subnet_calculator/src/networking/mod.rs

use std::{str::FromStr};
use ip::IpAddr;

pub mod ip;

#[allow(dead_code)]
#[derive(Debug, Eq, PartialEq)]
pub enum NetworkingErr {
    InvalidCIDRErr,
    InvalidSubnetMask,
    InvalidNetwork,
    InvalidIPErr
}


#[allow(unused)]
pub struct Network {
    network_address: IpAddr,
    broadcast_addr: IpAddr,
    num_hosts: u32,
    subnet_mask: Option<IpAddr>
}

impl Network {

    #[allow(unused)]
    /// Function that constucts a network struct.
    /// 
    /// ```
    /// let network = Network::new(&IpAddr::V4(127, 0, 0, 1), 32);
    /// ```
    pub fn new(given_address: &IpAddr, subnet_mask: &IpAddr) -> Network {
        Network { 
            network_address: given_address.clone(), 
            broadcast_addr: given_address.clone(), 
            num_hosts: 0, 
            subnet_mask: Some(subnet_mask.clone())
        }
    }

    /// Function that constucts a subnet, returning a vector of all subnets included
    /// 
    /// ```
    /// let networks = Network::create_subnet(&IpAddr::V4(127, 0, 0, 1), 32);
    /// ```
    pub fn create_subnet(network_address: &IpAddr, cidr: u8) -> Result<Vec<Network>, NetworkingErr> {
        //Get number of host and network bits.
        let subnet_mask = match Network::gen_subnet_mask(cidr) {
            Ok(ip) => ip,
            Err(_) => return Err(NetworkingErr::InvalidCIDRErr)
        };

        let network_bits = match subnet_mask {
            IpAddr::V4(oct1, oct2, oct3, oct4) => {
                oct1.count_zeros() + oct2.count_zeros() + oct3.count_zeros() + oct4.count_zeros()
            },
            IpAddr::V6(_) => return Err(NetworkingErr::InvalidIPErr)
        };

        //Determine the number of networks needed for the subnet. 
        let num_networks = get_num_networks(network_bits);

        
        //Get first address of each network
        //Need to get the most significant octet
        //Get number of bits available for host in specific octet
        //Determine Spacing 
        //Use Class constructor to generate each network.
        Ok(vec![Network::new(&IpAddr::V4(0, 0, 0, 0), &IpAddr::V4(0, 0, 0, 0))])
    }

    /// Function that takes in a u8 CIDR and converts it to an IP address.
    /// 
    /// ```
    /// let cidr: u8 = 22
    /// let subnet_mask: [u8; 4] = gen_subnet_mask(cidr);
    /// 
    /// >> IpAddr::V4(255, 255, 252, 0)
    /// ```
    fn gen_subnet_mask(mut cidr: u8) -> Result<IpAddr, NetworkingErr> {
        if cidr > 32 {
            return Err(NetworkingErr::InvalidCIDRErr)
        }

        let mut oct: [u8; 4] = [0; 4];

        for octet in oct.iter_mut() {
            *octet = if usize::from(cidr) >= 8 {
                cidr -= 8;
                u8::MAX
            }else{
                // Count the number of remaining 1s and convert to binary
                let mut count: u8 = 0;
                for i in ((8-cidr)..8).rev() {
                    count += u8::pow(2, u32::from(i));
                }
                cidr = 0;
                count
            }
        }

        Ok(IpAddr::V4(oct[0], oct[1], oct[2], oct[3]))
    }
    //pub fn generate_subnets(self) -> Vec<Network> {}
}

fn get_num_networks(mut network_bits: u8) -> u8 {
    for _ in 0..4 {
        if (network_bits / 8) > 1 {
            network_bits -= 8;
            continue;         
        }
    };
    network_bits
}

/// Function that takes in a string reference and returns the result of splitting a string into 
/// both its Address and CIDR
/// 
/// ```
/// let ip_string = String::from("192.168.0.1/24");
/// let result = match ip_and_cidr_from_string(&ip_string) {
///     Err(_) => panic!(),
///     Ok(ip_and_cidr) => ip_and_cidr
/// };
/// 
/// >> (IpAddr::V4(192, 168, 0, 1), 24)
/// ```
pub fn ip_and_cidr_from_string(ip_and_cidr: &String) -> Result<(IpAddr, u8), ip::InvalidIPErr>{
    let mut cidr: u8 = Default::default();
    let mut ip: String = Default::default();

    if ip_and_cidr.contains("/") {
        let split_ip_cidr = ip_and_cidr.split("/");
        if split_ip_cidr.clone().count() > 2 {
            return Err(ip::InvalidIPErr);
        }
        ip = split_ip_cidr.clone().into_iter().next().unwrap_or("0.0.0.0").to_owned();
        cidr = match split_ip_cidr.into_iter().last() {
            None => return Err(ip::InvalidIPErr),
            Some(cidr) => match cidr.trim().parse::<u8>() {
                Err(_) => return Err(ip::InvalidIPErr),
                Ok(cidr) => cidr
            }
        };
    }
    
    let ip_address: IpAddr = match IpAddr::from_str(&ip.trim()) {
        Err(_) => return Err(ip::InvalidIPErr),
        Ok(ip) => ip,
    };

    return Ok((ip_address, cidr))
}

mod tests {
    #[cfg(test)]
    #[test]
    fn string_to_ip_cidr_test() {
        use super::*;

        let ip_string = String::from("127.0.0.1/8");
        let result = match ip_and_cidr_from_string(&ip_string) {
            Err(_) => panic!(),
            Ok(ip_and_cidr) => ip_and_cidr
        };
        assert_eq!(result.0, IpAddr::V4(127, 0, 0, 1));
        assert_eq!(result.1, 8);
    }

    #[test]
    fn cidr_to_ip_test() {
        use super::*;

        assert_eq!(Network::gen_subnet_mask(22).unwrap(), IpAddr::V4(255, 255, 252, 0));
        assert_eq!(Network::gen_subnet_mask(24).unwrap(), IpAddr::V4(255, 255, 255, 0));
        assert_eq!(Network::gen_subnet_mask(0).unwrap(), IpAddr::V4(0, 0, 0, 0));
        assert_eq!(Network::gen_subnet_mask(4).unwrap(), IpAddr::V4(240, 0, 0, 0));
        assert_eq!(Network::gen_subnet_mask(35).unwrap_err(), NetworkingErr::InvalidCIDRErr);
    }
}