letmut i = 0; ifunsafe { *buffer.get_unchecked(0) } == b'-' {
signed_m = true;
i += 1;
}
whilelet Some(c) = buffer.get(i).copied() { if c == b'.' { if dot_index != len { return Err(Error::MalformedInput);
}
dot_index = i;
i += 1; continue;
} if c < b'0' || c > b'9' { break;
} if m10digits >= 17 { return Err(Error::InputTooLong);
}
m10 = 10 * m10 + (c - b'0') as u64; if m10 != 0 {
m10digits += 1;
}
i += 1;
}
iflet Some(b'e') | Some(b'E') = buffer.get(i) {
e_index = i;
i += 1; match buffer.get(i) {
Some(b'-') => {
signed_e = true;
i += 1;
}
Some(b'+') => i += 1,
_ => {}
} whilelet Some(c) = buffer.get(i).copied() { if c < b'0' || c > b'9' { return Err(Error::MalformedInput);
} if e10digits > 3 { // TODO: Be more lenient. Return +/-Infinity or +/-0 instead. return Err(Error::InputTooLong);
}
e10 = 10 * e10 + (c - b'0') as i32; if e10 != 0 {
e10digits += 1;
}
i += 1;
}
}
if i < len { return Err(Error::MalformedInput);
} if signed_e {
e10 = -e10;
}
e10 -= if dot_index < e_index {
(e_index - dot_index - 1) as i32
} else { 0
}; if m10 == 0 { return Ok(if signed_m { -0.0 } else { 0.0 });
}
if m10digits + e10 <= -324 || m10 == 0 { // Number is less than 1e-324, which should be rounded down to 0; return // +/-0.0. let ieee = (signed_m as u64) << (d2s::DOUBLE_EXPONENT_BITS + d2s::DOUBLE_MANTISSA_BITS); return Ok(f64::from_bits(ieee));
} if m10digits + e10 >= 310 { // Number is larger than 1e+309, which should be rounded to +/-Infinity. let ieee = ((signed_m as u64) << (d2s::DOUBLE_EXPONENT_BITS + d2s::DOUBLE_MANTISSA_BITS))
| (0x7ff_u64 << d2s::DOUBLE_MANTISSA_BITS); return Ok(f64::from_bits(ieee));
}
// Convert to binary float m2 * 2^e2, while retaining information about // whether the conversion was exact (trailing_zeros). let e2: i32; let m2: u64; letmut trailing_zeros: bool; if e10 >= 0 { // The length of m * 10^e in bits is: // log2(m10 * 10^e10) = log2(m10) + e10 log2(10) = log2(m10) + e10 + e10 * log2(5) // // We want to compute the DOUBLE_MANTISSA_BITS + 1 top-most bits (+1 for // the implicit leading one in IEEE format). We therefore choose a // binary output exponent of // log2(m10 * 10^e10) - (DOUBLE_MANTISSA_BITS + 1). // // We use floor(log2(5^e10)) so that we get at least this many bits; // better to have an additional bit than to not have enough bits.
e2 = floor_log2(m10)
.wrapping_add(e10 as u32)
.wrapping_add(log2_pow5(e10) as u32)
.wrapping_sub(d2s::DOUBLE_MANTISSA_BITS + 1) as i32;
// We now compute [m10 * 10^e10 / 2^e2] = [m10 * 5^e10 / 2^(e2-e10)]. // To that end, we use the DOUBLE_POW5_SPLIT table. let j = e2
.wrapping_sub(e10)
.wrapping_sub(ceil_log2_pow5(e10))
.wrapping_add(d2s::DOUBLE_POW5_BITCOUNT);
debug_assert!(j >= 0);
debug_assert!(e10 < d2s::DOUBLE_POW5_SPLIT.len() as i32);
m2 = mul_shift_64(
m10, unsafe { d2s::DOUBLE_POW5_SPLIT.get_unchecked(e10 as usize) },
j as u32,
);
// We also compute if the result is exact, i.e., // [m10 * 10^e10 / 2^e2] == m10 * 10^e10 / 2^e2. // This can only be the case if 2^e2 divides m10 * 10^e10, which in turn // requires that the largest power of 2 that divides m10 + e10 is // greater than e2. If e2 is less than e10, then the result must be // exact. Otherwise we use the existing multiple_of_power_of_2 function.
trailing_zeros =
e2 < e10 || e2 - e10 < 64 && multiple_of_power_of_2(m10, (e2 - e10) as u32);
} else {
e2 = floor_log2(m10)
.wrapping_add(e10 as u32)
.wrapping_sub(ceil_log2_pow5(-e10) as u32)
.wrapping_sub(d2s::DOUBLE_MANTISSA_BITS + 1) as i32; let j = e2
.wrapping_sub(e10)
.wrapping_add(ceil_log2_pow5(-e10))
.wrapping_sub(1)
.wrapping_add(d2s::DOUBLE_POW5_INV_BITCOUNT);
debug_assert!(-e10 < d2s::DOUBLE_POW5_INV_SPLIT.len() as i32);
m2 = mul_shift_64(
m10, unsafe { d2s::DOUBLE_POW5_INV_SPLIT.get_unchecked(-e10 as usize) },
j as u32,
);
trailing_zeros = multiple_of_power_of_5(m10, -e10 as u32);
}
// Compute the final IEEE exponent. letmut ieee_e2 = i32::max(0, e2 + DOUBLE_EXPONENT_BIAS as i32 + floor_log2(m2) as i32) as u32;
if ieee_e2 > 0x7fe { // Final IEEE exponent is larger than the maximum representable; return +/-Infinity. let ieee = ((signed_m as u64) << (d2s::DOUBLE_EXPONENT_BITS + d2s::DOUBLE_MANTISSA_BITS))
| (0x7ff_u64 << d2s::DOUBLE_MANTISSA_BITS); return Ok(f64::from_bits(ieee));
}
// We need to figure out how much we need to shift m2. The tricky part is // that we need to take the final IEEE exponent into account, so we need to // reverse the bias and also special-case the value 0. let shift = if ieee_e2 == 0 { 1 } else { ieee_e2 as i32 }
.wrapping_sub(e2)
.wrapping_sub(DOUBLE_EXPONENT_BIAS as i32)
.wrapping_sub(d2s::DOUBLE_MANTISSA_BITS as i32);
debug_assert!(shift >= 0);
// We need to round up if the exact value is more than 0.5 above the value // we computed. That's equivalent to checking if the last removed bit was 1 // and either the value was not just trailing zeros or the result would // otherwise be odd. // // We need to update trailing_zeros given that we have the exact output // exponent ieee_e2 now.
trailing_zeros &= (m2 & ((1_u64 << (shift - 1)) - 1)) == 0; let last_removed_bit = (m2 >> (shift - 1)) & 1; let round_up = last_removed_bit != 0 && (!trailing_zeros || ((m2 >> shift) & 1) != 0);
letmut ieee_m2 = (m2 >> shift).wrapping_add(round_up as u64);
debug_assert!(ieee_m2 <= 1_u64 << (d2s::DOUBLE_MANTISSA_BITS + 1));
ieee_m2 &= (1_u64 << d2s::DOUBLE_MANTISSA_BITS) - 1; if ieee_m2 == 0 && round_up { // Due to how the IEEE represents +/-Infinity, we don't need to check // for overflow here.
ieee_e2 += 1;
} let ieee = ((((signed_m as u64) << d2s::DOUBLE_EXPONENT_BITS) | ieee_e2 as u64)
<< d2s::DOUBLE_MANTISSA_BITS)
| ieee_m2;
Ok(f64::from_bits(ieee))
}
Messung V0.5 in Prozent
¤ Dauer der Verarbeitung: 0.10 Sekunden
(vorverarbeitet am 2026-06-22)
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