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// Copyright 2017 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// The vectorized implementation found below is a derived work
// from code written by Anton Blanchard <anton@au.ibm.com> found
// at https://github.com/antonblanchard/crc32-vpmsum. The original
// is dual licensed under GPL and Apache 2. As the copyright holder
// for the work, IBM has contributed this new work under
// the golang license.
// Changes include porting to Go assembler with modifications for
// the Go ABI for ppc64le.
#include "textflag.h"
#define POWER8_OFFSET 132
#define off16 R16
#define off32 R17
#define off48 R18
#define off64 R19
#define off80 R20
#define off96 R21
#define off112 R22
#define const1 V24
#define const2 V25
#define byteswap V26
#define mask_32bit V27
#define mask_64bit V28
#define zeroes V29
#define MAX_SIZE 32*1024
#define REFLECT
TEXT ·ppc64SlicingUpdateBy8(SB), NOSPLIT|NOFRAME, $0-44
MOVWZ crc+0(FP), R3 // incoming crc
MOVD table8+8(FP), R4 // *Table
MOVD p+16(FP), R5
MOVD p_len+24(FP), R6 // p len
CMP $0,R6 // len == 0?
BNE start
MOVW R3,ret+40(FP) // return crc
RET
start:
NOR R3,R3,R7 // ^crc
MOVWZ R7,R7 // 32 bits
CMP R6,$16
MOVD R6,CTR
BLT short
SRAD $3,R6,R8 // 8 byte chunks
MOVD R8,CTR
loop:
MOVWZ 0(R5),R8 // 0-3 bytes of p ?Endian?
MOVWZ 4(R5),R9 // 4-7 bytes of p
MOVD R4,R10 // &tab[0]
XOR R7,R8,R7 // crc ^= byte[0:3]
RLDICL $40,R9,$56,R17 // p[7]
SLD $2,R17,R17 // p[7]*4
RLDICL $40,R7,$56,R8 // crc>>24
ADD R17,R10,R17 // &tab[0][p[7]]
SLD $2,R8,R8 // crc>>24*4
RLDICL $48,R9,$56,R18 // p[6]
SLD $2,R18,R18 // p[6]*4
ADD $1024,R10,R10 // tab[1]
MOVWZ 0(R17),R21 // tab[0][p[7]]
RLDICL $56,R9,$56,R19 // p[5]
ADD R10,R18,R18 // &tab[1][p[6]]
SLD $2,R19,R19 // p[5]*4:1
MOVWZ 0(R18),R22 // tab[1][p[6]]
ADD $1024,R10,R10 // tab[2]
XOR R21,R22,R21 // xor done R22
ADD R19,R10,R19 // &tab[2][p[5]]
ANDCC $255,R9,R20 // p[4] ??
SLD $2,R20,R20 // p[4]*4
MOVWZ 0(R19),R23 // tab[2][p[5]]
ADD $1024,R10,R10 // &tab[3]
ADD R20,R10,R20 // tab[3][p[4]]
XOR R21,R23,R21 // xor done R23
ADD $1024,R10,R10 // &tab[4]
MOVWZ 0(R20),R24 // tab[3][p[4]]
ADD R10,R8,R23 // &tab[4][crc>>24]
XOR R21,R24,R21 // xor done R24
MOVWZ 0(R23),R25 // tab[4][crc>>24]
RLDICL $48,R7,$56,R24 // crc>>16&0xFF
XOR R21,R25,R21 // xor done R25
ADD $1024,R10,R10 // &tab[5]
SLD $2,R24,R24 // crc>>16&0xFF*4
ADD R24,R10,R24 // &tab[5][crc>>16&0xFF]
MOVWZ 0(R24),R26 // tab[5][crc>>16&0xFF]
XOR R21,R26,R21 // xor done R26
RLDICL $56,R7,$56,R25 // crc>>8
ADD $1024,R10,R10 // &tab[6]
SLD $2,R25,R25 // crc>>8&FF*2
ADD R25,R10,R25 // &tab[6][crc>>8&0xFF]
MOVBZ R7,R26 // crc&0xFF
ADD $1024,R10,R10 // &tab[7]
MOVWZ 0(R25),R27 // tab[6][crc>>8&0xFF]
SLD $2,R26,R26 // crc&0xFF*2
XOR R21,R27,R21 // xor done R27
ADD R26,R10,R26 // &tab[7][crc&0xFF]
ADD $8,R5 // p = p[8:]
MOVWZ 0(R26),R28 // tab[7][crc&0xFF]
XOR R21,R28,R21 // xor done R28
MOVWZ R21,R7 // crc for next round
BC 16,0,loop // next 8 bytes
ANDCC $7,R6,R8 // any leftover bytes
BEQ done // none --> done
MOVD R8,CTR // byte count
PCALIGN $16 // align short loop
short:
MOVBZ 0(R5),R8 // get v
MOVBZ R7,R9 // byte(crc) -> R8 BE vs LE?
SRD $8,R7,R14 // crc>>8
XOR R8,R9,R8 // byte(crc)^v -> R8
ADD $1,R5 // ptr to next v
SLD $2,R8 // convert index-> bytes
ADD R8,R4,R9 // &tab[byte(crc)^v]
MOVWZ 0(R9),R10 // tab[byte(crc)^v]
XOR R10,R14,R7 // loop crc in R7
BC 16,0,short
done:
NOR R7,R7,R7 // ^crc
MOVW R7,ret+40(FP) // return crc
RET
#ifdef BYTESWAP_DATA
DATA ·byteswapcons+0(SB)/8,$0x0706050403020100
DATA ·byteswapcons+8(SB)/8,$0x0f0e0d0c0b0a0908
GLOBL ·byteswapcons+0(SB),RODATA,$16
#endif
TEXT ·vectorCrc32(SB), NOSPLIT|NOFRAME, $0-36
MOVWZ crc+0(FP), R3 // incoming crc
MOVWZ ctab+4(FP), R14 // crc poly id
MOVD p+8(FP), R4
MOVD p_len+16(FP), R5 // p len
// R3 = incoming crc
// R14 = constant table identifier
// R5 = address of bytes
// R6 = length of bytes
// defines for index loads
MOVD $16,off16
MOVD $32,off32
MOVD $48,off48
MOVD $64,off64
MOVD $80,off80
MOVD $96,off96
MOVD $112,off112
MOVD $0,R15
MOVD R3,R10 // save initial crc
NOR R3,R3,R3 // ^crc
MOVWZ R3,R3 // 32 bits
VXOR zeroes,zeroes,zeroes // clear the V reg
VSPLTISW $-1,V0
VSLDOI $4,V29,V0,mask_32bit
VSLDOI $8,V29,V0,mask_64bit
VXOR V8,V8,V8
MTVSRD R3,VS40 // crc initial value VS40 = V8
#ifdef REFLECT
VSLDOI $8,zeroes,V8,V8 // or: VSLDOI V29,V8,V27,4 for top 32 bits?
#else
VSLDOI $4,V8,zeroes,V8
#endif
#ifdef BYTESWAP_DATA
MOVD $·byteswapcons(SB),R3
LVX (R3),byteswap
#endif
CMPU R5,$256 // length of bytes
BLT short
RLDICR $0,R5,$56,R6 // chunk to process
// First step for larger sizes
l1: MOVD $32768,R7
MOVD R7,R9
CMP R6,R7 // compare R6, R7 (MAX SIZE)
BGT top // less than MAX, just do remainder
MOVD R6,R7
top:
SUB R7,R6,R6
// mainloop does 128 bytes at a time
SRD $7,R7
// determine the offset into the constants table to start with.
// Each constant is 128 bytes, used against 16 bytes of data.
SLD $4,R7,R8
SRD $3,R9,R9
SUB R8,R9,R8
// The last iteration is reduced in a separate step
ADD $-1,R7
MOVD R7,CTR
// Determine which constant table (depends on poly)
CMP R14,$1
BNE castTable
MOVD $·IEEEConst(SB),R3
BR startConst
castTable:
MOVD $·CastConst(SB),R3
startConst:
ADD R3,R8,R3 // starting point in constants table
VXOR V0,V0,V0 // clear the V regs
VXOR V1,V1,V1
VXOR V2,V2,V2
VXOR V3,V3,V3
VXOR V4,V4,V4
VXOR V5,V5,V5
VXOR V6,V6,V6
VXOR V7,V7,V7
LVX (R3),const1 // loading constant values
CMP R15,$1 // Identify warm up pass
BEQ next
// First warm up pass: load the bytes to process
LVX (R4),V16
LVX (R4+off16),V17
LVX (R4+off32),V18
LVX (R4+off48),V19
LVX (R4+off64),V20
LVX (R4+off80),V21
LVX (R4+off96),V22
LVX (R4+off112),V23
ADD $128,R4 // bump up to next 128 bytes in buffer
VXOR V16,V8,V16 // xor in initial CRC in V8
next:
BC 18,0,first_warm_up_done
ADD $16,R3 // bump up to next constants
LVX (R3),const2 // table values
VPMSUMD V16,const1,V8 // second warm up pass
LVX (R4),V16 // load from buffer
OR $0,R2,R2
VPMSUMD V17,const1,V9 // vpmsumd with constants
LVX (R4+off16),V17 // load next from buffer
OR $0,R2,R2
VPMSUMD V18,const1,V10 // vpmsumd with constants
LVX (R4+off32),V18 // load next from buffer
OR $0,R2,R2
VPMSUMD V19,const1,V11 // vpmsumd with constants
LVX (R4+off48),V19 // load next from buffer
OR $0,R2,R2
VPMSUMD V20,const1,V12 // vpmsumd with constants
LVX (R4+off64),V20 // load next from buffer
OR $0,R2,R2
VPMSUMD V21,const1,V13 // vpmsumd with constants
LVX (R4+off80),V21 // load next from buffer
OR $0,R2,R2
VPMSUMD V22,const1,V14 // vpmsumd with constants
LVX (R4+off96),V22 // load next from buffer
OR $0,R2,R2
VPMSUMD V23,const1,V15 // vpmsumd with constants
LVX (R4+off112),V23 // load next from buffer
ADD $128,R4 // bump up to next 128 bytes in buffer
BC 18,0,first_cool_down
cool_top:
LVX (R3),const1 // constants
ADD $16,R3 // inc to next constants
OR $0,R2,R2
VXOR V0,V8,V0 // xor in previous vpmsumd
VPMSUMD V16,const2,V8 // vpmsumd with constants
LVX (R4),V16 // buffer
OR $0,R2,R2
VXOR V1,V9,V1 // xor in previous
VPMSUMD V17,const2,V9 // vpmsumd with constants
LVX (R4+off16),V17 // next in buffer
OR $0,R2,R2
VXOR V2,V10,V2 // xor in previous
VPMSUMD V18,const2,V10 // vpmsumd with constants
LVX (R4+off32),V18 // next in buffer
OR $0,R2,R2
VXOR V3,V11,V3 // xor in previous
VPMSUMD V19,const2,V11 // vpmsumd with constants
LVX (R4+off48),V19 // next in buffer
LVX (R3),const2 // get next constant
OR $0,R2,R2
VXOR V4,V12,V4 // xor in previous
VPMSUMD V20,const1,V12 // vpmsumd with constants
LVX (R4+off64),V20 // next in buffer
OR $0,R2,R2
VXOR V5,V13,V5 // xor in previous
VPMSUMD V21,const1,V13 // vpmsumd with constants
LVX (R4+off80),V21 // next in buffer
OR $0,R2,R2
VXOR V6,V14,V6 // xor in previous
VPMSUMD V22,const1,V14 // vpmsumd with constants
LVX (R4+off96),V22 // next in buffer
OR $0,R2,R2
VXOR V7,V15,V7 // xor in previous
VPMSUMD V23,const1,V15 // vpmsumd with constants
LVX (R4+off112),V23 // next in buffer
ADD $128,R4 // bump up buffer pointer
BC 16,0,cool_top // are we done?
first_cool_down:
// load the constants
// xor in the previous value
// vpmsumd the result with constants
LVX (R3),const1
ADD $16,R3
VXOR V0,V8,V0
VPMSUMD V16,const1,V8
OR $0,R2,R2
VXOR V1,V9,V1
VPMSUMD V17,const1,V9
OR $0,R2,R2
VXOR V2,V10,V2
VPMSUMD V18,const1,V10
OR $0,R2,R2
VXOR V3,V11,V3
VPMSUMD V19,const1,V11
OR $0,R2,R2
VXOR V4,V12,V4
VPMSUMD V20,const1,V12
OR $0,R2,R2
VXOR V5,V13,V5
VPMSUMD V21,const1,V13
OR $0,R2,R2
VXOR V6,V14,V6
VPMSUMD V22,const1,V14
OR $0,R2,R2
VXOR V7,V15,V7
VPMSUMD V23,const1,V15
OR $0,R2,R2
second_cool_down:
VXOR V0,V8,V0
VXOR V1,V9,V1
VXOR V2,V10,V2
VXOR V3,V11,V3
VXOR V4,V12,V4
VXOR V5,V13,V5
VXOR V6,V14,V6
VXOR V7,V15,V7
#ifdef REFLECT
VSLDOI $4,V0,zeroes,V0
VSLDOI $4,V1,zeroes,V1
VSLDOI $4,V2,zeroes,V2
VSLDOI $4,V3,zeroes,V3
VSLDOI $4,V4,zeroes,V4
VSLDOI $4,V5,zeroes,V5
VSLDOI $4,V6,zeroes,V6
VSLDOI $4,V7,zeroes,V7
#endif
LVX (R4),V8
LVX (R4+off16),V9
LVX (R4+off32),V10
LVX (R4+off48),V11
LVX (R4+off64),V12
LVX (R4+off80),V13
LVX (R4+off96),V14
LVX (R4+off112),V15
ADD $128,R4
VXOR V0,V8,V16
VXOR V1,V9,V17
VXOR V2,V10,V18
VXOR V3,V11,V19
VXOR V4,V12,V20
VXOR V5,V13,V21
VXOR V6,V14,V22
VXOR V7,V15,V23
MOVD $1,R15
CMP $0,R6
ADD $128,R6
BNE l1
ANDCC $127,R5
SUBC R5,$128,R6
ADD R3,R6,R3
SRD $4,R5,R7
MOVD R7,CTR
LVX (R3),V0
LVX (R3+off16),V1
LVX (R3+off32),V2
LVX (R3+off48),V3
LVX (R3+off64),V4
LVX (R3+off80),V5
LVX (R3+off96),V6
LVX (R3+off112),V7
ADD $128,R3
VPMSUMW V16,V0,V0
VPMSUMW V17,V1,V1
VPMSUMW V18,V2,V2
VPMSUMW V19,V3,V3
VPMSUMW V20,V4,V4
VPMSUMW V21,V5,V5
VPMSUMW V22,V6,V6
VPMSUMW V23,V7,V7
// now reduce the tail
CMP $0,R7
BEQ next1
LVX (R4),V16
LVX (R3),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off16),V16
LVX (R3+off16),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off32),V16
LVX (R3+off32),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off48),V16
LVX (R3+off48),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off64),V16
LVX (R3+off64),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off80),V16
LVX (R3+off80),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
BC 18,0,next1
LVX (R4+off96),V16
LVX (R3+off96),V17
VPMSUMW V16,V17,V16
VXOR V0,V16,V0
next1:
VXOR V0,V1,V0
VXOR V2,V3,V2
VXOR V4,V5,V4
VXOR V6,V7,V6
VXOR V0,V2,V0
VXOR V4,V6,V4
VXOR V0,V4,V0
barrett_reduction:
CMP R14,$1
BNE barcstTable
MOVD $·IEEEBarConst(SB),R3
BR startbarConst
barcstTable:
MOVD $·CastBarConst(SB),R3
startbarConst:
LVX (R3),const1
LVX (R3+off16),const2
VSLDOI $8,V0,V0,V1
VXOR V0,V1,V0
#ifdef REFLECT
VSPLTISB $1,V1
VSL V0,V1,V0
#endif
VAND V0,mask_64bit,V0
#ifndef REFLECT
VPMSUMD V0,const1,V1
VSLDOI $8,zeroes,V1,V1
VPMSUMD V1,const2,V1
VXOR V0,V1,V0
VSLDOI $8,V0,zeroes,V0
#else
VAND V0,mask_32bit,V1
VPMSUMD V1,const1,V1
VAND V1,mask_32bit,V1
VPMSUMD V1,const2,V1
VXOR V0,V1,V0
VSLDOI $4,V0,zeroes,V0
#endif
MFVSRD VS32,R3 // VS32 = V0
NOR R3,R3,R3 // return ^crc
MOVW R3,ret+32(FP)
RET
first_warm_up_done:
LVX (R3),const1
ADD $16,R3
VPMSUMD V16,const1,V8
VPMSUMD V17,const1,V9
VPMSUMD V18,const1,V10
VPMSUMD V19,const1,V11
VPMSUMD V20,const1,V12
VPMSUMD V21,const1,V13
VPMSUMD V22,const1,V14
VPMSUMD V23,const1,V15
BR second_cool_down
short:
CMP $0,R5
BEQ zero
// compute short constants
CMP R14,$1
BNE castshTable
MOVD $·IEEEConst(SB),R3
ADD $4080,R3
BR startshConst
castshTable:
MOVD $·CastConst(SB),R3
ADD $4080,R3
startshConst:
SUBC R5,$256,R6 // sub from 256
ADD R3,R6,R3
// calculate where to start
SRD $4,R5,R7
MOVD R7,CTR
VXOR V19,V19,V19
VXOR V20,V20,V20
LVX (R4),V0
LVX (R3),V16
VXOR V0,V8,V0
VPMSUMW V0,V16,V0
BC 18,0,v0
LVX (R4+off16),V1
LVX (R3+off16),V17
VPMSUMW V1,V17,V1
BC 18,0,v1
LVX (R4+off32),V2
LVX (R3+off32),V16
VPMSUMW V2,V16,V2
BC 18,0,v2
LVX (R4+off48),V3
LVX (R3+off48),V17
VPMSUMW V3,V17,V3
BC 18,0,v3
LVX (R4+off64),V4
LVX (R3+off64),V16
VPMSUMW V4,V16,V4
BC 18,0,v4
LVX (R4+off80),V5
LVX (R3+off80),V17
VPMSUMW V5,V17,V5
BC 18,0,v5
LVX (R4+off96),V6
LVX (R3+off96),V16
VPMSUMW V6,V16,V6
BC 18,0,v6
LVX (R4+off112),V7
LVX (R3+off112),V17
VPMSUMW V7,V17,V7
BC 18,0,v7
ADD $128,R3
ADD $128,R4
LVX (R4),V8
LVX (R3),V16
VPMSUMW V8,V16,V8
BC 18,0,v8
LVX (R4+off16),V9
LVX (R3+off16),V17
VPMSUMW V9,V17,V9
BC 18,0,v9
LVX (R4+off32),V10
LVX (R3+off32),V16
VPMSUMW V10,V16,V10
BC 18,0,v10
LVX (R4+off48),V11
LVX (R3+off48),V17
VPMSUMW V11,V17,V11
BC 18,0,v11
LVX (R4+off64),V12
LVX (R3+off64),V16
VPMSUMW V12,V16,V12
BC 18,0,v12
LVX (R4+off80),V13
LVX (R3+off80),V17
VPMSUMW V13,V17,V13
BC 18,0,v13
LVX (R4+off96),V14
LVX (R3+off96),V16
VPMSUMW V14,V16,V14
BC 18,0,v14
LVX (R4+off112),V15
LVX (R3+off112),V17
VPMSUMW V15,V17,V15
VXOR V19,V15,V19
v14: VXOR V20,V14,V20
v13: VXOR V19,V13,V19
v12: VXOR V20,V12,V20
v11: VXOR V19,V11,V19
v10: VXOR V20,V10,V20
v9: VXOR V19,V9,V19
v8: VXOR V20,V8,V20
v7: VXOR V19,V7,V19
v6: VXOR V20,V6,V20
v5: VXOR V19,V5,V19
v4: VXOR V20,V4,V20
v3: VXOR V19,V3,V19
v2: VXOR V20,V2,V20
v1: VXOR V19,V1,V19
v0: VXOR V20,V0,V20
VXOR V19,V20,V0
BR barrett_reduction
zero:
// This case is the original crc, so just return it
MOVW R10,ret+32(FP)
RET