There is no LU factorization function in R core. Although such factorization is a step of `solve`

, it is not made explicitly available as a stand-alone function. Can we write an R function for this? It needs mimic LAPACK routine `dgetrf`

. `Matrix`

package has an `lu`

function which is good, but it would be better if we could write a **trackable** R function, that can

- factorize the matrix till a certain column / row and return the intermediate result;
- continue the factorization from an intermediate result to another column / row or to the end.

This function would be useful for both educational and debugging purpose. The benefit for education is evident as we can illustrate the factorization / Gaussian elimination column by column. For debugging use, here are two examples.

In Inconsistent results between LU decomposition in R and Python, it is asked why LU factorization in R and Python gives different result. We can clearly see that both software return identical 1st pivot and 2nd pivot, but not the 3rd. So there must be something interesting when the factorization proceeds to the 3rd row / column. It would be good if we could retrieve that temporary result for an investigation.

In Can I stably invert a Vandermonde matrix with many small values in R? LU factorization is unstable for this type of matrix. In my answer, a 3 x 3 matrix is given for an example. I would expect `solve`

to produce an error complaining `U[3, 3] = 0`

, but running `solve`

for a few times I find that `solve`

is sometimes successful. So for a numerical investigation, I would like to know what happens when the factorization proceeds to the 2nd column / row.

Since the function is to be written in pure R code, it is expected to be slow for a moderate to big matrix. But performance is not an issue, as for education and debugging we only use a small matrix.

**A little introduction to dgetrf**

LAPACK's dgetrf computes LU factorization with row pivoting: `A = PLU`

. On exit of the factorization,

`L`

is a unit lower triangular matrix, stored in the lower triangular part of`A`

;`U`

is an upper triangular matrix, stored in the upper triangular part of`A`

;`P`

is a row permutation matrix stored as a separate permutation index vector.

Unless a pivot is **exactly zero** (not up to some tolerance), factorization should proceed.

**What I start with**

It is not challenging to write a LU factorization with neither row pivoting nor "pause / continue" option:

```
LU <- function (A) {
## check dimension
n <- dim(A)
if (n[1] != n[2]) stop("'A' must be a square matrix")
n <- n[1]
## Gaussian elimination
for (j in 1:(n - 1)) {
ind <- (j + 1):n
## check if the pivot is EXACTLY 0
piv <- A[j, j]
if (piv == 0) stop(sprintf("system is exactly singular: U[%d, %d] = 0", j, j))
l <- A[ind, j] / piv
## update `L` factor
A[ind, j] <- l
## update `U` factor by Gaussian elimination
A[ind, ind] <- A[ind, ind] - tcrossprod(l, A[j, ind])
}
A
}
```

This is shown to give correct result when pivoting is not required:

```
A <- structure(c(0.923065107548609, 0.922819485189393, 0.277002309216186,
0.532856695353985, 0.481061384081841, 0.0952619954477996,
0.261916425777599, 0.433514681644738, 0.677919807843864,
0.771985625848174, 0.705952850636095, 0.873727774480358,
0.28782021952793, 0.863347264472395, 0.627262107795104,
0.187472499441355), .Dim = c(4L, 4L))
oo <- LU(A)
oo
# [,1] [,2] [,3] [,4]
#[1,] 0.9230651 0.4810614 0.67791981 0.2878202
#[2,] 0.9997339 -0.3856714 0.09424621 0.5756036
#[3,] 0.3000897 -0.3048058 0.53124291 0.7163376
#[4,] 0.5772688 -0.4040044 0.97970570 -0.4479307
L <- diag(4)
low <- lower.tri(L)
L[low] <- oo[low]
L
# [,1] [,2] [,3] [,4]
#[1,] 1.0000000 0.0000000 0.0000000 0
#[2,] 0.9997339 1.0000000 0.0000000 0
#[3,] 0.3000897 -0.3048058 1.0000000 0
#[4,] 0.5772688 -0.4040044 0.9797057 1
U <- oo
U[low] <- 0
U
# [,1] [,2] [,3] [,4]
#[1,] 0.9230651 0.4810614 0.67791981 0.2878202
#[2,] 0.0000000 -0.3856714 0.09424621 0.5756036
#[3,] 0.0000000 0.0000000 0.53124291 0.7163376
#[4,] 0.0000000 0.0000000 0.00000000 -0.4479307
```

Comparison with `lu`

from `Matrix`

package:

```
library(Matrix)
rr <- expand(lu(A))
rr
#$L
#4 x 4 Matrix of class "dtrMatrix" (unitriangular)
# [,1] [,2] [,3] [,4]
#[1,] 1.0000000 . . .
#[2,] 0.9997339 1.0000000 . .
#[3,] 0.3000897 -0.3048058 1.0000000 .
#[4,] 0.5772688 -0.4040044 0.9797057 1.0000000
#
#$U
#4 x 4 Matrix of class "dtrMatrix"
# [,1] [,2] [,3] [,4]
#[1,] 0.92306511 0.48106138 0.67791981 0.28782022
#[2,] . -0.38567138 0.09424621 0.57560363
#[3,] . . 0.53124291 0.71633755
#[4,] . . . -0.44793070
#
#$P
#4 x 4 sparse Matrix of class "pMatrix"
#
#[1,] | . . .
#[2,] . | . .
#[3,] . . | .
#[4,] . . . |
```

Now consider a permuted `A`

:

```
B <- A[c(4, 3, 1, 2), ]
LU(B)
# [,1] [,2] [,3] [,4]
#[1,] 0.5328567 0.43351468 0.8737278 0.1874725
#[2,] 0.5198439 0.03655646 0.2517508 0.5298057
#[3,] 1.7322952 -7.38348421 1.0231633 3.8748743
#[4,] 1.7318343 -17.93154011 3.6876940 -4.2504433
```

The result is different from `LU(A)`

. However, since `Matrix::lu`

performs row pivoting, the result of `lu(B)`

only differs from `lu(A)`

in the permutation matrix:

```
expand(lu(B))$P
#4 x 4 sparse Matrix of class "pMatrix"
#
#[1,] . . . |
#[2,] . . | .
#[3,] | . . .
#[4,] . | . .
```

`pracma`

package also has an`lu`

function, but it does not apply pivoting. Readers can verify (using matrix`B`

) that it is equivalent to function`LU`

in my question.`pracma::lu`

is poorly written with a double loop-nest at R-level.`LU`

uses a single R-level loop hence is a better implementation.