snappy/snappy-stubs-internal.h

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// Copyright 2011 Google Inc. All Rights Reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// Various stubs for the open-source version of Snappy.
#ifndef THIRD_PARTY_SNAPPY_OPENSOURCE_SNAPPY_STUBS_INTERNAL_H_
#define THIRD_PARTY_SNAPPY_OPENSOURCE_SNAPPY_STUBS_INTERNAL_H_
#if HAVE_CONFIG_H
#include "config.h"
#endif
#include <stdint.h>
#include <cassert>
#include <cstdlib>
#include <cstring>
#include <limits>
#include <string>
#if HAVE_SYS_MMAN_H
#include <sys/mman.h>
#endif
#if HAVE_UNISTD_H
#include <unistd.h>
#endif
#if defined(_MSC_VER)
#include <intrin.h>
#endif // defined(_MSC_VER)
Avoid store-forwarding stalls in Zippy's IncrementalCopy NEW: Annotate `pattern` as initialized, for MSan. Snappy's IncrementalCopy routine optimizes for speed by reading and writing memory in blocks of eight or sixteen bytes. If the gap between the source and destination pointers is smaller than eight bytes, snappy's strategy is to expand the gap by issuing a series of partly-overlapping eight-byte loads+stores. Because the range of each load partly overlaps that of the store which preceded it, the store buffer cannot be forwarded to the load, and the load stalls while it waits for the store to retire. This is called a store-forwarding stall. We can use fewer loads and avoid most of the stalls by loading the first eight bytes into an 128-bit XMM register, then using PSHUFB to permute the register's contents in-place into the desired repeating sequence of bytes. When falling back to IncrementalCopySlow, use memset if the pattern size == 1. This eliminates around 60% of the stalls. name old time/op new time/op delta BM_UFlat/0 [html] 48.6µs ± 0% 48.2µs ± 0% -0.92% (p=0.000 n=19+18) BM_UFlat/1 [urls] 589µs ± 0% 576µs ± 0% -2.17% (p=0.000 n=19+18) BM_UFlat/2 [jpg] 7.12µs ± 0% 7.10µs ± 0% ~ (p=0.071 n=19+18) BM_UFlat/3 [jpg_200] 162ns ± 0% 151ns ± 0% -7.06% (p=0.000 n=19+18) BM_UFlat/4 [pdf] 8.25µs ± 0% 8.19µs ± 0% -0.74% (p=0.000 n=19+18) BM_UFlat/5 [html4] 218µs ± 0% 218µs ± 0% +0.09% (p=0.000 n=17+18) BM_UFlat/6 [txt1] 191µs ± 0% 189µs ± 0% -1.12% (p=0.000 n=19+18) BM_UFlat/7 [txt2] 168µs ± 0% 167µs ± 0% -1.01% (p=0.000 n=19+18) BM_UFlat/8 [txt3] 502µs ± 0% 499µs ± 0% -0.52% (p=0.000 n=19+18) BM_UFlat/9 [txt4] 704µs ± 0% 695µs ± 0% -1.26% (p=0.000 n=19+18) BM_UFlat/10 [pb] 45.6µs ± 0% 44.2µs ± 0% -3.13% (p=0.000 n=19+15) BM_UFlat/11 [gaviota] 188µs ± 0% 194µs ± 0% +3.06% (p=0.000 n=15+18) BM_UFlat/12 [cp] 15.1µs ± 2% 14.7µs ± 1% -2.09% (p=0.000 n=18+18) BM_UFlat/13 [c] 7.38µs ± 0% 7.36µs ± 0% -0.28% (p=0.000 n=16+18) BM_UFlat/14 [lsp] 2.31µs ± 0% 2.37µs ± 0% +2.64% (p=0.000 n=19+18) BM_UFlat/15 [xls] 984µs ± 0% 909µs ± 0% -7.59% (p=0.000 n=19+18) BM_UFlat/16 [xls_200] 215ns ± 0% 217ns ± 0% +0.71% (p=0.000 n=19+15) BM_UFlat/17 [bin] 289µs ± 0% 287µs ± 0% -0.71% (p=0.000 n=19+18) BM_UFlat/18 [bin_200] 161ns ± 0% 116ns ± 0% -28.09% (p=0.000 n=19+16) BM_UFlat/19 [sum] 31.9µs ± 0% 29.2µs ± 0% -8.37% (p=0.000 n=19+18) BM_UFlat/20 [man] 3.13µs ± 1% 3.07µs ± 0% -1.79% (p=0.000 n=19+18) name old allocs/op new allocs/op delta BM_UFlat/0 [html] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/1 [urls] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/2 [jpg] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/3 [jpg_200] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/4 [pdf] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/5 [html4] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/6 [txt1] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/7 [txt2] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/8 [txt3] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/9 [txt4] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/10 [pb] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/11 [gaviota] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/12 [cp] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/13 [c] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/14 [lsp] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/15 [xls] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/16 [xls_200] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/17 [bin] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/18 [bin_200] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/19 [sum] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) BM_UFlat/20 [man] 0.00 ±NaN% 0.00 ±NaN% ~ (all samples are equal) name old speed new speed delta BM_UFlat/0 [html] 2.11GB/s ± 0% 2.13GB/s ± 0% +0.92% (p=0.000 n=19+18) BM_UFlat/1 [urls] 1.19GB/s ± 0% 1.22GB/s ± 0% +2.22% (p=0.000 n=16+17) BM_UFlat/2 [jpg] 17.3GB/s ± 0% 17.3GB/s ± 0% ~ (p=0.074 n=19+18) BM_UFlat/3 [jpg_200] 1.23GB/s ± 0% 1.33GB/s ± 0% +7.58% (p=0.000 n=19+18) BM_UFlat/4 [pdf] 12.4GB/s ± 0% 12.5GB/s ± 0% +0.74% (p=0.000 n=19+18) BM_UFlat/5 [html4] 1.88GB/s ± 0% 1.88GB/s ± 0% -0.09% (p=0.000 n=18+18) BM_UFlat/6 [txt1] 798MB/s ± 0% 807MB/s ± 0% +1.13% (p=0.000 n=19+18) BM_UFlat/7 [txt2] 743MB/s ± 0% 751MB/s ± 0% +1.02% (p=0.000 n=19+18) BM_UFlat/8 [txt3] 850MB/s ± 0% 855MB/s ± 0% +0.52% (p=0.000 n=19+18) BM_UFlat/9 [txt4] 684MB/s ± 0% 693MB/s ± 0% +1.28% (p=0.000 n=19+18) BM_UFlat/10 [pb] 2.60GB/s ± 0% 2.69GB/s ± 0% +3.25% (p=0.000 n=19+16) BM_UFlat/11 [gaviota] 979MB/s ± 0% 950MB/s ± 0% -2.97% (p=0.000 n=15+18) BM_UFlat/12 [cp] 1.63GB/s ± 2% 1.67GB/s ± 1% +2.13% (p=0.000 n=18+18) BM_UFlat/13 [c] 1.51GB/s ± 0% 1.52GB/s ± 0% +0.29% (p=0.000 n=16+18) BM_UFlat/14 [lsp] 1.61GB/s ± 1% 1.57GB/s ± 0% -2.57% (p=0.000 n=19+18) BM_UFlat/15 [xls] 1.05GB/s ± 0% 1.13GB/s ± 0% +8.22% (p=0.000 n=19+18) BM_UFlat/16 [xls_200] 928MB/s ± 0% 921MB/s ± 0% -0.81% (p=0.000 n=19+17) BM_UFlat/17 [bin] 1.78GB/s ± 0% 1.79GB/s ± 0% +0.71% (p=0.000 n=19+18) BM_UFlat/18 [bin_200] 1.24GB/s ± 0% 1.72GB/s ± 0% +38.92% (p=0.000 n=19+18) BM_UFlat/19 [sum] 1.20GB/s ± 0% 1.31GB/s ± 0% +9.15% (p=0.000 n=19+18) BM_UFlat/20 [man] 1.35GB/s ± 1% 1.38GB/s ± 0% +1.84% (p=0.000 n=19+18)
2018-03-27 04:55:23 +00:00
#ifndef __has_feature
#define __has_feature(x) 0
#endif
#if __has_feature(memory_sanitizer)
#include <sanitizer/msan_interface.h>
#define SNAPPY_ANNOTATE_MEMORY_IS_INITIALIZED(address, size) \
__msan_unpoison((address), (size))
#else
#define SNAPPY_ANNOTATE_MEMORY_IS_INITIALIZED(address, size) /* empty */
#endif // __has_feature(memory_sanitizer)
#include "snappy-stubs-public.h"
// Used to enable 64-bit optimized versions of some routines.
#if defined(__PPC64__) || defined(__powerpc64__)
#define ARCH_PPC 1
#elif defined(__aarch64__) || defined(_M_ARM64)
Use 64-bit optimized code path for ARM64. This is inspired by https://github.com/google/snappy/pull/22. Benchmark results with the change, Pixel C with Android N2G48B Benchmark Time(ns) CPU(ns) Iterations --------------------------------------------------- BM_UFlat/0 119544 119253 1501 818.9MB/s html BM_UFlat/1 1223950 1208588 163 554.0MB/s urls BM_UFlat/2 16081 15962 11527 7.2GB/s jpg BM_UFlat/3 356 352 416666 540.6MB/s jpg_200 BM_UFlat/4 25010 24860 7683 3.8GB/s pdf BM_UFlat/5 484832 481572 407 811.1MB/s html4 BM_UFlat/6 408410 408713 482 354.9MB/s txt1 BM_UFlat/7 361714 361663 553 330.1MB/s txt2 BM_UFlat/8 1090582 1087912 182 374.1MB/s txt3 BM_UFlat/9 1503127 1503759 133 305.6MB/s txt4 BM_UFlat/10 114183 114285 1715 989.6MB/s pb BM_UFlat/11 406714 407331 491 431.5MB/s gaviota BM_UIOVec/0 370397 369888 538 264.0MB/s html BM_UIOVec/1 3207510 3190000 100 209.9MB/s urls BM_UIOVec/2 16589 16573 11223 6.9GB/s jpg BM_UIOVec/3 1052 1052 165289 181.2MB/s jpg_200 BM_UIOVec/4 49151 49184 3985 1.9GB/s pdf BM_UValidate/0 68115 68095 2893 1.4GB/s html BM_UValidate/1 792652 792000 250 845.4MB/s urls BM_UValidate/2 334 334 487804 343.1GB/s jpg BM_UValidate/3 235 235 666666 809.9MB/s jpg_200 BM_UValidate/4 6126 6130 32626 15.6GB/s pdf BM_ZFlat/0 292697 290560 678 336.1MB/s html (22.31 %) BM_ZFlat/1 4062080 4050000 100 165.3MB/s urls (47.78 %) BM_ZFlat/2 29225 29274 6422 3.9GB/s jpg (99.95 %) BM_ZFlat/3 1099 1098 163934 173.7MB/s jpg_200 (73.00 %) BM_ZFlat/4 44117 44233 4205 2.2GB/s pdf (83.30 %) BM_ZFlat/5 1158058 1157894 171 337.4MB/s html4 (22.52 %) BM_ZFlat/6 1102983 1093922 181 132.6MB/s txt1 (57.88 %) BM_ZFlat/7 974142 975490 204 122.4MB/s txt2 (61.91 %) BM_ZFlat/8 2984670 2990000 100 136.1MB/s txt3 (54.99 %) BM_ZFlat/9 4100130 4090000 100 112.4MB/s txt4 (66.26 %) BM_ZFlat/10 276236 275139 716 411.0MB/s pb (19.68 %) BM_ZFlat/11 760091 759541 262 231.4MB/s gaviota (37.72 %) Baseline benchmark results, Pixel C with Android N2G48B Benchmark Time(ns) CPU(ns) Iterations --------------------------------------------------- BM_UFlat/0 148957 147565 1335 661.8MB/s html BM_UFlat/1 1527257 1500000 132 446.4MB/s urls BM_UFlat/2 19589 19397 8764 5.9GB/s jpg BM_UFlat/3 425 418 408163 455.3MB/s jpg_200 BM_UFlat/4 30096 29552 6497 3.2GB/s pdf BM_UFlat/5 595933 594594 333 657.0MB/s html4 BM_UFlat/6 516315 514360 383 282.0MB/s txt1 BM_UFlat/7 454653 453514 441 263.2MB/s txt2 BM_UFlat/8 1382687 1361111 144 299.0MB/s txt3 BM_UFlat/9 1967590 1904761 105 241.3MB/s txt4 BM_UFlat/10 148271 144560 1342 782.3MB/s pb BM_UFlat/11 523997 510471 382 344.4MB/s gaviota BM_UIOVec/0 478443 465227 417 209.9MB/s html BM_UIOVec/1 4172860 4060000 100 164.9MB/s urls BM_UIOVec/2 21470 20975 7342 5.5GB/s jpg BM_UIOVec/3 1357 1330 75187 143.4MB/s jpg_200 BM_UIOVec/4 63143 61365 3031 1.6GB/s pdf BM_UValidate/0 86910 85125 2279 1.1GB/s html BM_UValidate/1 1022256 1000000 195 669.6MB/s urls BM_UValidate/2 420 417 400000 274.6GB/s jpg BM_UValidate/3 311 302 571428 630.0MB/s jpg_200 BM_UValidate/4 7778 7584 25445 12.6GB/s pdf BM_ZFlat/0 469209 457547 424 213.4MB/s html (22.31 %) BM_ZFlat/1 5633510 5460000 100 122.6MB/s urls (47.78 %) BM_ZFlat/2 37896 36693 4524 3.1GB/s jpg (99.95 %) BM_ZFlat/3 1485 1441 123456 132.3MB/s jpg_200 (73.00 %) BM_ZFlat/4 74870 72775 2652 1.3GB/s pdf (83.30 %) BM_ZFlat/5 1857321 1785714 112 218.8MB/s html4 (22.52 %) BM_ZFlat/6 1538723 1492307 130 97.2MB/s txt1 (57.88 %) BM_ZFlat/7 1338236 1310810 148 91.1MB/s txt2 (61.91 %) BM_ZFlat/8 4050820 4040000 100 100.7MB/s txt3 (54.99 %) BM_ZFlat/9 5234940 5230000 100 87.9MB/s txt4 (66.26 %) BM_ZFlat/10 400309 400000 495 282.7MB/s pb (19.68 %) BM_ZFlat/11 1063042 1058510 188 166.1MB/s gaviota (37.72 %)
2017-08-16 19:38:06 +00:00
#define ARCH_ARM 1
#endif
// Needed by OS X, among others.
#ifndef MAP_ANONYMOUS
#define MAP_ANONYMOUS MAP_ANON
#endif
// The size of an array, if known at compile-time.
// Will give unexpected results if used on a pointer.
// We undefine it first, since some compilers already have a definition.
#ifdef ARRAYSIZE
#undef ARRAYSIZE
#endif
#define ARRAYSIZE(a) int{sizeof(a) / sizeof(*(a))}
// Static prediction hints.
#if HAVE_BUILTIN_EXPECT
#define SNAPPY_PREDICT_FALSE(x) (__builtin_expect(x, 0))
#define SNAPPY_PREDICT_TRUE(x) (__builtin_expect(!!(x), 1))
#else
#define SNAPPY_PREDICT_FALSE(x) x
#define SNAPPY_PREDICT_TRUE(x) x
#endif // HAVE_BUILTIN_EXPECT
// Inlining hints.
#if HAVE_ATTRIBUTE_ALWAYS_INLINE
#define SNAPPY_ATTRIBUTE_ALWAYS_INLINE __attribute__((always_inline))
#else
#define SNAPPY_ATTRIBUTE_ALWAYS_INLINE
#endif // HAVE_ATTRIBUTE_ALWAYS_INLINE
#if HAVE_BUILTIN_PREFETCH
#define SNAPPY_PREFETCH(ptr) __builtin_prefetch(ptr, 0, 3)
#else
#define SNAPPY_PREFETCH(ptr) (void)(ptr)
#endif
// Stubbed version of ABSL_FLAG.
//
// In the open source version, flags can only be changed at compile time.
#define SNAPPY_FLAG(flag_type, flag_name, default_value, help) \
flag_type FLAGS_ ## flag_name = default_value
namespace snappy {
// Stubbed version of absl::GetFlag().
template <typename T>
inline T GetFlag(T flag) { return flag; }
static const uint32_t kuint32max = std::numeric_limits<uint32_t>::max();
static const int64_t kint64max = std::numeric_limits<int64_t>::max();
// Potentially unaligned loads and stores.
inline uint16_t UNALIGNED_LOAD16(const void *p) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single movzx/ldrh on clang/gcc/msvc.
uint16_t v;
std::memcpy(&v, p, sizeof(v));
return v;
}
inline uint32_t UNALIGNED_LOAD32(const void *p) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single mov/ldr on clang/gcc/msvc.
uint32_t v;
std::memcpy(&v, p, sizeof(v));
return v;
}
inline uint64_t UNALIGNED_LOAD64(const void *p) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single mov/ldr on clang/gcc/msvc.
uint64_t v;
std::memcpy(&v, p, sizeof(v));
return v;
}
inline void UNALIGNED_STORE16(void *p, uint16_t v) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single mov/strh on clang/gcc/msvc.
std::memcpy(p, &v, sizeof(v));
}
inline void UNALIGNED_STORE32(void *p, uint32_t v) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single mov/str on clang/gcc/msvc.
std::memcpy(p, &v, sizeof(v));
}
inline void UNALIGNED_STORE64(void *p, uint64_t v) {
Remove platform-dependent code for unaligned loads/stores. Snappy issues multi-byte (16/32/64-bit) loads and stores that are not aligned, meaning the addresses are 16/32/64-bit multiples. This is accomplished using two methods: 1) The portable method allocates a uint{16,32,64}_t on the stack, and std::memcpy()s the bytes into/from the integer. This method relies on well-defined behaviori (std::memcpy() works on all valid pointers, fixed-width unsigned integer types use a pure binary representation and therefore have no invalid values), and should compile to valid code on all platforms. 2) The fast method reinterpret_casts the address to a pointer to a uint{16,32,64}_t and dereferences the pointer. This is expected to compile to one hardware instruction (mov on x86, ldr/str on arm). The caveat is that the reinterpret_cast is undefined behavior (UB) unless the address happened to be a valid uint{16,32,64}_t pointer. The UB shows up as follows. * On architectures that don't have hardware instructions for unaligned loads / stores, the pointer access can trigger a hardware exceptions. This is mitigated by #ifdef blocks that attempt to restrict the fast method to platforms that support it. * On architectures that have separate instructions for aligned and unaligned access, the compiler may need an explicit hint to emit the hardware instruction for unaligned access. This is accomplished on Clang and GCC by wrapping the pointers into structs tagged with __attribute__((__packed__)). This CL removes the fast method. Fortunately, compilers have advanced enough that the portable method gets compiled down to the same instructions as the fast method, without the need for the caveats explained above. Specifically, modern Clang, GCC and MSVC optimize std::memcpy() to a single instruction (mov / ldr / str). A test case proving this can be seen at https://godbolt.org/z/gZg2Fk PiperOrigin-RevId: 306342728
2020-04-14 00:19:00 +00:00
// Compiles to a single mov/str on clang/gcc/msvc.
std::memcpy(p, &v, sizeof(v));
}
// Convert to little-endian storage, opposite of network format.
// Convert x from host to little endian: x = LittleEndian.FromHost(x);
// convert x from little endian to host: x = LittleEndian.ToHost(x);
//
// Store values into unaligned memory converting to little endian order:
// LittleEndian.Store16(p, x);
//
// Load unaligned values stored in little endian converting to host order:
// x = LittleEndian.Load16(p);
class LittleEndian {
public:
// Functions to do unaligned loads and stores in little-endian order.
static inline uint16_t Load16(const void *ptr) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
const uint8_t* const buffer = reinterpret_cast<const uint8_t*>(ptr);
return (static_cast<uint16_t>(buffer[0])) |
(static_cast<uint16_t>(buffer[1]) << 8);
#else
// memcpy() turns into a single instruction early in the optimization
// pipeline (relatively to a series of byte accesses). So, using memcpy
// instead of byte accesses may lead to better decisions in more stages of
// the optimization pipeline.
uint16_t value;
std::memcpy(&value, ptr, 2);
return value;
#endif
}
static inline uint32_t Load32(const void *ptr) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
const uint8_t* const buffer = reinterpret_cast<const uint8_t*>(ptr);
return (static_cast<uint32_t>(buffer[0])) |
(static_cast<uint32_t>(buffer[1]) << 8) |
(static_cast<uint32_t>(buffer[2]) << 16) |
(static_cast<uint32_t>(buffer[3]) << 24);
#else
// See Load16() for the rationale of using memcpy().
uint32_t value;
std::memcpy(&value, ptr, 4);
return value;
#endif
}
static inline uint64_t Load64(const void *ptr) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
const uint8_t* const buffer = reinterpret_cast<const uint8_t*>(ptr);
return (static_cast<uint64_t>(buffer[0])) |
(static_cast<uint64_t>(buffer[1]) << 8) |
(static_cast<uint64_t>(buffer[2]) << 16) |
(static_cast<uint64_t>(buffer[3]) << 24) |
(static_cast<uint64_t>(buffer[4]) << 32) |
(static_cast<uint64_t>(buffer[5]) << 40) |
(static_cast<uint64_t>(buffer[6]) << 48) |
(static_cast<uint64_t>(buffer[7]) << 56);
#else
// See Load16() for the rationale of using memcpy().
uint64_t value;
std::memcpy(&value, ptr, 8);
return value;
#endif
}
static inline void Store16(void *dst, uint16_t value) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
uint8_t* const buffer = reinterpret_cast<uint8_t*>(dst);
buffer[0] = static_cast<uint8_t>(value);
buffer[1] = static_cast<uint8_t>(value >> 8);
#else
// See Load16() for the rationale of using memcpy().
std::memcpy(dst, &value, 2);
#endif
}
static void Store32(void *dst, uint32_t value) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
uint8_t* const buffer = reinterpret_cast<uint8_t*>(dst);
buffer[0] = static_cast<uint8_t>(value);
buffer[1] = static_cast<uint8_t>(value >> 8);
buffer[2] = static_cast<uint8_t>(value >> 16);
buffer[3] = static_cast<uint8_t>(value >> 24);
#else
// See Load16() for the rationale of using memcpy().
std::memcpy(dst, &value, 4);
#endif
}
static void Store64(void* dst, uint64_t value) {
// Compiles to a single mov/str on recent clang and gcc.
#if SNAPPY_IS_BIG_ENDIAN
uint8_t* const buffer = reinterpret_cast<uint8_t*>(dst);
buffer[0] = static_cast<uint8_t>(value);
buffer[1] = static_cast<uint8_t>(value >> 8);
buffer[2] = static_cast<uint8_t>(value >> 16);
buffer[3] = static_cast<uint8_t>(value >> 24);
buffer[4] = static_cast<uint8_t>(value >> 32);
buffer[5] = static_cast<uint8_t>(value >> 40);
buffer[6] = static_cast<uint8_t>(value >> 48);
buffer[7] = static_cast<uint8_t>(value >> 56);
#else
// See Load16() for the rationale of using memcpy().
std::memcpy(dst, &value, 8);
#endif
}
static inline constexpr bool IsLittleEndian() {
#if SNAPPY_IS_BIG_ENDIAN
return false;
#else
return true;
#endif // SNAPPY_IS_BIG_ENDIAN
}
};
// Some bit-manipulation functions.
class Bits {
public:
// Return floor(log2(n)) for positive integer n.
static int Log2FloorNonZero(uint32_t n);
// Return floor(log2(n)) for positive integer n. Returns -1 iff n == 0.
static int Log2Floor(uint32_t n);
// Return the first set least / most significant bit, 0-indexed. Returns an
// undefined value if n == 0. FindLSBSetNonZero() is similar to ffs() except
// that it's 0-indexed.
static int FindLSBSetNonZero(uint32_t n);
static int FindLSBSetNonZero64(uint64_t n);
private:
// No copying
Bits(const Bits&);
void operator=(const Bits&);
};
#if HAVE_BUILTIN_CTZ
inline int Bits::Log2FloorNonZero(uint32_t n) {
assert(n != 0);
// (31 ^ x) is equivalent to (31 - x) for x in [0, 31]. An easy proof
// represents subtraction in base 2 and observes that there's no carry.
//
// GCC and Clang represent __builtin_clz on x86 as 31 ^ _bit_scan_reverse(x).
// Using "31 ^" here instead of "31 -" allows the optimizer to strip the
// function body down to _bit_scan_reverse(x).
return 31 ^ __builtin_clz(n);
}
inline int Bits::Log2Floor(uint32_t n) {
return (n == 0) ? -1 : Bits::Log2FloorNonZero(n);
}
inline int Bits::FindLSBSetNonZero(uint32_t n) {
assert(n != 0);
return __builtin_ctz(n);
}
#elif defined(_MSC_VER)
inline int Bits::Log2FloorNonZero(uint32_t n) {
assert(n != 0);
// NOLINTNEXTLINE(runtime/int): The MSVC intrinsic demands unsigned long.
unsigned long where;
_BitScanReverse(&where, n);
return static_cast<int>(where);
}
inline int Bits::Log2Floor(uint32_t n) {
// NOLINTNEXTLINE(runtime/int): The MSVC intrinsic demands unsigned long.
unsigned long where;
if (_BitScanReverse(&where, n))
return static_cast<int>(where);
return -1;
}
inline int Bits::FindLSBSetNonZero(uint32_t n) {
assert(n != 0);
// NOLINTNEXTLINE(runtime/int): The MSVC intrinsic demands unsigned long.
unsigned long where;
if (_BitScanForward(&where, n))
return static_cast<int>(where);
return 32;
}
#else // Portable versions.
inline int Bits::Log2FloorNonZero(uint32_t n) {
assert(n != 0);
int log = 0;
uint32_t value = n;
for (int i = 4; i >= 0; --i) {
int shift = (1 << i);
uint32_t x = value >> shift;
if (x != 0) {
value = x;
log += shift;
}
}
assert(value == 1);
return log;
}
inline int Bits::Log2Floor(uint32_t n) {
2019-04-25 15:44:08 +00:00
return (n == 0) ? -1 : Bits::Log2FloorNonZero(n);
}
inline int Bits::FindLSBSetNonZero(uint32_t n) {
assert(n != 0);
int rc = 31;
for (int i = 4, shift = 1 << 4; i >= 0; --i) {
const uint32_t x = n << shift;
if (x != 0) {
n = x;
rc -= shift;
}
shift >>= 1;
}
return rc;
}
#endif // End portable versions.
#if HAVE_BUILTIN_CTZ
inline int Bits::FindLSBSetNonZero64(uint64_t n) {
assert(n != 0);
return __builtin_ctzll(n);
}
#elif defined(_MSC_VER) && (defined(_M_X64) || defined(_M_ARM64))
// _BitScanForward64() is only available on x64 and ARM64.
inline int Bits::FindLSBSetNonZero64(uint64_t n) {
assert(n != 0);
// NOLINTNEXTLINE(runtime/int): The MSVC intrinsic demands unsigned long.
unsigned long where;
if (_BitScanForward64(&where, n))
return static_cast<int>(where);
return 64;
}
#else // Portable version.
// FindLSBSetNonZero64() is defined in terms of FindLSBSetNonZero().
inline int Bits::FindLSBSetNonZero64(uint64_t n) {
assert(n != 0);
const uint32_t bottombits = static_cast<uint32_t>(n);
if (bottombits == 0) {
// Bottom bits are zero, so scan the top bits.
return 32 + FindLSBSetNonZero(static_cast<uint32_t>(n >> 32));
} else {
return FindLSBSetNonZero(bottombits);
}
}
#endif // HAVE_BUILTIN_CTZ
// Variable-length integer encoding.
class Varint {
public:
// Maximum lengths of varint encoding of uint32_t.
static const int kMax32 = 5;
// Attempts to parse a varint32 from a prefix of the bytes in [ptr,limit-1].
// Never reads a character at or beyond limit. If a valid/terminated varint32
// was found in the range, stores it in *OUTPUT and returns a pointer just
// past the last byte of the varint32. Else returns NULL. On success,
// "result <= limit".
static const char* Parse32WithLimit(const char* ptr, const char* limit,
uint32_t* OUTPUT);
// REQUIRES "ptr" points to a buffer of length sufficient to hold "v".
// EFFECTS Encodes "v" into "ptr" and returns a pointer to the
// byte just past the last encoded byte.
static char* Encode32(char* ptr, uint32_t v);
// EFFECTS Appends the varint representation of "value" to "*s".
static void Append32(std::string* s, uint32_t value);
};
inline const char* Varint::Parse32WithLimit(const char* p,
const char* l,
uint32_t* OUTPUT) {
const unsigned char* ptr = reinterpret_cast<const unsigned char*>(p);
const unsigned char* limit = reinterpret_cast<const unsigned char*>(l);
uint32_t b, result;
if (ptr >= limit) return NULL;
b = *(ptr++); result = b & 127; if (b < 128) goto done;
if (ptr >= limit) return NULL;
b = *(ptr++); result |= (b & 127) << 7; if (b < 128) goto done;
if (ptr >= limit) return NULL;
b = *(ptr++); result |= (b & 127) << 14; if (b < 128) goto done;
if (ptr >= limit) return NULL;
b = *(ptr++); result |= (b & 127) << 21; if (b < 128) goto done;
if (ptr >= limit) return NULL;
b = *(ptr++); result |= (b & 127) << 28; if (b < 16) goto done;
return NULL; // Value is too long to be a varint32
done:
*OUTPUT = result;
return reinterpret_cast<const char*>(ptr);
}
inline char* Varint::Encode32(char* sptr, uint32_t v) {
// Operate on characters as unsigneds
uint8_t* ptr = reinterpret_cast<uint8_t*>(sptr);
static const uint8_t B = 128;
if (v < (1 << 7)) {
*(ptr++) = static_cast<uint8_t>(v);
} else if (v < (1 << 14)) {
*(ptr++) = static_cast<uint8_t>(v | B);
*(ptr++) = static_cast<uint8_t>(v >> 7);
} else if (v < (1 << 21)) {
*(ptr++) = static_cast<uint8_t>(v | B);
*(ptr++) = static_cast<uint8_t>((v >> 7) | B);
*(ptr++) = static_cast<uint8_t>(v >> 14);
} else if (v < (1 << 28)) {
*(ptr++) = static_cast<uint8_t>(v | B);
*(ptr++) = static_cast<uint8_t>((v >> 7) | B);
*(ptr++) = static_cast<uint8_t>((v >> 14) | B);
*(ptr++) = static_cast<uint8_t>(v >> 21);
} else {
*(ptr++) = static_cast<uint8_t>(v | B);
*(ptr++) = static_cast<uint8_t>((v>>7) | B);
*(ptr++) = static_cast<uint8_t>((v>>14) | B);
*(ptr++) = static_cast<uint8_t>((v>>21) | B);
*(ptr++) = static_cast<uint8_t>(v >> 28);
}
return reinterpret_cast<char*>(ptr);
}
// If you know the internal layout of the std::string in use, you can
// replace this function with one that resizes the string without
// filling the new space with zeros (if applicable) --
// it will be non-portable but faster.
inline void STLStringResizeUninitialized(std::string* s, size_t new_size) {
s->resize(new_size);
}
// Return a mutable char* pointing to a string's internal buffer,
// which may not be null-terminated. Writing through this pointer will
// modify the string.
//
// string_as_array(&str)[i] is valid for 0 <= i < str.size() until the
// next call to a string method that invalidates iterators.
//
// As of 2006-04, there is no standard-blessed way of getting a
// mutable reference to a string's internal buffer. However, issue 530
// (http://www.open-std.org/JTC1/SC22/WG21/docs/lwg-defects.html#530)
// proposes this as the method. It will officially be part of the standard
// for C++0x. This should already work on all current implementations.
inline char* string_as_array(std::string* str) {
return str->empty() ? NULL : &*str->begin();
}
} // namespace snappy
#endif // THIRD_PARTY_SNAPPY_OPENSOURCE_SNAPPY_STUBS_INTERNAL_H_