# Optimization for functions that produce NaN for some initial values

I would like to find all local minimums of the following objective function

``````func <- function(b){Mat=matrix(c(+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2),2,2);d=(det(Mat));return(d)}
``````

'func' is determinant of Fisher information matrix of Logistic regression model and is a function of parameters b1 and b2 where b1 belongs to [-.3, .3] and b2 to [6, 8]

Suppose these two initial values for b = c(b1, b2)

``````> in1 <- c(-0.04785405, 6.42711047)
> in2 <- c(0.2246729, 7.5211575)
``````

The local minimum with initial value `in1` is:

``````> optim(in1, fn = func, lower = c(-.3, 6), upper = c(.3, 8), method = "L-BFGS-B")

\$par
[1] -0.04785405  6.42711047

\$value
[1] 3.07185e-27

\$counts
1        1

\$convergence
[1] 52

\$message
[1] "ERROR: ABNORMAL_TERMINATION_IN_LNSRCH"
``````

As can be seen in the `\$massage` a termination happened in optimization process and minimum could not be computed and `optim` returned `in1` as local optima.

For 'in2' also an error is appeared:

``````> optim(in2, fn = func, lower = c(-.3, 6), upper = c(.3, 8), method = "L-BFGS-B")

Error in optim(in2, fn = func, lower = c(-0.3, 6), upper = c(0.3, 8),  :
L-BFGS-B needs finite values of 'fn'
``````

This error happened because the value of `func` for `in2' is`NaN`:

``````> func(in2)
[1] NaN
``````

However for `in1` the value of objective function at `in1` is calculated but the optimization is terminated because `optim` could not continue the calculation for another intial values:

``````> func(in1)
[1] 3.07185e-27
``````

Let me define func without det and just as matrix to see what happened:

``````Mat.func <- function(b){Mat=matrix(c(+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5)/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5)/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2,+0.5*1/((1/(exp(-b[1]-b[2]*-5)+1))*(1-(1/(exp(-b[1]-b[2]*-5)+1))))*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2*exp(-b[1] - b[2] * -5) * -5/(exp(-b[1] - b[2] * -5) + 1)^2+0.5*1/((1/(exp(-b[1]-b[2]*5)+1))*(1-(1/(exp(-b[1]-b[2]*5)+1))))*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2*exp(-b[1] - b[2] * 5) * 5/(exp(-b[1] - b[2] * 5) + 1)^2),2,2);d=Mat;return(d)}
``````

We get

``````         > Mat.func(in1)
[,1]         [,2]
[1,] 1.109883e-14 2.784007e-15
[2,] 2.784007e-15 2.774708e-13

> Mat.func(in2)
[,1] [,2]
[1,]  Inf  Inf
[2,]  Inf  Inf
``````

Hence, by double precision, values of `Mat.func(in2)` elements are `Inf`. I also rewrite `Mat.func` with mpfr function:

``````Mat.func.mpfr <-function(b, prec){ d=c(+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2,
+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) * -5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) * 5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2,
+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) * -5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5)/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) * 5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2,
+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*-5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) * -5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) * -5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * -5) + 1)^2+0.5*1/((1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))*(1-(1/(exp(-mpfr(b[1], precBits = prec)-mpfr(b[2], precBits = prec)*5)+1))))*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) * 5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2*exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) * 5/(exp(-mpfr(b[1], precBits = prec) - mpfr(b[2], precBits = prec) * 5) + 1)^2)
Mat = new("mpfrMatrix", d, Dim = c(2L, 2L))
return(Mat)}
``````

Thus:

``````require(Rmpfr)
> Mat.func.mpfr(c(in1), prec = 54)
'mpfrMatrix' of dim(.) =  (2, 2) of precision  54   bits
[,1]
[1,] 1.10988301365972506e-14
[2,] 2.78400749725484580e-15
[,2]
[1,] 2.78400749725484580e-15
[2,] 2.77470753414931256e-13

> Mat.func.mpfr(c(in2), prec = 54)
'mpfrMatrix' of dim(.) =  (2, 2) of precision  54   bits
[,1] [,2]
[1,]  Inf  Inf
[2,]  Inf  Inf

> Mat.func.mpfr(c(in2), prec = 55)
'mpfrMatrix' of dim(.) =  (2, 2) of precision  55   bits
[,1]
[1,]  4.16032108702067276e-17
[2,] -8.34300174643550123e-17
[,2]
[1,] -8.34300174643550154e-17
[2,]  1.04008027175516816e-15
``````

So by precision 55 the values of matrix elements are not `Inf` anymore. unfortunately, `mpfr` function changes the class of an objective and nor `det` neither r optimization functions can not be applied, to clarify I provide two examples:

``````> class(mpfr (1/3, 54))
[1] "mpfr"
attr(,"package")
[1] "Rmpfr"

## determinant
example1 <- function(x){
d <- c(mpfr(x, prec = 54), 3 * mpfr(x, prec = 54), 5 * mpfr(x, prec = 54), 7 * mpfr(x, prec = 54))
Mat = new("mpfrMatrix", d, Dim = c(2L, 2L))
return(det(Mat))
}

> example1(2)
Error in UseMethod("determinant") :
no applicable method for 'determinant' applied to an object of class "c('mpfrMatrix',    'mpfrArray', 'Mnumber', 'mNumber', 'mpfr', 'list', 'vector')"

##optimization
example2 <- function(x)  ## Rosenbrock Banana function
100 * (mpfr(x[2], prec = 54) - mpfr(x[1], prec = 54) * mpfr(x[1], prec = 54 ))^2 + (1 - mpfr(x[1], prec = 54))^2

> example2(c(-1.2, 1))
1 'mpfr' number of precision  54   bits
[1] 24.1999999999999957
> optim(c(-1.2,1), example2)
Error in optim(c(-1.2, 1), example2) :
(list) object cannot be coerced to type 'double'
``````

Hence, using mpfr could not solve the problem.

To find All the local minimums, an algorithm which applies different random initial values should be written. But as can be seen, for some initial values the function produces `NaN` (ignorance of these values would not be a good idea because it may generally results in missing some local minimums ,specially for functions that have lots of local optima).

I was wondering if there is any R package that can carry on optimization process with arbitrary precision to avoid `NaN` for objective functions?

Thank you

-
you might be able to reformulate your objective function to get fewer `NaN` values (e.g. by rearranging to minimize the possibility of underflow/overflow) –  Ben Bolker Jan 28 '13 at 1:27
So you are trying to minimize `log(det(some_matrix))`. 1) You get NaN whenever `det(some_matrix) < 0` because `log(x)` is not defined for `x < 0`; what meaning do you give to that? 2) The optimizer will try to find where `det(some_matrix) == 0`; maybe changing your objective to `abs(det(some_matrix))` will fix the asymptotic behavior. It's hard to say what you are trying to do. –  flodel Jan 28 '13 at 1:33
@flodel actually I tried it without log, but the answer was same. sorry the value of func(in1) and func(in2) that I wrote in the question are for det(some_matrix) and not log(det(some_matrix)) I removed log –  Ehsan Masoudi Jan 28 '13 at 6:48

I think the answer (I think 'agstudy' gave, too) is: Make sure that the function you minimize does NOT return NaN (or NA) but rather +Inf (if you minimize, or -Inf if you maximize).

2nd: Instead of log(det(.)) you REALLY should use
{ r <- determinant(., log=TRUE) ; if(r\$sign <= 0) -Inf else r\$modulus }

which is also more accurate. {Hint: do look how det is defined in R !}

Now to Rmpfr, I will reply separately. It should work like standard R to use "mpfr"-numbers, .... says the author of Rmpfr .... but you may need a bit of care. tryCatch() should not be needed, however.

-

I tried to reformulate your horrible(sorry for the term) objective function. I am pretty sure that w we can find with simpler form. Hope that others can use this to find a solution to your optimization problem...

``````func1 <- function(b){
A <- exp(-b[1]+5*b[2])
C <- exp(-b[1]-5*b[2])
A1 <- A + 1
C1 <- C + 1
D <- 1/A1
H <- 1/C1
K <- D*(1-D)
J <- H*(1-H)
M <- (A/A1^2)^2/K
N <- (C/C1^2)^2/J

Mat <- matrix(c( 1 *M    + 1  *N,
-5 *M    + 5  *N,
-5 *M    + 5  *N,
25 *M    + 25 *N),2,2)

Mat <- 0.5*Mat
d <- log(det(Mat))
return(d)
}
``````

EDIT

As I said you can simplify again your function. It looks much better

``````func1 <- function(b){
A <- exp(-b[1]+5*b[2])
C <- exp(-b[1]-5*b[2])
A1 <- A + 1
C1 <- C + 1
M <- A/A1^2
N <- C/C1^2
det.Mat <-25*M*N
log(det.Mat)
}
``````

Here some tests between the 2 functions.

``````func1(c(1,2))
[1] -16.7814
> func1(c(8,2))
[1] -17.03498
> func1(c(10,2))
[1] -18.16742
> func(c(10,2))
[1] -18.16742
> func(c(10,5))
[1] -46.83608
``````

The reformulation minimized the possibility of underflow/overflow ( can't store the intermediate result in the register)..that's why we get Inf and not NA(see below) , which is infinite but still a numeric, suitable for farther computing in opposition to NaN which is like an NA values..

func(c(10,100))
[1] NaN func1(c(10,100)) [1] -Inf

Now I test your optimization instruction, on the simpler form , and it converges as you can see:

``````in1 <- c(-0.04785405, 6.42711047)
in2 <- c(0.2246729, 7.5211575)
ll <- optim(in1, fn = func1, lower = c(-.3, 6), upper = c(.3, 8), method = "L-BFGS-B")
do.call(rbind,ll)

par         "-0.04785405"                                      "8"
value       "-76.7811241751318"                                "-76.7811241751318"
counts      "2"                                                "2"
convergence "0"                                                "0"
message     "CONVERGENCE: NORM OF PROJECTED GRADIENT <= PGTOL" "CONVERGENCE: NORM OF PROJECTED GRADIENT <= PGTOL"
``````

same thing for in2

``````optim(in2, fn = func1, lower = c(-.3, 6), upper = c(.3, 8), method = "L-BFGS-B")
\$par
[1] 0.2246729 8.0000000

\$value
[1] -76.78112

\$counts
2        2

\$convergence
[1] 0

\$message
[1] "CONVERGENCE: NORM OF PROJECTED GRADIENT <= PGTOL"
``````
-
I agree that the formulate of my function is horrible and thank you for your modification. actually, I did not write it!! in fact I applied functions `gsub`, `D`and `paste` to construct the information matrix for all nonlinear models without user-interfere and the formulate that you saw is auto-constructed. –  Ehsan Masoudi Jan 28 '13 at 7:03
@EhsanMasoudi ok but when you ask an answer here you have to do more effort..or at least give us how you have do to have such function...That 's said I update my answer for more simple function. –  agstudy Jan 28 '13 at 11:50
I would appreciate if you could explain why func(c(10, 100)) is "Nan" but func(c(10, 100)) is `-Inf' –  Ehsan Masoudi Jan 28 '13 at 13:56
I add some explanation...It is my interpretation of things..I am not a numeric specialist.. –  agstudy Jan 28 '13 at 14:17

Answering your problem, using the `Rmpfr` - produced matrix: (not quite efficiently though ...!...):

Yes, determinant() is not available for mpfr-matrices, however you can simply use something like

``````M <- Mat.func.mpfr(in2, prec = 55)
m <- as(M, "matrix")
ldm <- determinant(m) # is already  log() !
``````

and then use the

`````` { r <- determinant(., log=TRUE) ; if(r\$sign <= 0) -Inf else r\$modulus }
``````

I've mentioned above ... something much better than the ``wrong by design'' use of log(det(.))

-

For arb precision: `gmp` and / or `Rmpfr` . You might be better off with some `tryCatch` in your code instead, though (to avoid crashes when a given attempt causes that `NaN` error)

-
I edited the question with Rmpfr and as can be seen it could not be useful. Also, as i said ignoring NaN by tryCathch may leads to missing some local minimums. –  Ehsan Masoudi Jan 28 '13 at 9:08

Using `mpfr` can be useful to avoid computationally `NaN` in a function (and also halt in optimization algorithm). But `mpfr` output is an 'mpfr' class and some R functions (such as `optim` and `det`) may not work with this kind of class. As usual `as.numeric` can be applied to convert 'mpfr' class to a 'numeric' one.

``````exp(9000)
[1] Inf

require(Rmpfr)
number <- as.numeric(exp(mpfr(9000, prec = 54)))

class(number)
[1] "numeric"

round(number)
[1] 1.797693e+308

number * 1.797692e-308
[1] 3.231699

number * 1.797693e-307
[1] 32.317

number * (1/number)
[1] 1

number * .2
[1] 3.595386e+307

number * .9
[1] 1.617924e+308

number * 1.1
[1] Inf

number * 2
[1] Inf

number / 2
[1] 8.988466e+307

number + 2
[1] 1.797693e+308

number + 2 * 10 ^ 291
[1] 1.797693e+308

number + 2 * 10 ^ 292
[1] Inf

number - 2
[1] 1.797693e+308

number - 2 * 10 ^ 307
[1] 1.597693e+308

number - 2 * 10 ^ 308
[1] -Inf
``````

Now consider the following matrix function:

``````mat <- function(x){
x1 <- x[1]
x2 <- x[2]
d = matrix(c(exp(5 * x1+ 4 * x2), exp(9 * x1), exp(2 * x2 + 4 * x1),
exp(3 * x1)), 2, 2)
return(d)
}
``````

elements of this matrix is highly potential to produce `Inf`:

``````mat(c(300, 1))
[,1] [,2]
[1,]  Inf  Inf
[2,]  Inf  Inf
``````

So if `det` was returned in function environment, instead of a numeric result we got `NaN` and the `optim` function would definitely be terminated. To solve this problem the determinant of this function is written by `mpfr`:

``````func <- function (x){
x1 <- mpfr(x[1], prec = precision)
x2 <- mpfr(x[2], prec = precision)
mat <- new("mpfrMatrix",c(exp(5 * x1+ 4 * x2), exp(9 * x1), exp(2 * x2 + 4 * x1),   exp(3 * x1)), Dim = c(2L,2L))
d <- mat[1, 1] * mat[2, 2] - mat[2, 1] * mat[1, 2]
return(as.numeric(-d))
}
``````

then for x1 = 3 and x2 = 1 we have:

``````func(c(3,1))
[1] 6.39842e+17

optim(c(3, 1),func)

\$par
[1] 0.4500 1.4125

\$value
[1] -4549.866

\$counts
13       NA

\$convergence
[1] 0

\$message
NULL
``````

and for x1 = 300 and x2 = 1:

``````func(c(300,1))
[1] 1.797693e+308

optim(c(300, 1),func)
\$par
[1] 300   1

\$value
[1] 1.797693e+308

\$counts
3       NA

\$convergence
[1] 0

\$message
NULL
``````

As can bee seen, there is no halt and even `optim` claimes a convergence in the optimization process. However, it seems that there are no iterations and `optim` just returned the initial values as local minimums (definitely, 1.797693e+308 is not a local minimum of this function!!). In such these situations, applying `mpfr` can just prevent termination of optimization process, but if we really expect optimization algorithm to start from such this points which their values are `Inf` by R double-precision and continue the iteration to reach the local minimums, besides defining a function with 'mpfr' class, the optimization function also should have this ability to work with 'mpfr' class.

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Feel free to write an add-on package that does this. One difficulty is that most of R's optimizers use lower-level (C or FORTRAN) code internally, which will not easily be adaptable to using `mfpr`. One thought would be that you could try some of the optimizers in the `optimx` package, which have "pure-R" versions of conjugate gradient and quasi-Newton methods which might work `mfpr` objects. –  Ben Bolker Jan 29 '13 at 15:31
@Ben Bolker actually I would like to write this package and I also have chosen an appropriate package called Rsolnp which is pure-R and is based on a Matlab code. –  Ehsan Masoudi Jan 29 '13 at 15:51