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86a1e3e0e7
Summary: ... so that cache keys can be derived from DB manifest data before reading the file from storage--so that every part of the file can potentially go in a persistent cache. See updated comments in cache_key.cc for technical details. Importantly, the new cache key encoding uses some fancy but efficient math to pack data into the cache key without depending on the sizes of the various pieces. This simplifies some existing code creating cache keys, like cache warming before the file size is known. This should provide us an essentially permanent mapping between SST unique IDs and base cache keys, with the ability to "upgrade" SST unique IDs (and thus cache keys) with new SST format_versions. These cache keys are of similar, perhaps indistinguishable quality to the previous generation. Before this change (see "corrected" days between collision): ``` ./cache_bench -stress_cache_key -sck_keep_bits=43 18 collisions after 2 x 90 days, est 10 days between (1.15292e+19 corrected) ``` After this change (keep 43 bits, up through 50, to validate "trajectory" is ok on "corrected" days between collision): ``` 19 collisions after 3 x 90 days, est 14.2105 days between (1.63836e+19 corrected) 16 collisions after 5 x 90 days, est 28.125 days between (1.6213e+19 corrected) 15 collisions after 7 x 90 days, est 42 days between (1.21057e+19 corrected) 15 collisions after 17 x 90 days, est 102 days between (1.46997e+19 corrected) 15 collisions after 49 x 90 days, est 294 days between (2.11849e+19 corrected) 15 collisions after 62 x 90 days, est 372 days between (1.34027e+19 corrected) 15 collisions after 53 x 90 days, est 318 days between (5.72858e+18 corrected) 15 collisions after 309 x 90 days, est 1854 days between (1.66994e+19 corrected) ``` However, the change does modify (probably weaken) the "guaranteed unique" promise from this > SST files generated in a single process are guaranteed to have unique cache keys, unless/until number session ids * max file number = 2**86 to this (see https://github.com/facebook/rocksdb/issues/10388) > With the DB id limitation, we only have nice guaranteed unique cache keys for files generated in a single process until biggest session_id_counter and offset_in_file reach combined 64 bits I don't think this is a practical concern, though. Pull Request resolved: https://github.com/facebook/rocksdb/pull/10394 Test Plan: unit tests updated, see simulation results above Reviewed By: jay-zhuang Differential Revision: D38667529 Pulled By: pdillinger fbshipit-source-id: 49af3fe7f47e5b61162809a78b76c769fd519fba
317 lines
8.6 KiB
C++
317 lines
8.6 KiB
C++
// Copyright (c) Facebook, Inc. and its affiliates. All Rights Reserved.
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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#pragma once
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#include "util/coding_lean.h"
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#include "util/math.h"
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#ifdef TEST_UINT128_COMPAT
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#undef HAVE_UINT128_EXTENSION
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#endif
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namespace ROCKSDB_NAMESPACE {
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// Unsigned128 is a 128 bit value supporting (at least) bitwise operators,
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// shifts, and comparisons. __uint128_t is not always available.
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#ifdef HAVE_UINT128_EXTENSION
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using Unsigned128 = __uint128_t;
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#else
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struct Unsigned128 {
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uint64_t lo;
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uint64_t hi;
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inline Unsigned128() {
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static_assert(sizeof(Unsigned128) == 2 * sizeof(uint64_t),
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"unexpected overhead in representation");
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lo = 0;
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hi = 0;
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}
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inline Unsigned128(uint64_t lower) {
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lo = lower;
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hi = 0;
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}
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inline Unsigned128(uint64_t lower, uint64_t upper) {
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lo = lower;
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hi = upper;
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}
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explicit operator uint64_t() { return lo; }
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explicit operator uint32_t() { return static_cast<uint32_t>(lo); }
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explicit operator uint16_t() { return static_cast<uint16_t>(lo); }
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explicit operator uint8_t() { return static_cast<uint8_t>(lo); }
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};
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inline Unsigned128 operator<<(const Unsigned128& lhs, unsigned shift) {
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shift &= 127;
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Unsigned128 rv;
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if (shift >= 64) {
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rv.lo = 0;
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rv.hi = lhs.lo << (shift & 63);
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} else {
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uint64_t tmp = lhs.lo;
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rv.lo = tmp << shift;
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// Ensure shift==0 shifts away everything. (This avoids another
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// conditional branch on shift == 0.)
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tmp = tmp >> 1 >> (63 - shift);
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rv.hi = tmp | (lhs.hi << shift);
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}
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return rv;
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}
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inline Unsigned128& operator<<=(Unsigned128& lhs, unsigned shift) {
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lhs = lhs << shift;
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return lhs;
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}
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inline Unsigned128 operator>>(const Unsigned128& lhs, unsigned shift) {
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shift &= 127;
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Unsigned128 rv;
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if (shift >= 64) {
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rv.hi = 0;
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rv.lo = lhs.hi >> (shift & 63);
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} else {
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uint64_t tmp = lhs.hi;
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rv.hi = tmp >> shift;
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// Ensure shift==0 shifts away everything
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tmp = tmp << 1 << (63 - shift);
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rv.lo = tmp | (lhs.lo >> shift);
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}
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return rv;
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}
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inline Unsigned128& operator>>=(Unsigned128& lhs, unsigned shift) {
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lhs = lhs >> shift;
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return lhs;
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}
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inline Unsigned128 operator&(const Unsigned128& lhs, const Unsigned128& rhs) {
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return Unsigned128(lhs.lo & rhs.lo, lhs.hi & rhs.hi);
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}
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inline Unsigned128& operator&=(Unsigned128& lhs, const Unsigned128& rhs) {
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lhs = lhs & rhs;
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return lhs;
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}
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inline Unsigned128 operator|(const Unsigned128& lhs, const Unsigned128& rhs) {
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return Unsigned128(lhs.lo | rhs.lo, lhs.hi | rhs.hi);
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}
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inline Unsigned128& operator|=(Unsigned128& lhs, const Unsigned128& rhs) {
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lhs = lhs | rhs;
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return lhs;
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}
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inline Unsigned128 operator^(const Unsigned128& lhs, const Unsigned128& rhs) {
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return Unsigned128(lhs.lo ^ rhs.lo, lhs.hi ^ rhs.hi);
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}
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inline Unsigned128& operator^=(Unsigned128& lhs, const Unsigned128& rhs) {
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lhs = lhs ^ rhs;
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return lhs;
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}
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inline Unsigned128 operator~(const Unsigned128& v) {
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return Unsigned128(~v.lo, ~v.hi);
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}
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inline bool operator==(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.lo == rhs.lo && lhs.hi == rhs.hi;
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}
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inline bool operator!=(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.lo != rhs.lo || lhs.hi != rhs.hi;
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}
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inline bool operator>(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.hi > rhs.hi || (lhs.hi == rhs.hi && lhs.lo > rhs.lo);
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}
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inline bool operator<(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.hi < rhs.hi || (lhs.hi == rhs.hi && lhs.lo < rhs.lo);
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}
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inline bool operator>=(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.hi > rhs.hi || (lhs.hi == rhs.hi && lhs.lo >= rhs.lo);
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}
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inline bool operator<=(const Unsigned128& lhs, const Unsigned128& rhs) {
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return lhs.hi < rhs.hi || (lhs.hi == rhs.hi && lhs.lo <= rhs.lo);
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}
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#endif
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inline uint64_t Lower64of128(Unsigned128 v) {
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#ifdef HAVE_UINT128_EXTENSION
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return static_cast<uint64_t>(v);
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#else
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return v.lo;
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#endif
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}
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inline uint64_t Upper64of128(Unsigned128 v) {
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#ifdef HAVE_UINT128_EXTENSION
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return static_cast<uint64_t>(v >> 64);
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#else
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return v.hi;
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#endif
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}
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// This generally compiles down to a single fast instruction on 64-bit.
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// This doesn't really make sense as operator* because it's not a
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// general 128x128 multiply and provides more output than 64x64 multiply.
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inline Unsigned128 Multiply64to128(uint64_t a, uint64_t b) {
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#ifdef HAVE_UINT128_EXTENSION
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return Unsigned128{a} * Unsigned128{b};
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#else
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// Full decomposition
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// NOTE: GCC seems to fully understand this code as 64-bit x 64-bit
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// -> 128-bit multiplication and optimize it appropriately.
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uint64_t tmp = uint64_t{b & 0xffffFFFF} * uint64_t{a & 0xffffFFFF};
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uint64_t lower = tmp & 0xffffFFFF;
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tmp >>= 32;
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tmp += uint64_t{b & 0xffffFFFF} * uint64_t{a >> 32};
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// Avoid overflow: first add lower 32 of tmp2, and later upper 32
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uint64_t tmp2 = uint64_t{b >> 32} * uint64_t{a & 0xffffFFFF};
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tmp += tmp2 & 0xffffFFFF;
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lower |= tmp << 32;
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tmp >>= 32;
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tmp += tmp2 >> 32;
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tmp += uint64_t{b >> 32} * uint64_t{a >> 32};
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return Unsigned128(lower, tmp);
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#endif
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}
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template <>
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inline int FloorLog2(Unsigned128 v) {
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if (Upper64of128(v) == 0) {
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return FloorLog2(Lower64of128(v));
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} else {
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return FloorLog2(Upper64of128(v)) + 64;
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}
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}
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template <>
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inline int CountTrailingZeroBits(Unsigned128 v) {
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if (Lower64of128(v) != 0) {
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return CountTrailingZeroBits(Lower64of128(v));
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} else {
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return CountTrailingZeroBits(Upper64of128(v)) + 64;
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}
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}
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template <>
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inline int BitsSetToOne(Unsigned128 v) {
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return BitsSetToOne(Lower64of128(v)) + BitsSetToOne(Upper64of128(v));
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}
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template <>
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inline int BitParity(Unsigned128 v) {
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return BitParity(Lower64of128(v) ^ Upper64of128(v));
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}
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template <>
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inline Unsigned128 EndianSwapValue(Unsigned128 v) {
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return (Unsigned128{EndianSwapValue(Lower64of128(v))} << 64) |
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EndianSwapValue(Upper64of128(v));
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}
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template <>
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inline Unsigned128 ReverseBits(Unsigned128 v) {
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return (Unsigned128{ReverseBits(Lower64of128(v))} << 64) |
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ReverseBits(Upper64of128(v));
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}
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template <>
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inline Unsigned128 DownwardInvolution(Unsigned128 v) {
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return (Unsigned128{DownwardInvolution(Upper64of128(v))} << 64) |
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DownwardInvolution(Upper64of128(v) ^ Lower64of128(v));
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}
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template <typename T>
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struct IsUnsignedUpTo128
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: std::integral_constant<bool, std::is_unsigned<T>::value ||
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std::is_same<T, Unsigned128>::value> {};
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inline void EncodeFixed128(char* dst, Unsigned128 value) {
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EncodeFixed64(dst, Lower64of128(value));
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EncodeFixed64(dst + 8, Upper64of128(value));
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}
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inline Unsigned128 DecodeFixed128(const char* ptr) {
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Unsigned128 rv = DecodeFixed64(ptr + 8);
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return (rv << 64) | DecodeFixed64(ptr);
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}
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// A version of EncodeFixed* for generic algorithms. Likely to be used
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// with Unsigned128, so lives here for now.
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template <typename T>
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inline void EncodeFixedGeneric(char* /*dst*/, T /*value*/) {
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// Unfortunately, GCC does not appear to optimize this simple code down
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// to a trivial load on Intel:
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//
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// T ret_val = 0;
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// for (size_t i = 0; i < sizeof(T); ++i) {
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// ret_val |= (static_cast<T>(static_cast<unsigned char>(ptr[i])) << (8 *
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// i));
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// }
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// return ret_val;
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//
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// But does unroll the loop, and does optimize manually unrolled version
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// for specific sizes down to a trivial load. I have no idea why it doesn't
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// do both on this code.
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// So instead, we rely on specializations
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static_assert(sizeof(T) == 0, "No specialization provided for this type");
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}
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template <>
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inline void EncodeFixedGeneric(char* dst, uint16_t value) {
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return EncodeFixed16(dst, value);
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}
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template <>
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inline void EncodeFixedGeneric(char* dst, uint32_t value) {
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return EncodeFixed32(dst, value);
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}
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template <>
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inline void EncodeFixedGeneric(char* dst, uint64_t value) {
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return EncodeFixed64(dst, value);
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}
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template <>
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inline void EncodeFixedGeneric(char* dst, Unsigned128 value) {
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return EncodeFixed128(dst, value);
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}
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// A version of EncodeFixed* for generic algorithms.
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template <typename T>
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inline T DecodeFixedGeneric(const char* /*dst*/) {
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static_assert(sizeof(T) == 0, "No specialization provided for this type");
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}
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template <>
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inline uint16_t DecodeFixedGeneric(const char* dst) {
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return DecodeFixed16(dst);
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}
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template <>
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inline uint32_t DecodeFixedGeneric(const char* dst) {
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return DecodeFixed32(dst);
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}
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template <>
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inline uint64_t DecodeFixedGeneric(const char* dst) {
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return DecodeFixed64(dst);
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}
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template <>
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inline Unsigned128 DecodeFixedGeneric(const char* dst) {
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return DecodeFixed128(dst);
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}
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} // namespace ROCKSDB_NAMESPACE
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