# Getting the length of an int

I am trying to get the length (the number of digits when interpreted in decimal) of an `int` in rust. I found a way to do it, however am looking for method that comes from the primitive itself. This is what I have:

``````let num = 90.to_string();
println!("num: {}", num.chars().count())
// num: 2
``````

I am looking at https://docs.rs/digits/0.3.3/digits/struct.Digits.html#method.length. is this a good candidate? How do I use it? Or are there other crates that does it for me?

One liners with less type conversion is the ideal solution I am looking for.

• Is `90.to_string().len()` what you need? Commented Sep 23, 2021 at 13:17
• i like that one @hzqelf - the ideal case would be a func that does not change the type to string Commented Sep 23, 2021 at 15:00
• You can use the log of the number. Commented Jun 11, 2023 at 21:44

You could loop and check how often you can divide the number by 10 before it becomes a single digit. Or in the other direction (because division is slower than multiplication), check how often you can multiply `10*10*...*10` until you reach the number:

``````fn length(n: u32, base: u32) -> u32 {
let mut power = base;
let mut count = 1;
while n >= power {
count += 1;
if let Some(new_power) = power.checked_mul(base) {
power = new_power;
} else {
break;
}
}
count
}
``````

Since rust 1.67, you can use:

``````n.checked_ilog10().unwrap_or(0) + 1
``````
• i was more looking for a one liner sort of. I can't shake off the thought that such a one liner should exist :/ . great answer nonetheless Commented Sep 23, 2021 at 13:01
• @AthulMuralidhar I'm curious as to what you find useful with one liner in such a context. Commented Sep 23, 2021 at 22:38
• No need to worry about division being slower than multiplication if you’re dividing by a constant. The optimiser will represent the division as multiplication by inverse anyway. Commented Sep 25, 2021 at 6:27
• @user What integer constant can you multiply a `u32` by to divide it by 10? Commented Sep 25, 2021 at 9:56
• Compilers sometimes transform more aggressively than you'd think. It turns out that my `length` function, when called with a compile-time constant 10, doesn't multiply anything at all; it just gets turned into a series of `if` statements Commented Sep 25, 2021 at 12:26

Here is a one-liner that doesn't require strings or floating point:

``````println!("num: {}", successors(Some(n), |&n| (n >= 10).then(|| n / 10)).count());
``````

It simply counts the number of times the initial number needs to be divided by 10 in order to reach 0.

EDIT: the first version of this answer used `iterate` from the (excellent and highly recommended) `itertools` crate, but @trentcl pointed out that `successors` from the stdlib does the same. For reference, here is the version using `iterate`:

``````println!("num: {}", iterate(n, |&n| n / 10).take_while(|&n| n > 0).count().max(1));
``````
• You could do much the same in `std` with `successors`. `std`-only version: `successors(Some(n), |&n| (n >= 10).then(|| n / 10)).count()` (this comment does not constitute programming advice) Commented Sep 23, 2021 at 18:20
• @trentcl Nice, thanks! I was actually looking for something like `successors()`, but failed to find it and settled for `itertools::iterate()`. Commented Sep 24, 2021 at 8:33

Here's a (barely) one-liner that's faster than doing a string conversion, using std::iter stuff:

``````let some_int = 9834;
let decimal_places = (0..).take_while(|i| 10u64.pow(*i) <= some_int).count();
``````
• Neat, but has an overflow error for inputs greater than 1 billion. Commented Sep 23, 2021 at 14:54
• @Daniel thanks, changed the base to u64 Commented Sep 23, 2021 at 17:53
• The overflow is still there, it's just moved to inputs greater than or equal to 10 quintillion. play.rust-lang.org/… Commented Sep 23, 2021 at 18:21
• True, but if the input stays i/u32 it's fine. Commented Sep 23, 2021 at 18:52
• Or not, that made some_int to be inferred as u64 (because it needs to be).. damn Commented Sep 23, 2021 at 19:18

The first method below relies on the following formula, where `a` and `b` are the logarithmic bases.

``````log<a>( x ) = log<b>( x ) / log<b>( a )

log<a>( x ) = log<2>( x ) / log<2>( a )  // Substituting 2 for `b`.
``````

The following function can be applied to finding the number of digits for bases that are a power of 2. This approach is very fast.

``````fn num_digits_base_pow2(n: u64, b: u32) -> u32
{
}
``````

The bits are counted for both `n` (the number we want to represent) and `b` (the base) to find their log2 floor values. Then the adjusted ratio of these values gives the ceiling log value in the desired base.

For a general purpose approach to finding the number of digits for arbitrary bases, the following should suffice.

``````fn num_digits(n: u64, b: u32) -> u32
{
(n as f64).log(b as f64).ceil() as u32
}
``````
• Performance-wise, floating-point `log` is a single HW instruction, which will be faster than a SW loop. However, you can replace your `while` loops using `leading_zeros`: `n_floor_log2 = 32-x.leading_zeros()`
– Jmb
Commented Sep 24, 2021 at 13:46

if num is signed:

``````let digits = (num.abs() as f64 + 0.1).log10().ceil() as u32;
``````

A nice property of numbers that is always good to have in mind is that the number of digits required to write a number \$x\$ in base \$n\$ is actually \$\lceil log_n(x + 1) \rceil\$.

Therefore, one can simply write the following function (notice the cast from `u32` to `f32`, since integers don't have a log function).

``````fn length(n: u32, base: u32) -> u32 {
let n = (n+1) as f32;
n.log(base as f32).ceil() as u32
}
``````

You can easily adapt it for negative numbers. For floating point numbers this might be a bit (i.e. a lot) more tricky.

To take into account Daniel's comment about the pathological cases introduced by using f32, note that, with nightly Rust, integers have a logarithm method. (Notice that, imo, those are implementation details, and you should more focus on understanding the algorithm than the implementation.):

``````#![feature(int_log)]

fn length(n: u32, base: u32) -> u32 {
n.log(base) + 1
}
``````
• Not every `u32` fits into a `f32` without rounding error, so your solution ends up returning the wrong result in some cases, e.g. length(0x8000047f, 2) = 31, but length(0x80000480, 2) = 32. Also, you have an overflow bug, `(n+1)` crashes for `n=0xffffffff` Commented Sep 23, 2021 at 10:49
• @Daniel I technically agree with you (and I updated the answer accordingly). That being said, OP might want to have a look at Hacker's delight for nice mathematical tricks like this one : en.wikipedia.org/wiki/Hacker's_Delight Commented Sep 23, 2021 at 13:19
• The problem with these "simple" approaches is that they often just don't work. For example, this returns 5 for both 9999 and 10000. Commented Sep 23, 2021 at 17:15
• @user4815162342 I disagree with you. The error you mentionned is just due to the fact that I wrote the example quickly (and was easily fixed), not to the fact of a deep fallacy in the reasoning. Typically, approaches based on logarithm will fail on case where `n = 0`. Yes, this is known, and it is not important in the answer. The purpose of answering questions is to give an approach, then OP can integrate that into a more robust context. I would argue that having a logarithm approach is better than creating a string and counting, or having a loop (except, maybe, in the case of base 2). Commented Sep 23, 2021 at 18:20
• I have read the whole post, thanks, and no, adding a second non-buggy option (which only works for people on nightly who are willing to rely on unstable features) does not erase the problems in the first snippet. If you write code with bugs in it the solution is to fix the bugs, not to write more code. Commented Sep 23, 2021 at 18:48