tailscale/util/sha256x/sha256.go

// Copyright (c) 2022 Tailscale Inc & AUTHORS All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

// Package sha256x is like crypto/sha256 with extra methods.
// It exports a concrete Hash type
// rather than only returning an interface implementation.
package sha256x

import (
	"crypto/sha256"
	"encoding/binary"
	"hash"
)

var _ hash.Hash = (*Hash)(nil)

// Hash is a hash.Hash for SHA-256,
// but has efficient methods for hashing fixed-width integers.
type Hash struct {
	// The optimization is to maintain our own block and
	// only call h.Write with entire blocks.
	// This avoids double-copying of buffers within sha256.digest itself.
	// However, it does mean that sha256.digest.x goes unused,
	// which is a waste of 64B.

	h  hash.Hash              // always *sha256.digest
	x  [sha256.BlockSize]byte // equivalent to sha256.digest.x
	nx int                    // equivalent to sha256.digest.nx
}

func New() *Hash {
	return &Hash{h: sha256.New()}
}

func (h *Hash) Write(b []byte) (int, error) {
	h.HashBytes(b)
	return len(b), nil
}

func (h *Hash) Sum(b []byte) []byte {
	if h.nx > 0 {
		// This causes block mis-alignment. Future operations will be correct,
		// but are less efficient until Reset is called.
		h.h.Write(h.x[:h.nx])
		h.nx = 0
	}
	return h.h.Sum(b)
}

func (h *Hash) Reset() {
	h.h.Reset()
	h.nx = 0
}

func (h *Hash) Size() int {
	return h.h.Size()
}

func (h *Hash) BlockSize() int {
	return h.h.BlockSize()
}

func (h *Hash) HashUint8(n uint8) {
	// NOTE: This method is carefully written to be inlineable.
	if h.nx <= len(h.x)-1 {
		h.x[h.nx] = n
		h.nx += 1
	} else {
		h.hashUint8Slow(n) // mark "noinline" to keep this within inline budget
	}
}

//go:noinline
func (h *Hash) hashUint8Slow(n uint8) { h.hashUint(uint64(n), 1) }

func (h *Hash) HashUint16(n uint16) {
	// NOTE: This method is carefully written to be inlineable.
	if h.nx <= len(h.x)-2 {
		binary.LittleEndian.PutUint16(h.x[h.nx:], n)
		h.nx += 2
	} else {
		h.hashUint16Slow(n) // mark "noinline" to keep this within inline budget
	}
}

//go:noinline
func (h *Hash) hashUint16Slow(n uint16) { h.hashUint(uint64(n), 2) }

func (h *Hash) HashUint32(n uint32) {
	// NOTE: This method is carefully written to be inlineable.
	if h.nx <= len(h.x)-4 {
		binary.LittleEndian.PutUint32(h.x[h.nx:], n)
		h.nx += 4
	} else {
		h.hashUint32Slow(n) // mark "noinline" to keep this within inline budget
	}
}

//go:noinline
func (h *Hash) hashUint32Slow(n uint32) { h.hashUint(uint64(n), 4) }

func (h *Hash) HashUint64(n uint64) {
	// NOTE: This method is carefully written to be inlineable.
	if h.nx <= len(h.x)-8 {
		binary.LittleEndian.PutUint64(h.x[h.nx:], n)
		h.nx += 8
	} else {
		h.hashUint64Slow(n) // mark "noinline" to keep this within inline budget
	}
}

//go:noinline
func (h *Hash) hashUint64Slow(n uint64) { h.hashUint(uint64(n), 8) }

func (h *Hash) hashUint(n uint64, i int) {
	for ; i > 0; i-- {
		if h.nx == len(h.x) {
			h.h.Write(h.x[:])
			h.nx = 0
		}
		h.x[h.nx] = byte(n)
		h.nx += 1
		n >>= 8
	}
}

func (h *Hash) HashBytes(b []byte) {
	// Nearly identical to sha256.digest.Write.
	if h.nx > 0 {
		n := copy(h.x[h.nx:], b)
		h.nx += n
		if h.nx == len(h.x) {
			h.h.Write(h.x[:])
			h.nx = 0
		}
		b = b[n:]
	}
	if len(b) >= len(h.x) {
		n := len(b) &^ (len(h.x) - 1) // n is a multiple of len(h.x)
		h.h.Write(b[:n])
		b = b[n:]
	}
	if len(b) > 0 {
		h.nx = copy(h.x[:], b)
	}
}

// TODO: Add Hash.MarshalBinary and Hash.UnmarshalBinary?
util/sha256x: new package (#5337) The hash.Hash provided by sha256.New is much more efficient if we always provide it with data a multiple of the block size. This avoids double-copying of data into the internal block of sha256.digest.x. Effectively, we are managing a block ourselves to ensure we only ever call hash.Hash.Write with full blocks. Performance: name old time/op new time/op delta Hash 33.5µs ± 1% 20.6µs ± 1% -38.40% (p=0.000 n=10+9) The logic has gone through CPU-hours of fuzzing. Signed-off-by: Joe Tsai <joetsai@digital-static.net> 2022-08-10 23:49:36 +01:00			`// Copyright (c) 2022 Tailscale Inc & AUTHORS All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`// Package sha256x is like crypto/sha256 with extra methods.`
			`// It exports a concrete Hash type`
			`// rather than only returning an interface implementation.`
			`package sha256x`

			`import (`
			`"crypto/sha256"`
			`"encoding/binary"`
			`"hash"`
			`)`

			`var _ hash.Hash = (*Hash)(nil)`

			`// Hash is a hash.Hash for SHA-256,`
			`// but has efficient methods for hashing fixed-width integers.`
			`type Hash struct {`
			`// The optimization is to maintain our own block and`
			`// only call h.Write with entire blocks.`
			`// This avoids double-copying of buffers within sha256.digest itself.`
			`// However, it does mean that sha256.digest.x goes unused,`
			`// which is a waste of 64B.`

			`h hash.Hash // always *sha256.digest`
			`x [sha256.BlockSize]byte // equivalent to sha256.digest.x`
			`nx int // equivalent to sha256.digest.nx`
			`}`

			`func New() *Hash {`
			`return &Hash{h: sha256.New()}`
			`}`

			`func (h *Hash) Write(b []byte) (int, error) {`
			`h.HashBytes(b)`
			`return len(b), nil`
			`}`

			`func (h *Hash) Sum(b []byte) []byte {`
			`if h.nx > 0 {`
			`// This causes block mis-alignment. Future operations will be correct,`
			`// but are less efficient until Reset is called.`
			`h.h.Write(h.x[:h.nx])`
			`h.nx = 0`
			`}`
			`return h.h.Sum(b)`
			`}`

			`func (h *Hash) Reset() {`
			`h.h.Reset()`
			`h.nx = 0`
			`}`

			`func (h *Hash) Size() int {`
			`return h.h.Size()`
			`}`

			`func (h *Hash) BlockSize() int {`
			`return h.h.BlockSize()`
			`}`

			`func (h *Hash) HashUint8(n uint8) {`
			`// NOTE: This method is carefully written to be inlineable.`
			`if h.nx <= len(h.x)-1 {`
			`h.x[h.nx] = n`
			`h.nx += 1`
			`} else {`
			`h.hashUint8Slow(n) // mark "noinline" to keep this within inline budget`
			`}`
			`}`

			`//go:noinline`
			`func (h *Hash) hashUint8Slow(n uint8) { h.hashUint(uint64(n), 1) }`

			`func (h *Hash) HashUint16(n uint16) {`
			`// NOTE: This method is carefully written to be inlineable.`
			`if h.nx <= len(h.x)-2 {`
			`binary.LittleEndian.PutUint16(h.x[h.nx:], n)`
			`h.nx += 2`
			`} else {`
			`h.hashUint16Slow(n) // mark "noinline" to keep this within inline budget`
			`}`
			`}`

			`//go:noinline`
			`func (h *Hash) hashUint16Slow(n uint16) { h.hashUint(uint64(n), 2) }`

			`func (h *Hash) HashUint32(n uint32) {`
			`// NOTE: This method is carefully written to be inlineable.`
			`if h.nx <= len(h.x)-4 {`
			`binary.LittleEndian.PutUint32(h.x[h.nx:], n)`
			`h.nx += 4`
			`} else {`
			`h.hashUint32Slow(n) // mark "noinline" to keep this within inline budget`
			`}`
			`}`

			`//go:noinline`
			`func (h *Hash) hashUint32Slow(n uint32) { h.hashUint(uint64(n), 4) }`

			`func (h *Hash) HashUint64(n uint64) {`
			`// NOTE: This method is carefully written to be inlineable.`
			`if h.nx <= len(h.x)-8 {`
			`binary.LittleEndian.PutUint64(h.x[h.nx:], n)`
			`h.nx += 8`
			`} else {`
			`h.hashUint64Slow(n) // mark "noinline" to keep this within inline budget`
			`}`
			`}`

			`//go:noinline`
			`func (h *Hash) hashUint64Slow(n uint64) { h.hashUint(uint64(n), 8) }`

			`func (h *Hash) hashUint(n uint64, i int) {`
			`for ; i > 0; i-- {`
			`if h.nx == len(h.x) {`
			`h.h.Write(h.x[:])`
			`h.nx = 0`
			`}`
			`h.x[h.nx] = byte(n)`
			`h.nx += 1`
			`n >>= 8`
			`}`
			`}`

			`func (h *Hash) HashBytes(b []byte) {`
			`// Nearly identical to sha256.digest.Write.`
			`if h.nx > 0 {`
			`n := copy(h.x[h.nx:], b)`
			`h.nx += n`
			`if h.nx == len(h.x) {`
			`h.h.Write(h.x[:])`
			`h.nx = 0`
			`}`
			`b = b[n:]`
			`}`
			`if len(b) >= len(h.x) {`
			`n := len(b) &^ (len(h.x) - 1) // n is a multiple of len(h.x)`
			`h.h.Write(b[:n])`
			`b = b[n:]`
			`}`
			`if len(b) > 0 {`
			`h.nx = copy(h.x[:], b)`
			`}`
			`}`

			`// TODO: Add Hash.MarshalBinary and Hash.UnmarshalBinary?`