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/* crc32c.c -- compute CRC-32C using the Intel crc32 instruction
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* Copyright (C) 2013 Mark Adler |
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* Version 1.1 1 Aug 2013 Mark Adler |
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*/ |
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/*
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This software is provided 'as-is', without any express or implied |
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warranty. In no event will the author be held liable for any damages |
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arising from the use of this software. |
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|
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Permission is granted to anyone to use this software for any purpose, |
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including commercial applications, and to alter it and redistribute it |
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freely, subject to the following restrictions: |
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|
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1. The origin of this software must not be misrepresented; you must not |
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claim that you wrote the original software. If you use this software |
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in a product, an acknowledgment in the product documentation would be |
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appreciated but is not required. |
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2. Altered source versions must be plainly marked as such, and must not be |
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misrepresented as being the original software. |
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3. This notice may not be removed or altered from any source distribution. |
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|
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Mark Adler |
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madler@alumni.caltech.edu |
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*/ |
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/* Use hardware CRC instruction on Intel SSE 4.2 processors. This computes a
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CRC-32C, *not* the CRC-32 used by Ethernet and zip, gzip, etc. A software |
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version is provided as a fall-back, as well as for speed comparisons. */ |
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/* Version history:
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1.0 10 Feb 2013 First version |
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1.1 1 Aug 2013 Correct comments on why three crc instructions in parallel |
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*/ |
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#include <stdio.h> |
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#include <stdlib.h> |
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#include <stdint.h> |
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#include <unistd.h> |
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#include "crc32c.h" |
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/*****************************************************************/ |
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/* */ |
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/* CRC LOOKUP TABLE */ |
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/* ================ */ |
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/* The following CRC lookup table was generated automagically */ |
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/* by the Rocksoft^tm Model CRC Algorithm Table Generation */ |
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/* Program V1.0 using the following model parameters: */ |
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/* */ |
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/* Width : 4 bytes. */ |
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/* Poly : 0x1EDC6F41L */ |
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/* Reverse : TRUE. */ |
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/* */ |
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/* For more information on the Rocksoft^tm Model CRC Algorithm, */ |
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/* see the document titled "A Painless Guide to CRC Error */ |
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/* Detection Algorithms" by Ross Williams */ |
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/* (ross@guest.adelaide.edu.au.). This document is likely to be */ |
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/* in the FTP archive "ftp.adelaide.edu.au/pub/rocksoft". */ |
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/* */ |
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/*****************************************************************/ |
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uint32_t crctable[256] = { |
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0x00000000L, 0xF26B8303L, 0xE13B70F7L, 0x1350F3F4L, |
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0xC79A971FL, 0x35F1141CL, 0x26A1E7E8L, 0xD4CA64EBL, |
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0x8AD958CFL, 0x78B2DBCCL, 0x6BE22838L, 0x9989AB3BL, |
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0x4D43CFD0L, 0xBF284CD3L, 0xAC78BF27L, 0x5E133C24L, |
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0x105EC76FL, 0xE235446CL, 0xF165B798L, 0x030E349BL, |
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0xD7C45070L, 0x25AFD373L, 0x36FF2087L, 0xC494A384L, |
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0x9A879FA0L, 0x68EC1CA3L, 0x7BBCEF57L, 0x89D76C54L, |
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0x5D1D08BFL, 0xAF768BBCL, 0xBC267848L, 0x4E4DFB4BL, |
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0x20BD8EDEL, 0xD2D60DDDL, 0xC186FE29L, 0x33ED7D2AL, |
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0xE72719C1L, 0x154C9AC2L, 0x061C6936L, 0xF477EA35L, |
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0xAA64D611L, 0x580F5512L, 0x4B5FA6E6L, 0xB93425E5L, |
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0x6DFE410EL, 0x9F95C20DL, 0x8CC531F9L, 0x7EAEB2FAL, |
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0x30E349B1L, 0xC288CAB2L, 0xD1D83946L, 0x23B3BA45L, |
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0xF779DEAEL, 0x05125DADL, 0x1642AE59L, 0xE4292D5AL, |
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0xBA3A117EL, 0x4851927DL, 0x5B016189L, 0xA96AE28AL, |
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0x7DA08661L, 0x8FCB0562L, 0x9C9BF696L, 0x6EF07595L, |
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0x417B1DBCL, 0xB3109EBFL, 0xA0406D4BL, 0x522BEE48L, |
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0x86E18AA3L, 0x748A09A0L, 0x67DAFA54L, 0x95B17957L, |
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0xCBA24573L, 0x39C9C670L, 0x2A993584L, 0xD8F2B687L, |
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0x0C38D26CL, 0xFE53516FL, 0xED03A29BL, 0x1F682198L, |
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0x5125DAD3L, 0xA34E59D0L, 0xB01EAA24L, 0x42752927L, |
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0x96BF4DCCL, 0x64D4CECFL, 0x77843D3BL, 0x85EFBE38L, |
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0xDBFC821CL, 0x2997011FL, 0x3AC7F2EBL, 0xC8AC71E8L, |
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0x1C661503L, 0xEE0D9600L, 0xFD5D65F4L, 0x0F36E6F7L, |
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0x61C69362L, 0x93AD1061L, 0x80FDE395L, 0x72966096L, |
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0xA65C047DL, 0x5437877EL, 0x4767748AL, 0xB50CF789L, |
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0xEB1FCBADL, 0x197448AEL, 0x0A24BB5AL, 0xF84F3859L, |
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0x2C855CB2L, 0xDEEEDFB1L, 0xCDBE2C45L, 0x3FD5AF46L, |
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0x7198540DL, 0x83F3D70EL, 0x90A324FAL, 0x62C8A7F9L, |
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0xB602C312L, 0x44694011L, 0x5739B3E5L, 0xA55230E6L, |
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0xFB410CC2L, 0x092A8FC1L, 0x1A7A7C35L, 0xE811FF36L, |
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0x3CDB9BDDL, 0xCEB018DEL, 0xDDE0EB2AL, 0x2F8B6829L, |
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0x82F63B78L, 0x709DB87BL, 0x63CD4B8FL, 0x91A6C88CL, |
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0x456CAC67L, 0xB7072F64L, 0xA457DC90L, 0x563C5F93L, |
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0x082F63B7L, 0xFA44E0B4L, 0xE9141340L, 0x1B7F9043L, |
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0xCFB5F4A8L, 0x3DDE77ABL, 0x2E8E845FL, 0xDCE5075CL, |
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0x92A8FC17L, 0x60C37F14L, 0x73938CE0L, 0x81F80FE3L, |
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0x55326B08L, 0xA759E80BL, 0xB4091BFFL, 0x466298FCL, |
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0x1871A4D8L, 0xEA1A27DBL, 0xF94AD42FL, 0x0B21572CL, |
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0xDFEB33C7L, 0x2D80B0C4L, 0x3ED04330L, 0xCCBBC033L, |
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0xA24BB5A6L, 0x502036A5L, 0x4370C551L, 0xB11B4652L, |
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0x65D122B9L, 0x97BAA1BAL, 0x84EA524EL, 0x7681D14DL, |
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0x2892ED69L, 0xDAF96E6AL, 0xC9A99D9EL, 0x3BC21E9DL, |
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0xEF087A76L, 0x1D63F975L, 0x0E330A81L, 0xFC588982L, |
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0xB21572C9L, 0x407EF1CAL, 0x532E023EL, 0xA145813DL, |
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0x758FE5D6L, 0x87E466D5L, 0x94B49521L, 0x66DF1622L, |
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0x38CC2A06L, 0xCAA7A905L, 0xD9F75AF1L, 0x2B9CD9F2L, |
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0xFF56BD19L, 0x0D3D3E1AL, 0x1E6DCDEEL, 0xEC064EEDL, |
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0xC38D26C4L, 0x31E6A5C7L, 0x22B65633L, 0xD0DDD530L, |
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0x0417B1DBL, 0xF67C32D8L, 0xE52CC12CL, 0x1747422FL, |
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0x49547E0BL, 0xBB3FFD08L, 0xA86F0EFCL, 0x5A048DFFL, |
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0x8ECEE914L, 0x7CA56A17L, 0x6FF599E3L, 0x9D9E1AE0L, |
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0xD3D3E1ABL, 0x21B862A8L, 0x32E8915CL, 0xC083125FL, |
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0x144976B4L, 0xE622F5B7L, 0xF5720643L, 0x07198540L, |
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0x590AB964L, 0xAB613A67L, 0xB831C993L, 0x4A5A4A90L, |
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0x9E902E7BL, 0x6CFBAD78L, 0x7FAB5E8CL, 0x8DC0DD8FL, |
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0xE330A81AL, 0x115B2B19L, 0x020BD8EDL, 0xF0605BEEL, |
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0x24AA3F05L, 0xD6C1BC06L, 0xC5914FF2L, 0x37FACCF1L, |
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0x69E9F0D5L, 0x9B8273D6L, 0x88D28022L, 0x7AB90321L, |
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0xAE7367CAL, 0x5C18E4C9L, 0x4F48173DL, 0xBD23943EL, |
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0xF36E6F75L, 0x0105EC76L, 0x12551F82L, 0xE03E9C81L, |
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0x34F4F86AL, 0xC69F7B69L, 0xD5CF889DL, 0x27A40B9EL, |
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0x79B737BAL, 0x8BDCB4B9L, 0x988C474DL, 0x6AE7C44EL, |
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0xBE2DA0A5L, 0x4C4623A6L, 0x5F16D052L, 0xAD7D5351L |
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}; |
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uint32_t crc32c(uint8_t *buf, int len) |
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/* CRC-32C (iSCSI) polynomial in reversed bit order. */ |
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#define POLY 0x82f63b78 |
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/* Table for a quadword-at-a-time software crc. */ |
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static __thread int crc32_sw_init = 0; |
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static uint32_t crc32c_table[8][256]; |
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/* Construct table for software CRC-32C calculation. */ |
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static void crc32c_init_sw(void) |
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{ |
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uint32_t n, crc, k; |
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crc32_sw_init = 1; |
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for (n = 0; n < 256; n++) |
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{ |
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crc = n; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc = crc & 1 ? (crc >> 1) ^ POLY : crc >> 1; |
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crc32c_table[0][n] = crc; |
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} |
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for (n = 0; n < 256; n++) |
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{ |
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crc = crc32c_table[0][n]; |
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for (k = 1; k < 8; k++) |
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{ |
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crc = crc32c_table[0][crc & 0xff] ^ (crc >> 8); |
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crc32c_table[k][n] = crc; |
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} |
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} |
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} |
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/* Table-driven software version as a fall-back. This is about 15 times slower
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than using the hardware instructions. This assumes little-endian integers, |
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as is the case on Intel processors that the assembler code here is for. */ |
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static uint32_t crc32c_sw(uint32_t crci, const void *buf, size_t len) |
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{ |
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const unsigned char *next = (const unsigned char*)buf; |
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uint64_t crc; |
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if (!crc32_sw_init) |
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crc32c_init_sw(); |
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crc = crci ^ 0xffffffff; |
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while (len && ((uintptr_t)next & 7) != 0) |
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{ |
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crc = crc32c_table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8); |
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len--; |
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} |
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while (len >= 8) |
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{ |
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crc ^= *(uint64_t *)next; |
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crc = crc32c_table[7][crc & 0xff] ^ |
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crc32c_table[6][(crc >> 8) & 0xff] ^ |
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crc32c_table[5][(crc >> 16) & 0xff] ^ |
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crc32c_table[4][(crc >> 24) & 0xff] ^ |
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crc32c_table[3][(crc >> 32) & 0xff] ^ |
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crc32c_table[2][(crc >> 40) & 0xff] ^ |
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crc32c_table[1][(crc >> 48) & 0xff] ^ |
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crc32c_table[0][crc >> 56]; |
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next += 8; |
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len -= 8; |
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} |
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while (len) |
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{ |
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crc = crc32c_table[0][(crc ^ *next++) & 0xff] ^ (crc >> 8); |
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len--; |
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} |
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return (uint32_t)crc ^ 0xffffffff; |
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} |
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/* Multiply a matrix times a vector over the Galois field of two elements,
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GF(2). Each element is a bit in an unsigned integer. mat must have at |
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least as many entries as the power of two for most significant one bit in |
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vec. */ |
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static inline uint32_t gf2_matrix_times(uint32_t *mat, uint32_t vec) |
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{ |
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uint32_t sum; |
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sum = 0; |
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while (vec) |
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{ |
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if (vec & 1) |
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sum ^= *mat; |
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vec >>= 1; |
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mat++; |
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} |
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return sum; |
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} |
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/* Multiply a matrix by itself over GF(2). Both mat and square must have 32
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rows. */ |
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static inline void gf2_matrix_square(uint32_t *square, uint32_t *mat) |
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{ |
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int n; |
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for (n = 0; n < 32; n++) |
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square[n] = gf2_matrix_times(mat, mat[n]); |
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} |
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/* Construct an operator to apply len zeros to a crc. len must be a power of
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two. If len is not a power of two, then the result is the same as for the |
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largest power of two less than len. The result for len == 0 is the same as |
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for len == 1. A version of this routine could be easily written for any |
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len, but that is not needed for this application. */ |
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static void crc32c_zeros_op(uint32_t *even, size_t len) |
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{ |
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int n; |
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uint32_t row; |
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uint32_t odd[32]; /* odd-power-of-two zeros operator */ |
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/* put operator for one zero bit in odd */ |
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odd[0] = POLY; /* CRC-32C polynomial */ |
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row = 1; |
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for (n = 1; n < 32; n++) |
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{ |
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odd[n] = row; |
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row <<= 1; |
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} |
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/* put operator for two zero bits in even */ |
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gf2_matrix_square(even, odd); |
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/* put operator for four zero bits in odd */ |
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gf2_matrix_square(odd, even); |
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/* first square will put the operator for one zero byte (eight zero bits),
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in even -- next square puts operator for two zero bytes in odd, and so |
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on, until len has been rotated down to zero */ |
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do |
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{ |
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gf2_matrix_square(even, odd); |
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len >>= 1; |
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if (len == 0) |
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return; |
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gf2_matrix_square(odd, even); |
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len >>= 1; |
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} while (len); |
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/* answer ended up in odd -- copy to even */ |
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for (n = 0; n < 32; n++) |
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even[n] = odd[n]; |
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} |
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/* Take a length and build four lookup tables for applying the zeros operator
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for that length, byte-by-byte on the operand. */ |
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static void crc32c_zeros(uint32_t zeros[][256], size_t len) |
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{ |
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uint32_t n; |
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uint32_t op[32]; |
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crc32c_zeros_op(op, len); |
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for (n = 0; n < 256; n++) |
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{ |
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zeros[0][n] = gf2_matrix_times(op, n); |
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zeros[1][n] = gf2_matrix_times(op, n << 8); |
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zeros[2][n] = gf2_matrix_times(op, n << 16); |
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zeros[3][n] = gf2_matrix_times(op, n << 24); |
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} |
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} |
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/* Apply the zeros operator table to crc. */ |
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static inline uint32_t crc32c_shift(uint32_t zeros[][256], uint32_t crc) |
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{ |
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return zeros[0][crc & 0xff] ^ zeros[1][(crc >> 8) & 0xff] ^ |
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zeros[2][(crc >> 16) & 0xff] ^ zeros[3][crc >> 24]; |
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} |
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/* Block sizes for three-way parallel crc computation. LONG and SHORT must
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both be powers of two. The associated string constants must be set |
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accordingly, for use in constructing the assembler instructions. */ |
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#define LONG 8192 |
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#define LONGx1 "8192" |
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#define LONGx2 "16384" |
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#define SHORT 256 |
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#define SHORTx1 "256" |
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#define SHORTx2 "512" |
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/* Tables for hardware crc that shift a crc by LONG and SHORT zeros. */ |
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static __thread int crc32c_hw_init = 0; |
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static uint32_t crc32c_long[4][256]; |
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static uint32_t crc32c_short[4][256]; |
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/* Initialize tables for shifting crcs. */ |
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static void crc32c_init_hw(void) |
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{ |
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uint32_t crc = 0xffffffff; |
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while (len-- > 0) |
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{ |
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crc = (crc>>8) ^ crctable[(crc ^ (*buf++)) & 0xFF]; |
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} |
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return crc^0xffffffff; |
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crc32c_hw_init = 1; |
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crc32c_zeros(crc32c_long, LONG); |
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crc32c_zeros(crc32c_short, SHORT); |
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} |
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uint32_t crc32c_zero4(uint8_t *buf, int len) |
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/* Compute CRC-32C using the Intel hardware instruction. */ |
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static uint32_t crc32c_hw(uint32_t crc, const void *buf, size_t len) |
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{ |
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uint32_t crc = 0xffffffff; |
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// pretend that first 4 bytes are zero
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crc = (crc>>8) ^ crctable[(crc ^ 0) & 0xFF]; |
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crc = (crc>>8) ^ crctable[(crc ^ 0) & 0xFF]; |
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crc = (crc>>8) ^ crctable[(crc ^ 0) & 0xFF]; |
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crc = (crc>>8) ^ crctable[(crc ^ 0) & 0xFF]; |
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while (len-- > 0) |
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{ |
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crc = (crc>>8) ^ crctable[(crc ^ (*buf++)) & 0xFF]; |
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} |
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return crc^0xffffffff; |
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const unsigned char *next = (const unsigned char*)buf; |
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const unsigned char *end; |
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uint64_t crc0, crc1, crc2; /* need to be 64 bits for crc32q */ |
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/* populate shift tables the first time through */ |
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if (!crc32c_hw_init) |
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crc32c_init_hw(); |
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/* pre-process the crc */ |
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crc0 = crc ^ 0xffffffff; |
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/* compute the crc for up to seven leading bytes to bring the data pointer
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to an eight-byte boundary */ |
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while (len && ((uintptr_t)next & 7) != 0) |
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{ |
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__asm__( |
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"crc32b\t" "(%1), %0" |
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: "=r"(crc0) |
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: "r"(next), "0"(crc0) |
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); |
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next++; |
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len--; |
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} |
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/* compute the crc on sets of LONG*3 bytes, executing three independent crc
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instructions, each on LONG bytes -- this is optimized for the Nehalem, |
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Westmere, Sandy Bridge, and Ivy Bridge architectures, which have a |
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throughput of one crc per cycle, but a latency of three cycles */ |
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while (len >= LONG*3) |
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{ |
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crc1 = 0; |
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crc2 = 0; |
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end = next + LONG; |
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do |
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{ |
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__asm__( |
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"crc32q\t" "(%3), %0\n\t" |
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"crc32q\t" LONGx1 "(%3), %1\n\t" |
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"crc32q\t" LONGx2 "(%3), %2" |
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: "=r"(crc0), "=r"(crc1), "=r"(crc2) |
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: "r"(next), "0"(crc0), "1"(crc1), "2"(crc2) |
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); |
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next += 8; |
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} while (next < end); |
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crc0 = crc32c_shift(crc32c_long, crc0) ^ crc1; |
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crc0 = crc32c_shift(crc32c_long, crc0) ^ crc2; |
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next += LONG*2; |
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len -= LONG*3; |
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} |
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||||
/* do the same thing, but now on SHORT*3 blocks for the remaining data less
|
||||
than a LONG*3 block */ |
||||
while (len >= SHORT*3) |
||||
{ |
||||
crc1 = 0; |
||||
crc2 = 0; |
||||
end = next + SHORT; |
||||
do |
||||
{ |
||||
__asm__( |
||||
"crc32q\t" "(%3), %0\n\t" |
||||
"crc32q\t" SHORTx1 "(%3), %1\n\t" |
||||
"crc32q\t" SHORTx2 "(%3), %2" |
||||
: "=r"(crc0), "=r"(crc1), "=r"(crc2) |
||||
: "r"(next), "0"(crc0), "1"(crc1), "2"(crc2) |
||||
); |
||||
next += 8; |
||||
} while (next < end); |
||||
crc0 = crc32c_shift(crc32c_short, crc0) ^ crc1; |
||||
crc0 = crc32c_shift(crc32c_short, crc0) ^ crc2; |
||||
next += SHORT*2; |
||||
len -= SHORT*3; |
||||
} |
||||
|
||||
/* compute the crc on the remaining eight-byte units less than a SHORT*3
|
||||
block */ |
||||
end = next + (len - (len & 7)); |
||||
while (next < end) |
||||
{ |
||||
__asm__( |
||||
"crc32q\t" "(%1), %0" |
||||
: "=r"(crc0) |
||||
: "r"(next), "0"(crc0) |
||||
); |
||||
next += 8; |
||||
} |
||||
len &= 7; |
||||
|
||||
/* compute the crc for up to seven trailing bytes */ |
||||
while (len) |
||||
{ |
||||
__asm__( |
||||
"crc32b\t" "(%1), %0" |
||||
: "=r"(crc0) |
||||
: "r"(next), "0"(crc0) |
||||
); |
||||
next++; |
||||
len--; |
||||
} |
||||
|
||||
/* return a post-processed crc */ |
||||
return (uint32_t)crc0 ^ 0xffffffff; |
||||
} |
||||
|
||||
/* Check for SSE 4.2. SSE 4.2 was first supported in Nehalem processors
|
||||
introduced in November, 2008. This does not check for the existence of the |
||||
cpuid instruction itself, which was introduced on the 486SL in 1992, so this |
||||
will fail on earlier x86 processors. cpuid works on all Pentium and later |
||||
processors. */ |
||||
#define SSE42(have) \ |
||||
do { \
|
||||
uint32_t eax, ecx; \
|
||||
eax = 1; \
|
||||
__asm__("cpuid" \
|
||||
: "=c"(ecx) \
|
||||
: "a"(eax) \
|
||||
: "%ebx", "%edx"); \
|
||||
(have) = (ecx >> 20) & 1; \
|
||||
} while (0) |
||||
|
||||
/* Compute a CRC-32C. If the crc32 instruction is available, use the hardware
|
||||
version. Otherwise, use the software version. */ |
||||
uint32_t crc32c(uint32_t crc, const void *buf, size_t len) |
||||
{ |
||||
int sse42; |
||||
|
||||
SSE42(sse42); |
||||
return sse42 ? crc32c_hw(crc, buf, len) : crc32c_sw(crc, buf, len); |
||||
} |
||||
|
||||
Loading…
Reference in new issue