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320 lines
6 KiB
ArmAsm
320 lines
6 KiB
ArmAsm
// Copyright 2011 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// +build gc
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#define NOSPLIT 4
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#define RODATA 8
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// castagnoliSSE42 updates the (non-inverted) crc with the given buffer.
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//
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// func castagnoliSSE42(crc uint32, p []byte) uint32
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TEXT ·castagnoliSSE42(SB), NOSPLIT, $0
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MOVL crc+0(FP), AX // CRC value
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MOVQ p+8(FP), SI // data pointer
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MOVQ p_len+16(FP), CX // len(p)
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// If there are fewer than 8 bytes to process, skip alignment.
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CMPQ CX, $8
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JL less_than_8
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MOVQ SI, BX
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ANDQ $7, BX
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JZ aligned
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// Process the first few bytes to 8-byte align the input.
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// BX = 8 - BX. We need to process this many bytes to align.
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SUBQ $1, BX
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XORQ $7, BX
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BTQ $0, BX
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JNC align_2
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CRC32B (SI), AX
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DECQ CX
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INCQ SI
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align_2:
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BTQ $1, BX
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JNC align_4
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// CRC32W (SI), AX
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BYTE $0x66; BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06
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SUBQ $2, CX
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ADDQ $2, SI
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align_4:
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BTQ $2, BX
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JNC aligned
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// CRC32L (SI), AX
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BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06
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SUBQ $4, CX
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ADDQ $4, SI
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aligned:
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// The input is now 8-byte aligned and we can process 8-byte chunks.
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CMPQ CX, $8
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JL less_than_8
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CRC32Q (SI), AX
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ADDQ $8, SI
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SUBQ $8, CX
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JMP aligned
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less_than_8:
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// We may have some bytes left over; process 4 bytes, then 2, then 1.
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BTQ $2, CX
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JNC less_than_4
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// CRC32L (SI), AX
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BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06
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ADDQ $4, SI
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less_than_4:
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BTQ $1, CX
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JNC less_than_2
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// CRC32W (SI), AX
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BYTE $0x66; BYTE $0xf2; BYTE $0x0f; BYTE $0x38; BYTE $0xf1; BYTE $0x06
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ADDQ $2, SI
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less_than_2:
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BTQ $0, CX
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JNC done
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CRC32B (SI), AX
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done:
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MOVL AX, ret+32(FP)
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RET
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// castagnoliSSE42Triple updates three (non-inverted) crcs with (24*rounds)
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// bytes from each buffer.
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//
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// func castagnoliSSE42Triple(
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// crc1, crc2, crc3 uint32,
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// a, b, c []byte,
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// rounds uint32,
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// ) (retA uint32, retB uint32, retC uint32)
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TEXT ·castagnoliSSE42Triple(SB), NOSPLIT, $0
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MOVL crcA+0(FP), AX
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MOVL crcB+4(FP), CX
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MOVL crcC+8(FP), DX
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MOVQ a+16(FP), R8 // data pointer
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MOVQ b+40(FP), R9 // data pointer
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MOVQ c+64(FP), R10 // data pointer
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MOVL rounds+88(FP), R11
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loop:
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CRC32Q (R8), AX
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CRC32Q (R9), CX
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CRC32Q (R10), DX
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CRC32Q 8(R8), AX
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CRC32Q 8(R9), CX
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CRC32Q 8(R10), DX
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CRC32Q 16(R8), AX
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CRC32Q 16(R9), CX
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CRC32Q 16(R10), DX
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ADDQ $24, R8
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ADDQ $24, R9
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ADDQ $24, R10
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DECQ R11
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JNZ loop
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MOVL AX, retA+96(FP)
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MOVL CX, retB+100(FP)
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MOVL DX, retC+104(FP)
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RET
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// func haveSSE42() bool
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TEXT ·haveSSE42(SB), NOSPLIT, $0
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XORQ AX, AX
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INCL AX
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CPUID
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SHRQ $20, CX
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ANDQ $1, CX
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MOVB CX, ret+0(FP)
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RET
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// func haveCLMUL() bool
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TEXT ·haveCLMUL(SB), NOSPLIT, $0
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XORQ AX, AX
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INCL AX
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CPUID
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SHRQ $1, CX
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ANDQ $1, CX
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MOVB CX, ret+0(FP)
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RET
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// func haveSSE41() bool
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TEXT ·haveSSE41(SB), NOSPLIT, $0
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XORQ AX, AX
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INCL AX
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CPUID
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SHRQ $19, CX
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ANDQ $1, CX
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MOVB CX, ret+0(FP)
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RET
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// CRC32 polynomial data
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//
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// These constants are lifted from the
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// Linux kernel, since they avoid the costly
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// PSHUFB 16 byte reversal proposed in the
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// original Intel paper.
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DATA r2r1kp<>+0(SB)/8, $0x154442bd4
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DATA r2r1kp<>+8(SB)/8, $0x1c6e41596
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DATA r4r3kp<>+0(SB)/8, $0x1751997d0
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DATA r4r3kp<>+8(SB)/8, $0x0ccaa009e
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DATA rupolykp<>+0(SB)/8, $0x1db710641
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DATA rupolykp<>+8(SB)/8, $0x1f7011641
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DATA r5kp<>+0(SB)/8, $0x163cd6124
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GLOBL r2r1kp<>(SB), RODATA, $16
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GLOBL r4r3kp<>(SB), RODATA, $16
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GLOBL rupolykp<>(SB), RODATA, $16
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GLOBL r5kp<>(SB), RODATA, $8
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// Based on http://www.intel.com/content/dam/www/public/us/en/documents/white-papers/fast-crc-computation-generic-polynomials-pclmulqdq-paper.pdf
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// len(p) must be at least 64, and must be a multiple of 16.
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// func ieeeCLMUL(crc uint32, p []byte) uint32
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TEXT ·ieeeCLMUL(SB), NOSPLIT, $0
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MOVL crc+0(FP), X0 // Initial CRC value
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MOVQ p+8(FP), SI // data pointer
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MOVQ p_len+16(FP), CX // len(p)
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MOVOU (SI), X1
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MOVOU 16(SI), X2
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MOVOU 32(SI), X3
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MOVOU 48(SI), X4
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PXOR X0, X1
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ADDQ $64, SI // buf+=64
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SUBQ $64, CX // len-=64
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CMPQ CX, $64 // Less than 64 bytes left
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JB remain64
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MOVOA r2r1kp<>+0(SB), X0
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loopback64:
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MOVOA X1, X5
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MOVOA X2, X6
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MOVOA X3, X7
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MOVOA X4, X8
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PCLMULQDQ $0, X0, X1
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PCLMULQDQ $0, X0, X2
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PCLMULQDQ $0, X0, X3
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PCLMULQDQ $0, X0, X4
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// Load next early
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MOVOU (SI), X11
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MOVOU 16(SI), X12
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MOVOU 32(SI), X13
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MOVOU 48(SI), X14
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PCLMULQDQ $0x11, X0, X5
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PCLMULQDQ $0x11, X0, X6
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PCLMULQDQ $0x11, X0, X7
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PCLMULQDQ $0x11, X0, X8
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PXOR X5, X1
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PXOR X6, X2
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PXOR X7, X3
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PXOR X8, X4
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PXOR X11, X1
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PXOR X12, X2
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PXOR X13, X3
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PXOR X14, X4
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ADDQ $0x40, DI
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ADDQ $64, SI // buf+=64
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SUBQ $64, CX // len-=64
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CMPQ CX, $64 // Less than 64 bytes left?
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JGE loopback64
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// Fold result into a single register (X1)
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remain64:
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MOVOA r4r3kp<>+0(SB), X0
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MOVOA X1, X5
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PCLMULQDQ $0, X0, X1
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PCLMULQDQ $0x11, X0, X5
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PXOR X5, X1
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PXOR X2, X1
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MOVOA X1, X5
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PCLMULQDQ $0, X0, X1
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PCLMULQDQ $0x11, X0, X5
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PXOR X5, X1
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PXOR X3, X1
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MOVOA X1, X5
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PCLMULQDQ $0, X0, X1
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PCLMULQDQ $0x11, X0, X5
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PXOR X5, X1
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PXOR X4, X1
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// If there is less than 16 bytes left we are done
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CMPQ CX, $16
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JB finish
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// Encode 16 bytes
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remain16:
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MOVOU (SI), X10
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MOVOA X1, X5
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PCLMULQDQ $0, X0, X1
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PCLMULQDQ $0x11, X0, X5
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PXOR X5, X1
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PXOR X10, X1
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SUBQ $16, CX
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ADDQ $16, SI
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CMPQ CX, $16
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JGE remain16
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finish:
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// Fold final result into 32 bits and return it
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PCMPEQB X3, X3
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PCLMULQDQ $1, X1, X0
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PSRLDQ $8, X1
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PXOR X0, X1
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MOVOA X1, X2
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MOVQ r5kp<>+0(SB), X0
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// Creates 32 bit mask. Note that we don't care about upper half.
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PSRLQ $32, X3
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PSRLDQ $4, X2
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PAND X3, X1
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PCLMULQDQ $0, X0, X1
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PXOR X2, X1
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MOVOA rupolykp<>+0(SB), X0
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MOVOA X1, X2
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PAND X3, X1
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PCLMULQDQ $0x10, X0, X1
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PAND X3, X1
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PCLMULQDQ $0, X0, X1
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PXOR X2, X1
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// PEXTRD $1, X1, AX (SSE 4.1)
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BYTE $0x66; BYTE $0x0f; BYTE $0x3a
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BYTE $0x16; BYTE $0xc8; BYTE $0x01
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MOVL AX, ret+32(FP)
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RET
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