**NB** This response has been reworked based on the exchange in the comments.

So there are several things going on here.

- I assumed that the dataset
`training`

which you provided is supposed to be the same as `training2`

in your code. The first column in this dataset is an id, and your code will include that as a parameter in the fit. Is that what you wanted??
- Your code for extracting a sample of rows is unnecessarily complex. You generate a sample of integers between 1 and
`nrow(training2)`

, and from that generate a vector of logical with `length=nrow(training2)`

. You don't need to do that: just use the vector of integers to index training2. It is *much* faster, especially with such a large dataset.
- When attempting a fit with such a large number of parameters (>1400),
`glm(...)`

seems to want an initial estimate of the means. Rather than spending time on that I just restricted the model to the first 9 parameters (columns 2:10).
- Using
`type=predict`

in the call to `glm(..)`

affects how weights are used. You are not using weights, so this parameter does nothing.
- However, in the call to
`predict(...)`

you *do* need to specify `type="predict"`

.
- Using
`maxit = 25`

generally meant the fits did not converge, so you need to experiment with that.
- In the small set of iterations I tried, none of the coefficients had
`p<0.0001`

, so I changed the cutoff to 0.1 for the sake of the example.
- And finally, using
`return(list(...))`

as in the code below, plus changing `.combine=cbind`

to `.combine=rbind`

returns an array of list objects, where each *row* corresponds to an iteration, and column 1 has the vector of predictions for that iteration, column 2 has the vector of p-values for that iteration, and column 3 has the vector of coefficients for that iteration.

Here's the code:

```
library(foreach)
set.seed(1)
training2 <- training
length_divisor <- 1000
iterations <- 5
predictions <- foreach(m=1:iterations,.combine=rbind) %do% {
training_positions <- sample(nrow(training2),
size=floor((nrow(training2)/length_divisor)))
# train_pos<-1:nrow(training2) %in% training_positions
glm_fit <- glm(default~ . ,
data=training2[training_positions,c(2:10,ncol(training2))],
family=binomial(logit),
control = list(maxit = 25))
pr <- predict(glm_fit,
newdata=training2[sample(1:nrow(training2),10),],
type="response")
s <- summary(glm_fit)
p <- s$coeff[,4]
c <- s$coeff[,1]
pvalues <- p[p<0.1]
coeffs <- c[p<0.1]
return(list(pr,pvalues,coeffs))
}
predictions
# [,1] [,2] [,3]
# result.1 Numeric,10 Numeric,0 Numeric,0
# result.2 Numeric,10 Numeric,0 Numeric,0
# result.3 Numeric,10 Numeric,2 Numeric,2
# result.4 Numeric,10 Numeric,0 Numeric,0
# result.5 Numeric,10 Numeric,0 Numeric,0
```

So in this arrangement, `predictions[,1]`

is a list of all the prediction vectors, `prediction[,2]`

is a list of all the p-values<0.1 for each iteration, and `prediction[,3]`

is a list of all the coefficients with p-value<0.1 for each iteration.

`list`

and change the`.combine`

parameter. – Roland Feb 14 '14 at 18:11caretpackage, which I suggest you take a look at; it can work with bagged models such as this... – Gavin Simpson Feb 14 '14 at 18:56