#[derive(Debug, Clone, Copy, PartialEq, Eq, Hash, PartialOrd, Ord, strum :: EnumIter)]
#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
#[cfg_attr(feature = "arbitrary", derive(arbitrary::Arbitrary))]
#[cfg_attr(feature = "mem_size", derive(mem_dbg::MemSize))]
#[cfg_attr(feature = "mem_dbg", derive(mem_dbg::MemDbg))]
#[cfg_attr(feature = "mem_size", mem_size(flat))]
pub enum IronIsotope {
Fe45,
Fe46,
Fe47,
Fe48,
Fe49,
Fe50,
Fe51,
Fe52,
Fe53,
Fe54,
Fe55,
Fe56,
Fe57,
Fe58,
Fe59,
Fe60,
Fe61,
Fe62,
Fe63,
Fe64,
Fe65,
Fe66,
Fe67,
Fe68,
Fe69,
Fe70,
Fe71,
Fe72,
Fe73,
Fe74,
Fe75,
Fe76,
}
impl super::RelativeAtomicMass for IronIsotope {
#[inline]
fn relative_atomic_mass(&self) -> f64 {
match self {
Self::Fe45 => 45.01442f64,
Self::Fe46 => 46.00063f64,
Self::Fe47 => 46.99185f64,
Self::Fe48 => 47.98023f64,
Self::Fe49 => 48.973429f64,
Self::Fe50 => 49.962975f64,
Self::Fe51 => 50.956841f64,
Self::Fe52 => 51.9481131f64,
Self::Fe53 => 52.9453064f64,
Self::Fe54 => 53.93960899f64,
Self::Fe55 => 54.93829199f64,
Self::Fe56 => 55.93493633f64,
Self::Fe57 => 56.93539284f64,
Self::Fe58 => 57.93327443f64,
Self::Fe59 => 58.93487434f64,
Self::Fe60 => 59.9340711f64,
Self::Fe61 => 60.9367462f64,
Self::Fe62 => 61.9367918f64,
Self::Fe63 => 62.9402727f64,
Self::Fe64 => 63.9409878f64,
Self::Fe65 => 64.9450115f64,
Self::Fe66 => 65.94625f64,
Self::Fe67 => 66.95054f64,
Self::Fe68 => 67.95295f64,
Self::Fe69 => 68.95807f64,
Self::Fe70 => 69.96102f64,
Self::Fe71 => 70.96672f64,
Self::Fe72 => 71.96983f64,
Self::Fe73 => 72.97572f64,
Self::Fe74 => 73.97935f64,
Self::Fe75 => 74.984219f64,
Self::Fe76 => 75.988631f64,
}
}
}
impl super::ElementVariant for IronIsotope {
#[inline]
fn element(&self) -> crate::Element {
crate::Element::Fe
}
}
impl super::MassNumber for IronIsotope {
#[inline]
fn mass_number(&self) -> u16 {
match self {
Self::Fe45 => 45u16,
Self::Fe46 => 46u16,
Self::Fe47 => 47u16,
Self::Fe48 => 48u16,
Self::Fe49 => 49u16,
Self::Fe50 => 50u16,
Self::Fe51 => 51u16,
Self::Fe52 => 52u16,
Self::Fe53 => 53u16,
Self::Fe54 => 54u16,
Self::Fe55 => 55u16,
Self::Fe56 => 56u16,
Self::Fe57 => 57u16,
Self::Fe58 => 58u16,
Self::Fe59 => 59u16,
Self::Fe60 => 60u16,
Self::Fe61 => 61u16,
Self::Fe62 => 62u16,
Self::Fe63 => 63u16,
Self::Fe64 => 64u16,
Self::Fe65 => 65u16,
Self::Fe66 => 66u16,
Self::Fe67 => 67u16,
Self::Fe68 => 68u16,
Self::Fe69 => 69u16,
Self::Fe70 => 70u16,
Self::Fe71 => 71u16,
Self::Fe72 => 72u16,
Self::Fe73 => 73u16,
Self::Fe74 => 74u16,
Self::Fe75 => 75u16,
Self::Fe76 => 76u16,
}
}
}
impl super::IsotopicComposition for IronIsotope {
#[inline]
fn isotopic_composition(&self) -> Option<f64> {
match self {
Self::Fe54 => Some(0.05845f64),
Self::Fe56 => Some(0.91754f64),
Self::Fe57 => Some(0.02119f64),
Self::Fe58 => Some(0.00282f64),
_ => None,
}
}
}
impl super::MostAbundantIsotope for IronIsotope {
fn most_abundant_isotope() -> Self {
Self::Fe56
}
}
impl From<IronIsotope> for crate::Isotope {
fn from(isotope: IronIsotope) -> Self {
crate::Isotope::Fe(isotope)
}
}
impl From<IronIsotope> for crate::Element {
fn from(_isotope: IronIsotope) -> Self {
crate::Element::Fe
}
}
impl TryFrom<u64> for IronIsotope {
type Error = crate::errors::Error;
fn try_from(value: u64) -> Result<Self, Self::Error> {
match value {
45u64 => Ok(Self::Fe45),
46u64 => Ok(Self::Fe46),
47u64 => Ok(Self::Fe47),
48u64 => Ok(Self::Fe48),
49u64 => Ok(Self::Fe49),
50u64 => Ok(Self::Fe50),
51u64 => Ok(Self::Fe51),
52u64 => Ok(Self::Fe52),
53u64 => Ok(Self::Fe53),
54u64 => Ok(Self::Fe54),
55u64 => Ok(Self::Fe55),
56u64 => Ok(Self::Fe56),
57u64 => Ok(Self::Fe57),
58u64 => Ok(Self::Fe58),
59u64 => Ok(Self::Fe59),
60u64 => Ok(Self::Fe60),
61u64 => Ok(Self::Fe61),
62u64 => Ok(Self::Fe62),
63u64 => Ok(Self::Fe63),
64u64 => Ok(Self::Fe64),
65u64 => Ok(Self::Fe65),
66u64 => Ok(Self::Fe66),
67u64 => Ok(Self::Fe67),
68u64 => Ok(Self::Fe68),
69u64 => Ok(Self::Fe69),
70u64 => Ok(Self::Fe70),
71u64 => Ok(Self::Fe71),
72u64 => Ok(Self::Fe72),
73u64 => Ok(Self::Fe73),
74u64 => Ok(Self::Fe74),
75u64 => Ok(Self::Fe75),
76u64 => Ok(Self::Fe76),
_ => Err(crate::errors::Error::Isotope(crate::Element::Fe, value)),
}
}
}
impl TryFrom<u8> for IronIsotope {
type Error = crate::errors::Error;
fn try_from(value: u8) -> Result<Self, Self::Error> {
Self::try_from(u64::from(value))
}
}
impl TryFrom<u16> for IronIsotope {
type Error = crate::errors::Error;
fn try_from(value: u16) -> Result<Self, Self::Error> {
Self::try_from(u64::from(value))
}
}
impl TryFrom<u32> for IronIsotope {
type Error = crate::errors::Error;
fn try_from(value: u32) -> Result<Self, Self::Error> {
Self::try_from(u64::from(value))
}
}
impl core::fmt::Display for IronIsotope {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
match self {
Self::Fe45 => write!(f, "Fe45"),
Self::Fe46 => write!(f, "Fe46"),
Self::Fe47 => write!(f, "Fe47"),
Self::Fe48 => write!(f, "Fe48"),
Self::Fe49 => write!(f, "Fe49"),
Self::Fe50 => write!(f, "Fe50"),
Self::Fe51 => write!(f, "Fe51"),
Self::Fe52 => write!(f, "Fe52"),
Self::Fe53 => write!(f, "Fe53"),
Self::Fe54 => write!(f, "Fe54"),
Self::Fe55 => write!(f, "Fe55"),
Self::Fe56 => write!(f, "Fe56"),
Self::Fe57 => write!(f, "Fe57"),
Self::Fe58 => write!(f, "Fe58"),
Self::Fe59 => write!(f, "Fe59"),
Self::Fe60 => write!(f, "Fe60"),
Self::Fe61 => write!(f, "Fe61"),
Self::Fe62 => write!(f, "Fe62"),
Self::Fe63 => write!(f, "Fe63"),
Self::Fe64 => write!(f, "Fe64"),
Self::Fe65 => write!(f, "Fe65"),
Self::Fe66 => write!(f, "Fe66"),
Self::Fe67 => write!(f, "Fe67"),
Self::Fe68 => write!(f, "Fe68"),
Self::Fe69 => write!(f, "Fe69"),
Self::Fe70 => write!(f, "Fe70"),
Self::Fe71 => write!(f, "Fe71"),
Self::Fe72 => write!(f, "Fe72"),
Self::Fe73 => write!(f, "Fe73"),
Self::Fe74 => write!(f, "Fe74"),
Self::Fe75 => write!(f, "Fe75"),
Self::Fe76 => write!(f, "Fe76"),
}
}
}
#[cfg(test)]
mod tests {
use strum::IntoEnumIterator;
use super::*;
use crate::isotopes::{
ElementVariant, IsotopicComposition, MassNumber, MostAbundantIsotope, RelativeAtomicMass,
};
#[test]
fn test_relative_atomic_mass() {
for isotope in IronIsotope::iter() {
let mass = isotope.relative_atomic_mass();
assert!(mass > 0.0, "Mass should be positive for {isotope:?}");
}
}
#[test]
fn test_element() {
for isotope in IronIsotope::iter() {
let element = isotope.element();
assert_eq!(element, crate::Element::Fe, "Element should be correct for {isotope:?}");
}
}
#[test]
fn test_mass_number() {
for isotope in IronIsotope::iter() {
let mass_number = isotope.mass_number();
assert!(
mass_number > 0 && mass_number < 300,
"Mass number should be reasonable for {isotope:?}"
);
}
}
#[test]
fn test_isotopic_composition() {
for isotope in IronIsotope::iter() {
let comp = isotope.isotopic_composition();
if let Some(c) = comp {
assert!(
(0.0..=1.0).contains(&c),
"Composition should be between 0 and 1 for {isotope:?}"
);
}
}
}
#[test]
fn test_most_abundant() {
let most_abundant = IronIsotope::most_abundant_isotope();
let _ = most_abundant.relative_atomic_mass();
}
#[test]
fn test_from_isotope() {
for isotope in IronIsotope::iter() {
let iso: crate::Isotope = isotope.into();
match iso {
crate::Isotope::Fe(i) => assert_eq!(i, isotope),
_ => panic!("Wrong isotope type"),
}
}
}
#[test]
fn test_from_element() {
for isotope in IronIsotope::iter() {
let elem: crate::Element = isotope.into();
assert_eq!(elem, crate::Element::Fe);
}
}
#[test]
fn test_try_from_mass_number() {
for isotope in IronIsotope::iter() {
let mass = isotope.mass_number();
let iso = IronIsotope::try_from(mass).unwrap();
assert_eq!(iso, isotope);
let iso_u32 = IronIsotope::try_from(u32::from(mass)).unwrap();
assert_eq!(iso_u32, isotope);
if let Ok(mass_u8) = u8::try_from(mass) {
let iso_u8 = IronIsotope::try_from(mass_u8).unwrap();
assert_eq!(iso_u8, isotope);
}
}
assert!(IronIsotope::try_from(0_u16).is_err());
assert!(IronIsotope::try_from(1000_u16).is_err());
assert!(IronIsotope::try_from(0_u32).is_err());
assert!(IronIsotope::try_from(1000_u32).is_err());
assert!(IronIsotope::try_from(0_u8).is_err());
}
#[test]
fn test_display() {
for isotope in IronIsotope::iter() {
let s = alloc::format!("{isotope}");
assert!(!s.is_empty(), "Display should not be empty for {isotope:?}");
}
}
}