nalgebra/src/lib.rs

516 lines
13 KiB
Rust
Raw Normal View History

2017-02-13 01:17:09 +08:00
/*!
# nalgebra
**nalgebra** is a linear algebra library written for Rust targeting:
* General-purpose linear algebra (still lacks a lot of features)
* Real time computer graphics.
* Real time computer physics.
## Using **nalgebra**
You will need the last stable build of the [rust compiler](http://www.rust-lang.org)
and the official package manager: [cargo](https://github.com/rust-lang/cargo).
Simply add the following to your `Cargo.toml` file:
```.ignore
[dependencies]
2018-07-20 22:35:57 +08:00
nalgebra = "0.16"
2017-02-13 01:17:09 +08:00
```
Most useful functionalities of **nalgebra** are grouped in the root module `nalgebra::`.
However, the recommended way to use **nalgebra** is to import types and traits
explicitly, and call free-functions using the `na::` prefix:
```.rust
#[macro_use]
extern crate approx; // For the macro relative_eq!
extern crate nalgebra as na;
use na::{Vector3, Rotation3};
fn main() {
let axis = Vector3::x_axis();
let angle = 1.57;
let b = Rotation3::from_axis_angle(&axis, angle);
relative_eq!(b.axis().unwrap(), axis);
relative_eq!(b.angle(), angle);
}
```
## Features
**nalgebra** is meant to be a general-purpose, low-dimensional, linear algebra library, with
an optimized set of tools for computer graphics and physics. Those features include:
* A single parametrizable type `Matrix` for vectors, (square or rectangular) matrices, and slices
with dimensions known either at compile-time (using type-level integers) or at runtime.
* Matrices and vectors with compile-time sizes are statically allocated while dynamic ones are
allocated on the heap.
* Convenient aliases for low-dimensional matrices and vectors: `Vector1` to `Vector6` and
`Matrix1x1` to `Matrix6x6`, including rectangular matrices like `Matrix2x5`.
2017-02-13 01:17:09 +08:00
* Points sizes known at compile time, and convenience aliases: `Point1` to `Point6`.
* Translation (seen as a transformation that composes by multiplication): `Translation2`,
`Translation3`.
* Rotation matrices: `Rotation2`, `Rotation3`.
* Quaternions: `Quaternion`, `UnitQuaternion` (for 3D rotation).
* Unit complex numbers can be used for 2D rotation: `UnitComplex`.
* Algebraic entities with a norm equal to one: `Unit<T>`, e.g., `Unit<Vector3<f32>>`.
* Isometries (translation rotation): `Isometry2`, `Isometry3`
* Similarity transformations (translation rotation uniform scale): `Similarity2`, `Similarity3`.
* Affine transformations stored as an homogeneous matrix: `Affine2`, `Affine3`.
* Projective (i.e. invertible) transformations stored as an homogeneous matrix: `Projective2`,
`Projective3`.
* General transformations that does not have to be invertible, stored as an homogeneous matrix:
`Transform2`, `Transform3`.
* 3D projections for computer graphics: `Perspective3`, `Orthographic3`.
* Matrix factorizations: `Cholesky`, `QR`, `LU`, `FullPivLU`, `SVD`, `RealSchur`, `Hessenberg`, `SymmetricEigen`.
* Insertion and removal of rows of columns of a matrix.
* Implements traits from the [alga](https://crates.io/crates/alga) crate for
2017-02-13 01:17:09 +08:00
generic programming.
*/
// #![feature(plugin)]
//
// #![plugin(clippy)]
2017-02-13 01:17:09 +08:00
#![deny(non_camel_case_types)]
#![deny(unused_parens)]
#![deny(non_upper_case_globals)]
#![deny(unused_qualifications)]
#![deny(unused_results)]
2018-02-02 19:26:40 +08:00
#![deny(missing_docs)]
#![warn(incoherent_fundamental_impls)]
2017-04-09 19:19:27 +08:00
#![doc(html_root_url = "http://nalgebra.org/rustdoc")]
#![cfg_attr(not(feature = "std"), no_std)]
2018-05-24 23:17:34 +08:00
#![cfg_attr(all(feature = "alloc", not(feature = "std")), feature(alloc))]
#[cfg(feature = "arbitrary")]
extern crate quickcheck;
#[cfg(feature = "serde")]
2017-02-13 01:17:09 +08:00
extern crate serde;
#[cfg(feature = "serde")]
2017-02-13 01:17:09 +08:00
#[macro_use]
extern crate serde_derive;
#[cfg(feature = "abomonation-serialize")]
extern crate abomonation;
2017-07-25 23:04:12 +08:00
#[cfg(feature = "mint")]
extern crate mint;
#[macro_use]
extern crate approx;
extern crate generic_array;
#[cfg(feature = "std")]
extern crate matrixmultiply;
2018-02-02 19:26:35 +08:00
extern crate num_complex;
extern crate num_traits as num;
extern crate rand;
extern crate typenum;
extern crate alga;
2018-05-24 23:17:34 +08:00
#[cfg(all(feature = "alloc", not(feature = "std")))]
extern crate alloc;
#[cfg(not(feature = "std"))]
extern crate core as std;
pub mod base;
#[cfg(feature = "debug")]
pub mod debug;
pub mod geometry;
pub mod linalg;
#[cfg(feature = "std")]
#[deprecated(
note = "The 'core' module is being renamed 'based' to avoid conflicts with the 'core' crate."
)]
pub use base as core;
pub use base::*;
pub use geometry::*;
pub use linalg::*;
2018-02-02 19:26:35 +08:00
use std::cmp::{self, Ordering, PartialOrd};
Api change: deal with inplace/out of place methods. Before, it was too easy to use an out of place method instead of the inplace one since they name were pretty mutch the same. This kind of confusion may lead to silly bugs very hard to understand. Thus the following changes have been made when a method is available both inplace and out-of-place: * inplace version keep a short name. * out-of-place version are suffixed by `_cpy` (meaning `copy`), and are static methods. Methods applying transformations (rotation, translation or general transform) are now prefixed by `append`, and a `prepend` version is available too. Also, free functions doing in-place modifications dont really make sense. They have been removed. Here are the naming changes: * `invert` -> `inv` * `inverted` -> `Inv::inv_cpy` * `transpose` -> `transpose` * `transposed` -> `Transpose::transpose_cpy` * `transform_by` -> `append_transformation` * `transformed` -> `Transform::append_transformation_cpy` * `rotate_by` -> `apppend_rotation` * `rotated` -> `Rotation::append_rotation_cpy` * `translate_by` -> `apppend_translation` * `translate` -> `Translation::append_translation_cpy` * `normalized` -> `Norm::normalize_cpy` * `rotated_wrt_point` -> `RotationWithTranslation::append_rotation_wrt_point_cpy` * `rotated_wrt_center` -> `RotationWithTranslation::append_rotation_wrt_center_cpy` Note that using those static methods is very verbose, and using in-place methods require an explicit import of the related trait. This is a way to convince the user to use free functions most of the time.
2013-10-14 16:22:32 +08:00
use alga::general::{
Additive, AdditiveGroup, Identity, Inverse, JoinSemilattice, Lattice, MeetSemilattice,
Multiplicative, SupersetOf,
};
use alga::linear::SquareMatrix as AlgaSquareMatrix;
2018-02-02 19:26:35 +08:00
use alga::linear::{EuclideanSpace, FiniteDimVectorSpace, InnerSpace, NormedSpace};
use num::Signed;
2017-02-13 01:17:09 +08:00
2018-02-02 19:26:35 +08:00
pub use alga::general::{Id, Real};
2017-02-13 01:17:09 +08:00
/*
*
* Multiplicative identity.
*
*/
/// Gets the ubiquitous multiplicative identity element.
///
/// Same as `Id::new()`.
#[inline]
pub fn id() -> Id {
Id::new()
}
Api change: deal with inplace/out of place methods. Before, it was too easy to use an out of place method instead of the inplace one since they name were pretty mutch the same. This kind of confusion may lead to silly bugs very hard to understand. Thus the following changes have been made when a method is available both inplace and out-of-place: * inplace version keep a short name. * out-of-place version are suffixed by `_cpy` (meaning `copy`), and are static methods. Methods applying transformations (rotation, translation or general transform) are now prefixed by `append`, and a `prepend` version is available too. Also, free functions doing in-place modifications dont really make sense. They have been removed. Here are the naming changes: * `invert` -> `inv` * `inverted` -> `Inv::inv_cpy` * `transpose` -> `transpose` * `transposed` -> `Transpose::transpose_cpy` * `transform_by` -> `append_transformation` * `transformed` -> `Transform::append_transformation_cpy` * `rotate_by` -> `apppend_rotation` * `rotated` -> `Rotation::append_rotation_cpy` * `translate_by` -> `apppend_translation` * `translate` -> `Translation::append_translation_cpy` * `normalized` -> `Norm::normalize_cpy` * `rotated_wrt_point` -> `RotationWithTranslation::append_rotation_wrt_point_cpy` * `rotated_wrt_center` -> `RotationWithTranslation::append_rotation_wrt_center_cpy` Note that using those static methods is very verbose, and using in-place methods require an explicit import of the related trait. This is a way to convince the user to use free functions most of the time.
2013-10-14 16:22:32 +08:00
/// Gets the multiplicative identity element.
#[inline]
pub fn one<T: Identity<Multiplicative>>() -> T {
T::identity()
}
Api change: deal with inplace/out of place methods. Before, it was too easy to use an out of place method instead of the inplace one since they name were pretty mutch the same. This kind of confusion may lead to silly bugs very hard to understand. Thus the following changes have been made when a method is available both inplace and out-of-place: * inplace version keep a short name. * out-of-place version are suffixed by `_cpy` (meaning `copy`), and are static methods. Methods applying transformations (rotation, translation or general transform) are now prefixed by `append`, and a `prepend` version is available too. Also, free functions doing in-place modifications dont really make sense. They have been removed. Here are the naming changes: * `invert` -> `inv` * `inverted` -> `Inv::inv_cpy` * `transpose` -> `transpose` * `transposed` -> `Transpose::transpose_cpy` * `transform_by` -> `append_transformation` * `transformed` -> `Transform::append_transformation_cpy` * `rotate_by` -> `apppend_rotation` * `rotated` -> `Rotation::append_rotation_cpy` * `translate_by` -> `apppend_translation` * `translate` -> `Translation::append_translation_cpy` * `normalized` -> `Norm::normalize_cpy` * `rotated_wrt_point` -> `RotationWithTranslation::append_rotation_wrt_point_cpy` * `rotated_wrt_center` -> `RotationWithTranslation::append_rotation_wrt_center_cpy` Note that using those static methods is very verbose, and using in-place methods require an explicit import of the related trait. This is a way to convince the user to use free functions most of the time.
2013-10-14 16:22:32 +08:00
/// Gets the additive identity element.
#[inline]
pub fn zero<T: Identity<Additive>>() -> T {
T::identity()
Api change: deal with inplace/out of place methods. Before, it was too easy to use an out of place method instead of the inplace one since they name were pretty mutch the same. This kind of confusion may lead to silly bugs very hard to understand. Thus the following changes have been made when a method is available both inplace and out-of-place: * inplace version keep a short name. * out-of-place version are suffixed by `_cpy` (meaning `copy`), and are static methods. Methods applying transformations (rotation, translation or general transform) are now prefixed by `append`, and a `prepend` version is available too. Also, free functions doing in-place modifications dont really make sense. They have been removed. Here are the naming changes: * `invert` -> `inv` * `inverted` -> `Inv::inv_cpy` * `transpose` -> `transpose` * `transposed` -> `Transpose::transpose_cpy` * `transform_by` -> `append_transformation` * `transformed` -> `Transform::append_transformation_cpy` * `rotate_by` -> `apppend_rotation` * `rotated` -> `Rotation::append_rotation_cpy` * `translate_by` -> `apppend_translation` * `translate` -> `Translation::append_translation_cpy` * `normalized` -> `Norm::normalize_cpy` * `rotated_wrt_point` -> `RotationWithTranslation::append_rotation_wrt_point_cpy` * `rotated_wrt_center` -> `RotationWithTranslation::append_rotation_wrt_center_cpy` Note that using those static methods is very verbose, and using in-place methods require an explicit import of the related trait. This is a way to convince the user to use free functions most of the time.
2013-10-14 16:22:32 +08:00
}
/// Gets the origin of the given point.
#[inline]
pub fn origin<P: EuclideanSpace>() -> P {
P::origin()
}
/*
*
* Dimension
*
*/
/// The dimension of the given algebraic entity seen as a vector space.
#[inline]
pub fn dimension<V: FiniteDimVectorSpace>() -> usize {
V::dimension()
}
/*
*
* Ordering
*
*/
// XXX: this is very naive and could probably be optimized for specific types.
// XXX: also, we might just want to use divisions, but assuming `val` is usually not far from `min`
// or `max`, would it still be more efficient?
/// Wraps `val` into the range `[min, max]` using modular arithmetics.
///
/// The range must not be empty.
#[inline]
pub fn wrap<T>(mut val: T, min: T, max: T) -> T
2018-02-02 19:26:35 +08:00
where
T: Copy + PartialOrd + AdditiveGroup,
{
assert!(min < max, "Invalid wrapping bounds.");
let width = max - min;
if val < min {
val += width;
while val < min {
val += width
}
val
2018-02-02 19:26:35 +08:00
} else if val > max {
val -= width;
while val > max {
val -= width
}
val
2018-02-02 19:26:35 +08:00
} else {
val
}
}
/// Returns a reference to the input value clamped to the interval `[min, max]`.
///
/// In particular:
/// * If `min < val < max`, this returns `val`.
/// * If `val <= min`, this retuns `min`.
/// * If `val >= max`, this retuns `max`.
#[inline]
pub fn clamp<T: PartialOrd>(val: T, min: T, max: T) -> T {
if val > min {
if val < max {
val
2018-02-02 19:26:35 +08:00
} else {
max
}
2018-02-02 19:26:35 +08:00
} else {
min
}
}
/// Same as `cmp::max`.
#[inline]
pub fn max<T: Ord>(a: T, b: T) -> T {
cmp::max(a, b)
}
/// Same as `cmp::min`.
#[inline]
pub fn min<T: Ord>(a: T, b: T) -> T {
cmp::min(a, b)
}
/// The absolute value of `a`.
#[inline]
pub fn abs<T: Signed>(a: &T) -> T {
a.abs()
}
/// Returns the infimum of `a` and `b`.
#[inline]
pub fn inf<T: MeetSemilattice>(a: &T, b: &T) -> T {
a.meet(b)
}
/// Returns the supremum of `a` and `b`.
#[inline]
pub fn sup<T: JoinSemilattice>(a: &T, b: &T) -> T {
a.join(b)
}
/// Returns simultaneously the infimum and supremum of `a` and `b`.
#[inline]
pub fn inf_sup<T: Lattice>(a: &T, b: &T) -> (T, T) {
a.meet_join(b)
}
/// Compare `a` and `b` using a partial ordering relation.
#[inline]
pub fn partial_cmp<T: PartialOrd>(a: &T, b: &T) -> Option<Ordering> {
a.partial_cmp(b)
}
/// Returns `true` iff `a` and `b` are comparable and `a < b`.
#[inline]
pub fn partial_lt<T: PartialOrd>(a: &T, b: &T) -> bool {
a.lt(b)
}
/// Returns `true` iff `a` and `b` are comparable and `a <= b`.
#[inline]
pub fn partial_le<T: PartialOrd>(a: &T, b: &T) -> bool {
a.le(b)
}
/// Returns `true` iff `a` and `b` are comparable and `a > b`.
#[inline]
pub fn partial_gt<T: PartialOrd>(a: &T, b: &T) -> bool {
a.gt(b)
}
/// Returns `true` iff `a` and `b` are comparable and `a >= b`.
#[inline]
pub fn partial_ge<T: PartialOrd>(a: &T, b: &T) -> bool {
a.ge(b)
}
/// Return the minimum of `a` and `b` if they are comparable.
#[inline]
pub fn partial_min<'a, T: PartialOrd>(a: &'a T, b: &'a T) -> Option<&'a T> {
if let Some(ord) = a.partial_cmp(b) {
match ord {
Ordering::Greater => Some(b),
2018-02-02 19:26:35 +08:00
_ => Some(a),
}
2018-02-02 19:26:35 +08:00
} else {
None
}
}
/// Return the maximum of `a` and `b` if they are comparable.
#[inline]
pub fn partial_max<'a, T: PartialOrd>(a: &'a T, b: &'a T) -> Option<&'a T> {
if let Some(ord) = a.partial_cmp(b) {
match ord {
Ordering::Less => Some(b),
2018-02-02 19:26:35 +08:00
_ => Some(a),
}
2018-02-02 19:26:35 +08:00
} else {
None
}
}
/// Clamp `value` between `min` and `max`. Returns `None` if `value` is not comparable to
/// `min` or `max`.
#[inline]
pub fn partial_clamp<'a, T: PartialOrd>(value: &'a T, min: &'a T, max: &'a T) -> Option<&'a T> {
if let (Some(cmp_min), Some(cmp_max)) = (value.partial_cmp(min), value.partial_cmp(max)) {
if cmp_min == Ordering::Less {
Some(min)
2018-02-02 19:26:35 +08:00
} else if cmp_max == Ordering::Greater {
Some(max)
2018-02-02 19:26:35 +08:00
} else {
Some(value)
}
2018-02-02 19:26:35 +08:00
} else {
None
}
}
/// Sorts two values in increasing order using a partial ordering.
#[inline]
pub fn partial_sort2<'a, T: PartialOrd>(a: &'a T, b: &'a T) -> Option<(&'a T, &'a T)> {
if let Some(ord) = a.partial_cmp(b) {
match ord {
Ordering::Less => Some((a, b)),
2018-02-02 19:26:35 +08:00
_ => Some((b, a)),
}
2018-02-02 19:26:35 +08:00
} else {
None
}
}
/*
* Inverse
*/
/// Tries to gets an inverted copy of a square matrix.
#[inline]
pub fn try_inverse<M: AlgaSquareMatrix>(m: &M) -> Option<M> {
m.try_inverse()
}
2017-02-13 01:17:09 +08:00
/// Computes the multiplicative inverse of an (always invertible) algebraic entity.
#[inline]
pub fn inverse<M: Inverse<Multiplicative>>(m: &M) -> M {
m.inverse()
}
/*
* Inner vector space
*/
/// Computes the dot product of two vectors.
#[inline]
pub fn dot<V: FiniteDimVectorSpace>(a: &V, b: &V) -> V::Field {
a.dot(b)
}
2017-02-13 01:17:09 +08:00
/// Computes the smallest angle between two vectors.
#[inline]
pub fn angle<V: InnerSpace>(a: &V, b: &V) -> V::Real {
a.angle(b)
}
/*
* Normed space
*/
2017-02-13 01:17:09 +08:00
/// Computes the L2 (euclidean) norm of a vector.
#[inline]
pub fn norm<V: NormedSpace>(v: &V) -> V::Field {
v.norm()
}
2017-02-13 01:17:09 +08:00
/// Computes the squared L2 (euclidean) norm of the vector `v`.
#[inline]
pub fn norm_squared<V: NormedSpace>(v: &V) -> V::Field {
v.norm_squared()
2013-05-19 01:04:03 +08:00
}
/// A synonym function for `norm()` aka length.
#[inline]
pub fn magnitude<V: NormedSpace>(v: &V) -> V::Field {
v.norm()
}
/// A synonym function for `norm_squared()` aka length squared.
#[inline]
pub fn magnitude_squared<V: NormedSpace>(v: &V) -> V::Field {
v.norm_squared()
}
2017-02-13 01:17:09 +08:00
/// Computes the normalized version of the vector `v`.
#[inline]
pub fn normalize<V: NormedSpace>(v: &V) -> V {
v.normalize()
}
2017-02-13 01:17:09 +08:00
/// Computes the normalized version of the vector `v` or returns `None` if its norm is smaller than `min_norm`.
#[inline]
pub fn try_normalize<V: NormedSpace>(v: &V, min_norm: V::Field) -> Option<V> {
v.try_normalize(min_norm)
}
/*
*
* Point operations.
*
*/
/// The center of two points.
#[inline]
pub fn center<P: EuclideanSpace>(p1: &P, p2: &P) -> P {
P::from_coordinates((p1.coordinates() + p2.coordinates()) * convert(0.5))
}
/// The distance between two points.
#[inline]
pub fn distance<P: EuclideanSpace>(p1: &P, p2: &P) -> P::Real {
(p2.coordinates() - p1.coordinates()).norm()
}
/// The squared distance between two points.
#[inline]
pub fn distance_squared<P: EuclideanSpace>(p1: &P, p2: &P) -> P::Real {
(p2.coordinates() - p1.coordinates()).norm_squared()
}
/*
* Cast
*/
/// Converts an object from one type to an equivalent or more general one.
///
/// See also `::try_convert` for conversion to more specific types.
#[inline]
pub fn convert<From, To: SupersetOf<From>>(t: From) -> To {
To::from_subset(&t)
}
/// Attempts to convert an object to a more specific one.
///
/// See also `::convert` for conversion to more general types.
#[inline]
pub fn try_convert<From: SupersetOf<To>, To>(t: From) -> Option<To> {
t.to_subset()
}
/// Indicates if `::try_convert` will succeed without actually performing the conversion.
#[inline]
pub fn is_convertible<From: SupersetOf<To>, To>(t: &From) -> bool {
t.is_in_subset()
}
/// Use with care! Same as `try_convert` but without any property checks.
#[inline]
pub unsafe fn convert_unchecked<From: SupersetOf<To>, To>(t: From) -> To {
t.to_subset_unchecked()
}
/// Converts an object from one type to an equivalent or more general one.
#[inline]
pub fn convert_ref<From, To: SupersetOf<From>>(t: &From) -> To {
To::from_subset(t)
}
/// Attempts to convert an object to a more specific one.
#[inline]
pub fn try_convert_ref<From: SupersetOf<To>, To>(t: &From) -> Option<To> {
t.to_subset()
}
/// Use with care! Same as `try_convert` but without any property checks.
#[inline]
pub unsafe fn convert_ref_unchecked<From: SupersetOf<To>, To>(t: &From) -> To {
t.to_subset_unchecked()
}