Iray Programmer's Manual

Preface
Getting started
- Release overview
- Example programs
- How to compile a program
- How to run a program
- Starting and shutting down the Iray API
- A first image
Library design
- API modules
- Shared library
- Naming conventions
- Include files
- Include file compile-time configuration
- Main API access point
- Version numbers and compatibility
- Interfaces
- Reference counting
- Handle class
- Resources
- Strings
- Error handling
- Database, transactions and scopes
  - Transactions
  - Database scopes
- Runtime configuration
Rendering
- Rendering overview
- Rendering and canvases
- Render mode selection
- Progressive rendering of a scene
- Own canvas class
- Asynchronous rendering
- Multiple render contexts
Iray Photoreal
- Introduction
- System requirements
- Limitations
- Matte objects and matte lights
- Refractive objects and IOR handling
- Progressive rendering
- Caustic sampler
- Architectural sampler
- Light portals
- Rendering options
- Mixed mode rendering and load balancing
- Timeout prevention
- Integrated noise reduction
- Integrated bloom
Iray Interactive
- Introduction
- System requirements
- Limitations
- Progressive rendering
- Lighting
- Rendering options
- Path space filtering
- Output format
- Global performance settings
- Comparison with Iray Photoreal
Iray Realtime
- Introduction
- System requirements
- Limitations
- Rendering options
Iray Blend
- Introduction
- Rendering options
Scene database
- Overview of the scene database elements
- Creating a scene programmatically
Geometry
- Creating triangle meshes
- Creating polygon meshes
- Creating on-demand meshes
- Creating subdivision surfaces
- Creating freeform surfaces
Materials
- Material Definition Language
- Measured materials
- Editing and creating materials
Decals
Sources of light
- Emission distribution functions
- Light distribution from scene elements
Environment dome and implicit groundplane
- Environment function
- Environment dome
- Implicit groundplane
Camera
- Tonemapping
  - Photographic tonemapper
  - Custom tonemapper
- Depth of field
- Virtual backplate
- Motion blur
Physically plausible scene setup
- Recommendations for geometry preparation
- Recommendations for lights
  - Using photometric lights
  - Using environment and sunlight
- Recommendations for materials
- Recommendations for cameras
Networking
- Networking overview
- Networking modes
- Iray Bridge
Delivering an image from server-based rendering
- Running an HTTP server
- RTMP server
- RTMP client
- Running an RTMP and HTTP server with mouse interaction
Customization
- Extending the database with user-defined classes
- Extending neuray with plugins
- Extending supported file formats with plugins
Appendix
- Supported file formats and URI schemes
- Result canvas names
- Light path expression grammar
Bibliography

Modeling glass

In real life, glass objects always have a thickness. Even when really thin, their depth is often not inconsiderable. In order to compute proper refractions, Iray expects light rays to travel through solid geometry.

In some cases, the thickness really is negligible. Examples are far-away windows or soap bubbles, cases where refraction effects are no longer visible. In such cases, modeling objects without a thickness is fine, if the materials are set up accordingly. The thin-walled feature of MDL is designed for just this purpose. Remember that refractions will be ignored with this setting enabled.

Figure 1. Thin-walled glass material
File: images/modeling_glass_thinwalled.jpg

File: images/modeling_glass_thinwalled.jpg

Iray Photoreal will be able to properly compute and render refractions when glass is modeled as a solid geometry.

Figure 2. Glass material on a solid geometry
File: images/modeling_glass_thickwalled.jpg

File: images/modeling_glass_thickwalled.jpg

The following example illustrates how important it is to model glass geometries in the exact same way as they appear in real life in order to get an accurate result with Iray Photoreal.

Figure 3. Light bulb modeled with a single continuous line. Once the Lathe modifier is applied, the result will be a solid geometry. When rendered with a physical glass material, the bulb will look like its one solid piece of glass.
File: images/modeling_lightbulb_solid.jpg

File: images/modeling_lightbulb_solid.jpg

To model a realistic bulb, ensure that the hull is one thin layer of glass that always has a thickness. Model a very thin external layer.

Figure 4. Physically correct modelled lightbulb. Note the drastic difference between the solid lightbulb above and this version which uses a modelled hull.
File: images/modeling_lightbulb_shell.jpg

File: images/modeling_lightbulb_shell.jpg

When rendered with a physical glass material, the result will now be photorealistic. Note the strong refraction effects at the top of the bulb.