Expand description
§IterativeSolvers
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This library provides Rust implementations of iterative algorithms for solving linear system, drawing heavy inspiration from the Julia package IterativeSolvers.jl.
§Iterative Algorithms
- Conjugate Gradient (CG)
§Supported Linear Algebra Libraries
You can choose your preferred backend using Cargo features:
[dependencies]
iterative-solvers = { version = "0.1", default-features = false, features = ["faer"] }§Usage
Consider the following differential equation:
-\frac{d^2 u}{dx^2} = \pi^2 \sin(\pi x) \quad \text{for} \quad x \in (0, 1)with the boundary conditions:
u(0) = 0, \quad u(1) = 0.The solution to this problem is:
u(x) = \sin(\pi x).Now we use the central difference method to discretize the differential equation:
-\frac{u_{i+1} - 2u_i + u_{i-1}}{h^2} = \pi^2 \sin(\pi x_i) \quad \text{for} \quad i = 1, \ldots, N-1,where $h = 1/N$ is the step size, and $u_i$ is the approximation of $u(x_i)$. The boundary conditions are:
u_0 = 0, \quad u_N = 0.The coefficient matrix of this linear system is a symmetric tridiagonal matrix, whose diagonal elements are $2/h^2$ and the sub-diagonal elements are $-1/h^2$.
We can solve this linear system using the Conjugate Gradient (CG) method.
use iterative_solvers::{cg, CG, utils::sparse::symmetric_tridiagonal_csc};
use nalgebra::DVector;
use std::f64::consts::PI;
fn main() {
let n = 1024;
let h = 1.0 / 1024.0;
let a = vec![2.0 / (h * h); n - 1];
let b = vec![-1.0 / (h * h); n - 2];
// Store the symmetric tridiagonal matrix in CSC format
let mat = symmetric_tridiagonal_csc(&a, &b).unwrap();
// Generate the right-hand side vector
let rhs: Vec<_> = (1..n)
.map(|i| PI * PI * (i as f64 * h * PI).sin())
.collect();
// Generate the exact solution
let solution: Vec<_> = (1..n).map(|i| (i as f64 * h * PI).sin()).collect();
let solution = DVector::from_vec(solution);
let rhs = DVector::from_vec(rhs);
// Solve the linear system using the CG method
let result = cg(&mat, &rhs, 1e-10, 1e-8).unwrap();
// Calculate the error
let e = (solution - result.solution()).norm();
println!("error: {}", e);
}If you want to know the residual, the approximate solution and the conjugate direction at each iteration, the iterator will help you.
let abstol = 1e-10;
let reltol = 1e-8;
let mut solver = CG::new(&mat, &rhs, abstol, reltol).unwrap();
while let Some(residual) = solver.next() {
println!("residual: {residual}");
println!("solution: {:#?}", solver.solution());
println!("conjugate direction: {:#?}", solver.conjugate_direction());
}
let e = (solution - solver.solution()).norm();
println!("error: {}", e);§License
Licensed under either of:
- Apache License, Version 2.0, (LICENSE-APACHE or https://www.apache.org/licenses/LICENSE-2.0)
- MIT license (LICENSE-MIT or https://opensource.org/licenses/MIT)
at your option.
§Contribution
Unless you explicitly state otherwise, any contribution intentionally submitted for inclusion in the work by you, as defined in the Apache-2.0 license, shall be dual licensed as above, without any additional terms or conditions.
Re-exports§
pub use error::*;
Modules§
- cg
- Conjugate Gradient (CG) method.
- error
- Error and Result type for iterative solvers.
- ops
- utils
- Utility functions for creating sparse and dense matrices.
Structs§
- CG
- Conjugate Gradient (CG) method for solving linear systems Ax = b.
Traits§
Functions§
- cg
- Solve a linear system Ax = b using the Conjugate Gradient method.
- cg_
with_ initial_ guess - Solve a linear system Ax = b using the Conjugate Gradient method.