Eine aufbereitete Darstellung der Quelle

 
     
 
 
Anforderungen  |   Konzepte  |   Entwurf  |   Entwicklung  |   Qualitätssicherung  |   Lebenszyklus  |   Steuerung
 
 
 
 

Benutzer

Quelle  prop.rs

  Sprache: Rust
 

#[cfg(miri)]
#[macro_export]
macro_rules! define_memchr_quickcheck {
    ($($tt:tt)*) => {};
}

#[cfg(not(miri))]
#[macro_export]
macro_rules! define_memchr_quickcheck {
    ($mod:ident) => {
        define_memchr_quickcheck!($mod, new);
    };
    ($mod:ident, $cons:ident) => {
        use alloc::vec::Vec;

        use quickcheck::TestResult;

        use crate::tests::memchr::{
            naive,
            prop::{double_ended_take, naive1_iter, naive2_iter, naive3_iter},
        };

        quickcheck::quickcheck! {
            fn qc_memchr_matches_naive(n1: u8, corpus: Vec<u8>) -> TestResult {
                let expected = naive::memchr(n1, &corpus);
                let got = match $mod::One::$cons(n1) {
                    None => return TestResult::discard(),
                    Some(f) => f.find(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memrchr_matches_naive(n1: u8, corpus: Vec<u8>) -> TestResult {
                let expected = naive::memrchr(n1, &corpus);
                let got = match $mod::One::$cons(n1) {
                    None => return TestResult::discard(),
                    Some(f) => f.rfind(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memchr2_matches_naive(n1: u8, n2: u8, corpus: Vec<u8>) -> TestResult {
                let expected = naive::memchr2(n1, n2, &corpus);
                let got = match $mod::Two::$cons(n1, n2) {
                    None => return TestResult::discard(),
                    Some(f) => f.find(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memrchr2_matches_naive(n1: u8, n2: u8, corpus: Vec<u8>) -> TestResult {
                let expected = naive::memrchr2(n1, n2, &corpus);
                let got = match $mod::Two::$cons(n1, n2) {
                    None => return TestResult::discard(),
                    Some(f) => f.rfind(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memchr3_matches_naive(
                n1: u8, n2: u8, n3: u8,
                corpus: Vec<u8>
            ) -> TestResult {
                let expected = naive::memchr3(n1, n2, n3, &corpus);
                let got = match $mod::Three::$cons(n1, n2, n3) {
                    None => return TestResult::discard(),
                    Some(f) => f.find(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memrchr3_matches_naive(
                n1: u8, n2: u8, n3: u8,
                corpus: Vec<u8>
            ) -> TestResult {
                let expected = naive::memrchr3(n1, n2, n3, &corpus);
                let got = match $mod::Three::$cons(n1, n2, n3) {
                    None => return TestResult::discard(),
                    Some(f) => f.rfind(&corpus),
                };
                TestResult::from_bool(expected == got)
            }

            fn qc_memchr_double_ended_iter(
                needle: u8, data: Vec<u8>, take_side: Vec<bool>
            ) -> TestResult {
                // make nonempty
                let mut take_side = take_side;
                if take_side.is_empty() { take_side.push(true) };

                let finder = match $mod::One::$cons(needle) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let iter = finder.iter(&data);
                let got = double_ended_take(
                    iter,
                    take_side.iter().cycle().cloned(),
                );
                let expected = naive1_iter(needle, &data);

                TestResult::from_bool(got.iter().cloned().eq(expected))
            }

            fn qc_memchr2_double_ended_iter(
                needle1: u8, needle2: u8, data: Vec<u8>, take_side: Vec<bool>
            ) -> TestResult {
                // make nonempty
                let mut take_side = take_side;
                if take_side.is_empty() { take_side.push(true) };

                let finder = match $mod::Two::$cons(needle1, needle2) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let iter = finder.iter(&data);
                let got = double_ended_take(
                    iter,
                    take_side.iter().cycle().cloned(),
                );
                let expected = naive2_iter(needle1, needle2, &data);

                TestResult::from_bool(got.iter().cloned().eq(expected))
            }

            fn qc_memchr3_double_ended_iter(
                needle1: u8, needle2: u8, needle3: u8,
                data: Vec<u8>, take_side: Vec<bool>
            ) -> TestResult {
                // make nonempty
                let mut take_side = take_side;
                if take_side.is_empty() { take_side.push(true) };

                let finder = match $mod::Three::$cons(needle1, needle2, needle3) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let iter = finder.iter(&data);
                let got = double_ended_take(
                    iter,
                    take_side.iter().cycle().cloned(),
                );
                let expected = naive3_iter(needle1, needle2, needle3, &data);

                TestResult::from_bool(got.iter().cloned().eq(expected))
            }

            fn qc_memchr1_iter(data: Vec<u8>) -> TestResult {
                let needle = 0;
                let finder = match $mod::One::$cons(needle) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data);
                let expected = naive1_iter(needle, &data);
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr1_rev_iter(data: Vec<u8>) -> TestResult {
                let needle = 0;

                let finder = match $mod::One::$cons(needle) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data).rev();
                let expected = naive1_iter(needle, &data).rev();
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr2_iter(data: Vec<u8>) -> TestResult {
                let needle1 = 0;
                let needle2 = 1;

                let finder = match $mod::Two::$cons(needle1, needle2) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data);
                let expected = naive2_iter(needle1, needle2, &data);
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr2_rev_iter(data: Vec<u8>) -> TestResult {
                let needle1 = 0;
                let needle2 = 1;

                let finder = match $mod::Two::$cons(needle1, needle2) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data).rev();
                let expected = naive2_iter(needle1, needle2, &data).rev();
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr3_iter(data: Vec<u8>) -> TestResult {
                let needle1 = 0;
                let needle2 = 1;
                let needle3 = 2;

                let finder = match $mod::Three::$cons(needle1, needle2, needle3) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data);
                let expected = naive3_iter(needle1, needle2, needle3, &data);
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr3_rev_iter(data: Vec<u8>) -> TestResult {
                let needle1 = 0;
                let needle2 = 1;
                let needle3 = 2;

                let finder = match $mod::Three::$cons(needle1, needle2, needle3) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let got = finder.iter(&data).rev();
                let expected = naive3_iter(needle1, needle2, needle3, &data).rev();
                TestResult::from_bool(got.eq(expected))
            }

            fn qc_memchr1_iter_size_hint(data: Vec<u8>) -> TestResult {
                // test that the size hint is within reasonable bounds
                let needle = 0;
                let finder = match $mod::One::$cons(needle) {
                    None => return TestResult::discard(),
                    Some(finder) => finder,
                };
                let mut iter = finder.iter(&data);
                let mut real_count = data
                    .iter()
                    .filter(|&&elt| elt == needle)
                    .count();

                while let Some(index) = iter.next() {
                    real_count -= 1;
                    let (lower, upper) = iter.size_hint();
                    assert!(lower <= real_count);
                    assert!(upper.unwrap() >= real_count);
                    assert!(upper.unwrap() <= data.len() - index);
                }
                TestResult::passed()
            }
        }
    };
}

// take items from a DEI, taking front for each true and back for each false.
// Return a vector with the concatenation of the fronts and the reverse of the
// backs.
#[cfg(not(miri))]
pub(cratefn double_ended_take<I, J>(
    mut iter: I,
    take_side: J,
) -> alloc::vec::Vec<I::Item>
where
    I: DoubleEndedIterator,
    J: Iterator<Item = bool>,
{
    let mut found_front = alloc::vec![];
    let mut found_back = alloc::vec![];

    for take_front in take_side {
        if take_front {
            if let Some(pos) = iter.next() {
                found_front.push(pos);
            } else {
                break;
            }
        } else {
            if let Some(pos) = iter.next_back() {
                found_back.push(pos);
            } else {
                break;
            }
        };
    }

    let mut all_found = found_front;
    all_found.extend(found_back.into_iter().rev());
    all_found
}

// return an iterator of the 0-based indices of haystack that match the needle
#[cfg(not(miri))]
pub(cratefn naive1_iter<'a>(
    n1: u8,
    haystack: &'a [u8],
) -> impl DoubleEndedIterator<Item = usize> + 'a {
    haystack.iter().enumerate().filter(move |&(_, &b)| b == n1).map(|t| t.0)
}

#[cfg(not(miri))]
pub(cratefn naive2_iter<'a>(
    n1: u8,
    n2: u8,
    haystack: &'a [u8],
) -> impl DoubleEndedIterator<Item = usize> + 'a {
    haystack
        .iter()
        .enumerate()
        .filter(move |&(_, &b)| b == n1 || b == n2)
        .map(|t| t.0)
}

#[cfg(not(miri))]
pub(cratefn naive3_iter<'a>(
    n1: u8,
    n2: u8,
    n3: u8,
    haystack: &'a [u8],
) -> impl DoubleEndedIterator<Item = usize> + 'a {
    haystack
        .iter()
        .enumerate()
        .filter(move |&(_, &b)| b == n1 || b == n2 || b == n3)
        .map(|t| t.0)
}

Messung V0.5 in Prozent
C=98 H=97 G=97

¤ Dauer der Verarbeitung: 0.50 Sekunden  (vorverarbeitet am  2026-06-19) ¤

*© Formatika GbR, Deutschland






Wurzel

Suchen

PVS Prover

Isabelle Prover

NIST Cobol Testsuite

Cephes Mathematical Library

Vienna Development Method

Haftungshinweis

Die Informationen auf dieser Webseite wurden nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit, noch Qualität der bereit gestellten Informationen zugesichert.

Bemerkung:

Die farbliche Syntaxdarstellung und die Messung sind noch experimentell.






                                                                                                                                                                                                                                                                                                                                                                                                     


Neuigkeiten

     Aktuelles
     Motto des Tages

Software

     Quellcodebibliothek
     Eigene Quellcodes
     Fremde Quellcodes
     Suchen

Aktivitäten

     Artikel über Sicherheit
     Anleitung zur Aktivierung von SSL

Muße

     Gedichte
     Musik
     Bilder

Jenseits des Üblichen ....

Besucherstatistik

Besucherstatistik