Files

aho_corasick

packed

teddy

compile.rsmod.rsruntime.rs

api.rsmod.rspattern.rsrabinkarp.rsvector.rs

ahocorasick.rsautomaton.rsbuffer.rsbyte_frequencies.rsclasses.rsdfa.rserror.rslib.rsnfa.rsprefilter.rsstate_id.rs

ansi_term

ansi.rsdebug.rsdifference.rsdisplay.rslib.rsstyle.rswindows.rswrite.rs

atty

lib.rs

backtrace

backtrace

libunwind.rsmod.rs

symbolize

dladdr.rslibbacktrace.rsmod.rs

capture.rslib.rsprint.rstypes.rs

backtrace_sys

lib.rs

bitflags

lib.rs

blindbid

blindbid.rsbuffer.rsgadgets.rsmain.rspipe.rs

block_buffer

lib.rs

block_padding

lib.rs

bulletproofs

r1cs

constraint_system.rslinear_combination.rsmod.rsproof.rsprover.rsverifier.rs

range_proof

dealer.rsmessages.rsmod.rsparty.rs

errors.rsgenerators.rsinner_product_proof.rslib.rstranscript.rsutil.rs

byte_tools

lib.rs

byteorder

io.rslib.rs

cfg_if

lib.rs

chrono

format

mod.rsparse.rsparsed.rsscan.rsstrftime.rs

naive

date.rsdatetime.rsinternals.rsisoweek.rstime.rs

offset

fixed.rslocal.rsmod.rsutc.rs

date.rsdatetime.rsdiv.rslib.rsround.rs

clap

app

help.rsmeta.rsmod.rsparser.rssettings.rsusage.rsvalidator.rs

args

arg_builder

base.rsflag.rsmod.rsoption.rspositional.rsswitched.rsvalued.rs

any_arg.rsarg.rsarg_matcher.rsarg_matches.rsgroup.rsmacros.rsmatched_arg.rsmod.rssettings.rssubcommand.rs

completions

bash.rselvish.rsfish.rsmacros.rsmod.rspowershell.rsshell.rszsh.rs

errors.rsfmt.rslib.rsmacros.rsmap.rsosstringext.rsstrext.rssuggestions.rsusage_parser.rs

clear_on_drop

clear.rsclear_on_drop.rsclear_stack_on_return.rsfnoption.rshide.rslib.rs

curve25519_dalek

backend

serial

curve_models

mod.rs

scalar_mul

mod.rspippenger.rsprecomputed_straus.rsstraus.rsvariable_base.rsvartime_double_base.rs

u64

constants.rsfield.rsmod.rsscalar.rs

mod.rs

mod.rs

constants.rsedwards.rsfield.rslib.rsmacros.rsmontgomery.rsprelude.rsristretto.rsscalar.rstraits.rswindow.rs

digest

digest.rsdyn_digest.rserrors.rslib.rs

dusk_blindbidproof

blindbid

mod.rsproof.rsverify.rs

futures

main.rsmod.rsprove.rsverify.rs

error.rsgadgets.rslib.rs

dusk_tlv

error.rslib.rsreader.rswriter.rs

dusk_uds

communication.rslib.rsoptions.rsuds.rsworker.rs

env_logger

filter

mod.rsregex.rs

fmt

humantime

extern_impl.rsmod.rs

writer

termcolor

extern_impl.rsmod.rs

atty.rsmod.rs

mod.rs

lib.rs

failure

backtrace

mod.rs

as_fail.rscompat.rscontext.rslib.rsresult_ext.rs

failure_derive

lib.rs

fake_simd

lib.rs

futures

lib.rs

futures_channel

mpsc

mod.rsqueue.rssink_impl.rs

lib.rslock.rsoneshot.rs

futures_core

task

__internal

atomic_waker.rsmod.rs

mod.rspoll.rs

future.rslib.rsstream.rs

futures_executor

enter.rslib.rslocal_pool.rs

futures_io

lib.rs

futures_macro

join.rslib.rsselect.rs

futures_sink

lib.rs

futures_task

arc_wake.rsfuture_obj.rslib.rsnoop_waker.rsspawn.rswaker.rswaker_ref.rs

futures_util

async_await

join_mod.rsmod.rspending.rspoll.rsrandom.rsselect_mod.rs

future

future

catch_unwind.rschain.rsflatten.rsflatten_stream.rsfuse.rsinspect.rsinto_stream.rsmap.rsmod.rsnever_error.rsremote_handle.rsshared.rsthen.rsunit_error.rs

try_future

and_then.rserr_into.rsflatten_sink.rsflatten_stream_sink.rsinspect_err.rsinspect_ok.rsinto_future.rsmap_err.rsmap_ok.rsmod.rsor_else.rstry_chain.rstry_flatten_stream.rsunwrap_or_else.rs

abortable.rseither.rsjoin.rsjoin_all.rslazy.rsmaybe_done.rsmod.rsoption.rspending.rspoll_fn.rsready.rsselect.rsselect_all.rsselect_ok.rstry_join.rstry_join_all.rstry_select.rs

io

allow_std.rsbuf_reader.rsbuf_writer.rschain.rsclose.rscopy.rscopy_buf.rscursor.rsempty.rsflush.rsinto_sink.rslines.rsmod.rsread.rsread_exact.rsread_line.rsread_to_end.rsread_to_string.rsread_until.rsread_vectored.rsrepeat.rsseek.rssink.rssplit.rstake.rswindow.rswrite.rswrite_all.rswrite_vectored.rs

lock

bilock.rsmod.rsmutex.rs

sink

buffer.rsclose.rsdrain.rserr_into.rsfanout.rsflush.rsmap_err.rsmod.rssend.rssend_all.rswith.rswith_flat_map.rs

stream

futures_unordered

abort.rsiter.rsmod.rsready_to_run_queue.rstask.rs

stream

buffer_unordered.rsbuffered.rscatch_unwind.rschain.rschunks.rscollect.rsconcat.rsenumerate.rsfilter.rsfilter_map.rsflatten.rsfold.rsfor_each.rsfor_each_concurrent.rsforward.rsfuse.rsinspect.rsinto_future.rsmap.rsmod.rsnext.rspeek.rsselect_next_some.rsskip.rsskip_while.rssplit.rstake.rstake_while.rsthen.rszip.rs

try_stream

and_then.rserr_into.rsinspect_err.rsinspect_ok.rsinto_async_read.rsinto_stream.rsmap_err.rsmap_ok.rsmod.rsor_else.rstry_buffer_unordered.rstry_collect.rstry_concat.rstry_filter.rstry_filter_map.rstry_flatten.rstry_fold.rstry_for_each.rstry_for_each_concurrent.rstry_next.rstry_skip_while.rs

empty.rsfutures_ordered.rsiter.rsmod.rsonce.rspending.rspoll_fn.rsrepeat.rsselect.rsselect_all.rsunfold.rs

task

mod.rsspawn.rs

lib.rsnever.rs

generic_array

arr.rsfunctional.rshex.rsimpls.rsiter.rslib.rssequence.rs

humantime

date.rsduration.rslib.rswrapper.rs

keccak

lib.rs

lazy_static

inline_lazy.rslib.rs

libc

unix

linux_like

linux

gnu

b64

x86_64

align.rsmod.rsnot_x32.rs

mod.rs

align.rsmod.rs

align.rsmod.rs

mod.rs

align.rsmod.rs

fixed_width_ints.rslib.rsmacros.rs

log

lib.rsmacros.rs

memchr

x86

avx.rsmod.rssse2.rs

fallback.rsiter.rslib.rsnaive.rs

merlin

constants.rslib.rsstrobe.rstranscript.rs

num_cpus

lib.rs

num_integer

lib.rsroots.rs

num_traits

ops

checked.rsinv.rsmod.rsmul_add.rssaturating.rswrapping.rs

bounds.rscast.rsfloat.rsidentities.rsint.rslib.rsmacros.rspow.rssign.rs

opaque_debug

lib.rs

packed_simd

api

cast

macros.rsv128.rsv16.rsv256.rsv32.rsv512.rsv64.rs

cmp

eq.rsord.rspartial_eq.rspartial_ord.rsvertical.rs

fmt

binary.rsdebug.rslower_hex.rsoctal.rsupper_hex.rs

from

from_array.rsfrom_vector.rs

into_bits

arch_specific.rsmacros.rsv128.rsv16.rsv256.rsv32.rsv512.rsv64.rs

math

float

abs.rsconsts.rscos.rsexp.rsln.rsmul_add.rsmul_adde.rspowf.rsrecpre.rsrsqrte.rssin.rssqrt.rssqrte.rs

float.rs

minimal

iuf.rsmask.rsptr.rs

ops

scalar_arithmetic.rsscalar_bitwise.rsscalar_mask_bitwise.rsscalar_shifts.rsvector_arithmetic.rsvector_bitwise.rsvector_float_min_max.rsvector_int_min_max.rsvector_mask_bitwise.rsvector_neg.rsvector_rotates.rsvector_shifts.rs

ptr

gather_scatter.rs

reductions

bitwise.rsfloat_arithmetic.rsinteger_arithmetic.rsmask.rsmin_max.rs

slice

from_slice.rswrite_to_slice.rs

bit_manip.rsbitmask.rscast.rscmp.rsdefault.rsfmt.rsfrom.rshash.rsinto_bits.rsmath.rsminimal.rsops.rsptr.rsreductions.rsselect.rsshuffle.rsshuffle1_dyn.rsslice.rsswap_bytes.rs

codegen

math

float

abs.rscos.rscos_pi.rsexp.rsln.rsmacros.rsmul_add.rsmul_adde.rspowf.rssin.rssin_cos_pi.rssin_pi.rssqrt.rssqrte.rs

float.rs

reductions

mask

x86

sse.rssse2.rs

fallback_impl.rsx86.rs

mask.rs

bit_manip.rsllvm.rsmath.rspointer_sized_int.rsreductions.rsshuffle.rsshuffle1_dyn.rsswap_bytes.rsv128.rsv16.rsv256.rsv32.rsv512.rsv64.rsvPtr.rsvSize.rs

testing

macros.rs

api.rscodegen.rslib.rsmasks.rssealed.rstesting.rsv128.rsv16.rsv256.rsv32.rsv512.rsv64.rsvPtr.rsvSize.rs

pin_utils

lib.rsprojection.rsstack_pin.rs

proc_macro2

fallback.rslib.rsstrnom.rswrapper.rs

proc_macro_hack

lib.rs

proc_macro_nested

lib.rs

quick_error

lib.rs

quote

ext.rsformat.rsident_fragment.rslib.rsruntime.rsspanned.rsto_tokens.rs

rand

distributions

bernoulli.rsbinomial.rscauchy.rsdirichlet.rsexponential.rsfloat.rsgamma.rsinteger.rsmod.rsnormal.rsother.rspareto.rspoisson.rstriangular.rsuniform.rsunit_circle.rsunit_sphere.rsutils.rsweibull.rsweighted.rsziggurat_tables.rs

prng

mod.rs

rngs

adapter

mod.rsread.rsreseeding.rs

entropy.rsmock.rsmod.rssmall.rsstd.rsthread.rs

seq

index.rsmod.rs

deprecated.rslib.rsprelude.rs

rand_chacha

chacha.rslib.rs

rand_core

lib.rs

rand_hc

hc128.rslib.rs

rand_isaac

isaac.rsisaac64.rsisaac_array.rslib.rs

rand_jitter

dummy_log.rserror.rslib.rsplatform.rs

rand_os

dummy_log.rslib.rslinux_android.rsrandom_device.rs

rand_pcg

lib.rspcg128.rspcg64.rs

rand_xorshift

lib.rs

regex

literal

imp.rsmod.rs

backtrack.rscache.rscompile.rsdfa.rserror.rsexec.rsexpand.rsfind_byte.rsfreqs.rsinput.rslib.rspikevm.rsprog.rsre_builder.rsre_bytes.rsre_set.rsre_trait.rsre_unicode.rssparse.rsutf8.rs

regex_syntax

ast

mod.rsparse.rsprint.rsvisitor.rs

hir

literal

mod.rs

interval.rsmod.rsprint.rstranslate.rsvisitor.rs

unicode_tables

age.rscase_folding_simple.rsgeneral_category.rsgrapheme_cluster_break.rsmod.rsperl_word.rsproperty_bool.rsproperty_names.rsproperty_values.rsscript.rsscript_extension.rssentence_break.rsword_break.rs

either.rserror.rslib.rsparser.rsunicode.rsutf8.rs

rustc_demangle

legacy.rslib.rsv0.rs

serde

de

from_primitive.rsignored_any.rsimpls.rsmod.rsutf8.rsvalue.rs

private

de.rsmacros.rsmod.rsser.rs

ser

impls.rsimpossible.rsmod.rs

export.rsinteger128.rslib.rsmacros.rs

serde_derive

internals

ast.rsattr.rscase.rscheck.rsctxt.rsmod.rssymbol.rs

bound.rsde.rsdummy.rsfragment.rslib.rspretend.rsser.rstry.rs

sha2

consts.rslib.rssha256.rssha256_utils.rssha512.rssha512_utils.rs

sha3

lib.rsmacros.rspaddings.rsreader.rsstate.rs

slab

lib.rs

strsim

lib.rs

subtle

lib.rs

syn

gen

gen_helper.rsvisit.rs

attr.rsbigint.rsbuffer.rscustom_keyword.rscustom_punctuation.rsdata.rsderive.rsdiscouraged.rserror.rsexport.rsexpr.rsext.rsfile.rsgenerics.rsgroup.rsident.rsitem.rslib.rslifetime.rslit.rslookahead.rsmac.rsmacros.rsop.rsparse.rsparse_macro_input.rsparse_quote.rspat.rspath.rsprint.rspunctuated.rssealed.rsspan.rsspanned.rsstmt.rsthread.rstoken.rstt.rsty.rs

synstructure

lib.rsmacros.rs

termcolor

lib.rs

textwrap

indentation.rslib.rssplitting.rs

thread_local

lib.rsthread_id.rsunreachable.rs

time

display.rsduration.rslib.rsparse.rssys.rs

typenum

array.rsbit.rsint.rslib.rsmarker_traits.rsoperator_aliases.rsprivate.rstype_operators.rsuint.rs

unicode_width

lib.rstables.rs

unicode_xid

lib.rstables.rs

vec_map

lib.rs

>

// Copyright 2018 Developers of the Rand project.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// https://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or https://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.

//! Basic floating-point number distributions

use core::mem;
use Rng;
use distributions::{Distribution, Standard};
use distributions::utils::FloatSIMDUtils;
#[cfg(feature="simd_support")]
use packed_simd::*;

/// A distribution to sample floating point numbers uniformly in the half-open
/// interval `(0, 1]`, i.e. including 1 but not 0.
///
/// All values that can be generated are of the form `n * ε/2`. For `f32`
/// the 23 most significant random bits of a `u32` are used and for `f64` the
/// 53 most significant bits of a `u64` are used. The conversion uses the
/// multiplicative method.
///
/// See also: [`Standard`] which samples from `[0, 1)`, [`Open01`]
/// which samples from `(0, 1)` and [`Uniform`] which samples from arbitrary
/// ranges.
///
/// # Example
/// ```
/// use rand::{thread_rng, Rng};
/// use rand::distributions::OpenClosed01;
///
/// let val: f32 = thread_rng().sample(OpenClosed01);
/// println!("f32 from (0, 1): {}", val);
/// ```
///
/// [`Standard`]: crate::distributions::Standard
/// [`Open01`]: crate::distributions::Open01
/// [`Uniform`]: crate::distributions::uniform::Uniform
#[derive(Clone, Copy, Debug)]
pub struct OpenClosed01;

/// A distribution to sample floating point numbers uniformly in the open
/// interval `(0, 1)`, i.e. not including either endpoint.
///
/// All values that can be generated are of the form `n * ε + ε/2`. For `f32`
/// the 22 most significant random bits of an `u32` are used, for `f64` 52 from
/// an `u64`. The conversion uses a transmute-based method.
///
/// See also: [`Standard`] which samples from `[0, 1)`, [`OpenClosed01`]
/// which samples from `(0, 1]` and [`Uniform`] which samples from arbitrary
/// ranges.
///
/// # Example
/// ```
/// use rand::{thread_rng, Rng};
/// use rand::distributions::Open01;
///
/// let val: f32 = thread_rng().sample(Open01);
/// println!("f32 from (0, 1): {}", val);
/// ```
///
/// [`Standard`]: crate::distributions::Standard
/// [`OpenClosed01`]: crate::distributions::OpenClosed01
/// [`Uniform`]: crate::distributions::uniform::Uniform
#[derive(Clone, Copy, Debug)]
pub struct Open01;


pub(crate) trait IntoFloat {
    type F;

    /// Helper method to combine the fraction and a contant exponent into a
    /// float.
    ///
    /// Only the least significant bits of `self` may be set, 23 for `f32` and
    /// 52 for `f64`.
    /// The resulting value will fall in a range that depends on the exponent.
    /// As an example the range with exponent 0 will be
    /// [2<sup>0</sup>..2<sup>1</sup>), which is [1..2).
    fn into_float_with_exponent(self, exponent: i32) -> Self::F;
}

macro_rules! float_impls {
    ($ty:ident, $uty:ident, $f_scalar:ident, $u_scalar:ty,
     $fraction_bits:expr, $exponent_bias:expr) => {
        impl IntoFloat for $uty {
            type F = $ty;
            #[inline(always)]
            fn into_float_with_exponent(self, exponent: i32) -> $ty {
                // The exponent is encoded using an offset-binary representation
                let exponent_bits: $u_scalar =
                    (($exponent_bias + exponent) as $u_scalar) << $fraction_bits;
                // TODO: use from_bits when min compiler > 1.25 (see #545)
                // $ty::from_bits(self | exponent_bits)
                unsafe{ mem::transmute(self | exponent_bits) }
            }
        }

        impl Distribution<$ty> for Standard {
            fn sample<R: Rng + ?Sized>(&self, rng: &mut R) -> $ty {
                // Multiply-based method; 24/53 random bits; [0, 1) interval.
                // We use the most significant bits because for simple RNGs
                // those are usually more random.
                let float_size = mem::size_of::<$f_scalar>() as u32 * 8;
                let precision = $fraction_bits + 1;
                let scale = 1.0 / ((1 as $u_scalar << precision) as $f_scalar);

                let value: $uty = rng.gen();
                let value = value >> (float_size - precision);
                scale * $ty::cast_from_int(value)
            }
        }

        impl Distribution<$ty> for OpenClosed01 {
            fn sample<R: Rng + ?Sized>(&self, rng: &mut R) -> $ty {
                // Multiply-based method; 24/53 random bits; (0, 1] interval.
                // We use the most significant bits because for simple RNGs
                // those are usually more random.
                let float_size = mem::size_of::<$f_scalar>() as u32 * 8;
                let precision = $fraction_bits + 1;
                let scale = 1.0 / ((1 as $u_scalar << precision) as $f_scalar);

                let value: $uty = rng.gen();
                let value = value >> (float_size - precision);
                // Add 1 to shift up; will not overflow because of right-shift:
                scale * $ty::cast_from_int(value + 1)
            }
        }

        impl Distribution<$ty> for Open01 {
            fn sample<R: Rng + ?Sized>(&self, rng: &mut R) -> $ty {
                // Transmute-based method; 23/52 random bits; (0, 1) interval.
                // We use the most significant bits because for simple RNGs
                // those are usually more random.
                use core::$f_scalar::EPSILON;
                let float_size = mem::size_of::<$f_scalar>() as u32 * 8;

                let value: $uty = rng.gen();
                let fraction = value >> (float_size - $fraction_bits);
                fraction.into_float_with_exponent(0) - (1.0 - EPSILON / 2.0)
            }
        }
    }
}

float_impls! { f32, u32, f32, u32, 23, 127 }
float_impls! { f64, u64, f64, u64, 52, 1023 }

#[cfg(feature="simd_support")]
float_impls! { f32x2, u32x2, f32, u32, 23, 127 }
#[cfg(feature="simd_support")]
float_impls! { f32x4, u32x4, f32, u32, 23, 127 }
#[cfg(feature="simd_support")]
float_impls! { f32x8, u32x8, f32, u32, 23, 127 }
#[cfg(feature="simd_support")]
float_impls! { f32x16, u32x16, f32, u32, 23, 127 }

#[cfg(feature="simd_support")]
float_impls! { f64x2, u64x2, f64, u64, 52, 1023 }
#[cfg(feature="simd_support")]
float_impls! { f64x4, u64x4, f64, u64, 52, 1023 }
#[cfg(feature="simd_support")]
float_impls! { f64x8, u64x8, f64, u64, 52, 1023 }


#[cfg(test)]
mod tests {
    use Rng;
    use distributions::{Open01, OpenClosed01};
    use rngs::mock::StepRng;
    #[cfg(feature="simd_support")]
    use packed_simd::*;

    const EPSILON32: f32 = ::core::f32::EPSILON;
    const EPSILON64: f64 = ::core::f64::EPSILON;

    macro_rules! test_f32 {
        ($fnn:ident, $ty:ident, $ZERO:expr, $EPSILON:expr) => {
            #[test]
            fn $fnn() {
                // Standard
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.gen::<$ty>(), $ZERO);
                let mut one = StepRng::new(1 << 8 | 1 << (8 + 32), 0);
                assert_eq!(one.gen::<$ty>(), $EPSILON / 2.0);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.gen::<$ty>(), 1.0 - $EPSILON / 2.0);

                // OpenClosed01
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.sample::<$ty, _>(OpenClosed01),
                           0.0 + $EPSILON / 2.0);
                let mut one = StepRng::new(1 << 8 | 1 << (8 + 32), 0);
                assert_eq!(one.sample::<$ty, _>(OpenClosed01), $EPSILON);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.sample::<$ty, _>(OpenClosed01), $ZERO + 1.0);

                // Open01
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.sample::<$ty, _>(Open01), 0.0 + $EPSILON / 2.0);
                let mut one = StepRng::new(1 << 9 | 1 << (9 + 32), 0);
                assert_eq!(one.sample::<$ty, _>(Open01), $EPSILON / 2.0 * 3.0);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.sample::<$ty, _>(Open01), 1.0 - $EPSILON / 2.0);
            }
        }
    }
    test_f32! { f32_edge_cases, f32, 0.0, EPSILON32 }
    #[cfg(feature="simd_support")]
    test_f32! { f32x2_edge_cases, f32x2, f32x2::splat(0.0), f32x2::splat(EPSILON32) }
    #[cfg(feature="simd_support")]
    test_f32! { f32x4_edge_cases, f32x4, f32x4::splat(0.0), f32x4::splat(EPSILON32) }
    #[cfg(feature="simd_support")]
    test_f32! { f32x8_edge_cases, f32x8, f32x8::splat(0.0), f32x8::splat(EPSILON32) }
    #[cfg(feature="simd_support")]
    test_f32! { f32x16_edge_cases, f32x16, f32x16::splat(0.0), f32x16::splat(EPSILON32) }

    macro_rules! test_f64 {
        ($fnn:ident, $ty:ident, $ZERO:expr, $EPSILON:expr) => {
            #[test]
            fn $fnn() {
                // Standard
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.gen::<$ty>(), $ZERO);
                let mut one = StepRng::new(1 << 11, 0);
                assert_eq!(one.gen::<$ty>(), $EPSILON / 2.0);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.gen::<$ty>(), 1.0 - $EPSILON / 2.0);

                // OpenClosed01
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.sample::<$ty, _>(OpenClosed01),
                           0.0 + $EPSILON / 2.0);
                let mut one = StepRng::new(1 << 11, 0);
                assert_eq!(one.sample::<$ty, _>(OpenClosed01), $EPSILON);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.sample::<$ty, _>(OpenClosed01), $ZERO + 1.0);

                // Open01
                let mut zeros = StepRng::new(0, 0);
                assert_eq!(zeros.sample::<$ty, _>(Open01), 0.0 + $EPSILON / 2.0);
                let mut one = StepRng::new(1 << 12, 0);
                assert_eq!(one.sample::<$ty, _>(Open01), $EPSILON / 2.0 * 3.0);
                let mut max = StepRng::new(!0, 0);
                assert_eq!(max.sample::<$ty, _>(Open01), 1.0 - $EPSILON / 2.0);
            }
        }
    }
    test_f64! { f64_edge_cases, f64, 0.0, EPSILON64 }
    #[cfg(feature="simd_support")]
    test_f64! { f64x2_edge_cases, f64x2, f64x2::splat(0.0), f64x2::splat(EPSILON64) }
    #[cfg(feature="simd_support")]
    test_f64! { f64x4_edge_cases, f64x4, f64x4::splat(0.0), f64x4::splat(EPSILON64) }
    #[cfg(feature="simd_support")]
    test_f64! { f64x8_edge_cases, f64x8, f64x8::splat(0.0), f64x8::splat(EPSILON64) }
}