mirror of https://gitee.com/openkylin/linux.git
756 lines
14 KiB
ArmAsm
756 lines
14 KiB
ArmAsm
/*
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* Core of the accelerated CRC algorithm.
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* In your file, define the constants and CRC_FUNCTION_NAME
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* Then include this file.
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*
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* Calculate the checksum of data that is 16 byte aligned and a multiple of
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* 16 bytes.
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*
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* The first step is to reduce it to 1024 bits. We do this in 8 parallel
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* chunks in order to mask the latency of the vpmsum instructions. If we
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* have more than 32 kB of data to checksum we repeat this step multiple
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* times, passing in the previous 1024 bits.
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*
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* The next step is to reduce the 1024 bits to 64 bits. This step adds
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* 32 bits of 0s to the end - this matches what a CRC does. We just
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* calculate constants that land the data in this 32 bits.
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*
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* We then use fixed point Barrett reduction to compute a mod n over GF(2)
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* for n = CRC using POWER8 instructions. We use x = 32.
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*
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* http://en.wikipedia.org/wiki/Barrett_reduction
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*
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* Copyright (C) 2015 Anton Blanchard <anton@au.ibm.com>, IBM
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*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version
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* 2 of the License, or (at your option) any later version.
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*/
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#include <asm/ppc_asm.h>
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#include <asm/ppc-opcode.h>
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#define MAX_SIZE 32768
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.text
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#if defined(__BIG_ENDIAN__) && defined(REFLECT)
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#define BYTESWAP_DATA
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#elif defined(__LITTLE_ENDIAN__) && !defined(REFLECT)
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#define BYTESWAP_DATA
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#else
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#undef BYTESWAP_DATA
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#endif
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#define off16 r25
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#define off32 r26
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#define off48 r27
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#define off64 r28
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#define off80 r29
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#define off96 r30
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#define off112 r31
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#define const1 v24
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#define const2 v25
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#define byteswap v26
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#define mask_32bit v27
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#define mask_64bit v28
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#define zeroes v29
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#ifdef BYTESWAP_DATA
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#define VPERM(A, B, C, D) vperm A, B, C, D
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#else
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#define VPERM(A, B, C, D)
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#endif
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/* unsigned int CRC_FUNCTION_NAME(unsigned int crc, void *p, unsigned long len) */
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FUNC_START(CRC_FUNCTION_NAME)
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std r31,-8(r1)
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std r30,-16(r1)
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std r29,-24(r1)
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std r28,-32(r1)
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std r27,-40(r1)
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std r26,-48(r1)
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std r25,-56(r1)
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li off16,16
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li off32,32
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li off48,48
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li off64,64
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li off80,80
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li off96,96
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li off112,112
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li r0,0
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/* Enough room for saving 10 non volatile VMX registers */
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subi r6,r1,56+10*16
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subi r7,r1,56+2*16
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stvx v20,0,r6
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stvx v21,off16,r6
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stvx v22,off32,r6
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stvx v23,off48,r6
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stvx v24,off64,r6
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stvx v25,off80,r6
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stvx v26,off96,r6
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stvx v27,off112,r6
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stvx v28,0,r7
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stvx v29,off16,r7
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mr r10,r3
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vxor zeroes,zeroes,zeroes
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vspltisw v0,-1
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vsldoi mask_32bit,zeroes,v0,4
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vsldoi mask_64bit,zeroes,v0,8
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/* Get the initial value into v8 */
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vxor v8,v8,v8
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MTVRD(v8, R3)
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#ifdef REFLECT
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vsldoi v8,zeroes,v8,8 /* shift into bottom 32 bits */
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#else
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vsldoi v8,v8,zeroes,4 /* shift into top 32 bits */
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#endif
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#ifdef BYTESWAP_DATA
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addis r3,r2,.byteswap_constant@toc@ha
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addi r3,r3,.byteswap_constant@toc@l
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lvx byteswap,0,r3
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addi r3,r3,16
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#endif
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cmpdi r5,256
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blt .Lshort
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rldicr r6,r5,0,56
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/* Checksum in blocks of MAX_SIZE */
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1: lis r7,MAX_SIZE@h
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ori r7,r7,MAX_SIZE@l
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mr r9,r7
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cmpd r6,r7
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bgt 2f
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mr r7,r6
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2: subf r6,r7,r6
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/* our main loop does 128 bytes at a time */
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srdi r7,r7,7
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/*
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* Work out the offset into the constants table to start at. Each
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* constant is 16 bytes, and it is used against 128 bytes of input
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* data - 128 / 16 = 8
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*/
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sldi r8,r7,4
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srdi r9,r9,3
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subf r8,r8,r9
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/* We reduce our final 128 bytes in a separate step */
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addi r7,r7,-1
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mtctr r7
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addis r3,r2,.constants@toc@ha
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addi r3,r3,.constants@toc@l
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/* Find the start of our constants */
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add r3,r3,r8
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/* zero v0-v7 which will contain our checksums */
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vxor v0,v0,v0
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vxor v1,v1,v1
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vxor v2,v2,v2
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vxor v3,v3,v3
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vxor v4,v4,v4
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vxor v5,v5,v5
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vxor v6,v6,v6
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vxor v7,v7,v7
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lvx const1,0,r3
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/*
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* If we are looping back to consume more data we use the values
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* already in v16-v23.
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*/
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cmpdi r0,1
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beq 2f
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/* First warm up pass */
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lvx v16,0,r4
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lvx v17,off16,r4
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VPERM(v16,v16,v16,byteswap)
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VPERM(v17,v17,v17,byteswap)
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lvx v18,off32,r4
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lvx v19,off48,r4
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VPERM(v18,v18,v18,byteswap)
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VPERM(v19,v19,v19,byteswap)
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lvx v20,off64,r4
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lvx v21,off80,r4
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VPERM(v20,v20,v20,byteswap)
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VPERM(v21,v21,v21,byteswap)
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lvx v22,off96,r4
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lvx v23,off112,r4
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VPERM(v22,v22,v22,byteswap)
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VPERM(v23,v23,v23,byteswap)
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addi r4,r4,8*16
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/* xor in initial value */
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vxor v16,v16,v8
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2: bdz .Lfirst_warm_up_done
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addi r3,r3,16
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lvx const2,0,r3
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/* Second warm up pass */
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VPMSUMD(v8,v16,const1)
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lvx v16,0,r4
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VPERM(v16,v16,v16,byteswap)
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ori r2,r2,0
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VPMSUMD(v9,v17,const1)
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lvx v17,off16,r4
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VPERM(v17,v17,v17,byteswap)
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ori r2,r2,0
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VPMSUMD(v10,v18,const1)
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lvx v18,off32,r4
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VPERM(v18,v18,v18,byteswap)
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ori r2,r2,0
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VPMSUMD(v11,v19,const1)
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lvx v19,off48,r4
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VPERM(v19,v19,v19,byteswap)
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ori r2,r2,0
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VPMSUMD(v12,v20,const1)
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lvx v20,off64,r4
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VPERM(v20,v20,v20,byteswap)
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ori r2,r2,0
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VPMSUMD(v13,v21,const1)
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lvx v21,off80,r4
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VPERM(v21,v21,v21,byteswap)
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ori r2,r2,0
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VPMSUMD(v14,v22,const1)
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lvx v22,off96,r4
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VPERM(v22,v22,v22,byteswap)
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ori r2,r2,0
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VPMSUMD(v15,v23,const1)
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lvx v23,off112,r4
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VPERM(v23,v23,v23,byteswap)
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addi r4,r4,8*16
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bdz .Lfirst_cool_down
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/*
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* main loop. We modulo schedule it such that it takes three iterations
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* to complete - first iteration load, second iteration vpmsum, third
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* iteration xor.
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*/
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.balign 16
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4: lvx const1,0,r3
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addi r3,r3,16
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ori r2,r2,0
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vxor v0,v0,v8
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VPMSUMD(v8,v16,const2)
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lvx v16,0,r4
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VPERM(v16,v16,v16,byteswap)
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ori r2,r2,0
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vxor v1,v1,v9
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VPMSUMD(v9,v17,const2)
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lvx v17,off16,r4
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VPERM(v17,v17,v17,byteswap)
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ori r2,r2,0
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vxor v2,v2,v10
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VPMSUMD(v10,v18,const2)
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lvx v18,off32,r4
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VPERM(v18,v18,v18,byteswap)
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ori r2,r2,0
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vxor v3,v3,v11
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VPMSUMD(v11,v19,const2)
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lvx v19,off48,r4
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VPERM(v19,v19,v19,byteswap)
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lvx const2,0,r3
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ori r2,r2,0
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vxor v4,v4,v12
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VPMSUMD(v12,v20,const1)
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lvx v20,off64,r4
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VPERM(v20,v20,v20,byteswap)
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ori r2,r2,0
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vxor v5,v5,v13
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VPMSUMD(v13,v21,const1)
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lvx v21,off80,r4
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VPERM(v21,v21,v21,byteswap)
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ori r2,r2,0
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vxor v6,v6,v14
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VPMSUMD(v14,v22,const1)
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lvx v22,off96,r4
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VPERM(v22,v22,v22,byteswap)
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ori r2,r2,0
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vxor v7,v7,v15
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VPMSUMD(v15,v23,const1)
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lvx v23,off112,r4
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VPERM(v23,v23,v23,byteswap)
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addi r4,r4,8*16
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bdnz 4b
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.Lfirst_cool_down:
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/* First cool down pass */
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lvx const1,0,r3
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addi r3,r3,16
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vxor v0,v0,v8
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VPMSUMD(v8,v16,const1)
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ori r2,r2,0
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vxor v1,v1,v9
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VPMSUMD(v9,v17,const1)
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ori r2,r2,0
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vxor v2,v2,v10
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VPMSUMD(v10,v18,const1)
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ori r2,r2,0
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vxor v3,v3,v11
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VPMSUMD(v11,v19,const1)
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ori r2,r2,0
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vxor v4,v4,v12
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VPMSUMD(v12,v20,const1)
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ori r2,r2,0
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vxor v5,v5,v13
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VPMSUMD(v13,v21,const1)
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ori r2,r2,0
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vxor v6,v6,v14
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VPMSUMD(v14,v22,const1)
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ori r2,r2,0
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vxor v7,v7,v15
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VPMSUMD(v15,v23,const1)
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ori r2,r2,0
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.Lsecond_cool_down:
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/* Second cool down pass */
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vxor v0,v0,v8
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vxor v1,v1,v9
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vxor v2,v2,v10
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vxor v3,v3,v11
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vxor v4,v4,v12
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vxor v5,v5,v13
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vxor v6,v6,v14
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vxor v7,v7,v15
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#ifdef REFLECT
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/*
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* vpmsumd produces a 96 bit result in the least significant bits
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* of the register. Since we are bit reflected we have to shift it
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* left 32 bits so it occupies the least significant bits in the
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* bit reflected domain.
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*/
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vsldoi v0,v0,zeroes,4
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vsldoi v1,v1,zeroes,4
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vsldoi v2,v2,zeroes,4
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vsldoi v3,v3,zeroes,4
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vsldoi v4,v4,zeroes,4
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vsldoi v5,v5,zeroes,4
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vsldoi v6,v6,zeroes,4
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vsldoi v7,v7,zeroes,4
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#endif
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/* xor with last 1024 bits */
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lvx v8,0,r4
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lvx v9,off16,r4
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VPERM(v8,v8,v8,byteswap)
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VPERM(v9,v9,v9,byteswap)
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lvx v10,off32,r4
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lvx v11,off48,r4
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VPERM(v10,v10,v10,byteswap)
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VPERM(v11,v11,v11,byteswap)
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lvx v12,off64,r4
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lvx v13,off80,r4
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VPERM(v12,v12,v12,byteswap)
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VPERM(v13,v13,v13,byteswap)
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lvx v14,off96,r4
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lvx v15,off112,r4
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VPERM(v14,v14,v14,byteswap)
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VPERM(v15,v15,v15,byteswap)
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addi r4,r4,8*16
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vxor v16,v0,v8
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vxor v17,v1,v9
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vxor v18,v2,v10
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vxor v19,v3,v11
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vxor v20,v4,v12
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vxor v21,v5,v13
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vxor v22,v6,v14
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vxor v23,v7,v15
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li r0,1
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cmpdi r6,0
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addi r6,r6,128
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bne 1b
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/* Work out how many bytes we have left */
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andi. r5,r5,127
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/* Calculate where in the constant table we need to start */
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subfic r6,r5,128
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add r3,r3,r6
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/* How many 16 byte chunks are in the tail */
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srdi r7,r5,4
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mtctr r7
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/*
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* Reduce the previously calculated 1024 bits to 64 bits, shifting
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* 32 bits to include the trailing 32 bits of zeros
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*/
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lvx v0,0,r3
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lvx v1,off16,r3
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lvx v2,off32,r3
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lvx v3,off48,r3
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lvx v4,off64,r3
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lvx v5,off80,r3
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lvx v6,off96,r3
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lvx v7,off112,r3
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addi r3,r3,8*16
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VPMSUMW(v0,v16,v0)
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VPMSUMW(v1,v17,v1)
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VPMSUMW(v2,v18,v2)
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VPMSUMW(v3,v19,v3)
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VPMSUMW(v4,v20,v4)
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VPMSUMW(v5,v21,v5)
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VPMSUMW(v6,v22,v6)
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VPMSUMW(v7,v23,v7)
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/* Now reduce the tail (0 - 112 bytes) */
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cmpdi r7,0
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beq 1f
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lvx v16,0,r4
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lvx v17,0,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off16,r4
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lvx v17,off16,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off32,r4
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lvx v17,off32,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off48,r4
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lvx v17,off48,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off64,r4
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lvx v17,off64,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off80,r4
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lvx v17,off80,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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bdz 1f
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lvx v16,off96,r4
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lvx v17,off96,r3
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VPERM(v16,v16,v16,byteswap)
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VPMSUMW(v16,v16,v17)
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vxor v0,v0,v16
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/* Now xor all the parallel chunks together */
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1: vxor v0,v0,v1
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vxor v2,v2,v3
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vxor v4,v4,v5
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vxor v6,v6,v7
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vxor v0,v0,v2
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vxor v4,v4,v6
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vxor v0,v0,v4
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.Lbarrett_reduction:
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/* Barrett constants */
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addis r3,r2,.barrett_constants@toc@ha
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addi r3,r3,.barrett_constants@toc@l
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lvx const1,0,r3
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lvx const2,off16,r3
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vsldoi v1,v0,v0,8
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vxor v0,v0,v1 /* xor two 64 bit results together */
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#ifdef REFLECT
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/* shift left one bit */
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vspltisb v1,1
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vsl v0,v0,v1
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#endif
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vand v0,v0,mask_64bit
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#ifndef REFLECT
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/*
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* Now for the Barrett reduction algorithm. The idea is to calculate q,
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* the multiple of our polynomial that we need to subtract. By
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* doing the computation 2x bits higher (ie 64 bits) and shifting the
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* result back down 2x bits, we round down to the nearest multiple.
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*/
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VPMSUMD(v1,v0,const1) /* ma */
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vsldoi v1,zeroes,v1,8 /* q = floor(ma/(2^64)) */
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VPMSUMD(v1,v1,const2) /* qn */
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vxor v0,v0,v1 /* a - qn, subtraction is xor in GF(2) */
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/*
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* Get the result into r3. We need to shift it left 8 bytes:
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* V0 [ 0 1 2 X ]
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* V0 [ 0 X 2 3 ]
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*/
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vsldoi v0,v0,zeroes,8 /* shift result into top 64 bits */
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#else
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/*
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* The reflected version of Barrett reduction. Instead of bit
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* reflecting our data (which is expensive to do), we bit reflect our
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* constants and our algorithm, which means the intermediate data in
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* our vector registers goes from 0-63 instead of 63-0. We can reflect
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* the algorithm because we don't carry in mod 2 arithmetic.
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*/
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vand v1,v0,mask_32bit /* bottom 32 bits of a */
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VPMSUMD(v1,v1,const1) /* ma */
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vand v1,v1,mask_32bit /* bottom 32bits of ma */
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VPMSUMD(v1,v1,const2) /* qn */
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vxor v0,v0,v1 /* a - qn, subtraction is xor in GF(2) */
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/*
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* Since we are bit reflected, the result (ie the low 32 bits) is in
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* the high 32 bits. We just need to shift it left 4 bytes
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* V0 [ 0 1 X 3 ]
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* V0 [ 0 X 2 3 ]
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*/
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vsldoi v0,v0,zeroes,4 /* shift result into top 64 bits of */
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#endif
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/* Get it into r3 */
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MFVRD(R3, v0)
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.Lout:
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subi r6,r1,56+10*16
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subi r7,r1,56+2*16
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lvx v20,0,r6
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lvx v21,off16,r6
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lvx v22,off32,r6
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lvx v23,off48,r6
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lvx v24,off64,r6
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lvx v25,off80,r6
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lvx v26,off96,r6
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lvx v27,off112,r6
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lvx v28,0,r7
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lvx v29,off16,r7
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ld r31,-8(r1)
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ld r30,-16(r1)
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ld r29,-24(r1)
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ld r28,-32(r1)
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ld r27,-40(r1)
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ld r26,-48(r1)
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ld r25,-56(r1)
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blr
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.Lfirst_warm_up_done:
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lvx const1,0,r3
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addi r3,r3,16
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VPMSUMD(v8,v16,const1)
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VPMSUMD(v9,v17,const1)
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VPMSUMD(v10,v18,const1)
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VPMSUMD(v11,v19,const1)
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VPMSUMD(v12,v20,const1)
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VPMSUMD(v13,v21,const1)
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VPMSUMD(v14,v22,const1)
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VPMSUMD(v15,v23,const1)
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b .Lsecond_cool_down
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.Lshort:
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cmpdi r5,0
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beq .Lzero
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addis r3,r2,.short_constants@toc@ha
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addi r3,r3,.short_constants@toc@l
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/* Calculate where in the constant table we need to start */
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subfic r6,r5,256
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add r3,r3,r6
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/* How many 16 byte chunks? */
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srdi r7,r5,4
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mtctr r7
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vxor v19,v19,v19
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vxor v20,v20,v20
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lvx v0,0,r4
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lvx v16,0,r3
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VPERM(v0,v0,v16,byteswap)
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vxor v0,v0,v8 /* xor in initial value */
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VPMSUMW(v0,v0,v16)
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bdz .Lv0
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lvx v1,off16,r4
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lvx v17,off16,r3
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VPERM(v1,v1,v17,byteswap)
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VPMSUMW(v1,v1,v17)
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bdz .Lv1
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lvx v2,off32,r4
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lvx v16,off32,r3
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VPERM(v2,v2,v16,byteswap)
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VPMSUMW(v2,v2,v16)
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bdz .Lv2
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lvx v3,off48,r4
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lvx v17,off48,r3
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VPERM(v3,v3,v17,byteswap)
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VPMSUMW(v3,v3,v17)
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bdz .Lv3
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lvx v4,off64,r4
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lvx v16,off64,r3
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VPERM(v4,v4,v16,byteswap)
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VPMSUMW(v4,v4,v16)
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bdz .Lv4
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lvx v5,off80,r4
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lvx v17,off80,r3
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VPERM(v5,v5,v17,byteswap)
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VPMSUMW(v5,v5,v17)
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bdz .Lv5
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lvx v6,off96,r4
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lvx v16,off96,r3
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VPERM(v6,v6,v16,byteswap)
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VPMSUMW(v6,v6,v16)
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bdz .Lv6
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lvx v7,off112,r4
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lvx v17,off112,r3
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VPERM(v7,v7,v17,byteswap)
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VPMSUMW(v7,v7,v17)
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bdz .Lv7
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addi r3,r3,128
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addi r4,r4,128
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lvx v8,0,r4
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lvx v16,0,r3
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VPERM(v8,v8,v16,byteswap)
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VPMSUMW(v8,v8,v16)
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bdz .Lv8
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lvx v9,off16,r4
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lvx v17,off16,r3
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VPERM(v9,v9,v17,byteswap)
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VPMSUMW(v9,v9,v17)
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bdz .Lv9
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lvx v10,off32,r4
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lvx v16,off32,r3
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VPERM(v10,v10,v16,byteswap)
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VPMSUMW(v10,v10,v16)
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bdz .Lv10
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lvx v11,off48,r4
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lvx v17,off48,r3
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VPERM(v11,v11,v17,byteswap)
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VPMSUMW(v11,v11,v17)
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bdz .Lv11
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lvx v12,off64,r4
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lvx v16,off64,r3
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VPERM(v12,v12,v16,byteswap)
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VPMSUMW(v12,v12,v16)
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bdz .Lv12
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lvx v13,off80,r4
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lvx v17,off80,r3
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VPERM(v13,v13,v17,byteswap)
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VPMSUMW(v13,v13,v17)
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bdz .Lv13
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lvx v14,off96,r4
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lvx v16,off96,r3
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VPERM(v14,v14,v16,byteswap)
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VPMSUMW(v14,v14,v16)
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bdz .Lv14
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lvx v15,off112,r4
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lvx v17,off112,r3
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VPERM(v15,v15,v17,byteswap)
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VPMSUMW(v15,v15,v17)
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.Lv15: vxor v19,v19,v15
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.Lv14: vxor v20,v20,v14
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.Lv13: vxor v19,v19,v13
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.Lv12: vxor v20,v20,v12
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.Lv11: vxor v19,v19,v11
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.Lv10: vxor v20,v20,v10
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.Lv9: vxor v19,v19,v9
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.Lv8: vxor v20,v20,v8
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.Lv7: vxor v19,v19,v7
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.Lv6: vxor v20,v20,v6
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.Lv5: vxor v19,v19,v5
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.Lv4: vxor v20,v20,v4
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.Lv3: vxor v19,v19,v3
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.Lv2: vxor v20,v20,v2
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.Lv1: vxor v19,v19,v1
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.Lv0: vxor v20,v20,v0
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vxor v0,v19,v20
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b .Lbarrett_reduction
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.Lzero:
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mr r3,r10
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b .Lout
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FUNC_END(CRC_FUNCTION_NAME)
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