Not quite sure what you want here.
Thanks for the reproducible example: the output was

```
cc <- chisq.test(Oi,p=Ei,rescale.p=TRUE)
print(cc)
Chi-squared test for given probabilities
data: Oi
X-squared = 3090, df = 2, p-value < 0.00000000000000022
```

Inspecting the structure of the object reveals that the p-value in this case has underflowed to exactly zero:

```
List of 9
$ statistic: Named num 3090
..- attr(*, "names")= chr "X-squared"
$ parameter: Named num 2
..- attr(*, "names")= chr "df"
$ p.value : num 0
$ method : chr "Chi-squared test for given probabilities"
$ data.name: chr "Oi"
$ observed : Named num [1:3] 321 712 44
..- attr(*, "names")= chr [1:3] "A" "B" "C"
$ expected : Named num [1:3] 922.5 127.2 27.3
..- attr(*, "names")= chr [1:3] "A" "B" "C"
$ residuals: Named num [1:3] -19.8 51.8 3.2
..- attr(*, "names")= chr [1:3] "A" "B" "C"
$ stdres : Named num [1:3] -52.29 55.2 3.25
..- attr(*, "names")= chr [1:3] "A" "B" "C"
- attr(*, "class")= chr "htest"
```

I think if you want the exact p-value from this test you have to go a bit out of your way:

```
(pval <- pchisq(3090,2,lower.tail=FALSE,log.p=TRUE))
[1] -1545
```

So this is approximately 10^`pval/log(10)`

= 10^(-671) [R's minimum representable value is typically around 1e-308, see `.Machine$double.xmin`

]