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// Copyright 2017 The Abseil Authors.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// https://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#ifndef ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_
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#define ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_
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#include <cstddef>
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#include <cstdint>
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#include <limits>
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#include <type_traits>
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namespace absl {
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namespace random_internal {
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// Returns true if the input value is zero or a power of two. Useful for
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// determining if the range of output values in a URBG
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template <typename UIntType>
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constexpr bool IsPowerOfTwoOrZero(UIntType n) {
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return (n == 0) || ((n & (n - 1)) == 0);
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}
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// Computes the length of the range of values producible by the URBG, or returns
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// zero if that would encompass the entire range of representable values in
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// URBG::result_type.
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template <typename URBG>
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constexpr typename URBG::result_type RangeSize() {
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using result_type = typename URBG::result_type;
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return ((URBG::max)() == (std::numeric_limits<result_type>::max)() &&
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(URBG::min)() == std::numeric_limits<result_type>::lowest())
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? result_type{0}
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: (URBG::max)() - (URBG::min)() + result_type{1};
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}
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template <typename UIntType>
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constexpr UIntType LargestPowerOfTwoLessThanOrEqualTo(UIntType n) {
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return n < 2 ? n : 2 * LargestPowerOfTwoLessThanOrEqualTo(n / 2);
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}
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// Given a URBG generating values in the closed interval [Lo, Hi], returns the
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// largest power of two less than or equal to `Hi - Lo + 1`.
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template <typename URBG>
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constexpr typename URBG::result_type PowerOfTwoSubRangeSize() {
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return LargestPowerOfTwoLessThanOrEqualTo(RangeSize<URBG>());
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}
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// Computes the floor of the log. (i.e., std::floor(std::log2(N));
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template <typename UIntType>
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constexpr UIntType IntegerLog2(UIntType n) {
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return (n <= 1) ? 0 : 1 + IntegerLog2(n / 2);
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}
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// Returns the number of bits of randomness returned through
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// `PowerOfTwoVariate(urbg)`.
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template <typename URBG>
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constexpr size_t NumBits() {
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return RangeSize<URBG>() == 0
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? std::numeric_limits<typename URBG::result_type>::digits
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: IntegerLog2(PowerOfTwoSubRangeSize<URBG>());
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}
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// Given a shift value `n`, constructs a mask with exactly the low `n` bits set.
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// If `n == 0`, all bits are set.
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template <typename UIntType>
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constexpr UIntType MaskFromShift(UIntType n) {
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return ((n % std::numeric_limits<UIntType>::digits) == 0)
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? ~UIntType{0}
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: (UIntType{1} << n) - UIntType{1};
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}
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// FastUniformBits implements a fast path to acquire uniform independent bits
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// from a type which conforms to the [rand.req.urbg] concept.
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// Parameterized by:
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// `UIntType`: the result (output) type
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//
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// The std::independent_bits_engine [rand.adapt.ibits] adaptor can be
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// instantiated from an existing generator through a copy or a move. It does
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// not, however, facilitate the production of pseudorandom bits from an un-owned
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// generator that will outlive the std::independent_bits_engine instance.
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template <typename UIntType = uint64_t>
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class FastUniformBits {
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public:
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using result_type = UIntType;
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static constexpr result_type(min)() { return 0; }
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static constexpr result_type(max)() {
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return (std::numeric_limits<result_type>::max)();
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}
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template <typename URBG>
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result_type operator()(URBG& g); // NOLINT(runtime/references)
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private:
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static_assert(std::is_unsigned<UIntType>::value,
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"Class-template FastUniformBits<> must be parameterized using "
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"an unsigned type.");
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// PowerOfTwoVariate() generates a single random variate, always returning a
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// value in the half-open interval `[0, PowerOfTwoSubRangeSize<URBG>())`. If
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// the URBG already generates values in a power-of-two range, the generator
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// itself is used. Otherwise, we use rejection sampling on the largest
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// possible power-of-two-sized subrange.
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struct PowerOfTwoTag {};
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struct RejectionSamplingTag {};
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template <typename URBG>
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static typename URBG::result_type PowerOfTwoVariate(
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URBG& g) { // NOLINT(runtime/references)
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using tag =
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typename std::conditional<IsPowerOfTwoOrZero(RangeSize<URBG>()),
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PowerOfTwoTag, RejectionSamplingTag>::type;
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return PowerOfTwoVariate(g, tag{});
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}
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template <typename URBG>
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static typename URBG::result_type PowerOfTwoVariate(
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URBG& g, // NOLINT(runtime/references)
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PowerOfTwoTag) {
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return g() - (URBG::min)();
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}
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template <typename URBG>
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static typename URBG::result_type PowerOfTwoVariate(
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URBG& g, // NOLINT(runtime/references)
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RejectionSamplingTag) {
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// Use rejection sampling to ensure uniformity across the range.
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typename URBG::result_type u;
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do {
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u = g() - (URBG::min)();
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} while (u >= PowerOfTwoSubRangeSize<URBG>());
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return u;
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}
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// Generate() generates a random value, dispatched on whether
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// the underlying URBG must loop over multiple calls or not.
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template <typename URBG>
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result_type Generate(URBG& g, // NOLINT(runtime/references)
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std::true_type /* avoid_looping */);
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template <typename URBG>
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result_type Generate(URBG& g, // NOLINT(runtime/references)
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std::false_type /* avoid_looping */);
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};
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template <typename UIntType>
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template <typename URBG>
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typename FastUniformBits<UIntType>::result_type
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FastUniformBits<UIntType>::operator()(URBG& g) { // NOLINT(runtime/references)
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// kRangeMask is the mask used when sampling variates from the URBG when the
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// width of the URBG range is not a power of 2.
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// Y = (2 ^ kRange) - 1
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static_assert((URBG::max)() > (URBG::min)(),
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"URBG::max and URBG::min may not be equal.");
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using urbg_result_type = typename URBG::result_type;
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constexpr urbg_result_type kRangeMask =
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RangeSize<URBG>() == 0
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? (std::numeric_limits<urbg_result_type>::max)()
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: static_cast<urbg_result_type>(PowerOfTwoSubRangeSize<URBG>() - 1);
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return Generate(g, std::integral_constant<bool, (kRangeMask >= (max)())>{});
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}
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template <typename UIntType>
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template <typename URBG>
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typename FastUniformBits<UIntType>::result_type
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FastUniformBits<UIntType>::Generate(URBG& g, // NOLINT(runtime/references)
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std::true_type /* avoid_looping */) {
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// The width of the result_type is less than than the width of the random bits
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// provided by URBG. Thus, generate a single value and then simply mask off
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// the required bits.
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return PowerOfTwoVariate(g) & (max)();
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}
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template <typename UIntType>
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template <typename URBG>
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typename FastUniformBits<UIntType>::result_type
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FastUniformBits<UIntType>::Generate(URBG& g, // NOLINT(runtime/references)
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std::false_type /* avoid_looping */) {
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// See [rand.adapt.ibits] for more details on the constants calculated below.
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//
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// It is preferable to use roughly the same number of bits from each generator
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// call, however this is only possible when the number of bits provided by the
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// URBG is a divisor of the number of bits in `result_type`. In all other
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// cases, the number of bits used cannot always be the same, but it can be
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// guaranteed to be off by at most 1. Thus we run two loops, one with a
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// smaller bit-width size (`kSmallWidth`) and one with a larger width size
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// (satisfying `kLargeWidth == kSmallWidth + 1`). The loops are run
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// `kSmallIters` and `kLargeIters` times respectively such
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// that
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//
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// `kTotalWidth == kSmallIters * kSmallWidth
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// + kLargeIters * kLargeWidth`
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//
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// where `kTotalWidth` is the total number of bits in `result_type`.
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//
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constexpr size_t kTotalWidth = std::numeric_limits<result_type>::digits;
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constexpr size_t kUrbgWidth = NumBits<URBG>();
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constexpr size_t kTotalIters =
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kTotalWidth / kUrbgWidth + (kTotalWidth % kUrbgWidth != 0);
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constexpr size_t kSmallWidth = kTotalWidth / kTotalIters;
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constexpr size_t kLargeWidth = kSmallWidth + 1;
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//
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// Because `kLargeWidth == kSmallWidth + 1`, it follows that
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//
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// `kTotalWidth == kTotalIters * kSmallWidth + kLargeIters`
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//
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// and therefore
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//
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// `kLargeIters == kTotalWidth % kSmallWidth`
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//
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// Intuitively, each iteration with the large width accounts for one unit
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// of the remainder when `kTotalWidth` is divided by `kSmallWidth`. As
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// mentioned above, if the URBG width is a divisor of `kTotalWidth`, then
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// there would be no need for any large iterations (i.e., one loop would
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// suffice), and indeed, in this case, `kLargeIters` would be zero.
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constexpr size_t kLargeIters = kTotalWidth % kSmallWidth;
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constexpr size_t kSmallIters =
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(kTotalWidth - (kLargeWidth * kLargeIters)) / kSmallWidth;
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static_assert(
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kTotalWidth == kSmallIters * kSmallWidth + kLargeIters * kLargeWidth,
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"Error in looping constant calculations.");
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result_type s = 0;
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constexpr size_t kSmallShift = kSmallWidth % kTotalWidth;
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constexpr result_type kSmallMask = MaskFromShift(result_type{kSmallShift});
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for (size_t n = 0; n < kSmallIters; ++n) {
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s = (s << kSmallShift) +
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(static_cast<result_type>(PowerOfTwoVariate(g)) & kSmallMask);
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}
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constexpr size_t kLargeShift = kLargeWidth % kTotalWidth;
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constexpr result_type kLargeMask = MaskFromShift(result_type{kLargeShift});
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for (size_t n = 0; n < kLargeIters; ++n) {
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s = (s << kLargeShift) +
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(static_cast<result_type>(PowerOfTwoVariate(g)) & kLargeMask);
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}
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static_assert(
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kLargeShift == kSmallShift + 1 ||
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(kLargeShift == 0 &&
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kSmallShift == std::numeric_limits<result_type>::digits - 1),
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"Error in looping constant calculations");
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return s;
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}
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} // namespace random_internal
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} // namespace absl
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#endif // ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_
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