peridot/vendor/k8s.io/kube-openapi/pkg/internal/third_party/go-json-experiment/json/intern.go

// Copyright 2022 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.

package json

import (
	"encoding/binary"
	"math/bits"
)

// stringCache is a cache for strings converted from a []byte.
type stringCache [256]string // 256*unsafe.Sizeof(string("")) => 4KiB

// make returns the string form of b.
// It returns a pre-allocated string from c if present, otherwise
// it allocates a new string, inserts it into the cache, and returns it.
func (c *stringCache) make(b []byte) string {
	const (
		minCachedLen = 2   // single byte strings are already interned by the runtime
		maxCachedLen = 256 // large enough for UUIDs, IPv6 addresses, SHA-256 checksums, etc.
	)
	if c == nil || len(b) < minCachedLen || len(b) > maxCachedLen {
		return string(b)
	}

	// Compute a hash from the fixed-width prefix and suffix of the string.
	// This ensures hashing a string is a constant time operation.
	var h uint32
	switch {
	case len(b) >= 8:
		lo := binary.LittleEndian.Uint64(b[:8])
		hi := binary.LittleEndian.Uint64(b[len(b)-8:])
		h = hash64(uint32(lo), uint32(lo>>32)) ^ hash64(uint32(hi), uint32(hi>>32))
	case len(b) >= 4:
		lo := binary.LittleEndian.Uint32(b[:4])
		hi := binary.LittleEndian.Uint32(b[len(b)-4:])
		h = hash64(lo, hi)
	case len(b) >= 2:
		lo := binary.LittleEndian.Uint16(b[:2])
		hi := binary.LittleEndian.Uint16(b[len(b)-2:])
		h = hash64(uint32(lo), uint32(hi))
	}

	// Check the cache for the string.
	i := h % uint32(len(*c))
	if s := (*c)[i]; s == string(b) {
		return s
	}
	s := string(b)
	(*c)[i] = s
	return s
}

// hash64 returns the hash of two uint32s as a single uint32.
func hash64(lo, hi uint32) uint32 {
	// If avalanche=true, this is identical to XXH32 hash on a 8B string:
	//	var b [8]byte
	//	binary.LittleEndian.PutUint32(b[:4], lo)
	//	binary.LittleEndian.PutUint32(b[4:], hi)
	//	return xxhash.Sum32(b[:])
	const (
		prime1 = 0x9e3779b1
		prime2 = 0x85ebca77
		prime3 = 0xc2b2ae3d
		prime4 = 0x27d4eb2f
		prime5 = 0x165667b1
	)
	h := prime5 + uint32(8)
	h += lo * prime3
	h = bits.RotateLeft32(h, 17) * prime4
	h += hi * prime3
	h = bits.RotateLeft32(h, 17) * prime4
	// Skip final mix (avalanche) step of XXH32 for performance reasons.
	// Empirical testing shows that the improvements in unbiased distribution
	// does not outweigh the extra cost in computational complexity.
	const avalanche = false
	if avalanche {
		h ^= h >> 15
		h *= prime2
		h ^= h >> 13
		h *= prime3
		h ^= h >> 16
	}
	return h
}
Major upgrades Upgrade to Go 1.20.5, Hydra v2 SDK, rules-go v0.44.2 (with proper resolves), protobuf v25.3 and mass upgrade of Go dependencies. 2024-02-24 00:34:55 +00:00			`// Copyright 2022 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.`

			`package json`

			`import (`
			`"encoding/binary"`
			`"math/bits"`
			`)`

			`// stringCache is a cache for strings converted from a []byte.`
			`type stringCache [256]string // 256*unsafe.Sizeof(string("")) => 4KiB`

			`// make returns the string form of b.`
			`// It returns a pre-allocated string from c if present, otherwise`
			`// it allocates a new string, inserts it into the cache, and returns it.`
			`func (c *stringCache) make(b []byte) string {`
			`const (`
			`minCachedLen = 2 // single byte strings are already interned by the runtime`
			`maxCachedLen = 256 // large enough for UUIDs, IPv6 addresses, SHA-256 checksums, etc.`
			`)`
			`if c == nil \|\| len(b) < minCachedLen \|\| len(b) > maxCachedLen {`
			`return string(b)`
			`}`

			`// Compute a hash from the fixed-width prefix and suffix of the string.`
			`// This ensures hashing a string is a constant time operation.`
			`var h uint32`
			`switch {`
			`case len(b) >= 8:`
			`lo := binary.LittleEndian.Uint64(b[:8])`
			`hi := binary.LittleEndian.Uint64(b[len(b)-8:])`
			`h = hash64(uint32(lo), uint32(lo>>32)) ^ hash64(uint32(hi), uint32(hi>>32))`
			`case len(b) >= 4:`
			`lo := binary.LittleEndian.Uint32(b[:4])`
			`hi := binary.LittleEndian.Uint32(b[len(b)-4:])`
			`h = hash64(lo, hi)`
			`case len(b) >= 2:`
			`lo := binary.LittleEndian.Uint16(b[:2])`
			`hi := binary.LittleEndian.Uint16(b[len(b)-2:])`
			`h = hash64(uint32(lo), uint32(hi))`
			`}`

			`// Check the cache for the string.`
			`i := h % uint32(len(*c))`
			`if s := (*c)[i]; s == string(b) {`
			`return s`
			`}`
			`s := string(b)`
			`(*c)[i] = s`
			`return s`
			`}`

			`// hash64 returns the hash of two uint32s as a single uint32.`
			`func hash64(lo, hi uint32) uint32 {`
			`// If avalanche=true, this is identical to XXH32 hash on a 8B string:`
			`// var b [8]byte`
			`// binary.LittleEndian.PutUint32(b[:4], lo)`
			`// binary.LittleEndian.PutUint32(b[4:], hi)`
			`// return xxhash.Sum32(b[:])`
			`const (`
			`prime1 = 0x9e3779b1`
			`prime2 = 0x85ebca77`
			`prime3 = 0xc2b2ae3d`
			`prime4 = 0x27d4eb2f`
			`prime5 = 0x165667b1`
			`)`
			`h := prime5 + uint32(8)`
			`h += lo * prime3`
			`h = bits.RotateLeft32(h, 17) * prime4`
			`h += hi * prime3`
			`h = bits.RotateLeft32(h, 17) * prime4`
			`// Skip final mix (avalanche) step of XXH32 for performance reasons.`
			`// Empirical testing shows that the improvements in unbiased distribution`
			`// does not outweigh the extra cost in computational complexity.`
			`const avalanche = false`
			`if avalanche {`
			`h ^= h >> 15`
			`h *= prime2`
			`h ^= h >> 13`
			`h *= prime3`
			`h ^= h >> 16`
			`}`
			`return h`
			`}`