**Something wrong with your benchmarking**

It is really surprising that no one observed this!

You have used `t(X) %*% X`

inside `solve()`

. You should use `crossprod(X)`

, as `X'X`

is a symmetric matrix. `crossprod()`

only computes half of the matrix while copying the rest. `%*%`

forces computing all. So `crossprod()`

will be two times faster. This explains why in your benchmarking, you have roughly the same timing between `solve()`

and `lm.fit()`

.

On my old Intel Nahalem (2008 Intel Core 2 Duo), I have:

```
X <- matrix(runif(1000*1000),1000)
system.time(t(X)%*%X)
# user system elapsed
# 2.320 0.000 2.079
system.time(crossprod(X))
# user system elapsed
# 1.22 0.00 0.94
```

If your computer is faster, try using `X <- matrix(runif(2000*2000),2000)`

instead.

In the following, I will explain the computational details involved in all fitting methods.

**QR factorization v.s. Cholesky factorization**

`lm()`

/ `lm.fit()`

is QR based, while `solve()`

is Cholesky based. The computational costs of QR decomposition is `2 * n * p^2`

, while Cholesky method is `n * p^2 + p^3`

(`n * p^2`

for computing matrix cross product, `p^3`

for Cholesky decomposition). So you can see that when `n`

is much much greater than `p`

, Cholesky method is about 2 times faster than QR method. So there is really no need to benchmark here. (*in case you don't know, *`n`

is the number of data, `p`

is the number of parameters.)

**LINPACK QR v.s. LAPACK QR**

Typically, `lm.fit()`

uses (modified) `LINPACK`

QR factorization algorithm, rather than `LAPACK`

QR factorization algorithm. Maybe you are not very familiar with `BLAS/LINPACK/LAPACK`

; these are FORTRAN code providing kernel scientific matrix computations. `LINPACK`

calls level-1 BLAS, while `LAPACK`

calls level-3 `BLAS`

using block algorithms. On average, `LAPACK`

QR is 1.6 times faster than `LINPACK`

QR. **The critical reason that **`lm.fit()`

does not use `LAPACK`

version, is the need for partial column pivoting. `LAPACK`

version does full column pivoting, making it more difficult for `summary.lm()`

to use the `R`

matrix factor of QR decomposition to produce F-statistic and `ANOVA`

test.

**pivoting v.s. no pivoting**

`fastLm()`

from `RcppEigen`

package uses `LAPACK`

non-pivoted QR factorization. Again, you may be unclear about the QR factorization algorithm and pivoting issues. You only need to know that QR factorization with pivoting has only 50% share of level-3 `BLAS`

, while QR factorization without pivoting has 100% share of level-3 `BLAS`

. In this regard, giving up pivoting will speed up QR factorization process. Surely, the final result is different, and when the model matrix is rank deficient, no pivoting gives dangerous result.

There is a good question related to the different result you get from `fastLM`

: Why does `fastLm()`

return results when I run a regression with one observation?. @BenBolker, @DirkEddelbuettel and I had a very brief discussion in comments of Ben's answer.

**Conclusion: Do you want speed, or numerical stability?**

In terms of numerical stability, there is:

```
LINPACK pivoted QR > LAPACK pivoted QR > pivoted Cholesky > LAPACK non-pivoted QR
```

In terms of speed, there is:

```
LINPACK pivoted QR < LAPACK pivoted QR < pivoted Cholesky < LAPACK non-pivoted QR
```

As Dirk said,

*FWIW the RcppEigen package has a fuller set of decompositions in its *`fastLm()`

example. But here it is as Ben so eloquently stated: "this is part of the price you pay for speed.". We give you enough rope to hang yourself. If you want to protect yourself from yourself, stick with `lm()`

or `lm.fit()`

, or create a hybrid 'fast-but-safe' version.

**Fast and stable version**

Check my answer Here.

`lm()`

is doing a lot more than solving the least squares problem. The list generated by`lm()`

has 12 items. – lmo Apr 12 '16 at 11:32`lm.fit()`

you need`lm.fit(X,data$y)`

-- which is much closer to`solve`

in this case, although the mean is stillslightlylarger. – Ben Bolker Apr 12 '16 at 11:39