matterbridge/vendor/github.com/go-asn1-ber/asn1-ber/ber.go

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package ber
import (
"bytes"
"errors"
"fmt"
"io"
"io/ioutil"
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"math"
"os"
"reflect"
"strconv"
"strings"
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"time"
"unicode/utf8"
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)
// MaxPacketLengthBytes specifies the maximum allowed packet size when calling ReadPacket or DecodePacket. Set to 0 for
// no limit.
var MaxPacketLengthBytes int64 = math.MaxInt32
type Packet struct {
Identifier
Value interface{}
ByteValue []byte
Data *bytes.Buffer
Children []*Packet
Description string
}
type Identifier struct {
ClassType Class
TagType Type
Tag Tag
}
type Tag uint64
const (
TagEOC Tag = 0x00
TagBoolean Tag = 0x01
TagInteger Tag = 0x02
TagBitString Tag = 0x03
TagOctetString Tag = 0x04
TagNULL Tag = 0x05
TagObjectIdentifier Tag = 0x06
TagObjectDescriptor Tag = 0x07
TagExternal Tag = 0x08
TagRealFloat Tag = 0x09
TagEnumerated Tag = 0x0a
TagEmbeddedPDV Tag = 0x0b
TagUTF8String Tag = 0x0c
TagRelativeOID Tag = 0x0d
TagSequence Tag = 0x10
TagSet Tag = 0x11
TagNumericString Tag = 0x12
TagPrintableString Tag = 0x13
TagT61String Tag = 0x14
TagVideotexString Tag = 0x15
TagIA5String Tag = 0x16
TagUTCTime Tag = 0x17
TagGeneralizedTime Tag = 0x18
TagGraphicString Tag = 0x19
TagVisibleString Tag = 0x1a
TagGeneralString Tag = 0x1b
TagUniversalString Tag = 0x1c
TagCharacterString Tag = 0x1d
TagBMPString Tag = 0x1e
TagBitmask Tag = 0x1f // xxx11111b
// HighTag indicates the start of a high-tag byte sequence
HighTag Tag = 0x1f // xxx11111b
// HighTagContinueBitmask indicates the high-tag byte sequence should continue
HighTagContinueBitmask Tag = 0x80 // 10000000b
// HighTagValueBitmask obtains the tag value from a high-tag byte sequence byte
HighTagValueBitmask Tag = 0x7f // 01111111b
)
const (
// LengthLongFormBitmask is the mask to apply to the length byte to see if a long-form byte sequence is used
LengthLongFormBitmask = 0x80
// LengthValueBitmask is the mask to apply to the length byte to get the number of bytes in the long-form byte sequence
LengthValueBitmask = 0x7f
// LengthIndefinite is returned from readLength to indicate an indefinite length
LengthIndefinite = -1
)
var tagMap = map[Tag]string{
TagEOC: "EOC (End-of-Content)",
TagBoolean: "Boolean",
TagInteger: "Integer",
TagBitString: "Bit String",
TagOctetString: "Octet String",
TagNULL: "NULL",
TagObjectIdentifier: "Object Identifier",
TagObjectDescriptor: "Object Descriptor",
TagExternal: "External",
TagRealFloat: "Real (float)",
TagEnumerated: "Enumerated",
TagEmbeddedPDV: "Embedded PDV",
TagUTF8String: "UTF8 String",
TagRelativeOID: "Relative-OID",
TagSequence: "Sequence and Sequence of",
TagSet: "Set and Set OF",
TagNumericString: "Numeric String",
TagPrintableString: "Printable String",
TagT61String: "T61 String",
TagVideotexString: "Videotex String",
TagIA5String: "IA5 String",
TagUTCTime: "UTC Time",
TagGeneralizedTime: "Generalized Time",
TagGraphicString: "Graphic String",
TagVisibleString: "Visible String",
TagGeneralString: "General String",
TagUniversalString: "Universal String",
TagCharacterString: "Character String",
TagBMPString: "BMP String",
}
type Class uint8
const (
ClassUniversal Class = 0 // 00xxxxxxb
ClassApplication Class = 64 // 01xxxxxxb
ClassContext Class = 128 // 10xxxxxxb
ClassPrivate Class = 192 // 11xxxxxxb
ClassBitmask Class = 192 // 11xxxxxxb
)
var ClassMap = map[Class]string{
ClassUniversal: "Universal",
ClassApplication: "Application",
ClassContext: "Context",
ClassPrivate: "Private",
}
type Type uint8
const (
TypePrimitive Type = 0 // xx0xxxxxb
TypeConstructed Type = 32 // xx1xxxxxb
TypeBitmask Type = 32 // xx1xxxxxb
)
var TypeMap = map[Type]string{
TypePrimitive: "Primitive",
TypeConstructed: "Constructed",
}
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var Debug = false
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func PrintBytes(out io.Writer, buf []byte, indent string) {
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dataLines := make([]string, (len(buf)/30)+1)
numLines := make([]string, (len(buf)/30)+1)
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for i, b := range buf {
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dataLines[i/30] += fmt.Sprintf("%02x ", b)
numLines[i/30] += fmt.Sprintf("%02d ", (i+1)%100)
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}
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for i := 0; i < len(dataLines); i++ {
_, _ = out.Write([]byte(indent + dataLines[i] + "\n"))
_, _ = out.Write([]byte(indent + numLines[i] + "\n\n"))
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}
}
func WritePacket(out io.Writer, p *Packet) {
printPacket(out, p, 0, false)
}
func PrintPacket(p *Packet) {
printPacket(os.Stdout, p, 0, false)
}
// Return a string describing packet content. This is not recursive,
// If the packet is a sequence, use `printPacket()`, or browse
// sequence yourself.
func DescribePacket(p *Packet) string {
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classStr := ClassMap[p.ClassType]
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tagTypeStr := TypeMap[p.TagType]
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tagStr := fmt.Sprintf("0x%02X", p.Tag)
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if p.ClassType == ClassUniversal {
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tagStr = tagMap[p.Tag]
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}
value := fmt.Sprint(p.Value)
description := ""
if p.Description != "" {
description = p.Description + ": "
}
return fmt.Sprintf("%s(%s, %s, %s) Len=%d %q", description, classStr, tagTypeStr, tagStr, p.Data.Len(), value)
}
func printPacket(out io.Writer, p *Packet, indent int, printBytes bool) {
indentStr := ""
for len(indentStr) != indent {
indentStr += " "
}
_, _ = fmt.Fprintf(out, "%s%s\n", indentStr, DescribePacket(p))
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if printBytes {
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PrintBytes(out, p.Bytes(), indentStr)
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}
for _, child := range p.Children {
printPacket(out, child, indent+1, printBytes)
}
}
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// ReadPacket reads a single Packet from the reader.
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func ReadPacket(reader io.Reader) (*Packet, error) {
p, _, err := readPacket(reader)
if err != nil {
return nil, err
}
return p, nil
}
func DecodeString(data []byte) string {
return string(data)
}
func ParseInt64(bytes []byte) (ret int64, err error) {
if len(bytes) > 8 {
// We'll overflow an int64 in this case.
err = fmt.Errorf("integer too large")
return
}
for bytesRead := 0; bytesRead < len(bytes); bytesRead++ {
ret <<= 8
ret |= int64(bytes[bytesRead])
}
// Shift up and down in order to sign extend the result.
ret <<= 64 - uint8(len(bytes))*8
ret >>= 64 - uint8(len(bytes))*8
return
}
func encodeInteger(i int64) []byte {
n := int64Length(i)
out := make([]byte, n)
var j int
for ; n > 0; n-- {
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out[j] = byte(i >> uint((n-1)*8))
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j++
}
return out
}
func int64Length(i int64) (numBytes int) {
numBytes = 1
for i > 127 {
numBytes++
i >>= 8
}
for i < -128 {
numBytes++
i >>= 8
}
return
}
// DecodePacket decodes the given bytes into a single Packet
// If a decode error is encountered, nil is returned.
func DecodePacket(data []byte) *Packet {
p, _, _ := readPacket(bytes.NewBuffer(data))
return p
}
// DecodePacketErr decodes the given bytes into a single Packet
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// If a decode error is encountered, nil is returned.
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func DecodePacketErr(data []byte) (*Packet, error) {
p, _, err := readPacket(bytes.NewBuffer(data))
if err != nil {
return nil, err
}
return p, nil
}
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// readPacket reads a single Packet from the reader, returning the number of bytes read.
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func readPacket(reader io.Reader) (*Packet, int, error) {
identifier, length, read, err := readHeader(reader)
if err != nil {
return nil, read, err
}
p := &Packet{
Identifier: identifier,
}
p.Data = new(bytes.Buffer)
p.Children = make([]*Packet, 0, 2)
p.Value = nil
if p.TagType == TypeConstructed {
// TODO: if universal, ensure tag type is allowed to be constructed
// Track how much content we've read
contentRead := 0
for {
if length != LengthIndefinite {
// End if we've read what we've been told to
if contentRead == length {
break
}
// Detect if a packet boundary didn't fall on the expected length
if contentRead > length {
return nil, read, fmt.Errorf("expected to read %d bytes, read %d", length, contentRead)
}
}
// Read the next packet
child, r, err := readPacket(reader)
if err != nil {
return nil, read, unexpectedEOF(err)
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}
contentRead += r
read += r
// Test is this is the EOC marker for our packet
if isEOCPacket(child) {
if length == LengthIndefinite {
break
}
return nil, read, errors.New("eoc child not allowed with definite length")
}
// Append and continue
p.AppendChild(child)
}
return p, read, nil
}
if length == LengthIndefinite {
return nil, read, errors.New("indefinite length used with primitive type")
}
// Read definite-length content
if MaxPacketLengthBytes > 0 && int64(length) > MaxPacketLengthBytes {
return nil, read, fmt.Errorf("length %d greater than maximum %d", length, MaxPacketLengthBytes)
}
var content []byte
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if length > 0 {
// Read the content and limit it to the parsed length.
// If the content is less than the length, we return an EOF error.
content, err = ioutil.ReadAll(io.LimitReader(reader, int64(length)))
if err == nil && len(content) < int(length) {
err = io.EOF
}
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if err != nil {
return nil, read, unexpectedEOF(err)
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}
read += len(content)
} else {
// If length == 0, we set the ByteValue to an empty slice
content = make([]byte, 0)
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}
if p.ClassType == ClassUniversal {
p.Data.Write(content)
p.ByteValue = content
switch p.Tag {
case TagEOC:
case TagBoolean:
val, _ := ParseInt64(content)
p.Value = val != 0
case TagInteger:
p.Value, _ = ParseInt64(content)
case TagBitString:
case TagOctetString:
// the actual string encoding is not known here
// (e.g. for LDAP content is already an UTF8-encoded
// string). Return the data without further processing
p.Value = DecodeString(content)
case TagNULL:
case TagObjectIdentifier:
oid, err := parseObjectIdentifier(content)
if err == nil {
p.Value = OIDToString(oid)
}
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case TagObjectDescriptor:
case TagExternal:
case TagRealFloat:
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p.Value, err = ParseReal(content)
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case TagEnumerated:
p.Value, _ = ParseInt64(content)
case TagEmbeddedPDV:
case TagUTF8String:
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val := DecodeString(content)
if !utf8.Valid([]byte(val)) {
err = errors.New("invalid UTF-8 string")
} else {
p.Value = val
}
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case TagRelativeOID:
oid, err := parseObjectIdentifier(content)
if err == nil {
p.Value = OIDToString(oid)
}
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case TagSequence:
case TagSet:
case TagNumericString:
case TagPrintableString:
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val := DecodeString(content)
if err = isPrintableString(val); err == nil {
p.Value = val
}
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case TagT61String:
case TagVideotexString:
case TagIA5String:
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val := DecodeString(content)
for i, c := range val {
if c >= 0x7F {
err = fmt.Errorf("invalid character for IA5String at pos %d: %c", i, c)
break
}
}
if err == nil {
p.Value = val
}
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case TagUTCTime:
case TagGeneralizedTime:
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p.Value, err = ParseGeneralizedTime(content)
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case TagGraphicString:
case TagVisibleString:
case TagGeneralString:
case TagUniversalString:
case TagCharacterString:
case TagBMPString:
}
} else {
p.Data.Write(content)
}
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return p, read, err
}
func isPrintableString(val string) error {
for i, c := range val {
switch {
case c >= 'a' && c <= 'z':
case c >= 'A' && c <= 'Z':
case c >= '0' && c <= '9':
default:
switch c {
case '\'', '(', ')', '+', ',', '-', '.', '=', '/', ':', '?', ' ':
default:
return fmt.Errorf("invalid character in position %d", i)
}
}
}
return nil
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}
func (p *Packet) Bytes() []byte {
var out bytes.Buffer
out.Write(encodeIdentifier(p.Identifier))
out.Write(encodeLength(p.Data.Len()))
out.Write(p.Data.Bytes())
return out.Bytes()
}
func (p *Packet) AppendChild(child *Packet) {
p.Data.Write(child.Bytes())
p.Children = append(p.Children, child)
}
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func Encode(classType Class, tagType Type, tag Tag, value interface{}, description string) *Packet {
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p := new(Packet)
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p.ClassType = classType
p.TagType = tagType
p.Tag = tag
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p.Data = new(bytes.Buffer)
p.Children = make([]*Packet, 0, 2)
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p.Value = value
p.Description = description
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if value != nil {
v := reflect.ValueOf(value)
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if classType == ClassUniversal {
switch tag {
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case TagOctetString:
sv, ok := v.Interface().(string)
if ok {
p.Data.Write([]byte(sv))
}
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case TagEnumerated:
bv, ok := v.Interface().([]byte)
if ok {
p.Data.Write(bv)
}
case TagEmbeddedPDV:
bv, ok := v.Interface().([]byte)
if ok {
p.Data.Write(bv)
}
}
} else if classType == ClassContext {
switch tag {
case TagEnumerated:
bv, ok := v.Interface().([]byte)
if ok {
p.Data.Write(bv)
}
case TagEmbeddedPDV:
bv, ok := v.Interface().([]byte)
if ok {
p.Data.Write(bv)
}
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}
}
}
return p
}
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func NewSequence(description string) *Packet {
return Encode(ClassUniversal, TypeConstructed, TagSequence, nil, description)
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}
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func NewBoolean(classType Class, tagType Type, tag Tag, value bool, description string) *Packet {
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intValue := int64(0)
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if value {
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intValue = 1
}
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p := Encode(classType, tagType, tag, nil, description)
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p.Value = value
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p.Data.Write(encodeInteger(intValue))
return p
}
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// NewLDAPBoolean returns a RFC 4511-compliant Boolean packet.
func NewLDAPBoolean(classType Class, tagType Type, tag Tag, value bool, description string) *Packet {
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intValue := int64(0)
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if value {
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intValue = 255
}
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p := Encode(classType, tagType, tag, nil, description)
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p.Value = value
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p.Data.Write(encodeInteger(intValue))
return p
}
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func NewInteger(classType Class, tagType Type, tag Tag, value interface{}, description string) *Packet {
p := Encode(classType, tagType, tag, nil, description)
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p.Value = value
switch v := value.(type) {
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case int:
p.Data.Write(encodeInteger(int64(v)))
case uint:
p.Data.Write(encodeInteger(int64(v)))
case int64:
p.Data.Write(encodeInteger(v))
case uint64:
// TODO : check range or add encodeUInt...
p.Data.Write(encodeInteger(int64(v)))
case int32:
p.Data.Write(encodeInteger(int64(v)))
case uint32:
p.Data.Write(encodeInteger(int64(v)))
case int16:
p.Data.Write(encodeInteger(int64(v)))
case uint16:
p.Data.Write(encodeInteger(int64(v)))
case int8:
p.Data.Write(encodeInteger(int64(v)))
case uint8:
p.Data.Write(encodeInteger(int64(v)))
default:
// TODO : add support for big.Int ?
panic(fmt.Sprintf("Invalid type %T, expected {u|}int{64|32|16|8}", v))
}
return p
}
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func NewString(classType Class, tagType Type, tag Tag, value, description string) *Packet {
p := Encode(classType, tagType, tag, nil, description)
p.Value = value
p.Data.Write([]byte(value))
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return p
}
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func NewGeneralizedTime(classType Class, tagType Type, tag Tag, value time.Time, description string) *Packet {
p := Encode(classType, tagType, tag, nil, description)
var s string
if value.Nanosecond() != 0 {
s = value.Format(`20060102150405.000000000Z`)
} else {
s = value.Format(`20060102150405Z`)
}
p.Value = s
p.Data.Write([]byte(s))
return p
}
func NewReal(classType Class, tagType Type, tag Tag, value interface{}, description string) *Packet {
p := Encode(classType, tagType, tag, nil, description)
switch v := value.(type) {
case float64:
p.Data.Write(encodeFloat(v))
case float32:
p.Data.Write(encodeFloat(float64(v)))
default:
panic(fmt.Sprintf("Invalid type %T, expected float{64|32}", v))
}
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return p
}
func NewOID(classType Class, tagType Type, tag Tag, value interface{}, description string) *Packet {
p := Encode(classType, tagType, tag, nil, description)
switch v := value.(type) {
case string:
encoded, err := encodeOID(v)
if err != nil {
fmt.Printf("failed writing %v", err)
return nil
}
p.Value = v
p.Data.Write(encoded)
// TODO: support []int already ?
default:
panic(fmt.Sprintf("Invalid type %T, expected float{64|32}", v))
}
return p
}
// encodeOID takes a string representation of an OID and returns its DER-encoded byte slice along with any error.
func encodeOID(oidString string) ([]byte, error) {
// Convert the string representation to an asn1.ObjectIdentifier
parts := strings.Split(oidString, ".")
oid := make([]int, len(parts))
for i, part := range parts {
var val int
if _, err := fmt.Sscanf(part, "%d", &val); err != nil {
return nil, fmt.Errorf("invalid OID part '%s': %w", part, err)
}
oid[i] = val
}
if len(oid) < 2 || oid[0] > 2 || (oid[0] < 2 && oid[1] >= 40) {
panic(fmt.Sprintf("invalid object identifier % d", oid)) // TODO: not elegant
}
encoded := make([]byte, 0)
encoded = appendBase128Int(encoded[:0], int64(oid[0]*40+oid[1]))
for i := 2; i < len(oid); i++ {
encoded = appendBase128Int(encoded, int64(oid[i]))
}
return encoded, nil
}
func appendBase128Int(dst []byte, n int64) []byte {
l := base128IntLength(n)
for i := l - 1; i >= 0; i-- {
o := byte(n >> uint(i*7))
o &= 0x7f
if i != 0 {
o |= 0x80
}
dst = append(dst, o)
}
return dst
}
func base128IntLength(n int64) int {
if n == 0 {
return 1
}
l := 0
for i := n; i > 0; i >>= 7 {
l++
}
return l
}
func OIDToString(oi []int) string {
var s strings.Builder
s.Grow(32)
buf := make([]byte, 0, 19)
for i, v := range oi {
if i > 0 {
s.WriteByte('.')
}
s.Write(strconv.AppendInt(buf, int64(v), 10))
}
return s.String()
}
// parseObjectIdentifier parses an OBJECT IDENTIFIER from the given bytes and
// returns it. An object identifier is a sequence of variable length integers
// that are assigned in a hierarchy.
func parseObjectIdentifier(bytes []byte) (s []int, err error) {
if len(bytes) == 0 {
err = fmt.Errorf("zero length OBJECT IDENTIFIER")
return
}
// In the worst case, we get two elements from the first byte (which is
// encoded differently) and then every varint is a single byte long.
s = make([]int, len(bytes)+1)
// The first varint is 40*value1 + value2:
// According to this packing, value1 can take the values 0, 1 and 2 only.
// When value1 = 0 or value1 = 1, then value2 is <= 39. When value1 = 2,
// then there are no restrictions on value2.
v, offset, err := parseBase128Int(bytes, 0)
if err != nil {
return
}
if v < 80 {
s[0] = v / 40
s[1] = v % 40
} else {
s[0] = 2
s[1] = v - 80
}
i := 2
for ; offset < len(bytes); i++ {
v, offset, err = parseBase128Int(bytes, offset)
if err != nil {
return
}
s[i] = v
}
s = s[0:i]
return
}
// parseBase128Int parses a base-128 encoded int from the given offset in the
// given byte slice. It returns the value and the new offset.
func parseBase128Int(bytes []byte, initOffset int) (ret, offset int, err error) {
offset = initOffset
var ret64 int64
for shifted := 0; offset < len(bytes); shifted++ {
// 5 * 7 bits per byte == 35 bits of data
// Thus the representation is either non-minimal or too large for an int32
if shifted == 5 {
err = fmt.Errorf("base 128 integer too large")
return
}
ret64 <<= 7
b := bytes[offset]
// integers should be minimally encoded, so the leading octet should
// never be 0x80
if shifted == 0 && b == 0x80 {
err = fmt.Errorf("integer is not minimally encoded")
return
}
ret64 |= int64(b & 0x7f)
offset++
if b&0x80 == 0 {
ret = int(ret64)
// Ensure that the returned value fits in an int on all platforms
if ret64 > math.MaxInt32 {
err = fmt.Errorf("base 128 integer too large")
}
return
}
}
err = fmt.Errorf("truncated base 128 integer")
return
}