gotosocial/vendor/github.com/godbus/dbus/v5/variant_lexer.go

package dbus

import (
	"fmt"
	"strings"
	"unicode"
	"unicode/utf8"
)

// Heavily inspired by the lexer from text/template.

type varToken struct {
	typ varTokenType
	val string
}

type varTokenType byte

const (
	tokEOF varTokenType = iota
	tokError
	tokNumber
	tokString
	tokBool
	tokArrayStart
	tokArrayEnd
	tokDictStart
	tokDictEnd
	tokVariantStart
	tokVariantEnd
	tokComma
	tokColon
	tokType
	tokByteString
)

type varLexer struct {
	input  string
	start  int
	pos    int
	width  int
	tokens []varToken
}

type lexState func(*varLexer) lexState

func varLex(s string) []varToken {
	l := &varLexer{input: s}
	l.run()
	return l.tokens
}

func (l *varLexer) accept(valid string) bool {
	if strings.ContainsRune(valid, l.next()) {
		return true
	}
	l.backup()
	return false
}

func (l *varLexer) backup() {
	l.pos -= l.width
}

func (l *varLexer) emit(t varTokenType) {
	l.tokens = append(l.tokens, varToken{t, l.input[l.start:l.pos]})
	l.start = l.pos
}

func (l *varLexer) errorf(format string, v ...interface{}) lexState {
	l.tokens = append(l.tokens, varToken{
		tokError,
		fmt.Sprintf(format, v...),
	})
	return nil
}

func (l *varLexer) ignore() {
	l.start = l.pos
}

func (l *varLexer) next() rune {
	var r rune

	if l.pos >= len(l.input) {
		l.width = 0
		return -1
	}
	r, l.width = utf8.DecodeRuneInString(l.input[l.pos:])
	l.pos += l.width
	return r
}

func (l *varLexer) run() {
	for state := varLexNormal; state != nil; {
		state = state(l)
	}
}

func (l *varLexer) peek() rune {
	r := l.next()
	l.backup()
	return r
}

func varLexNormal(l *varLexer) lexState {
	for {
		r := l.next()
		switch {
		case r == -1:
			l.emit(tokEOF)
			return nil
		case r == '[':
			l.emit(tokArrayStart)
		case r == ']':
			l.emit(tokArrayEnd)
		case r == '{':
			l.emit(tokDictStart)
		case r == '}':
			l.emit(tokDictEnd)
		case r == '<':
			l.emit(tokVariantStart)
		case r == '>':
			l.emit(tokVariantEnd)
		case r == ':':
			l.emit(tokColon)
		case r == ',':
			l.emit(tokComma)
		case r == '\'' || r == '"':
			l.backup()
			return varLexString
		case r == '@':
			l.backup()
			return varLexType
		case unicode.IsSpace(r):
			l.ignore()
		case unicode.IsNumber(r) || r == '+' || r == '-':
			l.backup()
			return varLexNumber
		case r == 'b':
			pos := l.start
			if n := l.peek(); n == '"' || n == '\'' {
				return varLexByteString
			}
			// not a byte string; try to parse it as a type or bool below
			l.pos = pos + 1
			l.width = 1
			fallthrough
		default:
			// either a bool or a type. Try bools first.
			l.backup()
			if l.pos+4 <= len(l.input) {
				if l.input[l.pos:l.pos+4] == "true" {
					l.pos += 4
					l.emit(tokBool)
					continue
				}
			}
			if l.pos+5 <= len(l.input) {
				if l.input[l.pos:l.pos+5] == "false" {
					l.pos += 5
					l.emit(tokBool)
					continue
				}
			}
			// must be a type.
			return varLexType
		}
	}
}

var varTypeMap = map[string]string{
	"boolean":    "b",
	"byte":       "y",
	"int16":      "n",
	"uint16":     "q",
	"int32":      "i",
	"uint32":     "u",
	"int64":      "x",
	"uint64":     "t",
	"double":     "f",
	"string":     "s",
	"objectpath": "o",
	"signature":  "g",
}

func varLexByteString(l *varLexer) lexState {
	q := l.next()
Loop:
	for {
		switch l.next() {
		case '\\':
			if r := l.next(); r != -1 {
				break
			}
			fallthrough
		case -1:
			return l.errorf("unterminated bytestring")
		case q:
			break Loop
		}
	}
	l.emit(tokByteString)
	return varLexNormal
}

func varLexNumber(l *varLexer) lexState {
	l.accept("+-")
	digits := "0123456789"
	if l.accept("0") {
		if l.accept("x") {
			digits = "0123456789abcdefABCDEF"
		} else {
			digits = "01234567"
		}
	}
	for strings.ContainsRune(digits, l.next()) {
	}
	l.backup()
	if l.accept(".") {
		for strings.ContainsRune(digits, l.next()) {
		}
		l.backup()
	}
	if l.accept("eE") {
		l.accept("+-")
		for strings.ContainsRune("0123456789", l.next()) {
		}
		l.backup()
	}
	if r := l.peek(); unicode.IsLetter(r) {
		l.next()
		return l.errorf("bad number syntax: %q", l.input[l.start:l.pos])
	}
	l.emit(tokNumber)
	return varLexNormal
}

func varLexString(l *varLexer) lexState {
	q := l.next()
Loop:
	for {
		switch l.next() {
		case '\\':
			if r := l.next(); r != -1 {
				break
			}
			fallthrough
		case -1:
			return l.errorf("unterminated string")
		case q:
			break Loop
		}
	}
	l.emit(tokString)
	return varLexNormal
}

func varLexType(l *varLexer) lexState {
	at := l.accept("@")
	for {
		r := l.next()
		if r == -1 {
			break
		}
		if unicode.IsSpace(r) {
			l.backup()
			break
		}
	}
	if at {
		if _, err := ParseSignature(l.input[l.start+1 : l.pos]); err != nil {
			return l.errorf("%s", err)
		}
	} else {
		if _, ok := varTypeMap[l.input[l.start:l.pos]]; ok {
			l.emit(tokType)
			return varLexNormal
		}
		return l.errorf("unrecognized type %q", l.input[l.start:l.pos])
	}
	l.emit(tokType)
	return varLexNormal
}
[feature] Inherit resource limits from cgroups (#1336) When GTS is running in a container runtime which has configured CPU or memory limits or under an init system that uses cgroups to impose CPU and memory limits the values the Go runtime sees for GOMAXPROCS and GOMEMLIMIT are still based on the host resources, not the cgroup. At least for the throttling middlewares which use GOMAXPROCS to configure their queue size, this can result in GTS running with values too big compared to the resources that will actuall be available to it. This introduces 2 dependencies which can pick up resource contraints from the current cgroup and tune the Go runtime accordingly. This should result in the different queues being appropriately sized and in general more predictable performance. These dependencies are a no-op on non-Linux systems or if running in a cgroup that doesn't set a limit on CPU or memory. The automatic tuning of GOMEMLIMIT can be disabled by either explicitly setting GOMEMLIMIT yourself or by setting AUTOMEMLIMIT=off. The automatic tuning of GOMAXPROCS can similarly be counteracted by setting GOMAXPROCS yourself. 2023-01-17 20:59:04 +00:00			`package dbus`

			`import (`
			`"fmt"`
			`"strings"`
			`"unicode"`
			`"unicode/utf8"`
			`)`

			`// Heavily inspired by the lexer from text/template.`

			`type varToken struct {`
			`typ varTokenType`
			`val string`
			`}`

			`type varTokenType byte`

			`const (`
			`tokEOF varTokenType = iota`
			`tokError`
			`tokNumber`
			`tokString`
			`tokBool`
			`tokArrayStart`
			`tokArrayEnd`
			`tokDictStart`
			`tokDictEnd`
			`tokVariantStart`
			`tokVariantEnd`
			`tokComma`
			`tokColon`
			`tokType`
			`tokByteString`
			`)`

			`type varLexer struct {`
			`input string`
			`start int`
			`pos int`
			`width int`
			`tokens []varToken`
			`}`

			`type lexState func(*varLexer) lexState`

			`func varLex(s string) []varToken {`
			`l := &varLexer{input: s}`
			`l.run()`
			`return l.tokens`
			`}`

			`func (l *varLexer) accept(valid string) bool {`
			`if strings.ContainsRune(valid, l.next()) {`
			`return true`
			`}`
			`l.backup()`
			`return false`
			`}`

			`func (l *varLexer) backup() {`
			`l.pos -= l.width`
			`}`

			`func (l *varLexer) emit(t varTokenType) {`
			`l.tokens = append(l.tokens, varToken{t, l.input[l.start:l.pos]})`
			`l.start = l.pos`
			`}`

			`func (l *varLexer) errorf(format string, v ...interface{}) lexState {`
			`l.tokens = append(l.tokens, varToken{`
			`tokError,`
			`fmt.Sprintf(format, v...),`
			`})`
			`return nil`
			`}`

			`func (l *varLexer) ignore() {`
			`l.start = l.pos`
			`}`

			`func (l *varLexer) next() rune {`
			`var r rune`

			`if l.pos >= len(l.input) {`
			`l.width = 0`
			`return -1`
			`}`
			`r, l.width = utf8.DecodeRuneInString(l.input[l.pos:])`
			`l.pos += l.width`
			`return r`
			`}`

			`func (l *varLexer) run() {`
			`for state := varLexNormal; state != nil; {`
			`state = state(l)`
			`}`
			`}`

			`func (l *varLexer) peek() rune {`
			`r := l.next()`
			`l.backup()`
			`return r`
			`}`

			`func varLexNormal(l *varLexer) lexState {`
			`for {`
			`r := l.next()`
			`switch {`
			`case r == -1:`
			`l.emit(tokEOF)`
			`return nil`
			`case r == '[':`
			`l.emit(tokArrayStart)`
			`case r == ']':`
			`l.emit(tokArrayEnd)`
			`case r == '{':`
			`l.emit(tokDictStart)`
			`case r == '}':`
			`l.emit(tokDictEnd)`
			`case r == '<':`
			`l.emit(tokVariantStart)`
			`case r == '>':`
			`l.emit(tokVariantEnd)`
			`case r == ':':`
			`l.emit(tokColon)`
			`case r == ',':`
			`l.emit(tokComma)`
			`case r == '\'' \|\| r == '"':`
			`l.backup()`
			`return varLexString`
			`case r == '@':`
			`l.backup()`
			`return varLexType`
			`case unicode.IsSpace(r):`
			`l.ignore()`
			`case unicode.IsNumber(r) \|\| r == '+' \|\| r == '-':`
			`l.backup()`
			`return varLexNumber`
			`case r == 'b':`
			`pos := l.start`
			`if n := l.peek(); n == '"' \|\| n == '\'' {`
			`return varLexByteString`
			`}`
			`// not a byte string; try to parse it as a type or bool below`
			`l.pos = pos + 1`
			`l.width = 1`
			`fallthrough`
			`default:`
			`// either a bool or a type. Try bools first.`
			`l.backup()`
			`if l.pos+4 <= len(l.input) {`
			`if l.input[l.pos:l.pos+4] == "true" {`
			`l.pos += 4`
			`l.emit(tokBool)`
			`continue`
			`}`
			`}`
			`if l.pos+5 <= len(l.input) {`
			`if l.input[l.pos:l.pos+5] == "false" {`
			`l.pos += 5`
			`l.emit(tokBool)`
			`continue`
			`}`
			`}`
			`// must be a type.`
			`return varLexType`
			`}`
			`}`
			`}`

			`var varTypeMap = map[string]string{`
			`"boolean": "b",`
			`"byte": "y",`
			`"int16": "n",`
			`"uint16": "q",`
			`"int32": "i",`
			`"uint32": "u",`
			`"int64": "x",`
			`"uint64": "t",`
			`"double": "f",`
			`"string": "s",`
			`"objectpath": "o",`
			`"signature": "g",`
			`}`

			`func varLexByteString(l *varLexer) lexState {`
			`q := l.next()`
			`Loop:`
			`for {`
			`switch l.next() {`
			`case '\\':`
			`if r := l.next(); r != -1 {`
			`break`
			`}`
			`fallthrough`
			`case -1:`
			`return l.errorf("unterminated bytestring")`
			`case q:`
			`break Loop`
			`}`
			`}`
			`l.emit(tokByteString)`
			`return varLexNormal`
			`}`

			`func varLexNumber(l *varLexer) lexState {`
			`l.accept("+-")`
			`digits := "0123456789"`
			`if l.accept("0") {`
			`if l.accept("x") {`
			`digits = "0123456789abcdefABCDEF"`
			`} else {`
			`digits = "01234567"`
			`}`
			`}`
			`for strings.ContainsRune(digits, l.next()) {`
			`}`
			`l.backup()`
			`if l.accept(".") {`
			`for strings.ContainsRune(digits, l.next()) {`
			`}`
			`l.backup()`
			`}`
			`if l.accept("eE") {`
			`l.accept("+-")`
			`for strings.ContainsRune("0123456789", l.next()) {`
			`}`
			`l.backup()`
			`}`
			`if r := l.peek(); unicode.IsLetter(r) {`
			`l.next()`
			`return l.errorf("bad number syntax: %q", l.input[l.start:l.pos])`
			`}`
			`l.emit(tokNumber)`
			`return varLexNormal`
			`}`

			`func varLexString(l *varLexer) lexState {`
			`q := l.next()`
			`Loop:`
			`for {`
			`switch l.next() {`
			`case '\\':`
			`if r := l.next(); r != -1 {`
			`break`
			`}`
			`fallthrough`
			`case -1:`
			`return l.errorf("unterminated string")`
			`case q:`
			`break Loop`
			`}`
			`}`
			`l.emit(tokString)`
			`return varLexNormal`
			`}`

			`func varLexType(l *varLexer) lexState {`
			`at := l.accept("@")`
			`for {`
			`r := l.next()`
			`if r == -1 {`
			`break`
			`}`
			`if unicode.IsSpace(r) {`
			`l.backup()`
			`break`
			`}`
			`}`
			`if at {`
			`if _, err := ParseSignature(l.input[l.start+1 : l.pos]); err != nil {`
			`return l.errorf("%s", err)`
			`}`
			`} else {`
			`if _, ok := varTypeMap[l.input[l.start:l.pos]]; ok {`
			`l.emit(tokType)`
			`return varLexNormal`
			`}`
			`return l.errorf("unrecognized type %q", l.input[l.start:l.pos])`
			`}`
			`l.emit(tokType)`
			`return varLexNormal`
			`}`