src/hash/crc32/crc32_amd64.go - go - Git at Google

 // Copyright 2011 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.

 // AMD64-specific hardware-assisted CRC32 algorithms. See crc32.go for a
 // description of the interface that each architecture-specific file
 // implements.

 package crc32

 import (
 	"internal/cpu"
 	"unsafe"
 )

 // This file contains the code to call the SSE 4.2 version of the Castagnoli
 // and IEEE CRC.

 // castagnoliSSE42 is defined in crc32_amd64.s and uses the SSE 4.2 CRC32
 // instruction.
 //
 //go:noescape
 func castagnoliSSE42(crc uint32, p []byte) uint32

 // castagnoliSSE42Triple is defined in crc32_amd64.s and uses the SSE 4.2 CRC32
 // instruction.
 //
 //go:noescape
 func castagnoliSSE42Triple(
 	crcA, crcB, crcC uint32,
 	a, b, c []byte,
 	rounds uint32,
 ) (retA uint32, retB uint32, retC uint32)

 // ieeeCLMUL is defined in crc_amd64.s and uses the PCLMULQDQ
 // instruction as well as SSE 4.1.
 //
 //go:noescape
 func ieeeCLMUL(crc uint32, p []byte) uint32

 const castagnoliK1 = 168
 const castagnoliK2 = 1344

 type sse42Table [4]Table

 var castagnoliSSE42TableK1 *sse42Table
 var castagnoliSSE42TableK2 *sse42Table

 func archAvailableCastagnoli() bool {
 	return cpu.X86.HasSSE42
 }

 func archInitCastagnoli() {
 	if !cpu.X86.HasSSE42 {
 		panic("arch-specific Castagnoli not available")
 	}
 	castagnoliSSE42TableK1 = new(sse42Table)
 	castagnoliSSE42TableK2 = new(sse42Table)
 	// See description in updateCastagnoli.
 	//    t[0][i] = CRC(i000, O)
 	//    t[1][i] = CRC(0i00, O)
 	//    t[2][i] = CRC(00i0, O)
 	//    t[3][i] = CRC(000i, O)
 	// where O is a sequence of K zeros.
 	var tmp [castagnoliK2]byte
 	for b := 0; b < 4; b++ {
 		for i := 0; i < 256; i++ {
 			val := uint32(i) << uint32(b*8)
 			castagnoliSSE42TableK1[b][i] = castagnoliSSE42(val, tmp[:castagnoliK1])
 			castagnoliSSE42TableK2[b][i] = castagnoliSSE42(val, tmp[:])
 		}
 	}
 }

 // castagnoliShift computes the CRC32-C of K1 or K2 zeroes (depending on the
 // table given) with the given initial crc value. This corresponds to
 // CRC(crc, O) in the description in updateCastagnoli.
 func castagnoliShift(table *sse42Table, crc uint32) uint32 {
 	return table[3][crc>>24] ^
 		table[2][(crc>>16)&0xFF] ^
 		table[1][(crc>>8)&0xFF] ^
 		table[0][crc&0xFF]
 }

 func archUpdateCastagnoli(crc uint32, p []byte) uint32 {
 	if !cpu.X86.HasSSE42 {
 		panic("not available")
 	}

 	// This method is inspired from the algorithm in Intel's white paper:
 	//    "Fast CRC Computation for iSCSI Polynomial Using CRC32 Instruction"
 	// The same strategy of splitting the buffer in three is used but the
 	// combining calculation is different; the complete derivation is explained
 	// below.
 	//
 	// -- The basic idea --
 	//
 	// The CRC32 instruction (available in SSE4.2) can process 8 bytes at a
 	// time. In recent Intel architectures the instruction takes 3 cycles;
 	// however the processor can pipeline up to three instructions if they
 	// don't depend on each other.
 	//
 	// Roughly this means that we can process three buffers in about the same
 	// time we can process one buffer.
 	//
 	// The idea is then to split the buffer in three, CRC the three pieces
 	// separately and then combine the results.
 	//
 	// Combining the results requires precomputed tables, so we must choose a
 	// fixed buffer length to optimize. The longer the length, the faster; but
 	// only buffers longer than this length will use the optimization. We choose
 	// two cutoffs and compute tables for both:
 	//  - one around 512: 168*3=504
 	//  - one around 4KB: 1344*3=4032
 	//
 	// -- The nitty gritty --
 	//
 	// Let CRC(I, X) be the non-inverted CRC32-C of the sequence X (with
 	// initial non-inverted CRC I). This function has the following properties:
 	//   (a) CRC(I, AB) = CRC(CRC(I, A), B)
 	//   (b) CRC(I, A xor B) = CRC(I, A) xor CRC(0, B)
 	//
 	// Say we want to compute CRC(I, ABC) where A, B, C are three sequences of
 	// K bytes each, where K is a fixed constant. Let O be the sequence of K zero
 	// bytes.
 	//
 	// CRC(I, ABC) = CRC(I, ABO xor C)
 	//             = CRC(I, ABO) xor CRC(0, C)
 	//             = CRC(CRC(I, AB), O) xor CRC(0, C)
 	//             = CRC(CRC(I, AO xor B), O) xor CRC(0, C)
 	//             = CRC(CRC(I, AO) xor CRC(0, B), O) xor CRC(0, C)
 	//             = CRC(CRC(CRC(I, A), O) xor CRC(0, B), O) xor CRC(0, C)
 	//
 	// The castagnoliSSE42Triple function can compute CRC(I, A), CRC(0, B),
 	// and CRC(0, C) efficiently.  We just need to find a way to quickly compute
 	// CRC(uvwx, O) given a 4-byte initial value uvwx. We can precompute these
 	// values; since we can't have a 32-bit table, we break it up into four
 	// 8-bit tables:
 	//
 	//    CRC(uvwx, O) = CRC(u000, O) xor
 	//                   CRC(0v00, O) xor
 	//                   CRC(00w0, O) xor
 	//                   CRC(000x, O)
 	//
 	// We can compute tables corresponding to the four terms for all 8-bit
 	// values.

 	crc = ^crc

 	// If a buffer is long enough to use the optimization, process the first few
 	// bytes to align the buffer to an 8 byte boundary (if necessary).
 	if len(p) >= castagnoliK1*3 {
 		delta := int(uintptr(unsafe.Pointer(&p[0])) & 7)
 		if delta != 0 {
 			delta = 8 - delta
 			crc = castagnoliSSE42(crc, p[:delta])
 			p = p[delta:]
 		}
 	}

 	// Process 3*K2 at a time.
 	for len(p) >= castagnoliK2*3 {
 		// Compute CRC(I, A), CRC(0, B), and CRC(0, C).
 		crcA, crcB, crcC := castagnoliSSE42Triple(
 			crc, 0, 0,
 			p, p[castagnoliK2:], p[castagnoliK2*2:],
 			castagnoliK2/24)

 		// CRC(I, AB) = CRC(CRC(I, A), O) xor CRC(0, B)
 		crcAB := castagnoliShift(castagnoliSSE42TableK2, crcA) ^ crcB
 		// CRC(I, ABC) = CRC(CRC(I, AB), O) xor CRC(0, C)
 		crc = castagnoliShift(castagnoliSSE42TableK2, crcAB) ^ crcC
 		p = p[castagnoliK2*3:]
 	}

 	// Process 3*K1 at a time.
 	for len(p) >= castagnoliK1*3 {
 		// Compute CRC(I, A), CRC(0, B), and CRC(0, C).
 		crcA, crcB, crcC := castagnoliSSE42Triple(
 			crc, 0, 0,
 			p, p[castagnoliK1:], p[castagnoliK1*2:],
 			castagnoliK1/24)

 		// CRC(I, AB) = CRC(CRC(I, A), O) xor CRC(0, B)
 		crcAB := castagnoliShift(castagnoliSSE42TableK1, crcA) ^ crcB
 		// CRC(I, ABC) = CRC(CRC(I, AB), O) xor CRC(0, C)
 		crc = castagnoliShift(castagnoliSSE42TableK1, crcAB) ^ crcC
 		p = p[castagnoliK1*3:]
 	}

 	// Use the simple implementation for what's left.
 	crc = castagnoliSSE42(crc, p)
 	return ^crc
 }

 func archAvailableIEEE() bool {
 	return cpu.X86.HasPCLMULQDQ && cpu.X86.HasSSE41
 }

 var archIeeeTable8 *slicing8Table

 func archInitIEEE() {
 	if !cpu.X86.HasPCLMULQDQ || !cpu.X86.HasSSE41 {
 		panic("not available")
 	}
 	// We still use slicing-by-8 for small buffers.
 	archIeeeTable8 = slicingMakeTable(IEEE)
 }

 func archUpdateIEEE(crc uint32, p []byte) uint32 {
 	if !cpu.X86.HasPCLMULQDQ || !cpu.X86.HasSSE41 {
 		panic("not available")
 	}

 	if len(p) >= 64 {
 		left := len(p) & 15
 		do := len(p) - left
 		crc = ^ieeeCLMUL(^crc, p[:do])
 		p = p[do:]
 	}
 	if len(p) == 0 {
 		return crc
 	}
 	return slicingUpdate(crc, archIeeeTable8, p)
 }
	// Copyright 2011 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.

	// AMD64-specific hardware-assisted CRC32 algorithms. See crc32.go for a
	// description of the interface that each architecture-specific file
	// implements.

	package crc32

	import (
	"internal/cpu"
	"unsafe"
	)

	// This file contains the code to call the SSE 4.2 version of the Castagnoli
	// and IEEE CRC.

	// castagnoliSSE42 is defined in crc32_amd64.s and uses the SSE 4.2 CRC32
	// instruction.
	//
	//go:noescape
	func castagnoliSSE42(crc uint32, p []byte) uint32

	// castagnoliSSE42Triple is defined in crc32_amd64.s and uses the SSE 4.2 CRC32
	// instruction.
	//
	//go:noescape
	func castagnoliSSE42Triple(
	crcA, crcB, crcC uint32,
	a, b, c []byte,
	rounds uint32,
	) (retA uint32, retB uint32, retC uint32)

	// ieeeCLMUL is defined in crc_amd64.s and uses the PCLMULQDQ
	// instruction as well as SSE 4.1.
	//
	//go:noescape
	func ieeeCLMUL(crc uint32, p []byte) uint32

	const castagnoliK1 = 168
	const castagnoliK2 = 1344

	type sse42Table [4]Table

	var castagnoliSSE42TableK1 *sse42Table
	var castagnoliSSE42TableK2 *sse42Table

	func archAvailableCastagnoli() bool {
	return cpu.X86.HasSSE42
	}

	func archInitCastagnoli() {
	if !cpu.X86.HasSSE42 {
	panic("arch-specific Castagnoli not available")
	}
	castagnoliSSE42TableK1 = new(sse42Table)
	castagnoliSSE42TableK2 = new(sse42Table)
	// See description in updateCastagnoli.
	// t[0][i] = CRC(i000, O)
	// t[1][i] = CRC(0i00, O)
	// t[2][i] = CRC(00i0, O)
	// t[3][i] = CRC(000i, O)
	// where O is a sequence of K zeros.
	var tmp [castagnoliK2]byte
	for b := 0; b < 4; b++ {
	for i := 0; i < 256; i++ {
	val := uint32(i) << uint32(b*8)
	castagnoliSSE42TableK1[b][i] = castagnoliSSE42(val, tmp[:castagnoliK1])
	castagnoliSSE42TableK2[b][i] = castagnoliSSE42(val, tmp[:])
	}
	}
	}

	// castagnoliShift computes the CRC32-C of K1 or K2 zeroes (depending on the
	// table given) with the given initial crc value. This corresponds to
	// CRC(crc, O) in the description in updateCastagnoli.
	func castagnoliShift(table *sse42Table, crc uint32) uint32 {
	return table[3][crc>>24] ^
	table[2][(crc>>16)&0xFF] ^
	table[1][(crc>>8)&0xFF] ^
	table[0][crc&0xFF]
	}

	func archUpdateCastagnoli(crc uint32, p []byte) uint32 {
	if !cpu.X86.HasSSE42 {
	panic("not available")
	}

	// This method is inspired from the algorithm in Intel's white paper:
	// "Fast CRC Computation for iSCSI Polynomial Using CRC32 Instruction"
	// The same strategy of splitting the buffer in three is used but the
	// combining calculation is different; the complete derivation is explained
	// below.
	//
	// -- The basic idea --
	//
	// The CRC32 instruction (available in SSE4.2) can process 8 bytes at a
	// time. In recent Intel architectures the instruction takes 3 cycles;
	// however the processor can pipeline up to three instructions if they
	// don't depend on each other.
	//
	// Roughly this means that we can process three buffers in about the same
	// time we can process one buffer.
	//
	// The idea is then to split the buffer in three, CRC the three pieces
	// separately and then combine the results.
	//
	// Combining the results requires precomputed tables, so we must choose a
	// fixed buffer length to optimize. The longer the length, the faster; but
	// only buffers longer than this length will use the optimization. We choose
	// two cutoffs and compute tables for both:
	// - one around 512: 168*3=504
	// - one around 4KB: 1344*3=4032
	//
	// -- The nitty gritty --
	//
	// Let CRC(I, X) be the non-inverted CRC32-C of the sequence X (with
	// initial non-inverted CRC I). This function has the following properties:
	// (a) CRC(I, AB) = CRC(CRC(I, A), B)
	// (b) CRC(I, A xor B) = CRC(I, A) xor CRC(0, B)
	//
	// Say we want to compute CRC(I, ABC) where A, B, C are three sequences of
	// K bytes each, where K is a fixed constant. Let O be the sequence of K zero
	// bytes.
	//
	// CRC(I, ABC) = CRC(I, ABO xor C)
	// = CRC(I, ABO) xor CRC(0, C)
	// = CRC(CRC(I, AB), O) xor CRC(0, C)
	// = CRC(CRC(I, AO xor B), O) xor CRC(0, C)
	// = CRC(CRC(I, AO) xor CRC(0, B), O) xor CRC(0, C)
	// = CRC(CRC(CRC(I, A), O) xor CRC(0, B), O) xor CRC(0, C)
	//
	// The castagnoliSSE42Triple function can compute CRC(I, A), CRC(0, B),
	// and CRC(0, C) efficiently. We just need to find a way to quickly compute
	// CRC(uvwx, O) given a 4-byte initial value uvwx. We can precompute these
	// values; since we can't have a 32-bit table, we break it up into four
	// 8-bit tables:
	//
	// CRC(uvwx, O) = CRC(u000, O) xor
	// CRC(0v00, O) xor
	// CRC(00w0, O) xor
	// CRC(000x, O)
	//
	// We can compute tables corresponding to the four terms for all 8-bit
	// values.

	crc = ^crc

	// If a buffer is long enough to use the optimization, process the first few
	// bytes to align the buffer to an 8 byte boundary (if necessary).
	if len(p) >= castagnoliK1*3 {
	delta := int(uintptr(unsafe.Pointer(&p[0])) & 7)
	if delta != 0 {
	delta = 8 - delta
	crc = castagnoliSSE42(crc, p[:delta])
	p = p[delta:]
	}
	}

	// Process 3*K2 at a time.
	for len(p) >= castagnoliK2*3 {
	// Compute CRC(I, A), CRC(0, B), and CRC(0, C).
	crcA, crcB, crcC := castagnoliSSE42Triple(
	crc, 0, 0,
	p, p[castagnoliK2:], p[castagnoliK2*2:],
	castagnoliK2/24)

	// CRC(I, AB) = CRC(CRC(I, A), O) xor CRC(0, B)
	crcAB := castagnoliShift(castagnoliSSE42TableK2, crcA) ^ crcB
	// CRC(I, ABC) = CRC(CRC(I, AB), O) xor CRC(0, C)
	crc = castagnoliShift(castagnoliSSE42TableK2, crcAB) ^ crcC
	p = p[castagnoliK2*3:]
	}

	// Process 3*K1 at a time.
	for len(p) >= castagnoliK1*3 {
	// Compute CRC(I, A), CRC(0, B), and CRC(0, C).
	crcA, crcB, crcC := castagnoliSSE42Triple(
	crc, 0, 0,
	p, p[castagnoliK1:], p[castagnoliK1*2:],
	castagnoliK1/24)

	// CRC(I, AB) = CRC(CRC(I, A), O) xor CRC(0, B)
	crcAB := castagnoliShift(castagnoliSSE42TableK1, crcA) ^ crcB
	// CRC(I, ABC) = CRC(CRC(I, AB), O) xor CRC(0, C)
	crc = castagnoliShift(castagnoliSSE42TableK1, crcAB) ^ crcC
	p = p[castagnoliK1*3:]
	}

	// Use the simple implementation for what's left.
	crc = castagnoliSSE42(crc, p)
	return ^crc
	}

	func archAvailableIEEE() bool {
	return cpu.X86.HasPCLMULQDQ && cpu.X86.HasSSE41
	}

	var archIeeeTable8 *slicing8Table

	func archInitIEEE() {
	if !cpu.X86.HasPCLMULQDQ \|\| !cpu.X86.HasSSE41 {
	panic("not available")
	}
	// We still use slicing-by-8 for small buffers.
	archIeeeTable8 = slicingMakeTable(IEEE)
	}

	func archUpdateIEEE(crc uint32, p []byte) uint32 {
	if !cpu.X86.HasPCLMULQDQ \|\| !cpu.X86.HasSSE41 {
	panic("not available")
	}

	if len(p) >= 64 {
	left := len(p) & 15
	do := len(p) - left
	crc = ^ieeeCLMUL(^crc, p[:do])
	p = p[do:]
	}
	if len(p) == 0 {
	return crc
	}
	return slicingUpdate(crc, archIeeeTable8, p)
	}