Xray-core/common/strmatcher/mph_matcher.go

package strmatcher

import (
	"math/bits"
	"regexp"
	"sort"
	"strings"
	"unsafe"
)

// PrimeRK is the prime base used in Rabin-Karp algorithm.
const PrimeRK = 16777619

// calculate the rolling murmurHash of given string
func RollingHash(s string) uint32 {
	h := uint32(0)
	for i := len(s) - 1; i >= 0; i-- {
		h = h*PrimeRK + uint32(s[i])
	}
	return h
}

// A MphMatcherGroup is divided into three parts:
// 1. `full` and `domain` patterns are matched by Rabin-Karp algorithm and minimal perfect hash table;
// 2. `substr` patterns are matched by ac automaton;
// 3. `regex` patterns are matched with the regex library.
type MphMatcherGroup struct {
	ac            *ACAutomaton
	otherMatchers []matcherEntry
	rules         []string
	level0        []uint32
	level0Mask    int
	level1        []uint32
	level1Mask    int
	count         uint32
	ruleMap       *map[string]uint32
}

func (g *MphMatcherGroup) AddFullOrDomainPattern(pattern string, t Type) {
	h := RollingHash(pattern)
	switch t {
	case Domain:
		(*g.ruleMap)["."+pattern] = h*PrimeRK + uint32('.')
		fallthrough
	case Full:
		(*g.ruleMap)[pattern] = h
	default:
	}
}

func NewMphMatcherGroup() *MphMatcherGroup {
	return &MphMatcherGroup{
		ac:            nil,
		otherMatchers: nil,
		rules:         nil,
		level0:        nil,
		level0Mask:    0,
		level1:        nil,
		level1Mask:    0,
		count:         1,
		ruleMap:       &map[string]uint32{},
	}
}

// AddPattern adds a pattern to MphMatcherGroup
func (g *MphMatcherGroup) AddPattern(pattern string, t Type) (uint32, error) {
	switch t {
	case Substr:
		if g.ac == nil {
			g.ac = NewACAutomaton()
		}
		g.ac.Add(pattern, t)
	case Full, Domain:
		pattern = strings.ToLower(pattern)
		g.AddFullOrDomainPattern(pattern, t)
	case Regex:
		r, err := regexp.Compile(pattern)
		if err != nil {
			return 0, err
		}
		g.otherMatchers = append(g.otherMatchers, matcherEntry{
			m:  &regexMatcher{pattern: r},
			id: g.count,
		})
	default:
		panic("Unknown type")
	}
	return g.count, nil
}

// Build builds a minimal perfect hash table and ac automaton from insert rules
func (g *MphMatcherGroup) Build() {
	if g.ac != nil {
		g.ac.Build()
	}
	keyLen := len(*g.ruleMap)
	if keyLen == 0 {
		keyLen = 1
		(*g.ruleMap)["empty___"] = RollingHash("empty___")
	}
	g.level0 = make([]uint32, nextPow2(keyLen/4))
	g.level0Mask = len(g.level0) - 1
	g.level1 = make([]uint32, nextPow2(keyLen))
	g.level1Mask = len(g.level1) - 1
	var sparseBuckets = make([][]int, len(g.level0))
	var ruleIdx int
	for rule, hash := range *g.ruleMap {
		n := int(hash) & g.level0Mask
		g.rules = append(g.rules, rule)
		sparseBuckets[n] = append(sparseBuckets[n], ruleIdx)
		ruleIdx++
	}
	g.ruleMap = nil
	var buckets []indexBucket
	for n, vals := range sparseBuckets {
		if len(vals) > 0 {
			buckets = append(buckets, indexBucket{n, vals})
		}
	}
	sort.Sort(bySize(buckets))

	occ := make([]bool, len(g.level1))
	var tmpOcc []int
	for _, bucket := range buckets {
		var seed = uint32(0)
		for {
			findSeed := true
			tmpOcc = tmpOcc[:0]
			for _, i := range bucket.vals {
				n := int(strhashFallback(unsafe.Pointer(&g.rules[i]), uintptr(seed))) & g.level1Mask
				if occ[n] {
					for _, n := range tmpOcc {
						occ[n] = false
					}
					seed++
					findSeed = false
					break
				}
				occ[n] = true
				tmpOcc = append(tmpOcc, n)
				g.level1[n] = uint32(i)
			}
			if findSeed {
				g.level0[bucket.n] = seed
				break
			}
		}
	}
}

func nextPow2(v int) int {
	if v <= 1 {
		return 1
	}
	const MaxUInt = ^uint(0)
	n := (MaxUInt >> bits.LeadingZeros(uint(v))) + 1
	return int(n)
}

// Lookup searches for s in t and returns its index and whether it was found.
func (g *MphMatcherGroup) Lookup(h uint32, s string) bool {
	i0 := int(h) & g.level0Mask
	seed := g.level0[i0]
	i1 := int(strhashFallback(unsafe.Pointer(&s), uintptr(seed))) & g.level1Mask
	n := g.level1[i1]
	return s == g.rules[int(n)]
}

// Match implements IndexMatcher.Match.
func (g *MphMatcherGroup) Match(pattern string) []uint32 {
	result := []uint32{}
	hash := uint32(0)
	for i := len(pattern) - 1; i >= 0; i-- {
		hash = hash*PrimeRK + uint32(pattern[i])
		if pattern[i] == '.' {
			if g.Lookup(hash, pattern[i:]) {
				result = append(result, 1)
				return result
			}
		}
	}
	if g.Lookup(hash, pattern) {
		result = append(result, 1)
		return result
	}
	if g.ac != nil && g.ac.Match(pattern) {
		result = append(result, 1)
		return result
	}
	for _, e := range g.otherMatchers {
		if e.m.Match(pattern) {
			result = append(result, e.id)
			return result
		}
	}
	return nil
}

type indexBucket struct {
	n    int
	vals []int
}

type bySize []indexBucket

func (s bySize) Len() int           { return len(s) }
func (s bySize) Less(i, j int) bool { return len(s[i].vals) > len(s[j].vals) }
func (s bySize) Swap(i, j int)      { s[i], s[j] = s[j], s[i] }

type stringStruct struct {
	str unsafe.Pointer
	len int
}

func strhashFallback(a unsafe.Pointer, h uintptr) uintptr {
	x := (*stringStruct)(a)
	return memhashFallback(x.str, h, uintptr(x.len))
}

const (
	// Constants for multiplication: four random odd 64-bit numbers.
	m1 = 16877499708836156737
	m2 = 2820277070424839065
	m3 = 9497967016996688599
	m4 = 15839092249703872147
)

var hashkey = [4]uintptr{1, 1, 1, 1}

func memhashFallback(p unsafe.Pointer, seed, s uintptr) uintptr {
	h := uint64(seed + s*hashkey[0])
tail:
	switch {
	case s == 0:
	case s < 4:
		h ^= uint64(*(*byte)(p))
		h ^= uint64(*(*byte)(add(p, s>>1))) << 8
		h ^= uint64(*(*byte)(add(p, s-1))) << 16
		h = rotl31(h*m1) * m2
	case s <= 8:
		h ^= uint64(readUnaligned32(p))
		h ^= uint64(readUnaligned32(add(p, s-4))) << 32
		h = rotl31(h*m1) * m2
	case s <= 16:
		h ^= readUnaligned64(p)
		h = rotl31(h*m1) * m2
		h ^= readUnaligned64(add(p, s-8))
		h = rotl31(h*m1) * m2
	case s <= 32:
		h ^= readUnaligned64(p)
		h = rotl31(h*m1) * m2
		h ^= readUnaligned64(add(p, 8))
		h = rotl31(h*m1) * m2
		h ^= readUnaligned64(add(p, s-16))
		h = rotl31(h*m1) * m2
		h ^= readUnaligned64(add(p, s-8))
		h = rotl31(h*m1) * m2
	default:
		v1 := h
		v2 := uint64(seed * hashkey[1])
		v3 := uint64(seed * hashkey[2])
		v4 := uint64(seed * hashkey[3])
		for s >= 32 {
			v1 ^= readUnaligned64(p)
			v1 = rotl31(v1*m1) * m2
			p = add(p, 8)
			v2 ^= readUnaligned64(p)
			v2 = rotl31(v2*m2) * m3
			p = add(p, 8)
			v3 ^= readUnaligned64(p)
			v3 = rotl31(v3*m3) * m4
			p = add(p, 8)
			v4 ^= readUnaligned64(p)
			v4 = rotl31(v4*m4) * m1
			p = add(p, 8)
			s -= 32
		}
		h = v1 ^ v2 ^ v3 ^ v4
		goto tail
	}

	h ^= h >> 29
	h *= m3
	h ^= h >> 32
	return uintptr(h)
}
func add(p unsafe.Pointer, x uintptr) unsafe.Pointer {
	return unsafe.Pointer(uintptr(p) + x)
}
func readUnaligned32(p unsafe.Pointer) uint32 {
	q := (*[4]byte)(p)
	return uint32(q[0]) | uint32(q[1])<<8 | uint32(q[2])<<16 | uint32(q[3])<<24
}

func rotl31(x uint64) uint64 {
	return (x << 31) | (x >> (64 - 31))
}
func readUnaligned64(p unsafe.Pointer) uint64 {
	q := (*[8]byte)(p)
	return uint64(q[0]) | uint64(q[1])<<8 | uint64(q[2])<<16 | uint64(q[3])<<24 | uint64(q[4])<<32 | uint64(q[5])<<40 | uint64(q[6])<<48 | uint64(q[7])<<56
}
Refactor: A faster DomainMatcher implementation (#348) Co-authored-by: DarthVader <61409963+darsvador@users.noreply.github.com> 2021-04-18 08:21:17 +03:00			`package strmatcher`

			`import (`
			`"math/bits"`
			`"regexp"`
			`"sort"`
			`"strings"`
			`"unsafe"`
			`)`

			`// PrimeRK is the prime base used in Rabin-Karp algorithm.`
			`const PrimeRK = 16777619`

			`// calculate the rolling murmurHash of given string`
			`func RollingHash(s string) uint32 {`
			`h := uint32(0)`
			`for i := len(s) - 1; i >= 0; i-- {`
			`h = h*PrimeRK + uint32(s[i])`
			`}`
			`return h`
			`}`

			`// A MphMatcherGroup is divided into three parts:`
			// 1. `full` and `domain` patterns are matched by Rabin-Karp algorithm and minimal perfect hash table;
			// 2. `substr` patterns are matched by ac automaton;
			// 3. `regex` patterns are matched with the regex library.
			`type MphMatcherGroup struct {`
			`ac *ACAutomaton`
			`otherMatchers []matcherEntry`
			`rules []string`
			`level0 []uint32`
			`level0Mask int`
			`level1 []uint32`
			`level1Mask int`
			`count uint32`
			`ruleMap *map[string]uint32`
			`}`

			`func (g *MphMatcherGroup) AddFullOrDomainPattern(pattern string, t Type) {`
			`h := RollingHash(pattern)`
			`switch t {`
			`case Domain:`
			`(g.ruleMap)["."+pattern] = hPrimeRK + uint32('.')`
			`fallthrough`
			`case Full:`
			`(*g.ruleMap)[pattern] = h`
			`default:`
			`}`
			`}`

			`func NewMphMatcherGroup() *MphMatcherGroup {`
			`return &MphMatcherGroup{`
			`ac: nil,`
			`otherMatchers: nil,`
			`rules: nil,`
			`level0: nil,`
			`level0Mask: 0,`
			`level1: nil,`
			`level1Mask: 0,`
			`count: 1,`
			`ruleMap: &map[string]uint32{},`
			`}`
			`}`

			`// AddPattern adds a pattern to MphMatcherGroup`
			`func (g *MphMatcherGroup) AddPattern(pattern string, t Type) (uint32, error) {`
			`switch t {`
			`case Substr:`
			`if g.ac == nil {`
			`g.ac = NewACAutomaton()`
			`}`
			`g.ac.Add(pattern, t)`
			`case Full, Domain:`
			`pattern = strings.ToLower(pattern)`
			`g.AddFullOrDomainPattern(pattern, t)`
			`case Regex:`
			`r, err := regexp.Compile(pattern)`
			`if err != nil {`
			`return 0, err`
			`}`
			`g.otherMatchers = append(g.otherMatchers, matcherEntry{`
			`m: &regexMatcher{pattern: r},`
			`id: g.count,`
			`})`
			`default:`
			`panic("Unknown type")`
			`}`
			`return g.count, nil`
			`}`

			`// Build builds a minimal perfect hash table and ac automaton from insert rules`
			`func (g *MphMatcherGroup) Build() {`
			`if g.ac != nil {`
			`g.ac.Build()`
			`}`
			`keyLen := len(*g.ruleMap)`
			`if keyLen == 0 {`
			`keyLen = 1`
			`(*g.ruleMap)["empty___"] = RollingHash("empty___")`
			`}`
			`g.level0 = make([]uint32, nextPow2(keyLen/4))`
			`g.level0Mask = len(g.level0) - 1`
			`g.level1 = make([]uint32, nextPow2(keyLen))`
			`g.level1Mask = len(g.level1) - 1`
			`var sparseBuckets = make([][]int, len(g.level0))`
			`var ruleIdx int`
			`for rule, hash := range *g.ruleMap {`
			`n := int(hash) & g.level0Mask`
			`g.rules = append(g.rules, rule)`
			`sparseBuckets[n] = append(sparseBuckets[n], ruleIdx)`
			`ruleIdx++`
			`}`
			`g.ruleMap = nil`
			`var buckets []indexBucket`
			`for n, vals := range sparseBuckets {`
			`if len(vals) > 0 {`
			`buckets = append(buckets, indexBucket{n, vals})`
			`}`
			`}`
			`sort.Sort(bySize(buckets))`

			`occ := make([]bool, len(g.level1))`
			`var tmpOcc []int`
			`for _, bucket := range buckets {`
			`var seed = uint32(0)`
			`for {`
			`findSeed := true`
			`tmpOcc = tmpOcc[:0]`
			`for _, i := range bucket.vals {`
			`n := int(strhashFallback(unsafe.Pointer(&g.rules[i]), uintptr(seed))) & g.level1Mask`
			`if occ[n] {`
			`for _, n := range tmpOcc {`
			`occ[n] = false`
			`}`
			`seed++`
			`findSeed = false`
			`break`
			`}`
			`occ[n] = true`
			`tmpOcc = append(tmpOcc, n)`
			`g.level1[n] = uint32(i)`
			`}`
			`if findSeed {`
			`g.level0[bucket.n] = seed`
			`break`
			`}`
			`}`
			`}`
			`}`

			`func nextPow2(v int) int {`
			`if v <= 1 {`
			`return 1`
			`}`
			`const MaxUInt = ^uint(0)`
			`n := (MaxUInt >> bits.LeadingZeros(uint(v))) + 1`
			`return int(n)`
			`}`

			`// Lookup searches for s in t and returns its index and whether it was found.`
			`func (g *MphMatcherGroup) Lookup(h uint32, s string) bool {`
			`i0 := int(h) & g.level0Mask`
			`seed := g.level0[i0]`
			`i1 := int(strhashFallback(unsafe.Pointer(&s), uintptr(seed))) & g.level1Mask`
			`n := g.level1[i1]`
			`return s == g.rules[int(n)]`
			`}`

			`// Match implements IndexMatcher.Match.`
			`func (g *MphMatcherGroup) Match(pattern string) []uint32 {`
			`result := []uint32{}`
			`hash := uint32(0)`
			`for i := len(pattern) - 1; i >= 0; i-- {`
			`hash = hash*PrimeRK + uint32(pattern[i])`
			`if pattern[i] == '.' {`
			`if g.Lookup(hash, pattern[i:]) {`
			`result = append(result, 1)`
			`return result`
			`}`
			`}`
			`}`
			`if g.Lookup(hash, pattern) {`
			`result = append(result, 1)`
			`return result`
			`}`
			`if g.ac != nil && g.ac.Match(pattern) {`
			`result = append(result, 1)`
			`return result`
			`}`
			`for _, e := range g.otherMatchers {`
			`if e.m.Match(pattern) {`
			`result = append(result, e.id)`
			`return result`
			`}`
			`}`
			`return nil`
			`}`

			`type indexBucket struct {`
			`n int`
			`vals []int`
			`}`

			`type bySize []indexBucket`

			`func (s bySize) Len() int { return len(s) }`
			`func (s bySize) Less(i, j int) bool { return len(s[i].vals) > len(s[j].vals) }`
			`func (s bySize) Swap(i, j int) { s[i], s[j] = s[j], s[i] }`

			`type stringStruct struct {`
			`str unsafe.Pointer`
			`len int`
			`}`

			`func strhashFallback(a unsafe.Pointer, h uintptr) uintptr {`
			`x := (*stringStruct)(a)`
			`return memhashFallback(x.str, h, uintptr(x.len))`
			`}`

			`const (`
			`// Constants for multiplication: four random odd 64-bit numbers.`
			`m1 = 16877499708836156737`
			`m2 = 2820277070424839065`
			`m3 = 9497967016996688599`
			`m4 = 15839092249703872147`
			`)`

			`var hashkey = [4]uintptr{1, 1, 1, 1}`

			`func memhashFallback(p unsafe.Pointer, seed, s uintptr) uintptr {`
			`h := uint64(seed + s*hashkey[0])`
			`tail:`
			`switch {`
			`case s == 0:`
			`case s < 4:`
			`h ^= uint64((byte)(p))`
			`h ^= uint64((byte)(add(p, s>>1))) << 8`
			`h ^= uint64((byte)(add(p, s-1))) << 16`
			`h = rotl31(hm1) m2`
			`case s <= 8:`
			`h ^= uint64(readUnaligned32(p))`
			`h ^= uint64(readUnaligned32(add(p, s-4))) << 32`
			`h = rotl31(hm1) m2`
			`case s <= 16:`
			`h ^= readUnaligned64(p)`
			`h = rotl31(hm1) m2`
			`h ^= readUnaligned64(add(p, s-8))`
			`h = rotl31(hm1) m2`
			`case s <= 32:`
			`h ^= readUnaligned64(p)`
			`h = rotl31(hm1) m2`
			`h ^= readUnaligned64(add(p, 8))`
			`h = rotl31(hm1) m2`
			`h ^= readUnaligned64(add(p, s-16))`
			`h = rotl31(hm1) m2`
			`h ^= readUnaligned64(add(p, s-8))`
			`h = rotl31(hm1) m2`
			`default:`
			`v1 := h`
			`v2 := uint64(seed * hashkey[1])`
			`v3 := uint64(seed * hashkey[2])`
			`v4 := uint64(seed * hashkey[3])`
			`for s >= 32 {`
			`v1 ^= readUnaligned64(p)`
			`v1 = rotl31(v1m1) m2`
			`p = add(p, 8)`
			`v2 ^= readUnaligned64(p)`
			`v2 = rotl31(v2m2) m3`
			`p = add(p, 8)`
			`v3 ^= readUnaligned64(p)`
			`v3 = rotl31(v3m3) m4`
			`p = add(p, 8)`
			`v4 ^= readUnaligned64(p)`
			`v4 = rotl31(v4m4) m1`
			`p = add(p, 8)`
			`s -= 32`
			`}`
			`h = v1 ^ v2 ^ v3 ^ v4`
			`goto tail`
			`}`

			`h ^= h >> 29`
			`h *= m3`
			`h ^= h >> 32`
			`return uintptr(h)`
			`}`
			`func add(p unsafe.Pointer, x uintptr) unsafe.Pointer {`
			`return unsafe.Pointer(uintptr(p) + x)`
			`}`
			`func readUnaligned32(p unsafe.Pointer) uint32 {`
			`q := (*[4]byte)(p)`
			`return uint32(q[0]) \| uint32(q[1])<<8 \| uint32(q[2])<<16 \| uint32(q[3])<<24`
			`}`

			`func rotl31(x uint64) uint64 {`
			`return (x << 31) \| (x >> (64 - 31))`
			`}`
			`func readUnaligned64(p unsafe.Pointer) uint64 {`
			`q := (*[8]byte)(p)`
			`return uint64(q[0]) \| uint64(q[1])<<8 \| uint64(q[2])<<16 \| uint64(q[3])<<24 \| uint64(q[4])<<32 \| uint64(q[5])<<40 \| uint64(q[6])<<48 \| uint64(q[7])<<56`
			`}`