use alloc::vec::Vec;
use core::cmp::Ordering;
use core::fmt::{self, Display, Formatter};
use core::ops::{Add, BitAnd, BitOr, BitXor, Div, Mul, Neg, Not, Sub};
use core::str::FromStr;
use core::{i32, u32};
#[cfg(feature = "enable-serde")]
use serde_derive::{Deserialize, Serialize};
pub trait IntoBytes {
fn into_bytes(self) -> Vec<u8>;
}
impl IntoBytes for u8 {
fn into_bytes(self) -> Vec<u8> {
vec![self]
}
}
impl IntoBytes for i8 {
fn into_bytes(self) -> Vec<u8> {
vec![self as u8]
}
}
impl IntoBytes for i16 {
fn into_bytes(self) -> Vec<u8> {
self.to_le_bytes().to_vec()
}
}
impl IntoBytes for i32 {
fn into_bytes(self) -> Vec<u8> {
self.to_le_bytes().to_vec()
}
}
impl IntoBytes for Vec<u8> {
fn into_bytes(self) -> Vec<u8> {
self
}
}
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct Imm64(i64);
impl Imm64 {
pub fn new(x: i64) -> Self {
Self(x)
}
pub fn wrapping_neg(self) -> Self {
Self(self.0.wrapping_neg())
}
pub fn bits(&self) -> i64 {
self.0
}
#[must_use]
pub(crate) fn mask_to_width(&self, bit_width: u32) -> Self {
debug_assert!(bit_width.is_power_of_two());
if bit_width >= 64 {
return *self;
}
let bit_width = i64::from(bit_width);
let mask = (1 << bit_width) - 1;
let masked = self.0 & mask;
Imm64(masked)
}
#[must_use]
pub(crate) fn sign_extend_from_width(&self, bit_width: u32) -> Self {
debug_assert!(
bit_width.is_power_of_two(),
"{bit_width} is not a power of two"
);
if bit_width >= 64 {
return *self;
}
let bit_width = i64::from(bit_width);
let delta = 64 - bit_width;
let sign_extended = (self.0 << delta) >> delta;
Imm64(sign_extended)
}
}
impl From<Imm64> for i64 {
fn from(val: Imm64) -> i64 {
val.0
}
}
impl IntoBytes for Imm64 {
fn into_bytes(self) -> Vec<u8> {
self.0.to_le_bytes().to_vec()
}
}
impl From<i64> for Imm64 {
fn from(x: i64) -> Self {
Self(x)
}
}
impl Display for Imm64 {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
let x = self.0;
if x < 10_000 {
write!(f, "{}", x)
} else {
write_hex(x as u64, f)
}
}
}
fn parse_i64(s: &str) -> Result<i64, &'static str> {
let negative = s.starts_with('-');
let s2 = if negative || s.starts_with('+') {
&s[1..]
} else {
s
};
let mut value = parse_u64(s2)?;
if negative {
value = value.wrapping_neg();
if value as i64 > 0 {
return Err("Negative number too small");
}
}
Ok(value as i64)
}
impl FromStr for Imm64 {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
parse_i64(s).map(Self::new)
}
}
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct Uimm64(u64);
impl Uimm64 {
pub fn new(x: u64) -> Self {
Self(x)
}
pub fn wrapping_neg(self) -> Self {
Self(self.0.wrapping_neg())
}
}
impl From<Uimm64> for u64 {
fn from(val: Uimm64) -> u64 {
val.0
}
}
impl From<u64> for Uimm64 {
fn from(x: u64) -> Self {
Self(x)
}
}
fn write_hex(x: u64, f: &mut Formatter) -> fmt::Result {
let mut pos = (64 - x.leading_zeros() - 1) & 0xf0;
write!(f, "0x{:04x}", (x >> pos) & 0xffff)?;
while pos > 0 {
pos -= 16;
write!(f, "_{:04x}", (x >> pos) & 0xffff)?;
}
Ok(())
}
impl Display for Uimm64 {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
let x = self.0;
if x < 10_000 {
write!(f, "{}", x)
} else {
write_hex(x, f)
}
}
}
fn parse_u64(s: &str) -> Result<u64, &'static str> {
let mut value: u64 = 0;
let mut digits = 0;
if s.starts_with("-0x") {
return Err("Invalid character in hexadecimal number");
} else if let Some(num) = s.strip_prefix("0x") {
for ch in num.chars() {
match ch.to_digit(16) {
Some(digit) => {
digits += 1;
if digits > 16 {
return Err("Too many hexadecimal digits");
}
value = (value << 4) | u64::from(digit);
}
None => {
if ch != '_' {
return Err("Invalid character in hexadecimal number");
}
}
}
}
} else {
for ch in s.chars() {
match ch.to_digit(10) {
Some(digit) => {
digits += 1;
match value.checked_mul(10) {
None => return Err("Too large decimal number"),
Some(v) => value = v,
}
match value.checked_add(u64::from(digit)) {
None => return Err("Too large decimal number"),
Some(v) => value = v,
}
}
None => {
if ch != '_' {
return Err("Invalid character in decimal number");
}
}
}
}
}
if digits == 0 {
return Err("No digits in number");
}
Ok(value)
}
impl FromStr for Uimm64 {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
parse_u64(s).map(Self::new)
}
}
pub type Uimm8 = u8;
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct Uimm32(u32);
impl From<Uimm32> for u32 {
fn from(val: Uimm32) -> u32 {
val.0
}
}
impl From<Uimm32> for u64 {
fn from(val: Uimm32) -> u64 {
val.0.into()
}
}
impl From<Uimm32> for i64 {
fn from(val: Uimm32) -> i64 {
i64::from(val.0)
}
}
impl From<u32> for Uimm32 {
fn from(x: u32) -> Self {
Self(x)
}
}
impl Display for Uimm32 {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
if self.0 < 10_000 {
write!(f, "{}", self.0)
} else {
write_hex(u64::from(self.0), f)
}
}
}
impl FromStr for Uimm32 {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
parse_i64(s).and_then(|x| {
if 0 <= x && x <= i64::from(u32::MAX) {
Ok(Self(x as u32))
} else {
Err("Uimm32 out of range")
}
})
}
}
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct V128Imm(pub [u8; 16]);
impl V128Imm {
pub fn bytes(&self) -> impl Iterator<Item = &u8> {
self.0.iter()
}
pub fn to_vec(self) -> Vec<u8> {
self.0.to_vec()
}
pub fn as_slice(&self) -> &[u8] {
&self.0[..]
}
}
impl From<&[u8]> for V128Imm {
fn from(slice: &[u8]) -> Self {
assert_eq!(slice.len(), 16);
let mut buffer = [0; 16];
buffer.copy_from_slice(slice);
Self(buffer)
}
}
impl From<u128> for V128Imm {
fn from(val: u128) -> Self {
V128Imm(val.to_le_bytes())
}
}
#[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
pub struct Offset32(i32);
impl Offset32 {
pub fn new(x: i32) -> Self {
Self(x)
}
pub fn try_from_i64(x: i64) -> Option<Self> {
let x = i32::try_from(x).ok()?;
Some(Self::new(x))
}
pub fn try_add_i64(self, x: i64) -> Option<Self> {
let x = i32::try_from(x).ok()?;
let ret = self.0.checked_add(x)?;
Some(Self::new(ret))
}
}
impl From<Offset32> for i32 {
fn from(val: Offset32) -> i32 {
val.0
}
}
impl From<Offset32> for i64 {
fn from(val: Offset32) -> i64 {
i64::from(val.0)
}
}
impl From<i32> for Offset32 {
fn from(x: i32) -> Self {
Self(x)
}
}
impl From<u8> for Offset32 {
fn from(val: u8) -> Offset32 {
Self(val.into())
}
}
impl Display for Offset32 {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
if self.0 == 0 {
return Ok(());
}
write!(f, "{}", if self.0 < 0 { '-' } else { '+' })?;
let val = i64::from(self.0).abs();
if val < 10_000 {
write!(f, "{}", val)
} else {
write_hex(val as u64, f)
}
}
}
impl FromStr for Offset32 {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
if !(s.starts_with('-') || s.starts_with('+')) {
return Err("Offset must begin with sign");
}
parse_i64(s).and_then(|x| {
if i64::from(i32::MIN) <= x && x <= i64::from(i32::MAX) {
Ok(Self::new(x as i32))
} else {
Err("Offset out of range")
}
})
}
}
macro_rules! ignore {
($($t:tt)*) => {};
}
macro_rules! ieee_float {
(
name = $name:ident,
bits = $bits:literal,
significand_bits = $significand_bits:literal,
bits_ty = $bits_ty:ident,
float_ty = $float_ty:ident,
$(as_float = $as_float:ident,)?
$(rust_type_not_stable = $rust_type_not_stable:ident,)?
) => {
#[doc = concat!("binary", stringify!($bits))]
#[doc = stringify!($bits_ty)]
#[doc = stringify!($float_ty)]
#[derive(Copy, Clone, Debug, Eq, PartialEq, Hash)]
#[cfg_attr(feature = "enable-serde", derive(Serialize, Deserialize))]
#[repr(C)]
pub struct $name {
bits: $bits_ty
}
impl $name {
const BITS: u8 = $bits;
const SIGNIFICAND_BITS: u8 = $significand_bits;
const EXPONENT_BITS: u8 = Self::BITS - Self::SIGNIFICAND_BITS - 1;
const SIGN_MASK: $bits_ty = 1 << (Self::EXPONENT_BITS + Self::SIGNIFICAND_BITS);
const SIGNIFICAND_MASK: $bits_ty = $bits_ty::MAX >> (Self::EXPONENT_BITS + 1);
const EXPONENT_MASK: $bits_ty = !Self::SIGN_MASK & !Self::SIGNIFICAND_MASK;
pub const NAN: Self = Self::with_bits(Self::EXPONENT_MASK | (1 << (Self::SIGNIFICAND_BITS - 1)));
#[doc = concat!("`", stringify!($name), "`")]
pub const fn with_bits(bits: $bits_ty) -> Self {
Self { bits }
}
pub fn bits(self) -> $bits_ty {
self.bits
}
$(
#[doc = concat!("`", stringify!($name), "`")]
pub fn with_float(x: $float_ty) -> Self {
Self::with_bits(x.to_bits())
}
#[doc = concat!("`", stringify!($float_ty), "`.")]
pub fn $as_float(self) -> $float_ty {
$float_ty::from_bits(self.bits())
}
)?
pub fn abs(self) -> Self {
Self::with_bits(self.bits() & !Self::SIGN_MASK)
}
pub fn copysign(self, sign: Self) -> Self {
Self::with_bits((self.bits() & !Self::SIGN_MASK) | (sign.bits() & Self::SIGN_MASK))
}
pub fn minimum(self, other: Self) -> Self {
if self.is_nan() || other.is_nan() {
Self::NAN
} else if self.is_zero() && other.is_zero() {
if self.is_negative() {
self
} else {
other
}
} else if self <= other {
self
} else {
other
}
}
pub fn maximum(self, other: Self) -> Self {
if self.is_nan() || other.is_nan() {
Self::NAN
} else if self.is_zero() && other.is_zero() {
if self.is_positive() {
self
} else {
other
}
} else if self >= other {
self
} else {
other
}
}
#[doc = concat!("`", stringify!($name), "`")]
pub fn pow2<I: Into<i32>>(n: I) -> Self {
let n = n.into();
let w = Self::EXPONENT_BITS;
let t = Self::SIGNIFICAND_BITS;
let bias = (1 << (w - 1)) - 1;
let exponent = n + bias;
assert!(exponent > 0, "Underflow n={}", n);
assert!(exponent < (1 << w) + 1, "Overflow n={}", n);
Self::with_bits((exponent as $bits_ty) << t)
}
#[doc = concat!("`", stringify!($name), "`")]
#[doc = concat!("`", stringify!($float_ty), "`")]
pub fn fcvt_to_sint_negative_overflow<I: Into<i32>>(n: I) -> Self {
let n = n.into();
debug_assert!(n < i32::from(Self::BITS));
debug_assert!(i32::from(Self::SIGNIFICAND_BITS) + 1 - n < i32::from(Self::BITS));
Self::with_bits((1 << (Self::BITS - 1)) | Self::pow2(n - 1).bits() | (1 << (i32::from(Self::SIGNIFICAND_BITS) + 1 - n)))
}
#[doc = concat!("`", stringify!($name), "`,")]
pub fn is_nan(self) -> bool {
self.abs().bits() > Self::EXPONENT_MASK
}
pub fn is_positive(self) -> bool {
!self.is_negative()
}
pub fn is_negative(self) -> bool {
self.bits() & Self::SIGN_MASK == Self::SIGN_MASK
}
pub fn is_zero(self) -> bool {
self.abs().bits() == 0
}
pub fn non_nan(self) -> Option<Self> {
Some(self).filter(|f| !f.is_nan())
}
$(
pub fn sqrt(self) -> Self {
Self::with_float(self.$as_float().sqrt())
}
pub fn ceil(self) -> Self {
Self::with_float(self.$as_float().ceil())
}
pub fn floor(self) -> Self {
Self::with_float(self.$as_float().floor())
}
pub fn trunc(self) -> Self {
Self::with_float(self.$as_float().trunc())
}
pub fn round_ties_even(self) -> Self {
Self::with_float(self.$as_float().round_ties_even())
}
)?
}
impl PartialOrd for $name {
fn partial_cmp(&self, rhs: &Self) -> Option<Ordering> {
$(self.$as_float().partial_cmp(&rhs.$as_float()))?
$(
ignore!($rust_type_not_stable);
if self.is_nan() || rhs.is_nan() {
return None;
}
if self.is_zero() || rhs.is_zero() {
return Some(Ordering::Equal);
}
let lhs_positive = self.is_positive();
let rhs_positive = rhs.is_positive();
if lhs_positive != rhs_positive {
return lhs_positive.partial_cmp(&rhs_positive);
}
if lhs_positive {
self.bits().partial_cmp(&rhs.bits())
} else {
rhs.bits().partial_cmp(&self.bits())
}
)?
}
}
impl Display for $name {
fn fmt(&self, f: &mut Formatter) -> fmt::Result {
format_float(u128::from(self.bits()), Self::EXPONENT_BITS, Self::SIGNIFICAND_BITS, f)
}
}
impl FromStr for $name {
type Err = &'static str;
fn from_str(s: &str) -> Result<Self, &'static str> {
match parse_float(s, Self::EXPONENT_BITS, Self::SIGNIFICAND_BITS) {
Ok(b) => Ok(Self::with_bits(b.try_into().unwrap())),
Err(s) => Err(s),
}
}
}
impl IntoBytes for $name {
fn into_bytes(self) -> Vec<u8> {
self.bits().to_le_bytes().to_vec()
}
}
impl Neg for $name {
type Output = Self;
fn neg(self) -> Self {
Self::with_bits(self.bits() ^ Self::SIGN_MASK)
}
}
$(
impl From<$float_ty> for $name {
fn from(x: $float_ty) -> Self {
Self::with_float(x)
}
}
impl Add for $name {
type Output = Self;
fn add(self, rhs: Self) -> Self {
Self::with_float(self.$as_float() + rhs.$as_float())
}
}
impl Sub for $name {
type Output = Self;
fn sub(self, rhs: Self) -> Self {
Self::with_float(self.$as_float() - rhs.$as_float())
}
}
impl Mul for $name {
type Output = Self;
fn mul(self, rhs: Self) -> Self {
Self::with_float(self.$as_float() * rhs.$as_float())
}
}
impl Div for $name {
type Output = Self;
fn div(self, rhs: Self) -> Self::Output {
Self::with_float(self.$as_float() / rhs.$as_float())
}
}
)?
impl BitAnd for $name {
type Output = Self;
fn bitand(self, rhs: Self) -> Self {
Self::with_bits(self.bits() & rhs.bits())
}
}
impl BitOr for $name {
type Output = Self;
fn bitor(self, rhs: Self) -> Self {
Self::with_bits(self.bits() | rhs.bits())
}
}
impl BitXor for $name {
type Output = Self;
fn bitxor(self, rhs: Self) -> Self {
Self::with_bits(self.bits() ^ rhs.bits())
}
}
impl Not for $name {
type Output = Self;
fn not(self) -> Self {
Self::with_bits(!self.bits())
}
}
};
}
ieee_float! {
name = Ieee16,
bits = 16,
significand_bits = 10,
bits_ty = u16,
float_ty = f16,
rust_type_not_stable = rust_type_not_stable,
}
ieee_float! {
name = Ieee32,
bits = 32,
significand_bits = 23,
bits_ty = u32,
float_ty = f32,
as_float = as_f32,
}
ieee_float! {
name = Ieee64,
bits = 64,
significand_bits = 52,
bits_ty = u64,
float_ty = f64,
as_float = as_f64,
}
ieee_float! {
name = Ieee128,
bits = 128,
significand_bits = 112,
bits_ty = u128,
float_ty = f128,
rust_type_not_stable = rust_type_not_stable,
}
fn format_float(bits: u128, w: u8, t: u8, f: &mut Formatter) -> fmt::Result {
debug_assert!(w > 0 && w <= 16, "Invalid exponent range");
debug_assert!(1 + w + t <= 128, "Too large IEEE format for u128");
debug_assert!((t + w + 1).is_power_of_two(), "Unexpected IEEE format size");
let max_e_bits = (1u128 << w) - 1;
let t_bits = bits & ((1u128 << t) - 1); let e_bits = (bits >> t) & max_e_bits; let sign_bit = (bits >> (w + t)) & 1;
let bias: i32 = (1 << (w - 1)) - 1;
let e = e_bits as i32 - bias; let emin = 1 - bias; let digits = (t + 3) / 4;
let left_t_bits = t_bits << (4 * digits - t);
if sign_bit != 0 {
write!(f, "-")?;
}
if e_bits == 0 {
if t_bits == 0 {
write!(f, "0.0")
} else {
write!(
f,
"0x0.{0:01$x}p{2}",
left_t_bits,
usize::from(digits),
emin
)
}
} else if e_bits == max_e_bits {
if sign_bit == 0 {
write!(f, "+")?;
}
if t_bits == 0 {
write!(f, "Inf")
} else {
let payload = t_bits & ((1 << (t - 1)) - 1);
if t_bits & (1 << (t - 1)) != 0 {
if payload != 0 {
write!(f, "NaN:0x{:x}", payload)
} else {
write!(f, "NaN")
}
} else {
write!(f, "sNaN:0x{:x}", payload)
}
}
} else {
write!(f, "0x1.{0:01$x}p{2}", left_t_bits, usize::from(digits), e)
}
}
fn parse_float(s: &str, w: u8, t: u8) -> Result<u128, &'static str> {
debug_assert!(w > 0 && w <= 16, "Invalid exponent range");
debug_assert!(1 + w + t <= 128, "Too large IEEE format for u128");
debug_assert!((t + w + 1).is_power_of_two(), "Unexpected IEEE format size");
let (sign_bit, s2) = if let Some(num) = s.strip_prefix('-') {
(1u128 << (t + w), num)
} else if let Some(num) = s.strip_prefix('+') {
(0, num)
} else {
(0, s)
};
if !s2.starts_with("0x") {
let max_e_bits = ((1u128 << w) - 1) << t;
let quiet_bit = 1u128 << (t - 1);
if s2 == "0.0" {
return Ok(sign_bit);
}
if s2 == "Inf" {
return Ok(sign_bit | max_e_bits);
}
if s2 == "NaN" {
return Ok(sign_bit | max_e_bits | quiet_bit);
}
if let Some(nan) = s2.strip_prefix("NaN:0x") {
return match u128::from_str_radix(nan, 16) {
Ok(payload) if payload < quiet_bit => {
Ok(sign_bit | max_e_bits | quiet_bit | payload)
}
_ => Err("Invalid NaN payload"),
};
}
if let Some(nan) = s2.strip_prefix("sNaN:0x") {
return match u128::from_str_radix(nan, 16) {
Ok(payload) if 0 < payload && payload < quiet_bit => {
Ok(sign_bit | max_e_bits | payload)
}
_ => Err("Invalid sNaN payload"),
};
}
return Err("Float must be hexadecimal");
}
let s3 = &s2[2..];
let mut digits = 0u8;
let mut digits_before_period: Option<u8> = None;
let mut significand = 0u128;
let mut exponent = 0i32;
for (idx, ch) in s3.char_indices() {
match ch {
'.' => {
if digits_before_period != None {
return Err("Multiple radix points");
} else {
digits_before_period = Some(digits);
}
}
'p' => {
let exp_str = &s3[1 + idx..];
match exp_str.parse::<i16>() {
Ok(e) => {
exponent = i32::from(e);
break;
}
Err(_) => return Err("Bad exponent"),
}
}
_ => match ch.to_digit(16) {
Some(digit) => {
digits += 1;
if digits > 32 {
return Err("Too many digits");
}
significand = (significand << 4) | u128::from(digit);
}
None => return Err("Invalid character"),
},
}
}
if digits == 0 {
return Err("No digits");
}
if significand == 0 {
return Ok(sign_bit);
}
match digits_before_period {
None => {} Some(d) => exponent -= 4 * i32::from(digits - d),
};
let significant_bits = (128 - significand.leading_zeros()) as u8;
if significant_bits > t + 1 {
let adjust = significant_bits - (t + 1);
if significand & ((1u128 << adjust) - 1) != 0 {
return Err("Too many significant bits");
}
significand >>= adjust;
exponent += i32::from(adjust);
} else {
let adjust = t + 1 - significant_bits;
significand <<= adjust;
exponent -= i32::from(adjust);
}
debug_assert_eq!(significand >> t, 1);
let t_bits = significand & ((1 << t) - 1);
let max_exp = (1i32 << w) - 2;
let bias: i32 = (1 << (w - 1)) - 1;
exponent += bias + i32::from(t);
if exponent > max_exp {
Err("Magnitude too large")
} else if exponent > 0 {
let e_bits = (exponent as u128) << t;
Ok(sign_bit | e_bits | t_bits)
} else if 1 - exponent <= i32::from(t) {
let adjust = 1 - exponent;
if significand & ((1u128 << adjust) - 1) != 0 {
Err("Subnormal underflow")
} else {
significand >>= adjust;
Ok(sign_bit | significand)
}
} else {
Err("Magnitude too small")
}
}
#[cfg(test)]
mod tests {
use super::*;
use alloc::string::ToString;
use core::{f32, f64};
#[test]
fn format_imm64() {
assert_eq!(Imm64(0).to_string(), "0");
assert_eq!(Imm64(9999).to_string(), "9999");
assert_eq!(Imm64(10000).to_string(), "0x2710");
assert_eq!(Imm64(-9999).to_string(), "-9999");
assert_eq!(Imm64(-10000).to_string(), "-10000");
assert_eq!(Imm64(0xffff).to_string(), "0xffff");
assert_eq!(Imm64(0x10000).to_string(), "0x0001_0000");
}
#[test]
fn format_uimm64() {
assert_eq!(Uimm64(0).to_string(), "0");
assert_eq!(Uimm64(9999).to_string(), "9999");
assert_eq!(Uimm64(10000).to_string(), "0x2710");
assert_eq!(Uimm64(-9999i64 as u64).to_string(), "0xffff_ffff_ffff_d8f1");
assert_eq!(
Uimm64(-10000i64 as u64).to_string(),
"0xffff_ffff_ffff_d8f0"
);
assert_eq!(Uimm64(0xffff).to_string(), "0xffff");
assert_eq!(Uimm64(0x10000).to_string(), "0x0001_0000");
}
#[track_caller]
fn parse_ok<T: FromStr + Display>(text: &str, want: &str)
where
<T as FromStr>::Err: Display,
{
match text.parse::<T>() {
Err(s) => panic!("\"{}\".parse() error: {}", text, s),
Ok(x) => assert_eq!(x.to_string(), want),
}
}
fn parse_err<T: FromStr + Display>(text: &str, msg: &str)
where
<T as FromStr>::Err: Display,
{
match text.parse::<T>() {
Err(s) => assert_eq!(s.to_string(), msg),
Ok(x) => panic!("Wanted Err({}), but got {}", msg, x),
}
}
#[test]
fn parse_imm64() {
parse_ok::<Imm64>("0", "0");
parse_ok::<Imm64>("1", "1");
parse_ok::<Imm64>("-0", "0");
parse_ok::<Imm64>("-1", "-1");
parse_ok::<Imm64>("0x0", "0");
parse_ok::<Imm64>("0xf", "15");
parse_ok::<Imm64>("-0x9", "-9");
parse_ok::<Imm64>("0xffffffff_ffffffff", "-1");
parse_ok::<Imm64>("0x80000000_00000000", "-9223372036854775808");
parse_ok::<Imm64>("-0x80000000_00000000", "-9223372036854775808");
parse_err::<Imm64>("-0x80000000_00000001", "Negative number too small");
parse_ok::<Imm64>("18446744073709551615", "-1");
parse_ok::<Imm64>("-9223372036854775808", "-9223372036854775808");
parse_err::<Imm64>("18446744073709551616", "Too large decimal number");
parse_err::<Imm64>("184467440737095516100", "Too large decimal number");
parse_err::<Imm64>("-9223372036854775809", "Negative number too small");
parse_ok::<Imm64>("0_0", "0");
parse_ok::<Imm64>("-_10_0", "-100");
parse_ok::<Imm64>("_10_", "10");
parse_ok::<Imm64>("0x97_88_bb", "0x0097_88bb");
parse_ok::<Imm64>("0x_97_", "151");
parse_err::<Imm64>("", "No digits in number");
parse_err::<Imm64>("-", "No digits in number");
parse_err::<Imm64>("_", "No digits in number");
parse_err::<Imm64>("0x", "No digits in number");
parse_err::<Imm64>("0x_", "No digits in number");
parse_err::<Imm64>("-0x", "No digits in number");
parse_err::<Imm64>(" ", "Invalid character in decimal number");
parse_err::<Imm64>("0 ", "Invalid character in decimal number");
parse_err::<Imm64>(" 0", "Invalid character in decimal number");
parse_err::<Imm64>("--", "Invalid character in decimal number");
parse_err::<Imm64>("-0x-", "Invalid character in hexadecimal number");
parse_err::<Imm64>("abc", "Invalid character in decimal number");
parse_err::<Imm64>("-abc", "Invalid character in decimal number");
parse_err::<Imm64>("0x0_0000_0000_0000_0000", "Too many hexadecimal digits");
}
#[test]
fn parse_uimm64() {
parse_ok::<Uimm64>("0", "0");
parse_ok::<Uimm64>("1", "1");
parse_ok::<Uimm64>("0x0", "0");
parse_ok::<Uimm64>("0xf", "15");
parse_ok::<Uimm64>("0xffffffff_fffffff7", "0xffff_ffff_ffff_fff7");
parse_ok::<Uimm64>("0xffffffff_ffffffff", "0xffff_ffff_ffff_ffff");
parse_ok::<Uimm64>("0x80000000_00000000", "0x8000_0000_0000_0000");
parse_ok::<Uimm64>("18446744073709551615", "0xffff_ffff_ffff_ffff");
parse_err::<Uimm64>("18446744073709551616", "Too large decimal number");
parse_err::<Uimm64>("184467440737095516100", "Too large decimal number");
parse_ok::<Uimm64>("0_0", "0");
parse_ok::<Uimm64>("_10_", "10");
parse_ok::<Uimm64>("0x97_88_bb", "0x0097_88bb");
parse_ok::<Uimm64>("0x_97_", "151");
parse_err::<Uimm64>("", "No digits in number");
parse_err::<Uimm64>("_", "No digits in number");
parse_err::<Uimm64>("0x", "No digits in number");
parse_err::<Uimm64>("0x_", "No digits in number");
parse_err::<Uimm64>("-", "Invalid character in decimal number");
parse_err::<Uimm64>("-0x", "Invalid character in hexadecimal number");
parse_err::<Uimm64>(" ", "Invalid character in decimal number");
parse_err::<Uimm64>("0 ", "Invalid character in decimal number");
parse_err::<Uimm64>(" 0", "Invalid character in decimal number");
parse_err::<Uimm64>("--", "Invalid character in decimal number");
parse_err::<Uimm64>("-0x-", "Invalid character in hexadecimal number");
parse_err::<Uimm64>("-0", "Invalid character in decimal number");
parse_err::<Uimm64>("-1", "Invalid character in decimal number");
parse_err::<Uimm64>("abc", "Invalid character in decimal number");
parse_err::<Uimm64>("-abc", "Invalid character in decimal number");
parse_err::<Uimm64>("0x0_0000_0000_0000_0000", "Too many hexadecimal digits");
}
#[test]
fn format_offset32() {
assert_eq!(Offset32(0).to_string(), "");
assert_eq!(Offset32(1).to_string(), "+1");
assert_eq!(Offset32(-1).to_string(), "-1");
assert_eq!(Offset32(9999).to_string(), "+9999");
assert_eq!(Offset32(10000).to_string(), "+0x2710");
assert_eq!(Offset32(-9999).to_string(), "-9999");
assert_eq!(Offset32(-10000).to_string(), "-0x2710");
assert_eq!(Offset32(0xffff).to_string(), "+0xffff");
assert_eq!(Offset32(0x10000).to_string(), "+0x0001_0000");
}
#[test]
fn parse_offset32() {
parse_ok::<Offset32>("+0", "");
parse_ok::<Offset32>("+1", "+1");
parse_ok::<Offset32>("-0", "");
parse_ok::<Offset32>("-1", "-1");
parse_ok::<Offset32>("+0x0", "");
parse_ok::<Offset32>("+0xf", "+15");
parse_ok::<Offset32>("-0x9", "-9");
parse_ok::<Offset32>("-0x8000_0000", "-0x8000_0000");
parse_err::<Offset32>("+0x8000_0000", "Offset out of range");
}
#[test]
fn format_ieee16() {
assert_eq!(Ieee16::with_bits(0).to_string(), "0.0"); assert_eq!(Ieee16::with_bits(0x8000).to_string(), "-0.0"); assert_eq!(Ieee16::with_bits(0x3c00).to_string(), "0x1.000p0"); assert_eq!(Ieee16::with_bits(0x3e00).to_string(), "0x1.800p0"); assert_eq!(Ieee16::with_bits(0x3800).to_string(), "0x1.000p-1"); assert_eq!(
Ieee16::with_bits(0x1400).to_string(), "0x1.000p-10"
);
assert_eq!(
Ieee16::with_bits(0xfbff).to_string(), "-0x1.ffcp15"
);
assert_eq!(
Ieee16::with_bits(0x7bff).to_string(), "0x1.ffcp15"
);
assert_eq!(
Ieee16::with_bits(0x0400).to_string(), "0x1.000p-14"
);
assert_eq!(
Ieee16::with_bits(0x0200).to_string(), "0x0.800p-14"
);
assert_eq!(
Ieee16::with_bits(0x0001).to_string(), "0x0.004p-14"
);
assert_eq!(
Ieee16::with_bits(0x7c00).to_string(), "+Inf"
);
assert_eq!(
Ieee16::with_bits(0xfc00).to_string(), "-Inf"
);
assert_eq!(
Ieee16::with_bits(0x7e00).to_string(), "+NaN"
);
assert_eq!(
Ieee16::with_bits(0xfe00).to_string(), "-NaN"
);
assert_eq!(Ieee16::with_bits(0x7e01).to_string(), "+NaN:0x1");
assert_eq!(Ieee16::with_bits(0x7f01).to_string(), "+NaN:0x101");
assert_eq!(Ieee16::with_bits(0x7c01).to_string(), "+sNaN:0x1");
assert_eq!(Ieee16::with_bits(0x7d01).to_string(), "+sNaN:0x101");
}
#[test]
fn parse_ieee16() {
parse_ok::<Ieee16>("0.0", "0.0");
parse_ok::<Ieee16>("+0.0", "0.0");
parse_ok::<Ieee16>("-0.0", "-0.0");
parse_ok::<Ieee16>("0x0", "0.0");
parse_ok::<Ieee16>("0x0.0", "0.0");
parse_ok::<Ieee16>("0x.0", "0.0");
parse_ok::<Ieee16>("0x0.", "0.0");
parse_ok::<Ieee16>("0x1", "0x1.000p0");
parse_ok::<Ieee16>("+0x1", "0x1.000p0");
parse_ok::<Ieee16>("-0x1", "-0x1.000p0");
parse_ok::<Ieee16>("0x10", "0x1.000p4");
parse_ok::<Ieee16>("0x10.0", "0x1.000p4");
parse_err::<Ieee16>("0.", "Float must be hexadecimal");
parse_err::<Ieee16>(".0", "Float must be hexadecimal");
parse_err::<Ieee16>("0", "Float must be hexadecimal");
parse_err::<Ieee16>("-0", "Float must be hexadecimal");
parse_err::<Ieee16>(".", "Float must be hexadecimal");
parse_err::<Ieee16>("", "Float must be hexadecimal");
parse_err::<Ieee16>("-", "Float must be hexadecimal");
parse_err::<Ieee16>("0x", "No digits");
parse_err::<Ieee16>("0x..", "Multiple radix points");
parse_ok::<Ieee16>("0x0.ffe", "0x1.ffcp-1");
parse_ok::<Ieee16>("0x1.ffc", "0x1.ffcp0");
parse_ok::<Ieee16>("0x3.ff8", "0x1.ffcp1");
parse_ok::<Ieee16>("0x7.ff", "0x1.ffcp2");
parse_ok::<Ieee16>("0xf.fe", "0x1.ffcp3");
parse_err::<Ieee16>("0x1.ffe", "Too many significant bits");
parse_err::<Ieee16>("0x1.ffc00000000000000000000000000000", "Too many digits");
parse_ok::<Ieee16>("0x1p3", "0x1.000p3");
parse_ok::<Ieee16>("0x1p-3", "0x1.000p-3");
parse_ok::<Ieee16>("0x1.0p3", "0x1.000p3");
parse_ok::<Ieee16>("0x2.0p3", "0x1.000p4");
parse_ok::<Ieee16>("0x1.0p15", "0x1.000p15");
parse_ok::<Ieee16>("0x1.0p-14", "0x1.000p-14");
parse_ok::<Ieee16>("0x0.1p-10", "0x1.000p-14");
parse_err::<Ieee16>("0x2.0p15", "Magnitude too large");
parse_ok::<Ieee16>("0x1.0p-15", "0x0.800p-14");
parse_ok::<Ieee16>("0x1.0p-24", "0x0.004p-14");
parse_ok::<Ieee16>("0x0.004p-14", "0x0.004p-14");
parse_err::<Ieee16>("0x0.102p-14", "Subnormal underflow");
parse_err::<Ieee16>("0x1.8p-24", "Subnormal underflow");
parse_err::<Ieee16>("0x1.0p-25", "Magnitude too small");
parse_ok::<Ieee16>("Inf", "+Inf");
parse_ok::<Ieee16>("+Inf", "+Inf");
parse_ok::<Ieee16>("-Inf", "-Inf");
parse_ok::<Ieee16>("NaN", "+NaN");
parse_ok::<Ieee16>("+NaN", "+NaN");
parse_ok::<Ieee16>("-NaN", "-NaN");
parse_ok::<Ieee16>("NaN:0x0", "+NaN");
parse_err::<Ieee16>("NaN:", "Float must be hexadecimal");
parse_err::<Ieee16>("NaN:0", "Float must be hexadecimal");
parse_err::<Ieee16>("NaN:0x", "Invalid NaN payload");
parse_ok::<Ieee16>("NaN:0x001", "+NaN:0x1");
parse_ok::<Ieee16>("NaN:0x101", "+NaN:0x101");
parse_err::<Ieee16>("NaN:0x301", "Invalid NaN payload");
parse_ok::<Ieee16>("sNaN:0x1", "+sNaN:0x1");
parse_err::<Ieee16>("sNaN:0x0", "Invalid sNaN payload");
parse_ok::<Ieee16>("sNaN:0x101", "+sNaN:0x101");
parse_err::<Ieee16>("sNaN:0x301", "Invalid sNaN payload");
}
#[test]
fn pow2_ieee16() {
assert_eq!(Ieee16::pow2(0).to_string(), "0x1.000p0");
assert_eq!(Ieee16::pow2(1).to_string(), "0x1.000p1");
assert_eq!(Ieee16::pow2(-1).to_string(), "0x1.000p-1");
assert_eq!(Ieee16::pow2(15).to_string(), "0x1.000p15");
assert_eq!(Ieee16::pow2(-14).to_string(), "0x1.000p-14");
assert_eq!((-Ieee16::pow2(1)).to_string(), "-0x1.000p1");
}
#[test]
fn fcvt_to_sint_negative_overflow_ieee16() {
let n = 8;
assert_eq!(
"-0x1.020p7",
Ieee16::fcvt_to_sint_negative_overflow(n).to_string()
);
}
#[test]
fn format_ieee32() {
assert_eq!(Ieee32::with_float(0.0).to_string(), "0.0");
assert_eq!(Ieee32::with_float(-0.0).to_string(), "-0.0");
assert_eq!(Ieee32::with_float(1.0).to_string(), "0x1.000000p0");
assert_eq!(Ieee32::with_float(1.5).to_string(), "0x1.800000p0");
assert_eq!(Ieee32::with_float(0.5).to_string(), "0x1.000000p-1");
assert_eq!(
Ieee32::with_float(f32::EPSILON).to_string(),
"0x1.000000p-23"
);
assert_eq!(Ieee32::with_float(f32::MIN).to_string(), "-0x1.fffffep127");
assert_eq!(Ieee32::with_float(f32::MAX).to_string(), "0x1.fffffep127");
assert_eq!(
Ieee32::with_float(f32::MIN_POSITIVE).to_string(),
"0x1.000000p-126"
);
assert_eq!(
Ieee32::with_float(f32::MIN_POSITIVE / 2.0).to_string(),
"0x0.800000p-126"
);
assert_eq!(
Ieee32::with_float(f32::MIN_POSITIVE * f32::EPSILON).to_string(),
"0x0.000002p-126"
);
assert_eq!(Ieee32::with_float(f32::INFINITY).to_string(), "+Inf");
assert_eq!(Ieee32::with_float(f32::NEG_INFINITY).to_string(), "-Inf");
assert_eq!(Ieee32::with_float(f32::NAN).to_string(), "+NaN");
assert_eq!(Ieee32::with_float(-f32::NAN).to_string(), "-NaN");
assert_eq!(Ieee32::with_bits(0x7fc00001).to_string(), "+NaN:0x1");
assert_eq!(Ieee32::with_bits(0x7ff00001).to_string(), "+NaN:0x300001");
assert_eq!(Ieee32::with_bits(0x7f800001).to_string(), "+sNaN:0x1");
assert_eq!(Ieee32::with_bits(0x7fa00001).to_string(), "+sNaN:0x200001");
}
#[test]
fn parse_ieee32() {
parse_ok::<Ieee32>("0.0", "0.0");
parse_ok::<Ieee32>("+0.0", "0.0");
parse_ok::<Ieee32>("-0.0", "-0.0");
parse_ok::<Ieee32>("0x0", "0.0");
parse_ok::<Ieee32>("0x0.0", "0.0");
parse_ok::<Ieee32>("0x.0", "0.0");
parse_ok::<Ieee32>("0x0.", "0.0");
parse_ok::<Ieee32>("0x1", "0x1.000000p0");
parse_ok::<Ieee32>("+0x1", "0x1.000000p0");
parse_ok::<Ieee32>("-0x1", "-0x1.000000p0");
parse_ok::<Ieee32>("0x10", "0x1.000000p4");
parse_ok::<Ieee32>("0x10.0", "0x1.000000p4");
parse_err::<Ieee32>("0.", "Float must be hexadecimal");
parse_err::<Ieee32>(".0", "Float must be hexadecimal");
parse_err::<Ieee32>("0", "Float must be hexadecimal");
parse_err::<Ieee32>("-0", "Float must be hexadecimal");
parse_err::<Ieee32>(".", "Float must be hexadecimal");
parse_err::<Ieee32>("", "Float must be hexadecimal");
parse_err::<Ieee32>("-", "Float must be hexadecimal");
parse_err::<Ieee32>("0x", "No digits");
parse_err::<Ieee32>("0x..", "Multiple radix points");
parse_ok::<Ieee32>("0x0.ffffff", "0x1.fffffep-1");
parse_ok::<Ieee32>("0x1.fffffe", "0x1.fffffep0");
parse_ok::<Ieee32>("0x3.fffffc", "0x1.fffffep1");
parse_ok::<Ieee32>("0x7.fffff8", "0x1.fffffep2");
parse_ok::<Ieee32>("0xf.fffff0", "0x1.fffffep3");
parse_err::<Ieee32>("0x1.ffffff", "Too many significant bits");
parse_err::<Ieee32>("0x1.fffffe00000000000000000000000000", "Too many digits");
parse_ok::<Ieee32>("0x1p3", "0x1.000000p3");
parse_ok::<Ieee32>("0x1p-3", "0x1.000000p-3");
parse_ok::<Ieee32>("0x1.0p3", "0x1.000000p3");
parse_ok::<Ieee32>("0x2.0p3", "0x1.000000p4");
parse_ok::<Ieee32>("0x1.0p127", "0x1.000000p127");
parse_ok::<Ieee32>("0x1.0p-126", "0x1.000000p-126");
parse_ok::<Ieee32>("0x0.1p-122", "0x1.000000p-126");
parse_err::<Ieee32>("0x2.0p127", "Magnitude too large");
parse_ok::<Ieee32>("0x1.0p-127", "0x0.800000p-126");
parse_ok::<Ieee32>("0x1.0p-149", "0x0.000002p-126");
parse_ok::<Ieee32>("0x0.000002p-126", "0x0.000002p-126");
parse_err::<Ieee32>("0x0.100001p-126", "Subnormal underflow");
parse_err::<Ieee32>("0x1.8p-149", "Subnormal underflow");
parse_err::<Ieee32>("0x1.0p-150", "Magnitude too small");
parse_ok::<Ieee32>("Inf", "+Inf");
parse_ok::<Ieee32>("+Inf", "+Inf");
parse_ok::<Ieee32>("-Inf", "-Inf");
parse_ok::<Ieee32>("NaN", "+NaN");
parse_ok::<Ieee32>("+NaN", "+NaN");
parse_ok::<Ieee32>("-NaN", "-NaN");
parse_ok::<Ieee32>("NaN:0x0", "+NaN");
parse_err::<Ieee32>("NaN:", "Float must be hexadecimal");
parse_err::<Ieee32>("NaN:0", "Float must be hexadecimal");
parse_err::<Ieee32>("NaN:0x", "Invalid NaN payload");
parse_ok::<Ieee32>("NaN:0x000001", "+NaN:0x1");
parse_ok::<Ieee32>("NaN:0x300001", "+NaN:0x300001");
parse_err::<Ieee32>("NaN:0x400001", "Invalid NaN payload");
parse_ok::<Ieee32>("sNaN:0x1", "+sNaN:0x1");
parse_err::<Ieee32>("sNaN:0x0", "Invalid sNaN payload");
parse_ok::<Ieee32>("sNaN:0x200001", "+sNaN:0x200001");
parse_err::<Ieee32>("sNaN:0x400001", "Invalid sNaN payload");
}
#[test]
fn pow2_ieee32() {
assert_eq!(Ieee32::pow2(0).to_string(), "0x1.000000p0");
assert_eq!(Ieee32::pow2(1).to_string(), "0x1.000000p1");
assert_eq!(Ieee32::pow2(-1).to_string(), "0x1.000000p-1");
assert_eq!(Ieee32::pow2(127).to_string(), "0x1.000000p127");
assert_eq!(Ieee32::pow2(-126).to_string(), "0x1.000000p-126");
assert_eq!((-Ieee32::pow2(1)).to_string(), "-0x1.000000p1");
}
#[test]
fn fcvt_to_sint_negative_overflow_ieee32() {
for n in [8, 16] {
assert_eq!(
-((1u32 << (n - 1)) as f32) - 1.0,
Ieee32::fcvt_to_sint_negative_overflow(n).as_f32(),
"n = {n}"
);
}
}
#[test]
fn format_ieee64() {
assert_eq!(Ieee64::with_float(0.0).to_string(), "0.0");
assert_eq!(Ieee64::with_float(-0.0).to_string(), "-0.0");
assert_eq!(Ieee64::with_float(1.0).to_string(), "0x1.0000000000000p0");
assert_eq!(Ieee64::with_float(1.5).to_string(), "0x1.8000000000000p0");
assert_eq!(Ieee64::with_float(0.5).to_string(), "0x1.0000000000000p-1");
assert_eq!(
Ieee64::with_float(f64::EPSILON).to_string(),
"0x1.0000000000000p-52"
);
assert_eq!(
Ieee64::with_float(f64::MIN).to_string(),
"-0x1.fffffffffffffp1023"
);
assert_eq!(
Ieee64::with_float(f64::MAX).to_string(),
"0x1.fffffffffffffp1023"
);
assert_eq!(
Ieee64::with_float(f64::MIN_POSITIVE).to_string(),
"0x1.0000000000000p-1022"
);
assert_eq!(
Ieee64::with_float(f64::MIN_POSITIVE / 2.0).to_string(),
"0x0.8000000000000p-1022"
);
assert_eq!(
Ieee64::with_float(f64::MIN_POSITIVE * f64::EPSILON).to_string(),
"0x0.0000000000001p-1022"
);
assert_eq!(Ieee64::with_float(f64::INFINITY).to_string(), "+Inf");
assert_eq!(Ieee64::with_float(f64::NEG_INFINITY).to_string(), "-Inf");
assert_eq!(Ieee64::with_float(f64::NAN).to_string(), "+NaN");
assert_eq!(Ieee64::with_float(-f64::NAN).to_string(), "-NaN");
assert_eq!(
Ieee64::with_bits(0x7ff8000000000001).to_string(),
"+NaN:0x1"
);
assert_eq!(
Ieee64::with_bits(0x7ffc000000000001).to_string(),
"+NaN:0x4000000000001"
);
assert_eq!(
Ieee64::with_bits(0x7ff0000000000001).to_string(),
"+sNaN:0x1"
);
assert_eq!(
Ieee64::with_bits(0x7ff4000000000001).to_string(),
"+sNaN:0x4000000000001"
);
}
#[test]
fn parse_ieee64() {
parse_ok::<Ieee64>("0.0", "0.0");
parse_ok::<Ieee64>("-0.0", "-0.0");
parse_ok::<Ieee64>("0x0", "0.0");
parse_ok::<Ieee64>("0x0.0", "0.0");
parse_ok::<Ieee64>("0x.0", "0.0");
parse_ok::<Ieee64>("0x0.", "0.0");
parse_ok::<Ieee64>("0x1", "0x1.0000000000000p0");
parse_ok::<Ieee64>("-0x1", "-0x1.0000000000000p0");
parse_ok::<Ieee64>("0x10", "0x1.0000000000000p4");
parse_ok::<Ieee64>("0x10.0", "0x1.0000000000000p4");
parse_err::<Ieee64>("0.", "Float must be hexadecimal");
parse_err::<Ieee64>(".0", "Float must be hexadecimal");
parse_err::<Ieee64>("0", "Float must be hexadecimal");
parse_err::<Ieee64>("-0", "Float must be hexadecimal");
parse_err::<Ieee64>(".", "Float must be hexadecimal");
parse_err::<Ieee64>("", "Float must be hexadecimal");
parse_err::<Ieee64>("-", "Float must be hexadecimal");
parse_err::<Ieee64>("0x", "No digits");
parse_err::<Ieee64>("0x..", "Multiple radix points");
parse_ok::<Ieee64>("0x0.fffffffffffff8", "0x1.fffffffffffffp-1");
parse_ok::<Ieee64>("0x1.fffffffffffff", "0x1.fffffffffffffp0");
parse_ok::<Ieee64>("0x3.ffffffffffffe", "0x1.fffffffffffffp1");
parse_ok::<Ieee64>("0x7.ffffffffffffc", "0x1.fffffffffffffp2");
parse_ok::<Ieee64>("0xf.ffffffffffff8", "0x1.fffffffffffffp3");
parse_err::<Ieee64>("0x3.fffffffffffff", "Too many significant bits");
parse_err::<Ieee64>("0x001.fffffe000000000000000000000000", "Too many digits");
parse_ok::<Ieee64>("0x1p3", "0x1.0000000000000p3");
parse_ok::<Ieee64>("0x1p-3", "0x1.0000000000000p-3");
parse_ok::<Ieee64>("0x1.0p3", "0x1.0000000000000p3");
parse_ok::<Ieee64>("0x2.0p3", "0x1.0000000000000p4");
parse_ok::<Ieee64>("0x1.0p1023", "0x1.0000000000000p1023");
parse_ok::<Ieee64>("0x1.0p-1022", "0x1.0000000000000p-1022");
parse_ok::<Ieee64>("0x0.1p-1018", "0x1.0000000000000p-1022");
parse_err::<Ieee64>("0x2.0p1023", "Magnitude too large");
parse_ok::<Ieee64>("0x1.0p-1023", "0x0.8000000000000p-1022");
parse_ok::<Ieee64>("0x1.0p-1074", "0x0.0000000000001p-1022");
parse_ok::<Ieee64>("0x0.0000000000001p-1022", "0x0.0000000000001p-1022");
parse_err::<Ieee64>("0x0.10000000000008p-1022", "Subnormal underflow");
parse_err::<Ieee64>("0x1.8p-1074", "Subnormal underflow");
parse_err::<Ieee64>("0x1.0p-1075", "Magnitude too small");
parse_ok::<Ieee64>("Inf", "+Inf");
parse_ok::<Ieee64>("-Inf", "-Inf");
parse_ok::<Ieee64>("NaN", "+NaN");
parse_ok::<Ieee64>("-NaN", "-NaN");
parse_ok::<Ieee64>("NaN:0x0", "+NaN");
parse_err::<Ieee64>("NaN:", "Float must be hexadecimal");
parse_err::<Ieee64>("NaN:0", "Float must be hexadecimal");
parse_err::<Ieee64>("NaN:0x", "Invalid NaN payload");
parse_ok::<Ieee64>("NaN:0x000001", "+NaN:0x1");
parse_ok::<Ieee64>("NaN:0x4000000000001", "+NaN:0x4000000000001");
parse_err::<Ieee64>("NaN:0x8000000000001", "Invalid NaN payload");
parse_ok::<Ieee64>("sNaN:0x1", "+sNaN:0x1");
parse_err::<Ieee64>("sNaN:0x0", "Invalid sNaN payload");
parse_ok::<Ieee64>("sNaN:0x4000000000001", "+sNaN:0x4000000000001");
parse_err::<Ieee64>("sNaN:0x8000000000001", "Invalid sNaN payload");
}
#[test]
fn pow2_ieee64() {
assert_eq!(Ieee64::pow2(0).to_string(), "0x1.0000000000000p0");
assert_eq!(Ieee64::pow2(1).to_string(), "0x1.0000000000000p1");
assert_eq!(Ieee64::pow2(-1).to_string(), "0x1.0000000000000p-1");
assert_eq!(Ieee64::pow2(1023).to_string(), "0x1.0000000000000p1023");
assert_eq!(Ieee64::pow2(-1022).to_string(), "0x1.0000000000000p-1022");
assert_eq!((-Ieee64::pow2(1)).to_string(), "-0x1.0000000000000p1");
}
#[test]
fn fcvt_to_sint_negative_overflow_ieee64() {
for n in [8, 16, 32] {
assert_eq!(
-((1u64 << (n - 1)) as f64) - 1.0,
Ieee64::fcvt_to_sint_negative_overflow(n).as_f64(),
"n = {n}"
);
}
}
#[test]
fn format_ieee128() {
assert_eq!(
Ieee128::with_bits(0x00000000000000000000000000000000).to_string(), "0.0"
);
assert_eq!(
Ieee128::with_bits(0x80000000000000000000000000000000).to_string(), "-0.0"
);
assert_eq!(
Ieee128::with_bits(0x3fff0000000000000000000000000000).to_string(), "0x1.0000000000000000000000000000p0"
);
assert_eq!(
Ieee128::with_bits(0x3fff8000000000000000000000000000).to_string(), "0x1.8000000000000000000000000000p0"
);
assert_eq!(
Ieee128::with_bits(0x3ffe0000000000000000000000000000).to_string(), "0x1.0000000000000000000000000000p-1"
);
assert_eq!(
Ieee128::with_bits(0x3f8f0000000000000000000000000000).to_string(), "0x1.0000000000000000000000000000p-112"
);
assert_eq!(
Ieee128::with_bits(0xfffeffffffffffffffffffffffffffff).to_string(), "-0x1.ffffffffffffffffffffffffffffp16383"
);
assert_eq!(
Ieee128::with_bits(0x7ffeffffffffffffffffffffffffffff).to_string(), "0x1.ffffffffffffffffffffffffffffp16383"
);
assert_eq!(
Ieee128::with_bits(0x00010000000000000000000000000000).to_string(), "0x1.0000000000000000000000000000p-16382"
);
assert_eq!(
Ieee128::with_bits(0x00008000000000000000000000000000).to_string(), "0x0.8000000000000000000000000000p-16382"
);
assert_eq!(
Ieee128::with_bits(0x00000000000000000000000000000001).to_string(), "0x0.0000000000000000000000000001p-16382"
);
assert_eq!(
Ieee128::with_bits(0x7fff0000000000000000000000000000).to_string(), "+Inf"
);
assert_eq!(
Ieee128::with_bits(0xffff0000000000000000000000000000).to_string(), "-Inf"
);
assert_eq!(
Ieee128::with_bits(0x7fff8000000000000000000000000000).to_string(), "+NaN"
);
assert_eq!(
Ieee128::with_bits(0xffff8000000000000000000000000000).to_string(), "-NaN"
);
assert_eq!(
Ieee128::with_bits(0x7fff8000000000000000000000000001).to_string(),
"+NaN:0x1"
);
assert_eq!(
Ieee128::with_bits(0x7fffc000000000000000000000000001).to_string(),
"+NaN:0x4000000000000000000000000001"
);
assert_eq!(
Ieee128::with_bits(0x7fff0000000000000000000000000001).to_string(),
"+sNaN:0x1"
);
assert_eq!(
Ieee128::with_bits(0x7fff4000000000000000000000000001).to_string(),
"+sNaN:0x4000000000000000000000000001"
);
}
#[test]
fn parse_ieee128() {
parse_ok::<Ieee128>("0.0", "0.0");
parse_ok::<Ieee128>("-0.0", "-0.0");
parse_ok::<Ieee128>("0x0", "0.0");
parse_ok::<Ieee128>("0x0.0", "0.0");
parse_ok::<Ieee128>("0x.0", "0.0");
parse_ok::<Ieee128>("0x0.", "0.0");
parse_ok::<Ieee128>("0x1", "0x1.0000000000000000000000000000p0");
parse_ok::<Ieee128>("-0x1", "-0x1.0000000000000000000000000000p0");
parse_ok::<Ieee128>("0x10", "0x1.0000000000000000000000000000p4");
parse_ok::<Ieee128>("0x10.0", "0x1.0000000000000000000000000000p4");
parse_err::<Ieee128>("0.", "Float must be hexadecimal");
parse_err::<Ieee128>(".0", "Float must be hexadecimal");
parse_err::<Ieee128>("0", "Float must be hexadecimal");
parse_err::<Ieee128>("-0", "Float must be hexadecimal");
parse_err::<Ieee128>(".", "Float must be hexadecimal");
parse_err::<Ieee128>("", "Float must be hexadecimal");
parse_err::<Ieee128>("-", "Float must be hexadecimal");
parse_err::<Ieee128>("0x", "No digits");
parse_err::<Ieee128>("0x..", "Multiple radix points");
parse_ok::<Ieee128>(
"0x0.ffffffffffffffffffffffffffff8",
"0x1.ffffffffffffffffffffffffffffp-1",
);
parse_ok::<Ieee128>(
"0x1.ffffffffffffffffffffffffffff",
"0x1.ffffffffffffffffffffffffffffp0",
);
parse_ok::<Ieee128>(
"0x3.fffffffffffffffffffffffffffe",
"0x1.ffffffffffffffffffffffffffffp1",
);
parse_ok::<Ieee128>(
"0x7.fffffffffffffffffffffffffffc",
"0x1.ffffffffffffffffffffffffffffp2",
);
parse_ok::<Ieee128>(
"0xf.fffffffffffffffffffffffffff8",
"0x1.ffffffffffffffffffffffffffffp3",
);
parse_err::<Ieee128>(
"0x3.ffffffffffffffffffffffffffff",
"Too many significant bits",
);
parse_err::<Ieee128>("0x001.fffffe000000000000000000000000", "Too many digits");
parse_ok::<Ieee128>("0x1p3", "0x1.0000000000000000000000000000p3");
parse_ok::<Ieee128>("0x1p-3", "0x1.0000000000000000000000000000p-3");
parse_ok::<Ieee128>("0x1.0p3", "0x1.0000000000000000000000000000p3");
parse_ok::<Ieee128>("0x2.0p3", "0x1.0000000000000000000000000000p4");
parse_ok::<Ieee128>("0x1.0p16383", "0x1.0000000000000000000000000000p16383");
parse_ok::<Ieee128>("0x1.0p-16382", "0x1.0000000000000000000000000000p-16382");
parse_ok::<Ieee128>("0x0.1p-16378", "0x1.0000000000000000000000000000p-16382");
parse_err::<Ieee128>("0x2.0p16383", "Magnitude too large");
parse_ok::<Ieee128>("0x1.0p-16383", "0x0.8000000000000000000000000000p-16382");
parse_ok::<Ieee128>("0x1.0p-16494", "0x0.0000000000000000000000000001p-16382");
parse_ok::<Ieee128>(
"0x0.0000000000000000000000000001p-16382",
"0x0.0000000000000000000000000001p-16382",
);
parse_err::<Ieee128>(
"0x0.10000000000000000000000000008p-16382",
"Subnormal underflow",
);
parse_err::<Ieee128>("0x1.8p-16494", "Subnormal underflow");
parse_err::<Ieee128>("0x1.0p-16495", "Magnitude too small");
parse_ok::<Ieee128>("Inf", "+Inf");
parse_ok::<Ieee128>("-Inf", "-Inf");
parse_ok::<Ieee128>("NaN", "+NaN");
parse_ok::<Ieee128>("-NaN", "-NaN");
parse_ok::<Ieee128>("NaN:0x0", "+NaN");
parse_err::<Ieee128>("NaN:", "Float must be hexadecimal");
parse_err::<Ieee128>("NaN:0", "Float must be hexadecimal");
parse_err::<Ieee128>("NaN:0x", "Invalid NaN payload");
parse_ok::<Ieee128>("NaN:0x000001", "+NaN:0x1");
parse_ok::<Ieee128>(
"NaN:0x4000000000000000000000000001",
"+NaN:0x4000000000000000000000000001",
);
parse_err::<Ieee128>("NaN:0x8000000000000000000000000001", "Invalid NaN payload");
parse_ok::<Ieee128>("sNaN:0x1", "+sNaN:0x1");
parse_err::<Ieee128>("sNaN:0x0", "Invalid sNaN payload");
parse_ok::<Ieee128>(
"sNaN:0x4000000000000000000000000001",
"+sNaN:0x4000000000000000000000000001",
);
parse_err::<Ieee128>(
"sNaN:0x8000000000000000000000000001",
"Invalid sNaN payload",
);
}
#[test]
fn pow2_ieee128() {
assert_eq!(
Ieee128::pow2(0).to_string(),
"0x1.0000000000000000000000000000p0"
);
assert_eq!(
Ieee128::pow2(1).to_string(),
"0x1.0000000000000000000000000000p1"
);
assert_eq!(
Ieee128::pow2(-1).to_string(),
"0x1.0000000000000000000000000000p-1"
);
assert_eq!(
Ieee128::pow2(16383).to_string(),
"0x1.0000000000000000000000000000p16383"
);
assert_eq!(
Ieee128::pow2(-16382).to_string(),
"0x1.0000000000000000000000000000p-16382"
);
assert_eq!(
(-Ieee128::pow2(1)).to_string(),
"-0x1.0000000000000000000000000000p1"
);
}
#[test]
fn fcvt_to_sint_negative_overflow_ieee128() {
for (n, expected) in [
(8, "-0x1.0200000000000000000000000000p7"),
(16, "-0x1.0002000000000000000000000000p15"),
(32, "-0x1.0000000200000000000000000000p31"),
(64, "-0x1.0000000000000002000000000000p63"),
] {
assert_eq!(
expected,
Ieee128::fcvt_to_sint_negative_overflow(n).to_string(),
"n = {n}"
);
}
}
}