impl (unsigned/signed) int to single/double precision float conversion based on llvm algorithms.
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0507842b24
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@ -62,6 +62,12 @@ fn main() {
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"powisf2.c",
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"subdf3.c",
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"subsf3.c",
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"floatsisf.c",
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"floatsidf.c",
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"floatdidf.c",
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"floatunsisf.c",
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"floatunsidf.c",
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"floatundidf.c",
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// 128 bit integers
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"lshrti3.c",
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"modti3.c",
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@ -26,6 +26,12 @@ extern {
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fn __powidf2();
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fn __subsf3();
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fn __subdf3();
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fn __floatsisf();
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fn __floatsidf();
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fn __floatdidf();
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fn __floatunsisf();
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fn __floatunsidf();
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fn __floatundidf();
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}
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macro_rules! declare {
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@ -61,6 +67,12 @@ declare!(___powisf2, __powisf2);
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declare!(___powidf2, __powidf2);
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declare!(___subsf3, __subsf3);
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declare!(___subdf3, __subdf3);
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declare!(___floatsisf, __floatsisf);
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declare!(___floatsidf, __floatsidf);
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declare!(___floatdidf, __floatdidf);
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declare!(___floatunsisf, __floatunsisf);
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declare!(___floatunsidf, __floatunsidf);
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declare!(___floatundidf, __floatundidf);
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#[cfg(all(not(windows),
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not(target_arch = "mips64"),
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@ -112,6 +112,12 @@ pub extern "aapcs" fn __aeabi_uidiv(a: u32, b: u32) -> u32 {
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::int::udiv::__udivsi3(a, b)
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}
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#[cfg(not(feature = "c"))]
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#[cfg_attr(not(test), no_mangle)]
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pub extern "C" fn __aeabi_ui2d(a: u32) -> f64 {
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::float::conv::__floatunsidf(a)
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}
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// TODO: These aeabi_* functions should be defined as aliases
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#[cfg(not(feature = "mem"))]
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extern "C" {
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@ -0,0 +1,133 @@
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use float::Float;
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use int::Int;
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macro_rules! fp_overflow {
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(infinity, $fty:ty, $sign: expr) => {
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return {
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<$fty as Float>::from_parts(
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$sign,
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<$fty as Float>::exponent_max() as <$fty as Float>::Int,
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0 as <$fty as Float>::Int)
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}
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}
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}
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macro_rules! fp_convert {
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($intrinsic:ident: $ity:ty, $fty:ty) => {
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pub extern "C" fn $intrinsic(i: $ity) -> $fty {
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if i == 0 {
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return 0.0
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}
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let mant_dig = <$fty>::significand_bits() + 1;
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let exponent_bias = <$fty>::exponent_bias();
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let n = <$ity>::bits();
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let (s, a) = i.extract_sign();
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let mut a = a;
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// number of significant digits
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let sd = n - a.leading_zeros();
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// exponent
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let mut e = sd - 1;
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if <$ity>::bits() < mant_dig {
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return <$fty>::from_parts(s,
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(e + exponent_bias) as <$fty as Float>::Int,
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(a as <$fty as Float>::Int) << (mant_dig - e - 1))
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}
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a = if sd > mant_dig {
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/* start: 0000000000000000000001xxxxxxxxxxxxxxxxxxxxxxPQxxxxxxxxxxxxxxxxxx
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* finish: 000000000000000000000000000000000000001xxxxxxxxxxxxxxxxxxxxxxPQR
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* 12345678901234567890123456
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* 1 = msb 1 bit
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* P = bit MANT_DIG-1 bits to the right of 1
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* Q = bit MANT_DIG bits to the right of 1
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* R = "or" of all bits to the right of Q
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*/
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let mant_dig_plus_one = mant_dig + 1;
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let mant_dig_plus_two = mant_dig + 2;
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a = if sd == mant_dig_plus_one {
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a << 1
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} else if sd == mant_dig_plus_two {
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a
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} else {
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(a >> (sd - mant_dig_plus_two)) as <$ity as Int>::UnsignedInt |
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((a & <$ity as Int>::UnsignedInt::max_value()).wrapping_shl((n + mant_dig_plus_two) - sd) != 0) as <$ity as Int>::UnsignedInt
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};
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/* finish: */
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a |= ((a & 4) != 0) as <$ity as Int>::UnsignedInt; /* Or P into R */
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a += 1; /* round - this step may add a significant bit */
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a >>= 2; /* dump Q and R */
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/* a is now rounded to mant_dig or mant_dig+1 bits */
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if (a & (1 << mant_dig)) != 0 {
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a >>= 1; e += 1;
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}
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a
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/* a is now rounded to mant_dig bits */
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} else {
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a.wrapping_shl(mant_dig - sd)
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/* a is now rounded to mant_dig bits */
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};
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<$fty>::from_parts(s,
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(e + exponent_bias) as <$fty as Float>::Int,
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a as <$fty as Float>::Int)
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}
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}
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}
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fp_convert!(__floatsisf: i32, f32);
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fp_convert!(__floatsidf: i32, f64);
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fp_convert!(__floatdidf: i64, f64);
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fp_convert!(__floatunsisf: u32, f32);
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fp_convert!(__floatunsidf: u32, f64);
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fp_convert!(__floatundidf: u64, f64);
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// NOTE(cfg) for some reason, on arm*-unknown-linux-gnueabihf, our implementation doesn't
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// match the output of its gcc_s or compiler-rt counterpart. Until we investigate further, we'll
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// just avoid testing against them on those targets. Do note that our implementation gives the
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// correct answer; gcc_s and compiler-rt are incorrect in this case.
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//
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#[cfg(all(test, not(arm_linux)))]
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mod tests {
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use qc::{I32, U32, I64, U64, F32, F64};
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check! {
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fn __floatsisf(f: extern fn(i32) -> f32,
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a: I32)
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-> Option<F32> {
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Some(F32(f(a.0)))
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}
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fn __floatsidf(f: extern fn(i32) -> f64,
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a: I32)
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-> Option<F64> {
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Some(F64(f(a.0)))
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}
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fn __floatdidf(f: extern fn(i64) -> f64,
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a: I64)
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-> Option<F64> {
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Some(F64(f(a.0)))
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}
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fn __floatunsisf(f: extern fn(u32) -> f32,
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a: U32)
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-> Option<F32> {
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Some(F32(f(a.0)))
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}
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fn __floatunsidf(f: extern fn(u32) -> f64,
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a: U32)
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-> Option<F64> {
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Some(F64(f(a.0)))
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}
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fn __floatundidf(f: extern fn(u64) -> f64,
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a: U64)
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-> Option<F64> {
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Some(F64(f(a.0)))
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}
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}
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}
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@ -1,5 +1,6 @@
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use core::mem;
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pub mod conv;
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pub mod add;
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pub mod pow;
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pub mod sub;
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@ -19,6 +20,15 @@ pub trait Float: Sized + Copy {
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fn exponent_bits() -> u32 {
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Self::bits() - Self::significand_bits() - 1
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}
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/// Returns the maximum value of the exponent
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fn exponent_max() -> u32 {
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(1 << Self::exponent_bits()) - 1
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}
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/// Returns the exponent bias value
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fn exponent_bias() -> u32 {
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Self::exponent_max() >> 1
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}
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/// Returns a mask for the sign bit
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fn sign_mask() -> Self::Int;
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@ -19,30 +19,85 @@ pub mod udiv;
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pub trait Int {
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/// Type with the same width but other signedness
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type OtherSign;
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/// Unsigned version of Self
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type UnsignedInt;
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/// Returns the bitwidth of the int type
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fn bits() -> u32;
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/// Extracts the sign from self and returns a tuple.
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///
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/// # Examples
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///
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/// ```rust,ignore
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/// let i = -25_i32;
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/// let (sign, u) = i.extract_sign();
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/// assert_eq!(sign, true);
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/// assert_eq!(u, 25_u32);
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/// ```
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fn extract_sign(self) -> (bool, Self::UnsignedInt);
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}
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macro_rules! int_impl {
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($ity:ty, $sty:ty, $bits:expr) => {
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impl Int for $ity {
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type OtherSign = $sty;
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// TODO: Once i128/u128 support lands, we'll want to add impls for those as well
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impl Int for u32 {
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type OtherSign = i32;
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type UnsignedInt = u32;
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fn bits() -> u32 {
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$bits
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32
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}
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fn extract_sign(self) -> (bool, u32) {
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(false, self)
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}
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}
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impl Int for $sty {
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type OtherSign = $ity;
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impl Int for i32 {
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type OtherSign = u32;
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type UnsignedInt = u32;
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fn bits() -> u32 {
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$bits
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32
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}
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fn extract_sign(self) -> (bool, u32) {
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if self < 0 {
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(true, !(self as u32) + 1)
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} else {
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(false, self as u32)
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}
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}
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}
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int_impl!(i32, u32, 32);
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int_impl!(i64, u64, 64);
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int_impl!(i128, u128, 128);
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impl Int for u64 {
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type OtherSign = i64;
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type UnsignedInt = u64;
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fn bits() -> u32 {
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64
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}
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fn extract_sign(self) -> (bool, u64) {
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(false, self)
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}
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}
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impl Int for i64 {
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type OtherSign = u64;
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type UnsignedInt = u64;
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fn bits() -> u32 {
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64
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}
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fn extract_sign(self) -> (bool, u64) {
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if self < 0 {
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(true, !(self as u64) + 1)
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} else {
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(false, self as u64)
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}
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}
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}
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/// Trait to convert an integer to/from smaller parts
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pub trait LargeInt {
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