[−][src]Crate nphysics2d
nphysics
nphysics is a 2 and 3-dimensional physics engine for games and animations. It uses ncollide for collision detection, and nalgebra for vector/matrix math. 2D and 3D implementations both share the same code!
Examples are available in the examples2d
and examples3d
directories. There
is also a short (outdated) demonstration video.
An on-line version of this documentation is available
here. Feel free to ask for help and discuss features on
the official user forum.
Why another physics engine?
There are a lot of physics engine out there. However having a physics engine written in Rust is much more fun than writing bindings and has several advantages:
- it shows that Rust is suitable for soft real-time applications
- it shows how well Rust behaves with highly generic code
- it shows that there is no need to write two separate engine for 2D and 3D: genericity wrt the dimension is possible (modulo low level arithmetic specializations for each dimension).
- in a not-that-near future, C++ will die of ugliness. Then, people will search for a physics engine and nphysics will be there, proudly exhibiting its Rusty sexyness.
Features
- Static and dynamic rigid bodies.
- Common convex primitives: cone, box, ball, cylinder.
- Concave geometries build from convex primitives (aka. compound geometries).
- Stable stacking.
- Island based sleeping (objects deactivation).
- Ray casting.
- Swept sphere based continuous collision detection.
- Ball-in-socket joint.
- FixedJoint joint.
- Sensors.
- Deformable bodies (aka. soft-bodies)
- Kinematic bodies
What is missing?
nphysics is a very young library and needs to learn a lot of things to become a grown up. Many missing features are because of missing features on ncollide. Features missing from nphysics itself include:
- more joints, joint limits, joint motors and breakable joints.
- parallel pipeline
- GPU-based pipeline
Dependencies
All dependencies are automatically cloned with a recursive clone. The libraries needed to compile the physics engine are:
The libraries needed to compile the examples are:
Modules
algebra | Dynamics-specific algebraic entities: velocity, forces, and inertias. |
counters | Counters for benchmarking various parts of the physics engine. |
detection | Collision detection information. |
force_generator | Persistent force generation. |
joint | Joints using the reduced-coordinates formalism or using constraints. |
material | Material data structures. |
math | Compilation flags dependent aliases for mathematical types. |
object | Objects that may be added to the physical world. |
solver | Constraint solver. |
utils | Miscellaneous utilities. |
volumetric | Volume and inertia tensor computation. |
world | The physics world. |