// Copyright 2017 The Abseil Authors.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#ifndef ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_
#define ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_
#include <cstddef>
#include <cstdint>
#include <limits>
#include <type_traits>
#include "absl/base/config.h"
#include "absl/meta/type_traits.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace random_internal {
// Returns true if the input value is zero or a power of two. Useful for
// determining if the range of output values in a URBG
template <typename UIntType>
constexpr bool IsPowerOfTwoOrZero(UIntType n) {
return (n == 0) || ((n & (n - 1)) == 0);
}
// Computes the length of the range of values producible by the URBG, or returns
// zero if that would encompass the entire range of representable values in
// URBG::result_type.
template <typename URBG>
constexpr typename URBG::result_type RangeSize() {
using result_type = typename URBG::result_type;
static_assert((URBG::max)() != (URBG::min)(), "URBG range cannot be 0.");
return ((URBG::max)() == (std::numeric_limits<result_type>::max)() &&
(URBG::min)() == std::numeric_limits<result_type>::lowest())
? result_type{0}
: ((URBG::max)() - (URBG::min)() + result_type{1});
}
// Computes the floor of the log. (i.e., std::floor(std::log2(N));
template <typename UIntType>
constexpr UIntType IntegerLog2(UIntType n) {
return (n <= 1) ? 0 : 1 + IntegerLog2(n >> 1);
}
// Returns the number of bits of randomness returned through
// `PowerOfTwoVariate(urbg)`.
template <typename URBG>
constexpr size_t NumBits() {
return RangeSize<URBG>() == 0
? std::numeric_limits<typename URBG::result_type>::digits
: IntegerLog2(RangeSize<URBG>());
}
// Given a shift value `n`, constructs a mask with exactly the low `n` bits set.
// If `n == 0`, all bits are set.
template <typename UIntType>
constexpr UIntType MaskFromShift(size_t n) {
return ((n % std::numeric_limits<UIntType>::digits) == 0)
? ~UIntType{0}
: (UIntType{1} << n) - UIntType{1};
}
// Tags used to dispatch FastUniformBits::generate to the simple or more complex
// entropy extraction algorithm.
struct SimplifiedLoopTag {};
struct RejectionLoopTag {};
// FastUniformBits implements a fast path to acquire uniform independent bits
// from a type which conforms to the [rand.req.urbg] concept.
// Parameterized by:
// `UIntType`: the result (output) type
//
// The std::independent_bits_engine [rand.adapt.ibits] adaptor can be
// instantiated from an existing generator through a copy or a move. It does
// not, however, facilitate the production of pseudorandom bits from an un-owned
// generator that will outlive the std::independent_bits_engine instance.
template <typename UIntType = uint64_t>
class FastUniformBits {
public:
using result_type = UIntType;
static constexpr result_type(min)() { return 0; }
static constexpr result_type(max)() {
return (std::numeric_limits<result_type>::max)();
}
template <typename URBG>
result_type operator()(URBG& g); // NOLINT(runtime/references)
private:
static_assert(std::is_unsigned<UIntType>::value,
"Class-template FastUniformBits<> must be parameterized using "
"an unsigned type.");
// Generate() generates a random value, dispatched on whether
// the underlying URBG must use rejection sampling to generate a value,
// or whether a simplified loop will suffice.
template <typename URBG>
result_type Generate(URBG& g, // NOLINT(runtime/references)
SimplifiedLoopTag);
template <typename URBG>
result_type Generate(URBG& g, // NOLINT(runtime/references)
RejectionLoopTag);
};
template <typename UIntType>
template <typename URBG>
typename FastUniformBits<UIntType>::result_type
FastUniformBits<UIntType>::operator()(URBG& g) { // NOLINT(runtime/references)
// kRangeMask is the mask used when sampling variates from the URBG when the
// width of the URBG range is not a power of 2.
// Y = (2 ^ kRange) - 1
static_assert((URBG::max)() > (URBG::min)(),
"URBG::max and URBG::min may not be equal.");
using tag = absl::conditional_t<IsPowerOfTwoOrZero(RangeSize<URBG>()),
SimplifiedLoopTag, RejectionLoopTag>;
return Generate(g, tag{});
}
template <typename UIntType>
template <typename URBG>
typename FastUniformBits<UIntType>::result_type
FastUniformBits<UIntType>::Generate(URBG& g, // NOLINT(runtime/references)
SimplifiedLoopTag) {
// The simplified version of FastUniformBits works only on URBGs that have
// a range that is a power of 2. In this case we simply loop and shift without
// attempting to balance the bits across calls.
static_assert(IsPowerOfTwoOrZero(RangeSize<URBG>()),
"incorrect Generate tag for URBG instance");
static constexpr size_t kResultBits =
std::numeric_limits<result_type>::digits;
static constexpr size_t kUrbgBits = NumBits<URBG>();
static constexpr size_t kIters =
(kResultBits / kUrbgBits) + (kResultBits % kUrbgBits != 0);
static constexpr size_t kShift = (kIters == 1) ? 0 : kUrbgBits;
static constexpr auto kMin = (URBG::min)();
result_type r = static_cast<result_type>(g() - kMin);
for (size_t n = 1; n < kIters; ++n) {
r = (r << kShift) + static_cast<result_type>(g() - kMin);
}
return r;
}
template <typename UIntType>
template <typename URBG>
typename FastUniformBits<UIntType>::result_type
FastUniformBits<UIntType>::Generate(URBG& g, // NOLINT(runtime/references)
RejectionLoopTag) {
static_assert(!IsPowerOfTwoOrZero(RangeSize<URBG>()),
"incorrect Generate tag for URBG instance");
using urbg_result_type = typename URBG::result_type;
// See [rand.adapt.ibits] for more details on the constants calculated below.
//
// It is preferable to use roughly the same number of bits from each generator
// call, however this is only possible when the number of bits provided by the
// URBG is a divisor of the number of bits in `result_type`. In all other
// cases, the number of bits used cannot always be the same, but it can be
// guaranteed to be off by at most 1. Thus we run two loops, one with a
// smaller bit-width size (`kSmallWidth`) and one with a larger width size
// (satisfying `kLargeWidth == kSmallWidth + 1`). The loops are run
// `kSmallIters` and `kLargeIters` times respectively such
// that
//
// `kResultBits == kSmallIters * kSmallBits
// + kLargeIters * kLargeBits`
//
// where `kResultBits` is the total number of bits in `result_type`.
//
static constexpr size_t kResultBits =
std::numeric_limits<result_type>::digits; // w
static constexpr urbg_result_type kUrbgRange = RangeSize<URBG>(); // R
static constexpr size_t kUrbgBits = NumBits<URBG>(); // m
// compute the initial estimate of the bits used.
// [rand.adapt.ibits] 2 (c)
static constexpr size_t kA = // ceil(w/m)
(kResultBits / kUrbgBits) + ((kResultBits % kUrbgBits) != 0); // n'
static constexpr size_t kABits = kResultBits / kA; // w0'
static constexpr urbg_result_type kARejection =
((kUrbgRange >> kABits) << kABits); // y0'
// refine the selection to reduce the rejection frequency.
static constexpr size_t kTotalIters =
((kUrbgRange - kARejection) <= (kARejection / kA)) ? kA : (kA + 1); // n
// [rand.adapt.ibits] 2 (b)
static constexpr size_t kSmallIters =
kTotalIters - (kResultBits % kTotalIters); // n0
static constexpr size_t kSmallBits = kResultBits / kTotalIters; // w0
static constexpr urbg_result_type kSmallRejection =
((kUrbgRange >> kSmallBits) << kSmallBits); // y0
static constexpr size_t kLargeBits = kSmallBits + 1; // w0+1
static constexpr urbg_result_type kLargeRejection =
((kUrbgRange >> kLargeBits) << kLargeBits); // y1
//
// Because `kLargeBits == kSmallBits + 1`, it follows that
//
// `kResultBits == kSmallIters * kSmallBits + kLargeIters`
//
// and therefore
//
// `kLargeIters == kTotalWidth % kSmallWidth`
//
// Intuitively, each iteration with the large width accounts for one unit
// of the remainder when `kTotalWidth` is divided by `kSmallWidth`. As
// mentioned above, if the URBG width is a divisor of `kTotalWidth`, then
// there would be no need for any large iterations (i.e., one loop would
// suffice), and indeed, in this case, `kLargeIters` would be zero.
static_assert(kResultBits == kSmallIters * kSmallBits +
(kTotalIters - kSmallIters) * kLargeBits,
"Error in looping constant calculations.");
// The small shift is essentially small bits, but due to the potential
// of generating a smaller result_type from a larger urbg type, the actual
// shift might be 0.
static constexpr size_t kSmallShift = kSmallBits % kResultBits;
static constexpr auto kSmallMask =
MaskFromShift<urbg_result_type>(kSmallShift);
static constexpr size_t kLargeShift = kLargeBits % kResultBits;
static constexpr auto kLargeMask =
MaskFromShift<urbg_result_type>(kLargeShift);
static constexpr auto kMin = (URBG::min)();
result_type s = 0;
for (size_t n = 0; n < kSmallIters; ++n) {
urbg_result_type v;
do {
v = g() - kMin;
} while (v >= kSmallRejection);
s = (s << kSmallShift) + static_cast<result_type>(v & kSmallMask);
}
for (size_t n = kSmallIters; n < kTotalIters; ++n) {
urbg_result_type v;
do {
v = g() - kMin;
} while (v >= kLargeRejection);
s = (s << kLargeShift) + static_cast<result_type>(v & kLargeMask);
}
return s;
}
} // namespace random_internal
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_RANDOM_INTERNAL_FAST_UNIFORM_BITS_H_