/**
 *  _           _                 __                            _   _ _   _                                 _                    _                  _
 * | |         | |               / /                           | | (_) | (_)                               | |                  (_)                | |
 * | |__   __ _| |_ ___   ___   / /__ ___  _ __ ___  _ __   ___| |_ _| |_ ___   _____ ______ _ __ _   _ ___| |_ ______ ___ _ __  _ _ __  _ __   ___| |_ ___
 * | '_ \ / _` | __/ _ \ / _ \ / / __/ _ \| '_ ` _ \| '_ \ / _ \ __| | __| \ \ / / _ \______| '__| | | / __| __|______/ __| '_ \| | '_ \| '_ \ / _ \ __/ __|
 * | | | | (_| | || (_) | (_) / / (_| (_) | | | | | | |_) |  __/ |_| | |_| |\ V /  __/      | |  | |_| \__ \ |_       \__ \ | | | | |_) | |_) |  __/ |_\__ \
 * |_| |_|\__,_|\__\___/ \___/_/ \___\___/|_| |_| |_| .__/ \___|\__|_|\__|_| \_/ \___|      |_|   \__,_|___/\__|      |___/_| |_|_| .__/| .__/ \___|\__|___/
 *                                                  | |                                                                           | |   | |
 *                                                  |_|                                                                           |_|   |_|
 *
 * https://github.com/hatoo/competitive-rust-snippets
 */
#[allow(unused_imports)]
use std::cmp::{max, min, Ordering};
#[allow(unused_imports)]
use std::collections::{BTreeMap, BTreeSet, BinaryHeap, HashMap, HashSet, VecDeque};
#[allow(unused_imports)]
use std::iter::FromIterator;
#[allow(unused_imports)]
use std::io::{stdin, stdout, BufWriter, Write};
mod util {
    use std::io::{stdin, stdout, BufWriter, StdoutLock};
    use std::str::FromStr;
    use std::fmt::Debug;
    #[allow(dead_code)]
    pub fn line() -> String {
        let mut line: String = String::new();
        stdin().read_line(&mut line).unwrap();
        line.trim().to_string()
    }
    #[allow(dead_code)]
    pub fn chars() -> Vec<char> {
        line().chars().collect()
    }
    #[allow(dead_code)]
    pub fn gets<T: FromStr>() -> Vec<T>
    where
        <T as FromStr>::Err: Debug,
    {
        let mut line: String = String::new();
        stdin().read_line(&mut line).unwrap();
        line.split_whitespace()
            .map(|t| t.parse().unwrap())
            .collect()
    }
    #[allow(dead_code)]
    pub fn with_bufwriter<F: FnOnce(BufWriter<StdoutLock>) -> ()>(f: F) {
        let out = stdout();
        let writer = BufWriter::new(out.lock());
        f(writer)
    }
}
#[allow(unused_macros)]
macro_rules ! get { ( $ t : ty ) => { { let mut line : String = String :: new ( ) ; stdin ( ) . read_line ( & mut line ) . unwrap ( ) ; line . trim ( ) . parse ::<$ t > ( ) . unwrap ( ) } } ; ( $ ( $ t : ty ) ,* ) => { { let mut line : String = String :: new ( ) ; stdin ( ) . read_line ( & mut line ) . unwrap ( ) ; let mut iter = line . split_whitespace ( ) ; ( $ ( iter . next ( ) . unwrap ( ) . parse ::<$ t > ( ) . unwrap ( ) , ) * ) } } ; ( $ t : ty ; $ n : expr ) => { ( 0 ..$ n ) . map ( | _ | get ! ( $ t ) ) . collect ::< Vec < _ >> ( ) } ; ( $ ( $ t : ty ) ,*; $ n : expr ) => { ( 0 ..$ n ) . map ( | _ | get ! ( $ ( $ t ) ,* ) ) . collect ::< Vec < _ >> ( ) } ; ( $ t : ty ;; ) => { { let mut line : String = String :: new ( ) ; stdin ( ) . read_line ( & mut line ) . unwrap ( ) ; line . split_whitespace ( ) . map ( | t | t . parse ::<$ t > ( ) . unwrap ( ) ) . collect ::< Vec < _ >> ( ) } } ; ( $ t : ty ;; $ n : expr ) => { ( 0 ..$ n ) . map ( | _ | get ! ( $ t ;; ) ) . collect ::< Vec < _ >> ( ) } ; }
#[allow(unused_macros)]
macro_rules ! debug { ( $ ( $ a : expr ) ,* ) => { println ! ( concat ! ( $ ( stringify ! ( $ a ) , " = {:?}, " ) ,* ) , $ ( $ a ) ,* ) ; } }

#[allow(dead_code)]
/// Struct for maximum flow problem
pub struct Flow {
    /// to, capacity, rev
    edges: Vec<Vec<(usize, usize, usize)>>,
}
impl Flow {
    #[allow(dead_code)]
    pub fn new(max_size: usize) -> Flow {
        Flow {
            edges: vec![Vec::new(); max_size + 1],
        }
    }
    #[allow(dead_code)]
    pub fn add_edge(&mut self, from: usize, to: usize, cap: usize) {
        let from_rev = self.edges[to].len();
        let to_rev = self.edges[from].len();
        self.edges[from].push((to, cap, from_rev));
        self.edges[to].push((from, 0, to_rev));
    }
    #[allow(dead_code)]
    /// Calculate maximum flow by dinic's algorithm
    pub fn max_flow_dinic(&mut self, s: usize, t: usize) -> usize {
        let mut flow = 0;
        loop {
            let level = self.bfs_dinic(s);
            let mut iter = vec![0; self.edges.len()];
            if level[t].is_none() {
                return flow;
            }
            loop {
                let f = self.dfs_dinic(s, t, usize::max_value(), &level, &mut iter);
                if f == 0 {
                    break;
                }
                flow += f;
            }
        }
    }
    #[allow(dead_code)]
    fn bfs_dinic(&self, s: usize) -> Vec<Option<usize>> {
        let mut level = vec![None; self.edges.len()];
        let mut que = VecDeque::new();
        level[s] = Some(0);
        que.push_back(s);
        while !que.is_empty() {
            let v = que.pop_front().unwrap();
            let l = Some(level[v].unwrap() + 1);
            for &(to, cap, _) in &self.edges[v] {
                if cap > 0 && level[to].is_none() {
                    level[to] = l;
                    que.push_back(to);
                }
            }
        }
        level
    }
    #[allow(dead_code)]
    fn dfs_dinic(
        &mut self,
        v: usize,
        t: usize,
        f: usize,
        level: &[Option<usize>],
        iter: &mut [usize],
    ) -> usize {
        if v == t {
            return f;
        }
        for i in iter[v]..self.edges[v].len() {
            iter[v] = i;
            let (to, cap, rev) = self.edges[v][i];
            if cap > 0 && level[v].unwrap() < level[to].unwrap_or(0) {
                let d = self.dfs_dinic(to, t, min(f, cap), level, iter);
                if d > 0 {
                    self.edges[v][i].1 -= d;
                    self.edges[to][rev].1 += d;
                    return d;
                }
            }
        }
        0
    }
    #[allow(dead_code)]
    fn max_flow_ff(&mut self, s: usize, t: usize) -> usize {
        let mut flow = 0;
        let l = self.edges.len();
        loop {
            let f = self.dfs_ff(s, t, usize::max_value(), &mut vec![false; l]);
            if f == 0 {
                break;
            }
            flow += f;
        }
        flow
    }
    #[allow(dead_code)]
    fn dfs_ff(&mut self, v: usize, t: usize, f: usize, used: &mut [bool]) -> usize {
        if v == t {
            return f;
        }
        used[v] = true;
        for i in 0..self.edges[v].len() {
            let (to, cap, rev) = self.edges[v][i];
            if !used[to] && cap > 0 {
                let d = self.dfs_ff(to, t, min(f, cap), used);
                if d > 0 {
                    self.edges[v][i].1 -= d;
                    self.edges[to][rev].1 += d;
                    return d;
                }
            }
        }
        0
    }
    #[allow(dead_code)]
    fn cut(&self, s: usize) -> BTreeSet<usize> {
        let mut stack = Vec::new();
        let mut ss = BTreeSet::new();
        ss.insert(s);
        stack.push(s);
        while !stack.is_empty() {
            let v = stack.pop().unwrap();
            for &(to, cap, _) in &self.edges[v] {
                if cap > 0 && !ss.contains(&to) {
                    ss.insert(to);
                    stack.push(to);
                }
            }
        }
        ss
    }
}

const INF: usize = 1 << 60;

#[allow(dead_code)]
fn main() {
    let (n, m, d) = get!(usize, usize, usize);
    let fs = get!(usize, usize, usize, usize, usize; m);

    let mut sort_u = vec![Vec::new(); n + 1];
    for (i, &(u, v, p, q, w)) in fs.iter().enumerate() {
        sort_u[u].push((i, (u, v, p, q, w)));
    }

    let mut flow = Flow::new(2 + 2 * m);
    let s = 0;
    let t = 1;

    for (i, &(u, v, _p, q, w)) in fs.iter().enumerate() {
        let i = 2 * i + 2;
        let j = i + 1;

        flow.add_edge(i, j, w);

        if u == 1 {
            flow.add_edge(s, i, INF);
        }

        if v == n {
            flow.add_edge(j, t, INF);
        }

        // for (k, &(u1, _v1, p1, _q1, _w1)) in fs.iter().enumerate() {
        for &(k, (_u1, _v1, p1, _q1, _w1)) in &sort_u[v] {
            let k = 2 * k + 2;

            if q + d <= p1 {
                flow.add_edge(j, k, INF);
            }
        }
    }

    println!("{}", flow.max_flow_dinic(s, t));
}