the use of industry-standard .vdb files created through the OpenVDB library.

  • Compatibility with OpenVDB on a leaf data level, so that .vdb file may be loaded with minimal overhead.

VDB volumes have the following parameters:

Configuration parameters for VDB volumes.

Type

Name

Description

int

maxSamplingDepth

do not descend further than to this depth during sampling, the maximum value and the default is 3

uint32[]

node.level

level on which each input node exists, may be 1, 2 or 3 (levels are counted from the root level = 0 down)

vec3i[]

node.origin

the node origin index (per input node)

OSPData[]

node.data

data arrays with the node data (per input node). Nodes that are tiles are expected to have single-item arrays. Leaf-nodes with grid data expected to have compact 3D arrays in zyx layout (z changes most quickly) with the correct number of voxels for the level. Only OSP_FLOAT is supported as field OSPDataType.

int

filter

filter used for reconstructing the field, default is OSP_VOLUME_FILTER_TRILINEAR, alternatively OSP_VOLUME_FILTER_NEAREST, or OSP_VOLUME_FILTER_TRICUBIC.

int

gradientFilter

filter used for reconstructing the field during gradient computations, default same as filter

float

background

value that is used when sampling an undefined region outside the volume domain, default NaN

  1. Museth, K. VDB: High-Resolution Sparse Volumes with Dynamic Topology. ACM Transactions on Graphics 32(3), 2013. DOI: 10.1145/2487228.2487235

Particle Volume

Particle volumes consist of a set of points in space. Each point has a position, a radius, and a weight typically associated with an attribute. Particle volumes are created by passing the type string “particle” to ospNewVolume.

A radial basis function defines the contribution of that particle. Currently, we use the Gaussian radial basis function

\[\phi(P) = w \exp\left(-\frac{(P - p)^2}{2 r^2}\right),\]

where \(P\) is the particle position, \(p\) is the sample position, \(r\) is the radius and \(w\) is the weight. At each sample, the scalar field value is then computed as the sum of each radial basis function \(\phi\), for each particle that overlaps it.

The OSPRay / Open VKL implementation is similar to direct evaluation of samples in Reda et al. [2]. It uses an Embree-built BVH with a custom traversal, similar to the method in [1].

Configuration parameters for particle volumes.

Type

Name

Default

Description

vec3f[]

particle.position

data array of particle positions

float[]

particle.radius

data array of particle radii

float[]

particle.weight

NULL

optional data array of particle weights, specifying the height of the kernel.

float

radiusSupportFactor

3.0

The multiplier of the particle radius required for support. Larger radii ensure smooth results at the cost of performance. In the Gaussian kernel, the radius is one standard deviation (\(\sigma\)), so a value of 3 corresponds to \(3 \sigma\).

float

clampMaxCumulativeValue

0

The maximum cumulative value possible, set by user. All cumulative values will be clamped to this, and further traversal (RBF summation) of particle contributions will halt when this value is reached. A value of zero or less turns this off.

bool

estimateValueRanges

true

Enable heuristic estimation of value ranges which are used in internal acceleration structures as well as for determining the volume’s overall value range. When set to false, the user must specify clampMaxCumulativeValue, and all value ranges will be assumed [0–clampMaxCumulativeValue]. Disabling this switch may improve volume commit time, but will make volume rendering less efficient.

    1. Knoll, I. Wald, P. Navratil, A. Bowen, K. Reda, M.E., Papka, and K. Gaither, “RBF Volume Ray Casting on Multicore and Manycore CPUs”, 2014, Computer Graphics Forum, 33: 71–80. doi:10.1111/cgf.12363

    1. Reda, A. Knoll, K. Nomura, M. E. Papka, A. E. Johnson and J. Leigh, “Visualizing large-scale atomistic simulations in ultra-resolution immersive environments”, 2013 IEEE Symposium on Large-Scale Data Analysis and Visualization (LDAV), Atlanta, GA, 2013, pp. 59–65.

Transfer Function

Transfer functions map the scalar values of volumes to color and opacity and thus they can be used to visually emphasize certain features of the volume. To create a new transfer function of given type type use

OSPTransferFunction ospNewTransferFunction(const char *type);

The returned handle can be assigned to a volumetric model (described below) as parameter “transferFunction” using ospSetObject.

One type of transfer function that is supported by OSPRay is the linear transfer function, which interpolates between given equidistant colors and opacities. It is create by passing the string “piecewiseLinear” to ospNewTransferFunction and it is controlled by these parameters:

Parameters accepted by the linear transfer function.

Type

Name

Description

vec3f[]

color

data array of colors (linear RGB)

float[]

opacity

data array of opacities

vec2f

valueRange

domain (scalar range) this function maps from

The arrays color and opacity can be of different length.

VolumetricModels

Volumes in OSPRay are given volume rendering appearance information through VolumetricModels. This decouples the physical representation of the volume (and possible acceleration structures it contains) to rendering-specific parameters (where more than one set may exist concurrently). To create a volume instance, call

OSPVolumetricModel ospNewVolumetricModel(OSPVolume volume);

The passed volume can be NULL as long as the volume to be used is passed as a parameter. If both a volume is specified on object creation and as a parameter, the parameter value is used. If the parameter value is later removed, the volume object passed on object creation is again used.

Parameters understood by VolumetricModel.

Type

Name

Default

Description

OSPTransferFunction

transferFunction

transfer function to use

float

densityScale

1.0

makes volumes uniformly thinner or thicker

float

anisotropy

0.0

anisotropy of the (Henyey-Greenstein) phase function in [-1–1] (path tracer only), default to isotropic scattering

OSPVolume

volume

optional volume object this model references

Geometries

Geometries in OSPRay are objects that describe intersectable surfaces. To create a new geometry object of given type type use

OSPGeometry ospNewGeometry(const char *type);

Note that in the current implementation geometries are limited to a maximum of 232 primitives.

Mesh

A mesh consisting of either triangles or quads is created by calling ospNewGeometry with type string “mesh”. Once created, a mesh recognizes the following parameters:

Parameters defining a mesh geometry.

Type

Name

Description

vec3f[]

vertex.position

data array of vertex positions

vec3f[]

vertex.normal

data array of vertex normals

vec4f[] / vec3f[]

vertex.color

data array of vertex colors (linear RGBA/RGB)

vec2f[]

vertex.texcoord

data array of vertex texture coordinates

vec3ui[] / vec4ui[]

index

data array of (either triangle or quad) indices (into the vertex array(s))

The data type of index arrays differentiates between the underlying geometry, triangles are used for a index with vec3ui type and quads for vec4ui type. Quads are internally handled as a pair of two triangles, thus mixing triangles and quads is supported by encoding some triangle as a quad with the last two vertex indices being identical (w=z).

The vertex.position and index arrays are mandatory to create a valid mesh.

Subdivision

A mesh consisting of subdivision surfaces, created by specifying a geometry of type “subdivision”. Once created, a subdivision recognizes the following parameters:

Parameters defining a Subdivision geometry.

Type

Name

Description

vec3f[]

vertex.position

data array of vertex positions

vec4f[]

vertex.color

optional data array of vertex colors (linear RGBA)

vec2f[]

vertex.texcoord

optional data array of vertex texture coordinates

float

level

global level of tessellation, default 5

uint[]

index

data array of indices (into the vertex array(s))

float[]

index.level

optional data array of per-edge levels of tessellation, overrides global level

uint[]

face

optional data array holding the number of indices/edges (3 to 15) per face, defaults to 4 (a pure quad mesh)

vec2i[]

edgeCrease.index

optional data array of edge crease indices

float[]

edgeCrease.weight

optional data array of edge crease weights

uint[]

vertexCrease.index

optional data array of vertex crease indices

float[]

vertexCrease.weight

optional data array of vertex crease weights

uchar

mode

subdivision edge boundary mode, supported modes are:

OSP_SUBDIVISION_NO_BOUNDARY

OSP_SUBDIVISION_SMOOTH_BOUNDARY (default)

OSP_SUBDIVISION_PIN_CORNERS

OSP_SUBDIVISION_PIN_BOUNDARY

OSP_SUBDIVISION_PIN_ALL

The vertex and index arrays are mandatory to create a valid subdivision surface. If no face array is present then a pure quad mesh is assumed (the number of indices must be a multiple of 4). Optionally supported are edge and vertex creases.

Spheres

A geometry consisting of individual spheres, each of which can have an own radius, is created by calling ospNewGeometry with type string “sphere”. The spheres will not be tessellated but rendered procedurally and are thus perfectly round. To allow a variety of sphere representations in the application this geometry allows a flexible way of specifying the data of center position and radius within a data array:

Parameters defining a spheres geometry.

Type

Name

Default

Description

vec3f[]

sphere.position

data array of center positions

float[]

sphere.radius

NULL

optional data array of the per-sphere radius

vec2f[]

sphere.texcoord

NULL

optional data array of texture coordinates (constant per sphere)

float

radius

0.01

default radius for all spheres (if sphere.radius is not set)

Curves

A geometry consisting of multiple curves is created by calling ospNewGeometry with type string “curve”. The parameters defining this geometry are listed in the table below.

Parameters defining a curves geometry.

Type

Name

Description

vec4f[]

vertex.position_radius

data array of vertex position and per-vertex radius

vec2f[]

vertex.texcoord

data array of per-vertex texture coordinates

vec4f[]

vertex.color

data array of corresponding vertex colors (linear RGBA)

vec3f[]

vertex.normal

data array of curve normals (only for “ribbon” curves)

vec4f[]

vertex.tangent

data array of curve tangents (only for “hermite” curves)

uint32[]

index

data array of indices to the first vertex or tangent of a curve segment

uchar

type

OSPCurveType for rendering the curve. Supported types are:

OSP_FLAT

OSP_ROUND

OSP_RIBBON

OSP_DISJOINT

uchar

basis

OSPCurveBasis for defining the curve. Supported bases are:

OSP_LINEAR

OSP_BEZIER

OSP_BSPLINE

OSP_HERMITE

OSP_CATMULL_ROM

Positions in vertex.position_radius parameter supports per-vertex varying radii with data type vec4f[] and instantiate Embree curves internally for the relevant type/basis mapping.

The following section describes the properties of different curve basis’ and how they use the data provided in data buffers:

OSP_LINEAR

The indices point to the first of 2 consecutive control points in the vertex buffer. The first control point is the start and the second control point the end of the line segment. The curve goes through all control points listed in the vertex buffer.

OSP_BEZIER

The indices point to the first of 4 consecutive control points in the vertex buffer. The first control point represents the start point of the curve, and the 4th control point the end point of the curve. The Bézier basis is interpolating, thus the curve does go exactly through the first and fourth control vertex.

OSP_BSPLINE

The indices point to the first of 4 consecutive control points in the vertex buffer. This basis is not interpolating, thus the curve does in general not go through any of the control points directly. Using this basis, 3 control points can be shared for two continuous neighboring curve segments, e.g., the curves \((p0, p1, p2, p3)\) and \((p1, p2, p3, p4)\) are C1 continuous. This feature make this basis a good choice to construct continuous multi-segment curves, as memory consumption can be kept minimal.

OSP_HERMITE

It is necessary to have both vertex buffer and tangent buffer for using this basis. The indices point to the first of 2 consecutive points in the vertex buffer, and the first of 2 consecutive tangents in the tangent buffer. This basis is interpolating, thus does exactly go through the first and second control point, and the first order derivative at the begin and end matches exactly the value specified in the tangent buffer. When connecting two segments continuously, the end point and tangent of the previous segment can be shared.

OSP_CATMULL_ROM

The indices point to the first of 4 consecutive control points in the vertex buffer. If \((p0, p1, p2, p3)\) represent the points then this basis goes through \(p1\) and \(p2\), with tangents as \((p2-p0)/2\) and \((p3-p1)/2\).

The following section describes the properties of different curve types’ and how they define the geometry of a curve:

OSP_FLAT

This type enables faster rendering as the curve is rendered as a connected sequence of ray facing quads.

OSP_ROUND

This type enables rendering a real geometric surface for the curve which allows closeup views. This mode renders a sweep surface by sweeping a varying radius circle tangential along the curve.

OSP_RIBBON

The type enables normal orientation of the curve and requires a normal buffer be specified along with vertex buffer. The curve is rendered as a flat band whose center approximately follows the provided vertex buffer and whose normal orientation approximately follows the provided normal buffer. Not supported for basis OSP_LINEAR.

OSP_DISJOINT

Only supported for basis OSP_LINEAR; the segments are open and not connected at the joints, i.e., the curve segments are either individual cones or cylinders.

Boxes

OSPRay can directly render axis-aligned bounding boxes without the need to convert them to quads or triangles. To do so create a boxes geometry by calling ospNewGeometry with type string “box”.

Parameters defining a boxes geometry.

Type

Name

Description

box3f[]

box

data array of boxes

Planes

OSPRay can directly render planes defined by plane equation coefficients in its implicit form \(ax + by + cz + d = 0\). By default planes are infinite but their extents can be limited by defining optional bounding boxes. A planes geometry can be created by calling ospNewGeometry with type string “plane”.

Parameters defining a planes geometry.

Type

Name

Description

vec4f[]

plane.coefficients

data array of plane coefficients \((a, b, c, d)\)

box3f[]

plane.bounds

optional data array of bounding boxes

Isosurfaces

OSPRay can directly render multiple isosurfaces of a volume without first tessellating them. To do so create an isosurfaces geometry by calling ospNewGeometry with type string “isosurface”. The appearance information of the surfaces is set through the Geometric Model. Per-isosurface colors can be set by passing per-primitive colors to the Geometric Model, in order of the isosurface array.

Parameters defining an isosurfaces geometry.

Type

Name

Description

float

isovalue

single isovalues

float[]

isovalue

data array of isovalues

OSPVolume

volume

handle of the Volume to be isosurfaced

GeometricModels

Geometries are matched with surface appearance information through GeometricModels. These take a geometry, which defines the surface representation, and applies either full-object or per-primitive color and material information. To create a geometric model, call

OSPGeometricModel ospNewGeometricModel(OSPGeometry geometry);

The passed geometry can be NULL as long as the geometry to be used is passed as a parameter. If both a geometry is specified on object creation and as a parameter, the parameter value is used. If the parameter value is later removed, the geometry object passed on object creation is again used.

Color and material are fetched with the primitive ID of the hit (clamped to the valid range, thus a single color or material is fine), or mapped first via the index array (if present). All parameters are optional, however, some renderers (notably the path tracer) require a material to be set. Materials are either handles of OSPMaterial, or indices into the material array on the renderer, which allows to build a world which can be used by different types of renderers.

An invertNormals flag allows to invert (shading) normal vectors of the rendered geometry. That is particularly useful for clipping. By changing normal vectors orientation one can control whether inside or outside of the clipping geometry is being removed. For example, a clipping geometry with normals oriented outside clips everything what’s inside.

Parameters understood by GeometricModel.

Type

Name

Description

OSPMaterial / uint32

material

optional material applied to the geometry, may be an index into the material parameter on the renderer (if it exists)

vec4f

color

optional color assigned to the geometry (linear RGBA)

OSPMaterial[] / uint32[]

material

optional data array of (per-primitive) materials, may be an index into the material parameter on the renderer (if it exists)

vec4f[]

color

optional data array of (per-primitive) colors (linear RGBA)

uint8[]

index

optional data array of per-primitive indices into color and material

bool

invertNormals

inverts all shading normals (Ns), default false

OSPGeometry

geometry

optional [geometry] object this model references

Lights

To create a new light source of given type type use

OSPLight ospNewLight(const char *type);

All light sources accept the following parameters:

Parameters accepted by all lights.

Type

Name

Default

Description

vec3f

color

white

color of the light (linear RGB)

float

intensity

1

intensity of the light (a factor)

uchar

intensityQuantity

OSPIntensityQuantity to set the radiometric quantity represented by intensity. The default value depends on the light source.

bool

visible

true

whether the light can be directly seen

In OSPRay the intensity parameter of a light source can correspond to different types of radiometric quantities. The type of the value represented by a light’s intensity parameter is set using intensityQuantity, which accepts values from the enum type OSPIntensityQuantity. The supported types of OSPIntensityQuantity differ between the different light sources (see documentation of each specific light source).

Types of radiometric quantities used to interpret a light’s intensity parameter.

Name

Description

OSP_INTENSITY_QUANTITY_POWER

the overall amount of light energy emitted by the light source into the scene, unit is W

OSP_INTENSITY_QUANTITY_INTENSITY

the overall amount of light emitted by the light in a given direction, unit is W/sr

OSP_INTENSITY_QUANTITY_RADIANCE

the amount of light emitted by a point on the light source in a given direction, unit is W/sr/m2

OSP_INTENSITY_QUANTITY_IRRADIANCE

the amount of light arriving at a surface point, assuming the light is oriented towards to the surface, unit is W/m2

OSP_INTENSITY_QUANTITY_SCALE

a linear scaling factor for light sources with a built-in quantity (e.g., HDRI, or sunSky).

The following light types are supported by most OSPRay renderers.

Directional Light / Distant Light

The distant light (or traditionally the directional light) is thought to be far away (outside of the scene), thus its light arrives (almost) as parallel rays. It is created by passing the type string “distant” to ospNewLight. The distant light supports OSP_INTENSITY_QUANTITY_RADIANCE and OSP_INTENSITY_QUANTITY_IRRADIANCE (default) as intensityQuantity parameter value. In addition to the general parameters understood by all lights the distant light supports the following special parameters:

Special parameters accepted by the distant light.

Type

Name

Default

Description

vec3f

direction

\((0, 0, 1)\)

main emission direction of the distant light

float

angularDiameter

0

apparent size (angle in degree) of the light

Setting the angular diameter to a value greater than zero will result in soft shadows when the renderer uses stochastic sampling (like the path tracer). For instance, the apparent size of the sun is about 0.53°.

Point Light / Sphere Light

The sphere light (or the special case point light) is a light emitting uniformly in all directions from the surface toward the outside. It does not emit any light toward the inside of the sphere. It is created by passing the type string “sphere” to ospNewLight. The point light supports OSP_INTENSITY_QUANTITY_POWER, OSP_INTENSITY_QUANTITY_INTENSITY (default) and OSP_INTENSITY_QUANTITY_RADIANCE as intensityQuantity parameter value. In addition to the general parameters understood by all lights the sphere light supports the following special parameters:

Special parameters accepted by the sphere light.

Type

Name

Default

Description

vec3f

position

\((0, 0, 0)\)

the center of the sphere light

float

radius

0

the size of the sphere light

Setting the radius to a value greater than zero will result in soft shadows when the renderer uses stochastic sampling (like the path tracer).

Spotlight / Photometric Light

The spotlight is a light emitting into a cone of directions. It is created by passing the type string “spot” to ospNewLight. The spotlight supports OSP_INTENSITY_QUANTITY_POWER, OSP_INTENSITY_QUANTITY_INTENSITY (default) and OSP_INTENSITY_QUANTITY_RADIANCE as intensityQuantity parameter value. In addition to the general parameters understood by all lights the spotlight supports the special parameters listed in the table.

Special parameters accepted by the spotlight.

Type

Name

Default

Description

vec3f

position

\((0, 0, 0)\)

the center of the spotlight

vec3f

direction

\((0, 0, 1)\)

main emission direction of the spot

float

openingAngle

180

full opening angle (in degree) of the spot; outside of this cone is no illumination

float

penumbraAngle

5

size (angle in degree) of the “penumbra”, the region between the rim (of the illumination cone) and full intensity of the spot; should be smaller than half of openingAngle

float

radius

0

the size of the spotlight, the radius of a disk with normal direction

float

innerRadius

0

in combination with radius turns the disk into a ring

float[]

intensityDistribution

luminous intensity distribution for photometric lights; can be 2D for asymmetric illumination; values are assumed to be uniformly distributed

vec3f

c0

orientation, i.e., direction of the C0-(half)plane (only needed if illumination via intensityDistribution is asymmetric)

Angles used by the spotlight.

Angles used by the spotlight.

Setting the radius to a value greater than zero will result in soft shadows when the renderer uses stochastic sampling (like the path tracer). Additionally setting the inner radius will result in a ring instead of a disk emitting the light.

Measured light sources (IES, EULUMDAT, …) are supported by providing an intensityDistribution data array to modulate the intensity per direction. The mapping is using the C-γ coordinate system (see also below figure): the values of the first (or only) dimension of intensityDistribution are uniformly mapped to γ in [0–π]; the first intensity value to 0, the last value to π, thus at least two values need to be present. If the array has a second dimension then the intensities are not rotational symmetric around direction, but are accordingly mapped to the C-halfplanes in [0–2π]; the first “row” of values to 0 and 2π, the other rows such that they have uniform distance to its neighbors. The orientation of the C0-plane is specified via c0. A combination of using an intensityDistribution and OSP_INTENSITY_QUANTITY_POWER as intensityQuantity is not supported at the moment.

C-γ coordinate system for the mapping of ``intensityDistribution`` to the spotlight.

C-γ coordinate system for the mapping of intensityDistribution to the spotlight.

Quad Light

The quad 3 light is a planar, procedural area light source emitting uniformly on one side into the half-space. It is created by passing the type string “quad” to ospNewLight. The quad light supports OSP_INTENSITY_QUANTITY_POWER, OSP_INTENSITY_QUANTITY_INTENSITY and OSP_INTENSITY_QUANTITY_RADIANCE (default) as intensityQuantity parameter. In addition to the general parameters understood by all lights the quad light supports the following special parameters:

Special parameters accepted by the quad light.

Type

Name

Default

Description

vec3f

position

\((0, 0, 0)\)

position of one vertex of the quad light

vec3f

edge1

\((1, 0, 0)\)

vector to one adjacent vertex

vec3f

edge2

\((0, 1, 0)\)

vector to the other adjacent vertex

Defining a quad light which emits toward the reader.

Defining a quad light which emits toward the reader.

The emission side is determined by the cross product of edge1×edge2. Note that only renderers that use stochastic sampling (like the path tracer) will compute soft shadows from the quad light. Other renderers will just sample the center of the quad light, which results in hard shadows.

Cylinder Light

The cylinder light is a cylindrical, procedural area light source emitting uniformly outwardly into the space beyond the boundary. It is created by passing the type string “cylinder” to ospNewLight. The cylinder light supports OSP_INTENSITY_QUANTITY_POWER, OSP_INTENSITY_QUANTITY_INTENSITY and OSP_INTENSITY_QUANTITY_RADIANCE (default) as intensityQuantity parameter. In addition to the general parameters understood by all lights the cylinder light supports the following special parameters:

Special parameters accepted by the cylinder light.

Type

Name

Default

Description

vec3f

position0

\((0, 0, 0)\)

position of the start of the cylinder

vec3f

position1

\((0, 0, 1)\)

position of the end of the cylinder

float

radius

1

radius of the cylinder

Note that only renderers that use stochastic sampling (like the path tracer) will compute soft shadows from the cylinder light. Other renderers will just sample the closest point on the cylinder light, which results in hard shadows.

HDRI Light

The HDRI light is a textured light source surrounding the scene and illuminating it from infinity. It is created by passing the type string “hdri” to ospNewLight. The values of the HDRI correspond to radiance and therefore the HDRI light only accepts OSP_INTENSITY_QUANTITY_SCALE as intensityQuantity parameter value. In addition to the general parameters the HDRI light supports the following special parameters:

Special parameters accepted by the HDRI light.

Type

Name

Default

Description

vec3f

up

\((0, 1, 0)\)

up direction of the light

vec3f

direction

\((0, 0, 1)\)

direction to which the center of the texture will be mapped to (analog to panoramic camera)

OSPTexture

map

environment map in latitude / longitude format

Orientation and Mapping of an HDRI Light.

Orientation and Mapping of an HDRI Light.

Note that the SciVis renderer only shows the HDRI light in the background (like an environment map) without computing illumination of the scene.

Ambient Light

The ambient light surrounds the scene and illuminates it from infinity with constant radiance (determined by combining the parameters ``color` and intensity <#lights>`__). It is created by passing the type string “ambient” to ospNewLight. The ambient light supports OSP_INTENSITY_QUANTITY_RADIANCE and OSP_INTENSITY_QUANTITY_IRRADIANCE (default) as intensityQuantity parameter value.

Note that the SciVis renderer uses ambient lights to control the color and intensity of the computed ambient occlusion (AO).

Sun-Sky Light

The sun-sky light is a combination of a distant light for the sun and a procedural hdri light for the sky. It is created by passing the type string “sunSky” to ospNewLight. The sun-sky light surrounds the scene and illuminates it from infinity and can be used for rendering outdoor scenes. The radiance values are calculated using the Hošek-Wilkie sky model and solar radiance function. The underlying model of the sun-sky light returns radiance values and therefore the light only accepts OSP_INTENSITY_QUANTITY_SCALE as intensityQuantity parameter value. To rescale the returned radiance of the sky model the default value for the intensity parameter is set to 0.025. In addition to the general parameters the following special parameters are supported:

Special parameters accepted by the sunSky light.

Type

Name

Default

Description

vec3f

up

\((0, 1, 0)\)

zenith of sky

vec3f

direction

\((0, -1, 0)\)

main emission direction of the sun

float

turbidity

3

atmospheric turbidity due to particles, in [1–10]

float

albedo

0.3

ground reflectance, in [0–1]

float

horizonExtension

0.01

extend the sky dome by stretching the horizon, fraction of the lower hemisphere to cover, in [0–1]

The lowest elevation for the sun is restricted to the horizon.

Note that the SciVis renderer only computes illumination from the sun (yet the sky is still shown in the background, like an environment map).

Emissive Objects

The path tracer will consider illumination by geometries which have a light emitting material assigned (for example the Luminous material).

Scene Hierarchy

Groups

Groups in OSPRay represent collections of GeometricModels, VolumetricModels and Lights which share a common local-space coordinate system. To create a group call

OSPGroup ospNewGroup();

Groups take arrays of geometric models, volumetric models, clipping geometric models and lights, but they are all optional. In other words, there is no need to create empty arrays if there are no geometries, volumes or lights in the group.

By adding OSPGeometricModels to the clippingGeometry array a clipping geometry feature is enabled. Geometries assigned to this parameter will be used as clipping geometries. Any supported geometry can be used for clipping 4, the only requirement is that it has to distinctly partition space into clipping and non-clipping one. The use of clipping geometry that is not closed or infinite could result in rendering artifacts. User can decide which part of space is clipped by changing shading normals orientation with the invertNormals flag of the GeometricModel. All geometries and volumes assigned to geometry or volume will be clipped. All clipping geometries from all groups and Instances will be combined together – a union of these areas will be applied to all other objects in the world.

Parameters understood by groups.

Type

Name

Default

Description

OSPGeometricModel[]

geometry

NULL

data array of GeometricModels

OSPVolumetricModel[]

volume

NULL

data array of VolumetricModels

OSPGeometricModel[]

clippingGeometry

NULL

data array of GeometricModels used for clipping

OSPLight[]

light

NULL

data array of lights

bool

dynamicScene

false

use RTC_SCENE_DYNAMIC flag (faster BVH build, slower ray traversal), otherwise uses RTC_SCENE_STATIC flag (faster ray traversal, slightly slower BVH build)

bool

compactMode

false

tell Embree to use a more compact BVH in memory by trading ray traversal performance

bool

robustMode

false

tell Embree to enable more robust ray intersection code paths (slightly slower)

Instances

Instances in OSPRay represent a single group’s placement into the world via a transform. To create and instance call

OSPInstance ospNewInstance(OSPGroup);
Parameters understood by instances.

Type

Name

Default

Description

affine3f

transform

identity

world-space transform for all attached geometries and volumes, overridden by motion.* arrays

affine3f[]

motion.transform

uniformly distributed world-space transforms

vec3f[]

motion.scale

uniformly distributed world-space scale, overridden by motion.transform

vec3f[]

motion.pivot

uniformly distributed world-space translation which is applied before motion.rotation (i.e., the rotation center), overridden by motion.transform

quatf[]

motion.rotation

uniformly distributed world-space quaternion rotation, overridden by motion.transform

vec3f[]

motion.translation

uniformly distributed world-space translation, overridden by motion.transform

box1f

time

[0, 1]

time associated with first and last key in motion.* arrays (for motion blur)

World

Worlds are a container of scene data represented by instances. To create an (empty) world call

OSPWorld ospNewWorld();

Objects are placed in the world through an array of instances. Similar to groups, the array of instances is optional: there is no need to create empty arrays if there are no instances (though there will be nothing to render).

Applications can query the world (axis-aligned) bounding box after the world has been committed. To get this information, call

OSPBounds ospGetBounds(OSPObject);

The result is returned in the provided OSPBounds 5 struct:

typedef struct {
    float lower[3];
    float upper[3];
} OSPBounds;

This call can also take OSPGroup and OSPInstance as well: all other object types will return an empty bounding box.

Finally, Worlds can be configured with parameters for making various feature/performance trade-offs (similar to groups).

Parameters understood by worlds.

Type

Name

Default

Description

OSPInstance[]

instance

NULL

data array with handles of the instances

OSPLight[]

light

NULL

data array with handles of the lights

bool

dynamicScene

false

use RTC_SCENE_DYNAMIC flag (faster BVH build, slower ray traversal), otherwise uses RTC_SCENE_STATIC flag (faster ray traversal, slightly slower BVH build)

bool

compactMode

false

tell Embree to use a more compact BVH in memory by trading ray traversal performance

bool

robustMode

false

tell Embree to enable more robust ray intersection code paths (slightly slower)

Renderers

A renderer is the central object for rendering in OSPRay. Different renderers implement different features and support different materials. To create a new renderer of given type type use

OSPRenderer ospNewRenderer(const char *type);

General parameters of all renderers are

Parameters understood by all renderers.

Type

Name

Default

Description

int

pixelSamples

1

samples per pixel

int

maxPathLength

20

maximum ray recursion depth

float

minContribution

0.001

sample contributions below this value will be neglected to speedup rendering

float

varianceThreshold

0

threshold for adaptive accumulation

float / vec3f / vec4f

backgroundColor

black, transparent

background color and alpha (linear A/RGB/RGBA), if no map_backplate is set

OSPTexture

map_backplate

optional texture image used as background (use texture type texture2d)

OSPTexture

map_maxDepth

optional screen-sized float texture with maximum far distance per pixel (use texture type texture2d)

OSPMaterial[]

material

optional data array of materials which can be indexed by a GeometricModel’s material parameter

uchar

pixelFilter

OSP_PIXELFILTER_GAUSS

OSPPixelFilterType to select the pixel filter used by the renderer for antialiasing. Possible pixel filters are listed below.

OSPRay’s renderers support a feature called adaptive accumulation, which accelerates progressive rendering by stopping the rendering and refinement of image regions that have an estimated variance below the varianceThreshold. This feature requires a framebuffer with an OSP_FB_VARIANCE channel.

Per default the background of the rendered image will be transparent black, i.e., the alpha channel holds the opacity of the rendered objects. This eases transparency-aware blending of the image with an arbitrary background image by the application. The parameter backgroundColor or map_backplate can be used to already blend with a constant background color or backplate texture, respectively, (and alpha) during rendering.

OSPRay renderers support depth composition with images of other renderers, for example to incorporate help geometries of a 3D UI that were rendered with OpenGL. The screen-sized texture map_maxDepth must have format OSP_TEXTURE_R32F and flag OSP_TEXTURE_FILTER_NEAREST. The fetched values are used to limit the distance of primary rays, thus objects of other renderers can hide objects rendered by OSPRay.

OSPRay supports antialiasing in image space by using pixel filters, which are centered around the center of a pixel. The size \(w×w\) of the filter depends on the selected filter type. The types of supported pixel filters are defined by the OSPPixelFilterType enum and can be set using the pixelFilter parameter.

Pixel filter types supported by OSPRay for antialiasing in image space.

Name

Description

OSP_PIXELFILTER_POINT

a point filter only samples the center of the pixel, therefore the filter width is \(w = 0\)

OSP_PIXELFILTER_BOX

a uniform box filter with a width of \(w = 1\)

OSP_PIXELFILTER_GAUSS

a truncated, smooth Gaussian filter with a standard deviation of \(\sigma = 0.5\) and a filter width of \(w = 3\)

OSP_PIXELFILTER_MITCHELL

the Mitchell-Netravali filter with a width of \(w = 4\)

OSP_PIXELFILTER_BLACKMAN_HARRIS

the Blackman-Harris filter with a width of \(w = 3\)

SciVis Renderer

The SciVis renderer is a fast ray tracer for scientific visualization which supports volume rendering and ambient occlusion (AO). It is created by passing the type string “scivis” to ospNewRenderer. In addition to the general parameters understood by all renderers, the SciVis renderer supports the following parameters:

Special parameters understood by the SciVis renderer.

Type

Name

Default

Description

bool

shadows

false

whether to compute (hard) shadows

int

aoSamples

0

number of rays per sample to compute ambient occlusion

float

aoDistance

1020

maximum distance to consider for ambient occlusion

float

volumeSamplingRate

1

sampling rate for volumes

bool

visibleLights

false

whether light sources are potentially visible (as in the path tracer, regarding each light’s visible)

Note that the intensity (and color) of AO is deduced from an ambient light in the lights array. 6 If aoSamples is zero (the default) then ambient lights cause ambient illumination (without occlusion).

Ambient Occlusion Renderer

This renderer supports only a subset of the features of the SciVis renderer to gain performance. As the name suggest its main shading method is ambient occlusion (AO), lights are not considered at all and , Volume rendering is supported. The Ambient Occlusion renderer is created by passing the type string “ao” to ospNewRenderer. In addition to the general parameters understood by all renderers the following parameters are supported as well:

Special parameters understood by the Ambient Occlusion renderer.

Type

Name

Default

Description

int

aoSamples

1

number of rays per sample to compute ambient occlusion

float

aoDistance

1020

maximum distance to consider for ambient occlusion

float

aoIntensity

1

ambient occlusion strength

float

volumeSamplingRate

1

sampling rate for volumes

Path Tracer

The path tracer supports soft shadows, indirect illumination and realistic materials. This renderer is created by passing the type string “pathtracer” to ospNewRenderer. In addition to the general parameters understood by all renderers the path tracer supports the following special parameters:

Special parameters understood by the path tracer.

Type

Name

Default

Description

int

lightSamples

all

number of random light samples per path vertex, per default all light sources are sampled

int

roulettePathLength

5

ray recursion depth at which to start Russian roulette termination

float

maxContribution

samples are clamped to this value before they are accumulated into the framebuffer

bool

backgroundRefraction

false

allow for alpha blending even if background is seen through refractive objects like glass

The path tracer requires that materials are assigned to geometries, otherwise surfaces are treated as completely black.

The path tracer supports volumes with multiple scattering. The scattering albedo can be specified using the transfer function. Extinction is assumed to be spectrally constant.

Materials

Materials describe how light interacts with surfaces, they give objects their distinctive look. To let the given renderer create a new material of given type type call

OSPMaterial ospNewMaterial(const char *, const char *material_type);

Please note that the first argument is ignored.

The returned handle can then be used to assign the material to a given geometry with

void ospSetObject(OSPGeometricModel, "material", OSPMaterial);

OBJ Material

The OBJ material is the workhorse material supported by both the SciVis renderer and the path tracer (the Ambient Occlusion renderer only uses the kd and d parameter). It offers widely used common properties like diffuse and specular reflection and is based on the MTL material format of Lightwave’s OBJ scene files. To create an OBJ material pass the type string “obj” to ospNewMaterial. Its main parameters are

Main parameters of the OBJ material.

Type

Name

Default

Description

vec3f

kd

white 0.8

diffuse color (linear RGB)

vec3f

ks

black

specular color (linear RGB)

float

ns

10

shininess (Phong exponent), usually in [2–104]

float

d

opaque

opacity

vec3f

tf

black

transparency filter color (linear RGB)

OSPTexture

map_bump

NULL

normal map

In particular when using the path tracer it is important to adhere to the principle of energy conservation, i.e., that the amount of light reflected by a surface is not larger than the light arriving. Therefore the path tracer issues a warning and renormalizes the color parameters if the sum of Kd, Ks, and Tf is larger than one in any color channel. Similarly important to mention is that almost all materials of the real world reflect at most only about 80% of the incoming light. So even for a white sheet of paper or white wall paint do better not set Kd larger than 0.8; otherwise rendering times are unnecessary long and the contrast in the final images is low (for example, the corners of a white room would hardly be discernible, as can be seen in the figure below).

Comparison of diffuse rooms with 100% reflecting white paint (left) and realistic 80% reflecting white paint (right), which leads to higher overall contrast. Note that exposure has been adjusted to achieve similar brightness levels.

Comparison of diffuse rooms with 100% reflecting white paint (left) and realistic 80% reflecting white paint (right), which leads to higher overall contrast. Note that exposure has been adjusted to achieve similar brightness levels.

If present, the color component of geometries is also used for the diffuse color Kd and the alpha component is also used for the opacity d.

Normal mapping can simulate small geometric features via the texture map_Bump. The normals \(n\) in the normal map are with respect to the local tangential shading coordinate system and are encoded as \(½(n+1)\), thus a texel \((0.5, 0.5, 1)\) 7 represents the unperturbed shading normal \((0, 0, 1)\). Because of this encoding an sRGB gamma texture format is ignored and normals are always fetched as linear from a normal map. Note that the orientation of normal maps is important for a visually consistent look: by convention OSPRay uses a coordinate system with the origin in the lower left corner; thus a convexity will look green toward the top of the texture image (see also the example image of a normal map). If this is not the case flip the normal map vertically or invert its green channel.

Normal map representing an exalted square pyramidal frustum.

Normal map representing an exalted square pyramidal frustum.

Note that Tf colored transparency is implemented in the SciVis and the path tracer but normal mapping with map_Bump is currently supported in the path tracer only.

All parameters (except Tf) can be textured by passing a texture handle, prefixed with “map_”. The fetched texels are multiplied by the respective parameter value. If only the texture is given (but not the corresponding parameter), only the texture is used (the default value of the parameter is not multiplied). The color textures map_Kd and map_Ks are typically in one of the sRGB gamma encoded formats, whereas textures map_Ns and map_d are usually in a linear format (and only the first component is used). Additionally, all textures support texture transformations.

Rendering of a OBJ material with wood textures.

Rendering of a OBJ material with wood textures.

Principled

The Principled material is the most complex material offered by the path tracer, which is capable of producing a wide variety of materials (e.g., plastic, metal, wood, glass) by combining multiple different layers and lobes. It uses the GGX microfacet distribution with approximate multiple scattering for dielectrics and metals, uses the Oren-Nayar model for diffuse reflection, and is energy conserving. To create a Principled material, pass the type string “principled” to ospNewMaterial. Its parameters are listed in the table below.

Parameters of the Principled material.

Type

Name

Default

Description

vec3f

baseColor

white 0.8

base reflectivity (diffuse and/or metallic, linear RGB)

vec3f

edgeColor

white

edge tint (metallic only, linear RGB)

float

metallic

0

mix between dielectric (diffuse and/or specular) and metallic (specular only with complex IOR) in [0–1]

float

diffuse

1

diffuse reflection weight in [0–1]

float

specular

1

specular reflection/transmission weight in [0–1]

float

ior

1

dielectric index of refraction

float

transmission

0

specular transmission weight in [0–1]

vec3f

transmissionColor

white

attenuated color due to transmission (Beer’s law, linear RGB)

float

transmissionDepth

1

distance at which color attenuation is equal to transmissionColor

float

roughness

0

diffuse and specular roughness in [0–1], 0 is perfectly smooth

float

anisotropy

0

amount of specular anisotropy in [0–1]

float

rotation

0

rotation of the direction of anisotropy in [0–1], 1 is going full circle

float

normal

1

default normal map/scale for all layers

float

baseNormal

1

base normal map/scale (overrides default normal)

bool

thin

false

flag specifying whether the material is thin or solid

float

thickness

1

thickness of the material (thin only), affects the amount of color attenuation due to specular transmission

float

backlight

0

amount of diffuse transmission (thin only) in [0–2], 1 is 50% reflection and 50% transmission, 2 is transmission only

float

coat

0

clear coat layer weight in [0–1]

float

coatIor

1.5

clear coat index of refraction

vec3f

coatColor

white

clear coat color tint (linear RGB)

float

coatThickness

1

clear coat thickness, affects the amount of color attenuation

float

coatRoughness

0

clear coat roughness in [0–1], 0 is perfectly smooth

float

coatNormal

1

clear coat normal map/scale (overrides default normal)

float

sheen

0

sheen layer weight in [0–1]

vec3f

sheenColor

white

sheen color tint (linear RGB)

float

sheenTint

0

how much sheen is tinted from sheenColor toward baseColor

float

sheenRoughness

0.2

sheen roughness in [0–1], 0 is perfectly smooth

float

opacity

1

cut-out opacity/transparency, 1 is fully opaque

All parameters can be textured by passing a texture handle, prefixed with “map_” (e.g., “map_baseColor”). texture transformations are supported as well.

Rendering of a Principled coated brushed metal material with textured anisotropic rotation and a dust layer (sheen) on top.

Rendering of a Principled coated brushed metal material with textured anisotropic rotation and a dust layer (sheen) on top.

CarPaint

The CarPaint material is a specialized version of the Principled material for rendering different types of car paints. To create a CarPaint material, pass the type string “carPaint” to ospNewMaterial. Its parameters are listed in the table below.

Parameters of the CarPaint material.

Type

Name

Default

Description

vec3f

baseColor

white 0.8

diffuse base reflectivity (linear RGB)

float

roughness

0

diffuse roughness in [0–1], 0 is perfectly smooth

float

normal

1

normal map/scale

vec3f

flakeColor

Aluminium

color of metallic flakes (linear RGB)

float

flakeDensity

0

density of metallic flakes in [0–1], 0 disables flakes, 1 fully covers the surface with flakes

float

flakeScale

100

scale of the flake structure, higher values increase the amount of flakes

float

flakeSpread

0.3

flake spread in [0–1]

float

flakeJitter

0.75

flake randomness in [0–1]

float

flakeRoughness

0.3

flake roughness in [0–1], 0 is perfectly smooth

float

coat

1

clear coat layer weight in [0–1]

float

coatIor

1.5

clear coat index of refraction

vec3f

coatColor

white

clear coat color tint (linear RGB)

float

coatThickness

1

clear coat thickness, affects the amount of color attenuation

float

coatRoughness

0

clear coat roughness in [0–1], 0 is perfectly smooth

float

coatNormal

1

clear coat normal map/scale

vec3f

flipflopColor

white

reflectivity of coated flakes at grazing angle, used together with coatColor produces a pearlescent paint (linear RGB)

float

flipflopFalloff

1

flip flop color falloff, 1 disables the flip flop effect

All parameters can be textured by passing a texture handle, prefixed with “map_” (e.g., “map_baseColor”). texture transformations are supported as well.

Rendering of a pearlescent CarPaint material.

Rendering of a pearlescent CarPaint material.

Metal

The path tracer offers a physical metal, supporting changing roughness and realistic color shifts at edges. To create a Metal material pass the type string “metal” to ospNewMaterial. Its parameters are

Parameters of the Metal material.

Type

Name

Default

Description

vec3f[]

ior

Aluminium

data array of spectral samples of complex refractive index, each entry in the form (wavelength, eta, k), ordered by wavelength (which is in nm)

vec3f

eta

RGB complex refractive index, real part

vec3f

k

RGB complex refractive index, imaginary part

float

roughness

0.1

roughness in [0–1], 0 is perfect mirror

The main appearance (mostly the color) of the Metal material is controlled by the physical parameters eta and k, the wavelength-dependent, complex index of refraction. These coefficients are quite counter-intuitive but can be found in published measurements. For accuracy the index of refraction can be given as an array of spectral samples in ior, each sample a triplet of wavelength (in nm), eta, and k, ordered monotonically increasing by wavelength; OSPRay will then calculate the Fresnel in the spectral domain. Alternatively, eta and k can also be specified as approximated RGB coefficients; some examples are given in below table.

Index of refraction of selected metals as approximated RGB coefficients, based on data from https://refractiveindex.info/.

Metal

eta

k

Ag, Silver

(0.051, 0.043, 0.041)

(5.3, 3.6, 2.3)

Al, Aluminium

(1.5, 0.98, 0.6)

(7.6, 6.6, 5.4)

Au, Gold

(0.07, 0.37, 1.5)

(3.7, 2.3, 1.7)

Cr, Chromium

(3.2, 3.1, 2.3)

(3.3, 3.3, 3.1)

Cu, Copper

(0.1, 0.8, 1.1)

(3.5, 2.5, 2.4)

The roughness parameter controls the variation of microfacets and thus how polished the metal will look. The roughness can be modified by a texture map_roughness (texture transformations are supported as well) to create notable edging effects.

Rendering of golden Metal material with textured roughness.

Rendering of golden Metal material with textured roughness.

Alloy

The path tracer offers an alloy material, which behaves similar to Metal, but allows for more intuitive and flexible control of the color. To create an Alloy material pass the type string “alloy” to ospNewMaterial. Its parameters are

Parameters of the Alloy material.

Type

Name

Default

Description

vec3f

color

white 0.9

reflectivity at normal incidence (0 degree, linear RGB)

vec3f

edgeColor

white

reflectivity at grazing angle (90 degree, linear RGB)

float

roughness

0.1

roughness, in [0–1], 0 is perfect mirror

The main appearance of the Alloy material is controlled by the parameter color, while edgeColor influences the tint of reflections when seen at grazing angles (for real metals this is always 100% white). If present, the color component of geometries is also used for reflectivity at normal incidence color. As in Metal the roughness parameter controls the variation of microfacets and thus how polished the alloy will look. All parameters can be textured by passing a texture handle, prefixed with “map_”; texture transformations are supported as well.

Rendering of a fictional Alloy material with textured color.

Rendering of a fictional Alloy material with textured color.

Glass

The path tracer offers a realistic a glass material, supporting refraction and volumetric attenuation (i.e., the transparency color varies with the geometric thickness). To create a Glass material pass the type string “glass” to ospNewMaterial. Its parameters are

Parameters of the Glass material.

Type

Name

Default

Description

float

eta

1.5

index of refraction

vec3f

attenuationColor

white

resulting color due to attenuation (linear RGB)

float

attenuationDistance

1

distance affecting attenuation

For convenience, the rather counter-intuitive physical attenuation coefficients will be calculated from the user inputs in such a way, that the attenuationColor will be the result when white light traveled trough a glass of thickness attenuationDistance.

Rendering of a Glass material with orange attenuation.

Rendering of a Glass material with orange attenuation.

ThinGlass

The path tracer offers a thin glass material useful for objects with just a single surface, most prominently windows. It models a thin, transparent slab, i.e., it behaves as if a second, virtual surface is parallel to the real geometric surface. The implementation accounts for multiple internal reflections between the interfaces (including attenuation), but neglects parallax effects due to its (virtual) thickness. To create a such a thin glass material pass the type string “thinGlass” to ospNewMaterial. Its parameters are

Parameters of the ThinGlass material.

Type

Name

Default

Description

float

eta

1.5

index of refraction

vec3f

attenuationColor

white

resulting color due to attenuation (linear RGB)

float

attenuationDistance

1

distance affecting attenuation

float

thickness

1

virtual thickness

For convenience the attenuation is controlled the same way as with the Glass material. Additionally, the color due to attenuation can be modulated with a texture map_attenuationColor (texture transformations are supported as well). If present, the color component of geometries is also used for the attenuation color. The thickness parameter sets the (virtual) thickness and allows for easy exchange of parameters with the (real) Glass material; internally just the ratio between attenuationDistance and thickness is used to calculate the resulting attenuation and thus the material appearance.

Rendering of a ThinGlass material with red attenuation.

Rendering of a ThinGlass material with red attenuation.

Example image of a colored window made with textured attenuation of the ThinGlass material.

Example image of a colored window made with textured attenuation of the ThinGlass material.

MetallicPaint

The path tracer offers a metallic paint material, consisting of a base coat with optional flakes and a clear coat. To create a MetallicPaint material pass the type string “metallicPaint” to ospNewMaterial. Its parameters are listed in the table below.

Parameters of the MetallicPaint material.

Type

Name

Default

Description

vec3f

baseColor

white 0.8

color of base coat (linear RGB)

float

flakeAmount

0.3

amount of flakes, in [0–1]

vec3f

flakeColor

Aluminium

color of metallic flakes (linear RGB)

float

flakeSpread

0.5

spread of flakes, in [0–1]

float

eta

1.5

index of refraction of clear coat

The color of the base coat baseColor can be textured by a texture map_baseColor, which also supports texture transformations. If present, the color component of geometries is also used for the color of the base coat. Parameter flakeAmount controls the proportion of flakes in the base coat, so when setting it to 1 the baseColor will not be visible. The shininess of the metallic component is governed by flakeSpread, which controls the variation of the orientation of the flakes, similar to the roughness parameter of Metal. Note that the effect of the metallic flakes is currently only computed on average, thus individual flakes are not visible.

Rendering of a MetallicPaint material.

Rendering of a MetallicPaint material.

Luminous

The path tracer supports the Luminous material which emits light uniformly in all directions and which can thus be used to turn any geometric object into a light source. It is created by passing the type string “luminous” to ospNewMaterial. The amount of constant radiance that is emitted is determined by combining the general parameters of lights: `color and intensity <#lights>`__ (which essentially means that parameter intensityQuantity is not needed because it is always OSP_INTENSITY_QUANTITY_RADIANCE).

Parameters accepted by the Luminous material.

Type

Name

Default

Description

vec3f

color

white

color of the emitted light (linear RGB)

float

intensity

1

intensity of the light (a factor)

float

transparency

1

material transparency

Rendering of a yellow Luminous material.

Rendering of a yellow Luminous material.

Texture

OSPRay currently implements two texture types (texture2d and volume) and is open for extension to other types by applications. More types may be added in future releases.

To create a new texture use

OSPTexture ospNewTexture(const char *type);

Texture2D

The texture2d texture type implements an image-based texture, where its parameters are as follows

Parameters of texture2d texture type.

Type

Name

Description

int

format

OSPTextureFormat for the texture

int

filter

default OSP_TEXTURE_FILTER_BILINEAR, alternatively OSP_TEXTURE_FILTER_NEAREST

OSPData

data

the actual texel 2D data

The supported texture formats for texture2d are:

Supported texture formats by texture2d, i.e., valid constants of type OSPTextureFormat.

Name

Description

OSP_TEXTURE_RGBA8

8 bit [0–255] linear components red, green, blue, alpha

OSP_TEXTURE_SRGBA

8 bit sRGB gamma encoded color components, and linear alpha

OSP_TEXTURE_RGBA32F

32 bit float components red, green, blue, alpha

OSP_TEXTURE_RGB8

8 bit [0–255] linear components red, green, blue

OSP_TEXTURE_SRGB

8 bit sRGB gamma encoded components red, green, blue

OSP_TEXTURE_RGB32F

32 bit float components red, green, blue

OSP_TEXTURE_R8

8 bit [0–255] linear single component red

OSP_TEXTURE_RA8

8 bit [0–255] linear two components red, alpha

OSP_TEXTURE_L8

8 bit [0–255] gamma encoded luminance (replicated into red, green, blue)

OSP_TEXTURE_LA8

8 bit [0–255] gamma encoded luminance, and linear alpha

OSP_TEXTURE_R32F

32 bit float single component red

OSP_TEXTURE_RGBA16

16 bit [0–65535] linear components red, green, blue, alpha

OSP_TEXTURE_RGB16

16 bit [0–65535] linear components red, green, blue

OSP_TEXTURE_RA16

16 bit [0–65535] linear two components red, alpha

OSP_TEXTURE_R16

16 bit [0–65535] linear single component red

The size of the texture is inferred from the size of the 2D array data, which also needs have a compatible type to format. The texel data in data starts with the texels in the lower left corner of the texture image, like in OpenGL. Per default a texture fetch is filtered by performing bi-linear interpolation of the nearest 2×2 texels; if instead fetching only the nearest texel is desired (i.e., no filtering) then pass the OSP_TEXTURE_FILTER_NEAREST flag.

Texturing with texture2d image textures requires geometries with texture coordinates, e.g., a mesh with vertex.texcoord provided.

Volume Texture

The volume texture type implements texture lookups based on 3D object coordinates of the surface hit point on the associated geometry. If the given hit point is within the attached volume, the volume is sampled and classified with the transfer function attached to the volume. This implements the ability to visualize volume values (as colored by a transfer function) on arbitrary surfaces inside the volume (as opposed to an isosurface showing a particular value in the volume). Its parameters are as follows

Parameters of volume texture type.

Type

Name

Description

OSPVolume

volume

Volume used to generate color lookups

OSPTransferFunction

transferFunction

transfer function applied to volume

TextureVolume can be used for implementing slicing of volumes with any geometry type. It enables coloring of the slicing geometry with a different transfer function than that of the sliced volume.

Texture Transformations

All materials with textures also offer to manipulate the placement of these textures with the help of texture transformations. If so, this convention shall be used: the following parameters are prefixed with “texture_name.*”).

Parameters to define 2D texture coordinate transformations.

Type

Name

Description

linear2f

transform

linear transformation (rotation, scale)

float

rotation

angle in degree, counterclockwise, around center

vec2f

scale

enlarge texture, relative to center \((0.5, 0.5)\)

vec2f

translation

move texture in positive direction (right/up)

Above parameters are combined into a single affine2d transformation matrix and the transformations are applied in the given order. Rotation, scale and translation are interpreted “texture centric”, i.e., their effect seen by an user are relative to the texture (although the transformations are applied to the texture coordinates).

Parameter to define 3D volume texture transformations.

Type

Name

Description

affine3f

transform

linear transformation (rotation, scale) plus translation

Similarly, volume texture placement can also be modified by an affine3f transformation matrix.

Cameras

To create a new camera of given type type use

OSPCamera ospNewCamera(const char *type);

All cameras accept these parameters:

Parameters accepted by all cameras.

Type

Name

Default

Description

vec3f

position

\((0, 0, 0)\)

position of the camera

vec3f

direction

\((0, 0, 1)\)

main viewing direction of the camera

vec3f

up

\((0, 1, 0)\)

up direction of the camera

affine3f

transform

identity

additional world-space transform, overridden by motion.* arrays

float

nearClip

10-6

near clipping distance

vec2f

imageStart

\((0, 0)\)

start of image region (lower left corner)

vec2f

imageEnd

\((1, 1)\)

end of image region (upper right corner)

affine3f[]

motion.transform

additional uniformly distributed world-space transforms

vec3f[]

motion.scale

additional uniformly distributed world-space scale, overridden by motion.transform

vec3f[]

motion.pivot

additional uniformly distributed world-space translation which is applied before motion.rotation (i.e., the rotation center), overridden by motion.transform

quatf[]

motion.rotation

additional uniformly distributed world-space quaternion rotation, overridden by motion.transform

vec3f[]

motion.translation

additional uniformly distributed world-space translation, overridden by motion.transform

box1f

time

[0, 1]

time associated with first and last key in motion.* arrays

box1f

shutter

[0.5, 0.5]

start and end of shutter time (for motion blur), in [0, 1]

uchar

shutterType

OSP_SHUTTER_GLOBAL

OSPShutterType for motion blur, also allowed are:

OSP_SHUTTER_ROLLING_RIGHT

OSP_SHUTTER_ROLLING_LEFT

OSP_SHUTTER_ROLLING_DOWN

OSP_SHUTTER_ROLLING_UP

float

rollingShutterDuration

0

for a rolling shutter (see shutterType) the “open” time per line, in [0, shutter.upper-shutter.lower]

The camera is placed and oriented in the world with position, direction and up. Additionally, an extra transformation transform can be specified, which will only be applied to 3D vectors (i.e. position, direction and up), but does not affect any sizes (e.g., nearClip, apertureRadius, or height). The same holds for the array of transformations motion.transform to achieve camera motion blur (in combination with time and shutter).

OSPRay uses a right-handed coordinate system. The region of the camera sensor that is rendered to the image can be specified in normalized screen-space coordinates with imageStart (lower left corner) and imageEnd (upper right corner). This can be used, for example, to crop the image, to achieve asymmetrical view frusta, or to horizontally flip the image to view scenes which are specified in a left-handed coordinate system. Note that values outside the default range of [0–1] are valid, which is useful to easily realize overscan or film gate, or to emulate a shifted sensor.

Perspective Camera

The perspective camera implements a simple thin lens camera for perspective rendering, supporting optionally depth of field and stereo rendering (with the path tracer). It is created by passing the type string “perspective” to ospNewCamera. In addition to the general parameters understood by all cameras the perspective camera supports the special parameters listed in the table below.

Additional parameters accepted by the perspective camera.

Type

Name

Default

Description

float

fovy

60

the field of view (angle in degree) of the frame’s height

float

aspect

1

ratio of width by height of the frame (and image region)

float

apertureRadius

0

size of the aperture, controls the depth of field

float

focusDistance

1

distance at where the image is sharpest when depth of field is enabled

bool

architectural

false

vertical edges are projected to be parallel

uchar

stereoMode

OSP_STEREO_NONE

OSPStereoMode for stereo rendering, also allowed are:

OSP_STEREO_LEFT

OSP_STEREO_RIGHT

OSP_STEREO_SIDE_BY_SIDE

OSP_STEREO_TOP_BOTTOM (left eye at top half)

float

interpupillaryDistance

0.0635

distance between left and right eye when stereo is enabled

Note that when computing the aspect ratio a potentially set image region (using imageStart & imageEnd) needs to be regarded as well.

In architectural photography it is often desired for aesthetic reasons to display the vertical edges of buildings or walls vertically in the image as well, regardless of how the camera is tilted. Enabling the architectural mode achieves this by internally leveling the camera parallel to the ground (based on the up direction) and then shifting the lens such that the objects in direction dir are centered in the image. If finer control of the lens shift is needed use imageStart & imageEnd. Because the camera is now effectively leveled its image plane and thus the plane of focus is oriented parallel to the front of buildings, the whole façade appears sharp, as can be seen in the example images below. The resolution of the framebuffer is not altered by imageStart/imageEnd.

Example image created with the perspective camera, featuring depth of field.

Example image created with the perspective camera, featuring depth of field.

Enabling the ``architectural`` flag corrects the perspective projection distortion, resulting in parallel vertical edges.

Enabling the architectural flag corrects the perspective projection distortion, resulting in parallel vertical edges.

Example 3D stereo image using ``stereoMode = OSP_STEREO_SIDE_BY_SIDE``.

Example 3D stereo image using stereoMode = OSP_STEREO_SIDE_BY_SIDE.

Orthographic Camera

The orthographic camera implements a simple camera with orthographic projection, without support for depth. It is created by passing the type string “orthographic” to ospNewCamera. In addition to the general parameters understood by all cameras the orthographic camera supports the following special parameters:

Additional parameters accepted by the orthographic camera.

Type

Name

Description

float

height

size of the camera’s image plane in y, in world coordinates

float

aspect

ratio of width by height of the frame

For convenience the size of the camera sensor, and thus the extent of the scene that is captured in the image, can be controlled with the height parameter. The same effect can be achieved with imageStart and imageEnd, and both methods can be combined. In any case, the aspect ratio needs to be set accordingly to get an undistorted image.

Example image created with the orthographic camera.

Example image created with the orthographic camera.

Panoramic Camera

The panoramic camera implements a simple camera with support for stereo rendering. It captures the complete surrounding with a latitude / longitude mapping and thus the rendered images should best have a ratio of 2:1. A panoramic camera is created by passing the type string “panoramic” to ospNewCamera. It is placed and oriented in the scene by using the general parameters understood by all cameras.

Additional parameters accepted by the panoramic camera.

Type

Name

Description

uchar

stereoMode

OSPStereoMode for stereo rendering, possible values are:

OSP_STEREO_NONE (default)

OSP_STEREO_LEFT

OSP_STEREO_RIGHT

OSP_STEREO_SIDE_BY_SIDE

OSP_STEREO_TOP_BOTTOM (left eye at top half)

float

interpupillaryDistance

distance between left and right eye when stereo is enabled, default 0.0635

Latitude / longitude map created with the panoramic camera.

Latitude / longitude map created with the panoramic camera.

Picking

To get the world-space position of the geometry (if any) seen at [0–1] normalized screen-space pixel coordinates screenPos_x and screenPos_y use

void ospPick(OSPPickResult *,
    OSPFrameBuffer,
    OSPRenderer,
    OSPCamera,
    OSPWorld,
    float screenPos_x,
    float screenPos_y);

The result is returned in the provided OSPPickResult struct:

typedef struct {
    int hasHit;
    float worldPosition[3];
    OSPInstance instance;
    OSPGeometricModel model;
    uint32_t primID;
} OSPPickResult;

Note that ospPick considers exactly the same camera of the given renderer that is used to render an image, thus matching results can be expected. If the camera supports depth of field then the center of the lens and thus the center of the circle of confusion is used for picking. Note that the caller needs to ospRelease the instance and model handles of OSPPickResult once the information is not needed anymore.

Framebuffer

The framebuffer holds the rendered 2D image (and optionally auxiliary information associated with pixels). To create a new framebuffer object of given size size (in pixels), color format, and channels use

OSPFrameBuffer ospNewFrameBuffer(int size_x, int size_y,
    OSPFrameBufferFormat format = OSP_FB_SRGBA,
    uint32_t frameBufferChannels = OSP_FB_COLOR);

The parameter format describes the format the color buffer has on the host, and the format that ospMapFrameBuffer will eventually return. Valid values are:

Supported color formats of the framebuffer that can be passed to ospNewFrameBuffer, i.e., valid constants of type OSPFrameBufferFormat.

Name

Description

OSP_FB_NONE

framebuffer will not be mapped by the application

OSP_FB_RGBA8

8 bit [0–255] linear component red, green, blue, alpha

OSP_FB_SRGBA

8 bit sRGB gamma encoded color components, and linear alpha

OSP_FB_RGBA32F

32 bit float components red, green, blue, alpha

The parameter frameBufferChannels specifies which channels the framebuffer holds, and can be combined together by bitwise OR from the values of OSPFrameBufferChannel listed in the table below.

Framebuffer channels constants (of type OSPFrameBufferChannel), naming optional information the framebuffer can store. These values can be combined by bitwise OR when passed to ospNewFrameBuffer.

Name

Description

OSP_FB_COLOR

RGB color including alpha

OSP_FB_DEPTH

euclidean distance to the camera (not to the image plane), as linear 32 bit float; for multiple samples per pixel their minimum is taken

OSP_FB_ACCUM

accumulation buffer for progressive refinement

OSP_FB_VARIANCE

for estimation of the current noise level if OSP_FB_ACCUM is also present, see rendering

OSP_FB_NORMAL

accumulated world-space normal of the first non-specular hit, as vec3f

OSP_FB_ALBEDO

accumulated material albedo (color without illumination) at the first hit, as vec3f

If a certain channel value is not specified, the given buffer channel will not be present. Note that OSPRay makes a clear distinction between the external format of the framebuffer and the internal one: The external format is the format the user specifies in the format parameter; it specifies what color format OSPRay will eventually return the framebuffer to the application (when calling ospMapFrameBuffer): no matter what OSPRay uses internally, it will simply return a 2D array of pixels of that format, with possibly all kinds of reformatting, compression/decompression, etc., going on in-between the generation of the internal framebuffer and the mapping of the externally visible one.

In particular, OSP_FB_NONE is a perfectly valid pixel format for a framebuffer that an application will never map. For example, an application driving a display wall may well generate an intermediate framebuffer and eventually transfer its pixel to the individual displays using an OSPImageOperation image operation.

The application can map the given channel of a framebuffer – and thus access the stored pixel information – via

const void *ospMapFrameBuffer(OSPFrameBuffer, OSPFrameBufferChannel = OSP_FB_COLOR);

Note that OSP_FB_ACCUM or OSP_FB_VARIANCE cannot be mapped. The origin of the screen coordinate system in OSPRay is the lower left corner (as in OpenGL), thus the first pixel addressed by the returned pointer is the lower left pixel of the image.

A previously mapped channel of a framebuffer can be unmapped by passing the received pointer mapped to

void ospUnmapFrameBuffer(const void *mapped, OSPFrameBuffer);

The individual channels of a framebuffer can be cleared with

void ospResetAccumulation(OSPFrameBuffer);

This function will clear all accumulating buffers (OSP_FB_VARIANCE, OSP_FB_NORMAL, and OSP_FB_ALBEDO, if present) and resets the accumulation counter accumID. It is unspecified if the existing color and depth buffers are physically cleared when ospResetAccumulation is called.

If OSP_FB_VARIANCE is specified, an estimate of the variance of the last accumulated frame can be queried with

float ospGetVariance(OSPFrameBuffer);

Note this value is only updated after synchronizing with OSP_FRAME_FINISHED, as further described in asynchronous rendering. The estimated variance can be used by the application as a quality indicator and thus to decide whether to stop or to continue progressive rendering.

The framebuffer takes a list of pixel operations to be applied to the image in sequence as an OSPData. The pixel operations will be run in the order they are in the array.

Parameters accepted by the framebuffer.

Type

Name

Description

OSPImageOperation[]

imageOperation

ordered sequence of image operations

Image Operation

Image operations are functions that are applied to every pixel of a frame. Examples include post-processing, filtering, blending, tone mapping, or sending tiles to a display wall. To create a new pixel operation of given type type use

OSPImageOperation ospNewImageOperation(const char *type);

Tone Mapper

The tone mapper is a pixel operation which implements a generic filmic tone mapping operator. Using the default parameters it approximates the Academy Color Encoding System (ACES). The tone mapper is created by passing the type string “tonemapper” to ospNewImageOperation. The tone mapping curve can be customized using the parameters listed in the table below.

Parameters accepted by the tone mapper.

Type

Name

Default

Description

float

exposure

1.0

amount of light per unit area

float

contrast

1.6773

contrast (toe of the curve); typically is in [1–2]

float

shoulder

0.9714

highlight compression (shoulder of the curve); typically is in [0.9–1]

float

midIn

0.18

mid-level anchor input; default is 18% gray

float

midOut

0.18

mid-level anchor output; default is 18% gray

float

hdrMax

11.0785

maximum HDR input that is not clipped

bool

acesColor

true

apply the ACES color transforms

To use the popular “Uncharted 2” filmic tone mapping curve instead, set the parameters to the values listed in the table below.

Filmic tone mapping curve parameters. Note that the curve includes an exposure bias to match 18% middle gray.

Name

Value

contrast

1.1759

shoulder

0.9746

midIn

0.18

midOut

0.18

hdrMax

6.3704

acesColor

false

Denoiser

OSPRay comes with a module that adds support for Intel® Open Image Denoise. This is provided as an optional module as it creates an additional project dependency at compile time. The module implements a “denoiser” frame operation, which denoises the entire frame before the frame is completed.

Rendering

Asynchronous Rendering

Rendering is by default asynchronous (non-blocking), and is done by combining a framebuffer, renderer, camera, and world.

What to render and how to render it depends on the renderer’s parameters. If the framebuffer supports accumulation (i.e., it was created with OSP_FB_ACCUM) then successive calls to ospRenderFrame will progressively refine the rendered image.

To start an render task, use

OSPFuture ospRenderFrame(OSPFrameBuffer, OSPRenderer, OSPCamera, OSPWorld);

This returns an OSPFuture handle, which can be used to synchronize with the application, cancel, or query for progress of the running task. When ospRenderFrame is called, there is no guarantee when the associated task will begin execution.

Progress of a running frame can be queried with the following API function

float ospGetProgress(OSPFuture);

This returns the approximated progress of the task in [0-1].

Applications can cancel a currently running asynchronous operation via

void ospCancel(OSPFuture);

Applications can wait on the result of an asynchronous operation, or choose to only synchronize with a specific event. To synchronize with an OSPFuture use

void ospWait(OSPFuture, OSPSyncEvent = OSP_TASK_FINISHED);

The following are values which can be synchronized with the application

Supported events that can be passed to ospWait.

Name

Description

OSP_NONE_FINISHED

Do not wait for anything to be finished (immediately return from ospWait)

OSP_WORLD_COMMITTED

Wait for the world to be committed (not yet implemented)

OSP_WORLD_RENDERED

Wait for the world to be rendered, but not post-processing operations (Pixel/Tile/Frame Op)

OSP_FRAME_FINISHED

Wait for all rendering operations to complete

OSP_TASK_FINISHED

Wait on full completion of the task associated with the future. The underlying task may involve one or more of the above synchronization events

Currently only rendering can be invoked asynchronously. However, future releases of OSPRay may add more asynchronous versions of API calls (and thus return OSPFuture).

Applications can query whether particular events are complete with

int ospIsReady(OSPFuture, OSPSyncEvent = OSP_TASK_FINISHED);

As the given running task runs (as tracked by the OSPFuture), applications can query a boolean [0, 1] result if the passed event has been completed.

Applications can query how long an async task ran with

float ospGetTaskDuration(OSPFuture);

This returns the wall clock execution time of the task in seconds. If the task is still running, this will block until the task is completed. This is useful for applications to query exactly how long an asynchronous task executed without the overhead of measuring both task execution + synchronization by the calling application.

Asynchronously Rendering and ospCommit()

The use of either ospRenderFrame or ospRenderFrame requires that all objects in the scene being rendered have been committed before rendering occurs. If a call to ospCommit() happens while a frame is rendered, the result is undefined behavior and should be avoided.

Synchronous Rendering

For convenience in certain use cases, ospray_util.h provides a synchronous version of ospRenderFrame:

float ospRenderFrameBlocking(OSPFrameBuffer, OSPRenderer, OSPCamera, OSPWorld);

This version is the equivalent of:

ospRenderFrame
ospWait(f, OSP_TASK_FINISHED)
return ospGetVariance(fb)

This version is closest to ospRenderFrame from OSPRay v1.x.

Distributed Rendering with MPI

The purpose of the MPI module for OSPRay is to provide distributed rendering capabilities for OSPRay. The module enables image- and data-parallel rendering across HPC clusters using MPI, allowing applications to transparently distribute rendering work, or to render data sets which are too large to fit in memory on a single machine.

The MPI module provides two OSPRay devices to allow applications to leverage distributed rendering capabilities. The mpiOffload device provides transparent image-parallel rendering, where the same OSPRay application written for local rendering can be replicated across multiple nodes to distribute the rendering work. The mpiDistributed device allows MPI distributed applications to use OSPRay for distributed rendering, where each rank can render and independent piece of a global data set, or hybrid rendering where ranks partially or completely share data.

MPI Offload Rendering

The mpiOffload device can be used to distribute image rendering tasks across a cluster without requiring modifications to the application itself. Existing applications using OSPRay for local rendering simply be passed command line arguments to load the module and indicate that the mpiOffload device should be used for image-parallel rendering. To load the module, pass --osp:load-modules=mpi, to select the MPIOffloadDevice, pass --osp:device=mpiOffload. For example, the ospExamples application can be run as:

mpirun -n <N> ./ospExamples --osp:load-modules=mpi --osp:device=mpiOffload

and will automatically distribute the image rendering tasks among the corresponding N nodes. Note that in this configuration rank 0 will act as a master/application rank, and will run the user application code but not perform rendering locally. Thus, a minimum of 2 ranks are required, one master to run the application and one worker to perform the rendering. Running with 3 ranks for example would now distribute half the image rendering work to rank 1 and half to rank 2.

If more control is required over the placement of ranks to nodes, or you want to run a worker rank on the master node as well you can run the application and the ospray_mpi_worker program through MPI’s MPMD mode. The ospray_mpi_worker will load the MPI module and select the offload device by default.

mpirun -n 1 ./ospExamples --osp:load-modules=mpi --osp:device=mpiOffload \
  : -n <N> ./ospray_mpi_worker

If initializing the mpiOffload device manually, or passing parameters through the command line, the following parameters can be set:

Parameters specific to the mpiOffload Device.

Type

Name

Default

Description

string

mpiMode

mpi

The mode to communicate with the worker ranks. mpi will assume you’re launching the application and workers in the same mpi command (or split launch command). mpi is the only supported mode

uint

maxCommandBufferEntries

8192

Set the max number of commands to buffer before submitting the command buffer to the workers

uint

commandBufferSize

512 MiB

Set the max command buffer size to allow. Units are in MiB. Max size is 1.8 GiB

uint

maxInlineDataSize

32 MiB

Set the max size of an OSPData which can be inline’d into the command buffer instead of being sent separately. Max size is half the commandBufferSize. Units are in MiB

The maxCommandBufferEntries, commandBufferSize, and maxInlineDataSize can also be set via the environment variables: OSPRAY_MPI_MAX_COMMAND_BUFFER_ENTRIES, OSPRAY_MPI_COMMAND_BUFFER_SIZE, and OSPRAY_MPI_MAX_INLINE_DATA_SIZE, respectively.

The mpiOffload device does not support multiple init/shutdown cycles. Thus, to run ospBenchmark for this device make sure to exclude the init/shutdown test by passing --benchmark_filter=-ospInit_ospShutdown through the command line.

MPI Distributed Rendering

While MPI Offload rendering is used to transparently distribute rendering work without requiring modification to the application, MPI Distributed rendering is targeted at use of OSPRay within MPI-parallel applications. The MPI distributed device can be selected by loading the mpi module, and manually creating and using an instance of the mpiDistributed device:

ospLoadModule("mpi");

OSPDevice mpiDevice = ospNewDevice("mpiDistributed");
ospDeviceCommit(mpiDevice);
ospSetCurrentDevice(mpiDevice);

Your application can either initialize MPI before-hand, ensuring that MPI_THREAD_SERIALIZED or higher is supported, or allow the device to initialize MPI on commit. Thread multiple support is required if your application will make MPI calls while rendering asynchronously with OSPRay. When using the distributed device each rank can specify independent local data using the OSPRay API, as if rendering locally. However, when calling ospRenderFrameAsync the ranks will work collectively to render the data. The distributed device supports both image-parallel, where the data is replicated, and data-parallel, where the data is distributed, rendering modes. The mpiDistributed device will by default use each rank in MPI_COMM_WORLD as a render worker; however, it can also take a specific MPI communicator to use as the world communicator. Only those ranks in the specified communicator will participate in rendering.

Parameters specific to the distributed mpiDistributed Device.

Type

Name

Default

Description

void *

worldCommunicator

MPI_COMM_WORLD

The MPI communicator which the OSPRay workers should treat as their world

Parameters specific to the distributed OSPWorld.

Type

Name

Default

Description

box3f[]

region

NULL

A list of bounding boxes which bound the owned local data to be rendered by the rank

Parameters specific to the mpiRaycast renderer.

Type

Name

Default

Description

int

aoSamples

0

The number of AO samples to take per-pixel

float

aoDistance

1020

The AO ray length to use. Note that if the AO ray would have crossed a rank boundary and ghost geometry is not available, there will be visible artifacts in the shading

Image Parallel Rendering in the MPI Distributed Device

If all ranks specify exactly the same data, the distributed device can be used for image-parallel rendering. This works identical to the offload device, except that the MPI-aware application is able to load data in parallel on each rank rather than loading on the master and shipping data out to the workers. When a parallel file system is available, this can improve data load times. Image-parallel rendering is selected by specifying the same data on each rank, and using any of the existing local renderers (e.g., scivis, pathtracer). See ospMPIDistribTutorialReplicated for an example.

Data Parallel Rendering in the MPI Distributed Device

The MPI Distributed device also supports data-parallel rendering with sort-last compositing. Each rank can specify a different piece of data, as long as the bounding boxes of each rank’s data are non-overlapping. The rest of the scene setup is similar to local rendering; however, for distributed rendering only the mpiRaycast renderer is supported. This renderer implements a subset of the scivis rendering features which are suitable for implementation in a distributed environment.

By default the aggregate bounding box of the instances in the local world will be used as the bounds of that rank’s data. However, when using ghost zones for volume interpolation, geometry or ambient occlusion, each rank’s data can overlap. To clip these non-owned overlap regions out a set of regions (the region parameter) can pass as a parameter to the OSPWorld being rendered. Each rank can specify one or more non-overlapping box3f’s which bound the portions of its local data which it is responsible for rendering. See the ospMPIDistribTutorialVolume for an example.

Finally, the MPI distributed device also supports hybrid-parallel rendering, where multiple ranks can share a single piece of data. For each shared piece of data the rendering work will be assigned image-parallel among the ranks. Partially-shared regions are determined by finding those ranks specifying data with the same bounds (matching regions) and merging them. See the ospMPIDistribTutorialPartialRepl for an example.

Picking on Distributed Data in the MPI Distributed Device

Calling ospPick in the distributed device will find and return the closest global object at the screen position on the rank that owns that object. The other ranks will report no hit. Picking in the distributed device takes into account data clipping applied through the regions parameter to avoid picking ghost data.

Interaction with User Modules

The MPI Offload rendering mode trivially supports user modules, with the caveat that attempting to share data directly with the application (e.g., passing a void\ * or other tricks to the module) will not work in a distributed environment. Instead, use the ospNewSharedData API to share data from the application with OSPRay, which will in turn be copied over the network to the workers.

The MPI Distributed device also supports user modules, as all that is required for compositing the distributed data are the bounds of each rank’s local data.

MultiDevice Rendering

The multidevice module is an experimental OSPRay device type that renders images by delegating off pixel tiles to a number of internal delegate OSPRay devices. Multidevice is in still in an development stage and is currently limited to automatically creating ISPCDevice delegates.

If you wish to try it set the OSPRAY_NUM_SUBDEVICES environmental variable to the number of subdevices you want to create and tell OSPRay to both load the multidevice extension and create a multidevice for rendering instead of the default ISPCDevice.

One example in a bash like shell is as follows:

OSPRAY_NUM_SUBDEVICES=6 ./ospTutorial --osp:load-modules=multidevice --osp:device=multidevice
1

The number of items to be copied is defined by the size of the source array.

2

For consecutive memory addresses the x-index of the corresponding voxel changes the quickest.

3

actually a parallelogram

4

including spheres, boxes, infinite planes, closed meshes, closed subdivisions and curves

5

OSPBounds has essentially the same layout as the OSP_BOX3F `OSPDataType <#data>`__.

6

If there are multiple ambient lights then their contribution is added.

7

respectively \((127, 127, 255)\) for 8 bit textures and \((32767, 32767, 65535)\) for 16 bit textures