fc8dc48020
git-subtree-dir: third_party/abseil_cpp git-subtree-mainline:ffb2ae54be
git-subtree-split:768eb2ca28
359 lines
15 KiB
C++
359 lines
15 KiB
C++
// Copyright 2018 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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#include "absl/strings/internal/charconv_bigint.h"
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#include <algorithm>
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#include <cassert>
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#include <string>
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namespace absl {
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ABSL_NAMESPACE_BEGIN
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namespace strings_internal {
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namespace {
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// Table containing some large powers of 5, for fast computation.
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// Constant step size for entries in the kLargePowersOfFive table. Each entry
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// is larger than the previous entry by a factor of 5**kLargePowerOfFiveStep
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// (or 5**27).
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//
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// In other words, the Nth entry in the table is 5**(27*N).
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//
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// 5**27 is the largest power of 5 that fits in 64 bits.
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constexpr int kLargePowerOfFiveStep = 27;
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// The largest legal index into the kLargePowersOfFive table.
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//
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// In other words, the largest precomputed power of 5 is 5**(27*20).
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constexpr int kLargestPowerOfFiveIndex = 20;
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// Table of powers of (5**27), up to (5**27)**20 == 5**540.
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//
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// Used to generate large powers of 5 while limiting the number of repeated
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// multiplications required.
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//
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// clang-format off
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const uint32_t kLargePowersOfFive[] = {
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// 5**27 (i=1), start=0, end=2
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0xfa10079dU, 0x6765c793U,
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// 5**54 (i=2), start=2, end=6
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0x97d9f649U, 0x6664242dU, 0x29939b14U, 0x29c30f10U,
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// 5**81 (i=3), start=6, end=12
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0xc4f809c5U, 0x7bf3f22aU, 0x67bdae34U, 0xad340517U, 0x369d1b5fU, 0x10de1593U,
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// 5**108 (i=4), start=12, end=20
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0x92b260d1U, 0x9efff7c7U, 0x81de0ec6U, 0xaeba5d56U, 0x410664a4U, 0x4f40737aU,
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0x20d3846fU, 0x06d00f73U,
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// 5**135 (i=5), start=20, end=30
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0xff1b172dU, 0x13a1d71cU, 0xefa07617U, 0x7f682d3dU, 0xff8c90c0U, 0x3f0131e7U,
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0x3fdcb9feU, 0x917b0177U, 0x16c407a7U, 0x02c06b9dU,
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// 5**162 (i=6), start=30, end=42
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0x960f7199U, 0x056667ecU, 0xe07aefd8U, 0x80f2b9ccU, 0x8273f5e3U, 0xeb9a214aU,
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0x40b38005U, 0x0e477ad4U, 0x277d08e6U, 0xfa28b11eU, 0xd3f7d784U, 0x011c835bU,
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// 5**189 (i=7), start=42, end=56
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0xf723d9d5U, 0x3282d3f3U, 0xe00857d1U, 0x69659d25U, 0x2cf117cfU, 0x24da6d07U,
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0x954d1417U, 0x3e5d8cedU, 0x7a8bb766U, 0xfd785ae6U, 0x645436d2U, 0x40c78b34U,
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0x94151217U, 0x0072e9f7U,
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// 5**216 (i=8), start=56, end=72
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0x2b416aa1U, 0x7893c5a7U, 0xe37dc6d4U, 0x2bad2beaU, 0xf0fc846cU, 0x7575ae4bU,
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0x62587b14U, 0x83b67a34U, 0x02110cdbU, 0xf7992f55U, 0x00deb022U, 0xa4a23becU,
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0x8af5c5cdU, 0xb85b654fU, 0x818df38bU, 0x002e69d2U,
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// 5**243 (i=9), start=72, end=90
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0x3518cbbdU, 0x20b0c15fU, 0x38756c2fU, 0xfb5dc3ddU, 0x22ad2d94U, 0xbf35a952U,
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0xa699192aU, 0x9a613326U, 0xad2a9cedU, 0xd7f48968U, 0xe87dfb54U, 0xc8f05db6U,
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0x5ef67531U, 0x31c1ab49U, 0xe202ac9fU, 0x9b2957b5U, 0xa143f6d3U, 0x0012bf07U,
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// 5**270 (i=10), start=90, end=110
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0x8b971de9U, 0x21aba2e1U, 0x63944362U, 0x57172336U, 0xd9544225U, 0xfb534166U,
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0x08c563eeU, 0x14640ee2U, 0x24e40d31U, 0x02b06537U, 0x03887f14U, 0x0285e533U,
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0xb744ef26U, 0x8be3a6c4U, 0x266979b4U, 0x6761ece2U, 0xd9cb39e4U, 0xe67de319U,
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0x0d39e796U, 0x00079250U,
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// 5**297 (i=11), start=110, end=132
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0x260eb6e5U, 0xf414a796U, 0xee1a7491U, 0xdb9368ebU, 0xf50c105bU, 0x59157750U,
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0x9ed2fb5cU, 0xf6e56d8bU, 0xeaee8d23U, 0x0f319f75U, 0x2aa134d6U, 0xac2908e9U,
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0xd4413298U, 0x02f02a55U, 0x989d5a7aU, 0x70dde184U, 0xba8040a7U, 0x03200981U,
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0xbe03b11cU, 0x3c1c2a18U, 0xd60427a1U, 0x00030ee0U,
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// 5**324 (i=12), start=132, end=156
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0xce566d71U, 0xf1c4aa25U, 0x4e93ca53U, 0xa72283d0U, 0x551a73eaU, 0x3d0538e2U,
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0x8da4303fU, 0x6a58de60U, 0x0e660221U, 0x49cf61a6U, 0x8d058fc1U, 0xb9d1a14cU,
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0x4bab157dU, 0xc85c6932U, 0x518c8b9eU, 0x9b92b8d0U, 0x0d8a0e21U, 0xbd855df9U,
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0xb3ea59a1U, 0x8da29289U, 0x4584d506U, 0x3752d80fU, 0xb72569c6U, 0x00013c33U,
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// 5**351 (i=13), start=156, end=182
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0x190f354dU, 0x83695cfeU, 0xe5a4d0c7U, 0xb60fb7e8U, 0xee5bbcc4U, 0xb922054cU,
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0xbb4f0d85U, 0x48394028U, 0x1d8957dbU, 0x0d7edb14U, 0x4ecc7587U, 0x505e9e02U,
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0x4c87f36bU, 0x99e66bd6U, 0x44b9ed35U, 0x753037d4U, 0xe5fe5f27U, 0x2742c203U,
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0x13b2ed2bU, 0xdc525d2cU, 0xe6fde59aU, 0x77ffb18fU, 0x13c5752cU, 0x08a84bccU,
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0x859a4940U, 0x00007fb6U,
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// 5**378 (i=14), start=182, end=210
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0x4f98cb39U, 0xa60edbbcU, 0x83b5872eU, 0xa501acffU, 0x9cc76f78U, 0xbadd4c73U,
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0x43e989faU, 0xca7acf80U, 0x2e0c824fU, 0xb19f4ffcU, 0x092fd81cU, 0xe4eb645bU,
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0xa1ff84c2U, 0x8a5a83baU, 0xa8a1fae9U, 0x1db43609U, 0xb0fed50bU, 0x0dd7d2bdU,
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0x7d7accd8U, 0x91fa640fU, 0x37dcc6c5U, 0x1c417fd5U, 0xe4d462adU, 0xe8a43399U,
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0x131bf9a5U, 0x8df54d29U, 0x36547dc1U, 0x00003395U,
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// 5**405 (i=15), start=210, end=240
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0x5bd330f5U, 0x77d21967U, 0x1ac481b7U, 0x6be2f7ceU, 0x7f4792a9U, 0xe84c2c52U,
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0x84592228U, 0x9dcaf829U, 0xdab44ce1U, 0x3d0c311bU, 0x532e297dU, 0x4704e8b4U,
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0x9cdc32beU, 0x41e64d9dU, 0x7717bea1U, 0xa824c00dU, 0x08f50b27U, 0x0f198d77U,
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0x49bbfdf0U, 0x025c6c69U, 0xd4e55cd3U, 0xf083602bU, 0xb9f0fecdU, 0xc0864aeaU,
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0x9cb98681U, 0xaaf620e9U, 0xacb6df30U, 0x4faafe66U, 0x8af13c3bU, 0x000014d5U,
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// 5**432 (i=16), start=240, end=272
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0x682bb941U, 0x89a9f297U, 0xcba75d7bU, 0x404217b1U, 0xb4e519e9U, 0xa1bc162bU,
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0xf7f5910aU, 0x98715af5U, 0x2ff53e57U, 0xe3ef118cU, 0x490c4543U, 0xbc9b1734U,
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0x2affbe4dU, 0x4cedcb4cU, 0xfb14e99eU, 0x35e34212U, 0xece39c24U, 0x07673ab3U,
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0xe73115ddU, 0xd15d38e7U, 0x093eed3bU, 0xf8e7eac5U, 0x78a8cc80U, 0x25227aacU,
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0x3f590551U, 0x413da1cbU, 0xdf643a55U, 0xab65ad44U, 0xd70b23d7U, 0xc672cd76U,
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0x3364ea62U, 0x0000086aU,
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// 5**459 (i=17), start=272, end=306
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0x22f163ddU, 0x23cf07acU, 0xbe2af6c2U, 0xf412f6f6U, 0xc3ff541eU, 0x6eeaf7deU,
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0xa47047e0U, 0x408cda92U, 0x0f0eeb08U, 0x56deba9dU, 0xcfc6b090U, 0x8bbbdf04U,
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0x3933cdb3U, 0x9e7bb67dU, 0x9f297035U, 0x38946244U, 0xee1d37bbU, 0xde898174U,
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0x63f3559dU, 0x705b72fbU, 0x138d27d9U, 0xf8603a78U, 0x735eec44U, 0xe30987d5U,
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0xc6d38070U, 0x9cfe548eU, 0x9ff01422U, 0x7c564aa8U, 0x91cc60baU, 0xcbc3565dU,
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0x7550a50bU, 0x6909aeadU, 0x13234c45U, 0x00000366U,
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// 5**486 (i=18), start=306, end=342
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0x17954989U, 0x3a7d7709U, 0x98042de5U, 0xa9011443U, 0x45e723c2U, 0x269ffd6fU,
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0x58852a46U, 0xaaa1042aU, 0x2eee8153U, 0xb2b6c39eU, 0xaf845b65U, 0xf6c365d7U,
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0xe4cffb2bU, 0xc840e90cU, 0xabea8abbU, 0x5c58f8d2U, 0x5c19fa3aU, 0x4670910aU,
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0x4449f21cU, 0xefa645b3U, 0xcc427decU, 0x083c3d73U, 0x467cb413U, 0x6fe10ae4U,
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0x3caffc72U, 0x9f8da55eU, 0x5e5c8ea7U, 0x490594bbU, 0xf0871b0bU, 0xdd89816cU,
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0x8e931df8U, 0xe85ce1c9U, 0xcca090a5U, 0x575fa16bU, 0x6b9f106cU, 0x0000015fU,
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// 5**513 (i=19), start=342, end=380
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0xee20d805U, 0x57bc3c07U, 0xcdea624eU, 0xd3f0f52dU, 0x9924b4f4U, 0xcf968640U,
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0x61d41962U, 0xe87fb464U, 0xeaaf51c7U, 0x564c8b60U, 0xccda4028U, 0x529428bbU,
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0x313a1fa8U, 0x96bd0f94U, 0x7a82ebaaU, 0xad99e7e9U, 0xf2668cd4U, 0xbe33a45eU,
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0xfd0db669U, 0x87ee369fU, 0xd3ec20edU, 0x9c4d7db7U, 0xdedcf0d8U, 0x7cd2ca64U,
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0xe25a6577U, 0x61003fd4U, 0xe56f54ccU, 0x10b7c748U, 0x40526e5eU, 0x7300ae87U,
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0x5c439261U, 0x2c0ff469U, 0xbf723f12U, 0xb2379b61U, 0xbf59b4f5U, 0xc91b1c3fU,
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0xf0046d27U, 0x0000008dU,
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// 5**540 (i=20), start=380, end=420
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0x525c9e11U, 0xf4e0eb41U, 0xebb2895dU, 0x5da512f9U, 0x7d9b29d4U, 0x452f4edcU,
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0x0b90bc37U, 0x341777cbU, 0x63d269afU, 0x1da77929U, 0x0a5c1826U, 0x77991898U,
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0x5aeddf86U, 0xf853a877U, 0x538c31ccU, 0xe84896daU, 0xb7a0010bU, 0x17ef4de5U,
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0xa52a2adeU, 0x029fd81cU, 0x987ce701U, 0x27fefd77U, 0xdb46c66fU, 0x5d301900U,
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0x496998c0U, 0xbb6598b9U, 0x5eebb607U, 0xe547354aU, 0xdf4a2f7eU, 0xf06c4955U,
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0x96242ffaU, 0x1775fb27U, 0xbecc58ceU, 0xebf2a53bU, 0x3eaad82aU, 0xf41137baU,
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0x573e6fbaU, 0xfb4866b8U, 0x54002148U, 0x00000039U,
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};
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// clang-format on
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// Returns a pointer to the big integer data for (5**27)**i. i must be
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// between 1 and 20, inclusive.
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const uint32_t* LargePowerOfFiveData(int i) {
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return kLargePowersOfFive + i * (i - 1);
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}
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// Returns the size of the big integer data for (5**27)**i, in words. i must be
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// between 1 and 20, inclusive.
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int LargePowerOfFiveSize(int i) { return 2 * i; }
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} // namespace
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ABSL_DLL const uint32_t kFiveToNth[14] = {
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1, 5, 25, 125, 625, 3125, 15625,
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78125, 390625, 1953125, 9765625, 48828125, 244140625, 1220703125,
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};
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ABSL_DLL const uint32_t kTenToNth[10] = {
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1, 10, 100, 1000, 10000, 100000, 1000000, 10000000, 100000000, 1000000000,
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};
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template <int max_words>
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int BigUnsigned<max_words>::ReadFloatMantissa(const ParsedFloat& fp,
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int significant_digits) {
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SetToZero();
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assert(fp.type == FloatType::kNumber);
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if (fp.subrange_begin == nullptr) {
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// We already exactly parsed the mantissa, so no more work is necessary.
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words_[0] = fp.mantissa & 0xffffffffu;
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words_[1] = fp.mantissa >> 32;
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if (words_[1]) {
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size_ = 2;
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} else if (words_[0]) {
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size_ = 1;
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}
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return fp.exponent;
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}
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int exponent_adjust =
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ReadDigits(fp.subrange_begin, fp.subrange_end, significant_digits);
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return fp.literal_exponent + exponent_adjust;
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}
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template <int max_words>
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int BigUnsigned<max_words>::ReadDigits(const char* begin, const char* end,
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int significant_digits) {
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assert(significant_digits <= Digits10() + 1);
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SetToZero();
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bool after_decimal_point = false;
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// Discard any leading zeroes before the decimal point
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while (begin < end && *begin == '0') {
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++begin;
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}
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int dropped_digits = 0;
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// Discard any trailing zeroes. These may or may not be after the decimal
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// point.
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while (begin < end && *std::prev(end) == '0') {
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--end;
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++dropped_digits;
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}
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if (begin < end && *std::prev(end) == '.') {
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// If the string ends in '.', either before or after dropping zeroes, then
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// drop the decimal point and look for more digits to drop.
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dropped_digits = 0;
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--end;
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while (begin < end && *std::prev(end) == '0') {
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--end;
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++dropped_digits;
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}
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} else if (dropped_digits) {
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// We dropped digits, and aren't sure if they're before or after the decimal
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// point. Figure that out now.
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const char* dp = std::find(begin, end, '.');
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if (dp != end) {
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// The dropped trailing digits were after the decimal point, so don't
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// count them.
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dropped_digits = 0;
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}
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}
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// Any non-fraction digits we dropped need to be accounted for in our exponent
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// adjustment.
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int exponent_adjust = dropped_digits;
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uint32_t queued = 0;
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int digits_queued = 0;
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for (; begin != end && significant_digits > 0; ++begin) {
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if (*begin == '.') {
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after_decimal_point = true;
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continue;
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}
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if (after_decimal_point) {
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// For each fractional digit we emit in our parsed integer, adjust our
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// decimal exponent to compensate.
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--exponent_adjust;
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}
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int digit = (*begin - '0');
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--significant_digits;
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if (significant_digits == 0 && std::next(begin) != end &&
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(digit == 0 || digit == 5)) {
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// If this is the very last significant digit, but insignificant digits
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// remain, we know that the last of those remaining significant digits is
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// nonzero. (If it wasn't, we would have stripped it before we got here.)
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// So if this final digit is a 0 or 5, adjust it upward by 1.
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//
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// This adjustment is what allows incredibly large mantissas ending in
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// 500000...000000000001 to correctly round up, rather than to nearest.
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++digit;
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}
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queued = 10 * queued + digit;
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++digits_queued;
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if (digits_queued == kMaxSmallPowerOfTen) {
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MultiplyBy(kTenToNth[kMaxSmallPowerOfTen]);
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AddWithCarry(0, queued);
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queued = digits_queued = 0;
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}
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}
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// Encode any remaining digits.
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if (digits_queued) {
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MultiplyBy(kTenToNth[digits_queued]);
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AddWithCarry(0, queued);
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}
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// If any insignificant digits remain, we will drop them. But if we have not
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// yet read the decimal point, then we have to adjust the exponent to account
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// for the dropped digits.
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if (begin < end && !after_decimal_point) {
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// This call to std::find will result in a pointer either to the decimal
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// point, or to the end of our buffer if there was none.
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//
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// Either way, [begin, decimal_point) will contain the set of dropped digits
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// that require an exponent adjustment.
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const char* decimal_point = std::find(begin, end, '.');
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exponent_adjust += (decimal_point - begin);
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}
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return exponent_adjust;
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}
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template <int max_words>
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/* static */ BigUnsigned<max_words> BigUnsigned<max_words>::FiveToTheNth(
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int n) {
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BigUnsigned answer(1u);
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// Seed from the table of large powers, if possible.
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bool first_pass = true;
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while (n >= kLargePowerOfFiveStep) {
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int big_power =
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std::min(n / kLargePowerOfFiveStep, kLargestPowerOfFiveIndex);
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if (first_pass) {
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// just copy, rather than multiplying by 1
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std::copy(
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LargePowerOfFiveData(big_power),
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|
LargePowerOfFiveData(big_power) + LargePowerOfFiveSize(big_power),
|
|
answer.words_);
|
|
answer.size_ = LargePowerOfFiveSize(big_power);
|
|
first_pass = false;
|
|
} else {
|
|
answer.MultiplyBy(LargePowerOfFiveSize(big_power),
|
|
LargePowerOfFiveData(big_power));
|
|
}
|
|
n -= kLargePowerOfFiveStep * big_power;
|
|
}
|
|
answer.MultiplyByFiveToTheNth(n);
|
|
return answer;
|
|
}
|
|
|
|
template <int max_words>
|
|
void BigUnsigned<max_words>::MultiplyStep(int original_size,
|
|
const uint32_t* other_words,
|
|
int other_size, int step) {
|
|
int this_i = std::min(original_size - 1, step);
|
|
int other_i = step - this_i;
|
|
|
|
uint64_t this_word = 0;
|
|
uint64_t carry = 0;
|
|
for (; this_i >= 0 && other_i < other_size; --this_i, ++other_i) {
|
|
uint64_t product = words_[this_i];
|
|
product *= other_words[other_i];
|
|
this_word += product;
|
|
carry += (this_word >> 32);
|
|
this_word &= 0xffffffff;
|
|
}
|
|
AddWithCarry(step + 1, carry);
|
|
words_[step] = this_word & 0xffffffff;
|
|
if (this_word > 0 && size_ <= step) {
|
|
size_ = step + 1;
|
|
}
|
|
}
|
|
|
|
template <int max_words>
|
|
std::string BigUnsigned<max_words>::ToString() const {
|
|
BigUnsigned<max_words> copy = *this;
|
|
std::string result;
|
|
// Build result in reverse order
|
|
while (copy.size() > 0) {
|
|
int next_digit = copy.DivMod<10>();
|
|
result.push_back('0' + next_digit);
|
|
}
|
|
if (result.empty()) {
|
|
result.push_back('0');
|
|
}
|
|
std::reverse(result.begin(), result.end());
|
|
return result;
|
|
}
|
|
|
|
template class BigUnsigned<4>;
|
|
template class BigUnsigned<84>;
|
|
|
|
} // namespace strings_internal
|
|
ABSL_NAMESPACE_END
|
|
} // namespace absl
|