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moby--moby/vendor/github.com/google/certificate-transparency-go/asn1/asn1.go
Sebastiaan van Stijn 7084487fdc
Update cloudflare/cfssl to 1.3.2
Matching the version that is used in SwarmKit

Signed-off-by: Sebastiaan van Stijn <github@gone.nl>
2018-07-04 17:47:22 +02:00

1141 lines
33 KiB
Go

// Copyright 2009 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 asn1 implements parsing of DER-encoded ASN.1 data structures,
// as defined in ITU-T Rec X.690.
//
// See also ``A Layman's Guide to a Subset of ASN.1, BER, and DER,''
// http://luca.ntop.org/Teaching/Appunti/asn1.html.
//
// This is a fork of the Go standard library ASN.1 implementation
// (encoding/asn1). The main difference is that this version tries to correct
// for errors (e.g. use of tagPrintableString when the string data is really
// ISO8859-1 - a common error present in many x509 certificates in the wild.)
package asn1
// ASN.1 is a syntax for specifying abstract objects and BER, DER, PER, XER etc
// are different encoding formats for those objects. Here, we'll be dealing
// with DER, the Distinguished Encoding Rules. DER is used in X.509 because
// it's fast to parse and, unlike BER, has a unique encoding for every object.
// When calculating hashes over objects, it's important that the resulting
// bytes be the same at both ends and DER removes this margin of error.
//
// ASN.1 is very complex and this package doesn't attempt to implement
// everything by any means.
import (
"errors"
"fmt"
"math"
"math/big"
"reflect"
"strconv"
"strings"
"time"
"unicode/utf8"
)
// A StructuralError suggests that the ASN.1 data is valid, but the Go type
// which is receiving it doesn't match.
type StructuralError struct {
Msg string
Field string
}
func (e StructuralError) Error() string {
var prefix string
if e.Field != "" {
prefix = e.Field + ": "
}
return "asn1: structure error: " + prefix + e.Msg
}
// A SyntaxError suggests that the ASN.1 data is invalid.
type SyntaxError struct {
Msg string
Field string
}
func (e SyntaxError) Error() string {
var prefix string
if e.Field != "" {
prefix = e.Field + ": "
}
return "asn1: syntax error: " + prefix + e.Msg
}
// We start by dealing with each of the primitive types in turn.
// BOOLEAN
func parseBool(bytes []byte, fieldName string) (ret bool, err error) {
if len(bytes) != 1 {
err = SyntaxError{"invalid boolean", fieldName}
return
}
// DER demands that "If the encoding represents the boolean value TRUE,
// its single contents octet shall have all eight bits set to one."
// Thus only 0 and 255 are valid encoded values.
switch bytes[0] {
case 0:
ret = false
case 0xff:
ret = true
default:
err = SyntaxError{"invalid boolean", fieldName}
}
return
}
// INTEGER
// checkInteger returns nil if the given bytes are a valid DER-encoded
// INTEGER and an error otherwise.
func checkInteger(bytes []byte, fieldName string) error {
if len(bytes) == 0 {
return StructuralError{"empty integer", fieldName}
}
if len(bytes) == 1 {
return nil
}
if (bytes[0] == 0 && bytes[1]&0x80 == 0) || (bytes[0] == 0xff && bytes[1]&0x80 == 0x80) {
return StructuralError{"integer not minimally-encoded", fieldName}
}
return nil
}
// parseInt64 treats the given bytes as a big-endian, signed integer and
// returns the result.
func parseInt64(bytes []byte, fieldName string) (ret int64, err error) {
err = checkInteger(bytes, fieldName)
if err != nil {
return
}
if len(bytes) > 8 {
// We'll overflow an int64 in this case.
err = StructuralError{"integer too large", fieldName}
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
}
// parseInt treats the given bytes as a big-endian, signed integer and returns
// the result.
func parseInt32(bytes []byte, fieldName string) (int32, error) {
if err := checkInteger(bytes, fieldName); err != nil {
return 0, err
}
ret64, err := parseInt64(bytes, fieldName)
if err != nil {
return 0, err
}
if ret64 != int64(int32(ret64)) {
return 0, StructuralError{"integer too large", fieldName}
}
return int32(ret64), nil
}
var bigOne = big.NewInt(1)
// parseBigInt treats the given bytes as a big-endian, signed integer and returns
// the result.
func parseBigInt(bytes []byte, fieldName string) (*big.Int, error) {
if err := checkInteger(bytes, fieldName); err != nil {
return nil, err
}
ret := new(big.Int)
if len(bytes) > 0 && bytes[0]&0x80 == 0x80 {
// This is a negative number.
notBytes := make([]byte, len(bytes))
for i := range notBytes {
notBytes[i] = ^bytes[i]
}
ret.SetBytes(notBytes)
ret.Add(ret, bigOne)
ret.Neg(ret)
return ret, nil
}
ret.SetBytes(bytes)
return ret, nil
}
// BIT STRING
// BitString is the structure to use when you want an ASN.1 BIT STRING type. A
// bit string is padded up to the nearest byte in memory and the number of
// valid bits is recorded. Padding bits will be zero.
type BitString struct {
Bytes []byte // bits packed into bytes.
BitLength int // length in bits.
}
// At returns the bit at the given index. If the index is out of range it
// returns false.
func (b BitString) At(i int) int {
if i < 0 || i >= b.BitLength {
return 0
}
x := i / 8
y := 7 - uint(i%8)
return int(b.Bytes[x]>>y) & 1
}
// RightAlign returns a slice where the padding bits are at the beginning. The
// slice may share memory with the BitString.
func (b BitString) RightAlign() []byte {
shift := uint(8 - (b.BitLength % 8))
if shift == 8 || len(b.Bytes) == 0 {
return b.Bytes
}
a := make([]byte, len(b.Bytes))
a[0] = b.Bytes[0] >> shift
for i := 1; i < len(b.Bytes); i++ {
a[i] = b.Bytes[i-1] << (8 - shift)
a[i] |= b.Bytes[i] >> shift
}
return a
}
// parseBitString parses an ASN.1 bit string from the given byte slice and returns it.
func parseBitString(bytes []byte, fieldName string) (ret BitString, err error) {
if len(bytes) == 0 {
err = SyntaxError{"zero length BIT STRING", fieldName}
return
}
paddingBits := int(bytes[0])
if paddingBits > 7 ||
len(bytes) == 1 && paddingBits > 0 ||
bytes[len(bytes)-1]&((1<<bytes[0])-1) != 0 {
err = SyntaxError{"invalid padding bits in BIT STRING", fieldName}
return
}
ret.BitLength = (len(bytes)-1)*8 - paddingBits
ret.Bytes = bytes[1:]
return
}
// NULL
// NullRawValue is a RawValue with its Tag set to the ASN.1 NULL type tag (5).
var NullRawValue = RawValue{Tag: TagNull}
// NullBytes contains bytes representing the DER-encoded ASN.1 NULL type.
var NullBytes = []byte{TagNull, 0}
// OBJECT IDENTIFIER
// An ObjectIdentifier represents an ASN.1 OBJECT IDENTIFIER.
type ObjectIdentifier []int
// Equal reports whether oi and other represent the same identifier.
func (oi ObjectIdentifier) Equal(other ObjectIdentifier) bool {
if len(oi) != len(other) {
return false
}
for i := 0; i < len(oi); i++ {
if oi[i] != other[i] {
return false
}
}
return true
}
func (oi ObjectIdentifier) String() string {
var s string
for i, v := range oi {
if i > 0 {
s += "."
}
s += strconv.Itoa(v)
}
return s
}
// 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, fieldName string) (s []int, err error) {
if len(bytes) == 0 {
err = SyntaxError{"zero length OBJECT IDENTIFIER", fieldName}
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, fieldName)
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, fieldName)
if err != nil {
return
}
s[i] = v
}
s = s[0:i]
return
}
// ENUMERATED
// An Enumerated is represented as a plain int.
type Enumerated int
// FLAG
// A Flag accepts any data and is set to true if present.
type Flag bool
// 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, fieldName string) (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 = StructuralError{"base 128 integer too large", fieldName}
return
}
ret64 <<= 7
b := bytes[offset]
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 = StructuralError{"base 128 integer too large", fieldName}
}
return
}
}
err = SyntaxError{"truncated base 128 integer", fieldName}
return
}
// UTCTime
func parseUTCTime(bytes []byte) (ret time.Time, err error) {
s := string(bytes)
formatStr := "0601021504Z0700"
ret, err = time.Parse(formatStr, s)
if err != nil {
formatStr = "060102150405Z0700"
ret, err = time.Parse(formatStr, s)
}
if err != nil {
return
}
if serialized := ret.Format(formatStr); serialized != s {
err = fmt.Errorf("asn1: time did not serialize back to the original value and may be invalid: given %q, but serialized as %q", s, serialized)
return
}
if ret.Year() >= 2050 {
// UTCTime only encodes times prior to 2050. See https://tools.ietf.org/html/rfc5280#section-4.1.2.5.1
ret = ret.AddDate(-100, 0, 0)
}
return
}
// parseGeneralizedTime parses the GeneralizedTime from the given byte slice
// and returns the resulting time.
func parseGeneralizedTime(bytes []byte) (ret time.Time, err error) {
const formatStr = "20060102150405Z0700"
s := string(bytes)
if ret, err = time.Parse(formatStr, s); err != nil {
return
}
if serialized := ret.Format(formatStr); serialized != s {
err = fmt.Errorf("asn1: time did not serialize back to the original value and may be invalid: given %q, but serialized as %q", s, serialized)
}
return
}
// NumericString
// parseNumericString parses an ASN.1 NumericString from the given byte array
// and returns it.
func parseNumericString(bytes []byte, fieldName string) (ret string, err error) {
for _, b := range bytes {
if !isNumeric(b) {
return "", SyntaxError{"NumericString contains invalid character", fieldName}
}
}
return string(bytes), nil
}
// isNumeric reports whether the given b is in the ASN.1 NumericString set.
func isNumeric(b byte) bool {
return '0' <= b && b <= '9' ||
b == ' '
}
// PrintableString
// parsePrintableString parses an ASN.1 PrintableString from the given byte
// array and returns it.
func parsePrintableString(bytes []byte, fieldName string) (ret string, err error) {
for _, b := range bytes {
if !isPrintable(b, allowAsterisk, allowAmpersand) {
err = SyntaxError{"PrintableString contains invalid character", fieldName}
return
}
}
ret = string(bytes)
return
}
type asteriskFlag bool
type ampersandFlag bool
const (
allowAsterisk asteriskFlag = true
rejectAsterisk asteriskFlag = false
allowAmpersand ampersandFlag = true
rejectAmpersand ampersandFlag = false
)
// isPrintable reports whether the given b is in the ASN.1 PrintableString set.
// If asterisk is allowAsterisk then '*' is also allowed, reflecting existing
// practice. If ampersand is allowAmpersand then '&' is allowed as well.
func isPrintable(b byte, asterisk asteriskFlag, ampersand ampersandFlag) bool {
return 'a' <= b && b <= 'z' ||
'A' <= b && b <= 'Z' ||
'0' <= b && b <= '9' ||
'\'' <= b && b <= ')' ||
'+' <= b && b <= '/' ||
b == ' ' ||
b == ':' ||
b == '=' ||
b == '?' ||
// This is technically not allowed in a PrintableString.
// However, x509 certificates with wildcard strings don't
// always use the correct string type so we permit it.
(bool(asterisk) && b == '*') ||
// This is not technically allowed either. However, not
// only is it relatively common, but there are also a
// handful of CA certificates that contain it. At least
// one of which will not expire until 2027.
(bool(ampersand) && b == '&')
}
// IA5String
// parseIA5String parses an ASN.1 IA5String (ASCII string) from the given
// byte slice and returns it.
func parseIA5String(bytes []byte, fieldName string) (ret string, err error) {
for _, b := range bytes {
if b >= utf8.RuneSelf {
err = SyntaxError{"IA5String contains invalid character", fieldName}
return
}
}
ret = string(bytes)
return
}
// T61String
// parseT61String parses an ASN.1 T61String (8-bit clean string) from the given
// byte slice and returns it.
func parseT61String(bytes []byte) (ret string, err error) {
return string(bytes), nil
}
// UTF8String
// parseUTF8String parses an ASN.1 UTF8String (raw UTF-8) from the given byte
// array and returns it.
func parseUTF8String(bytes []byte) (ret string, err error) {
if !utf8.Valid(bytes) {
return "", errors.New("asn1: invalid UTF-8 string")
}
return string(bytes), nil
}
// A RawValue represents an undecoded ASN.1 object.
type RawValue struct {
Class, Tag int
IsCompound bool
Bytes []byte
FullBytes []byte // includes the tag and length
}
// RawContent is used to signal that the undecoded, DER data needs to be
// preserved for a struct. To use it, the first field of the struct must have
// this type. It's an error for any of the other fields to have this type.
type RawContent []byte
// Tagging
// parseTagAndLength parses an ASN.1 tag and length pair from the given offset
// into a byte slice. It returns the parsed data and the new offset. SET and
// SET OF (tag 17) are mapped to SEQUENCE and SEQUENCE OF (tag 16) since we
// don't distinguish between ordered and unordered objects in this code.
func parseTagAndLength(bytes []byte, initOffset int, fieldName string) (ret tagAndLength, offset int, err error) {
offset = initOffset
// parseTagAndLength should not be called without at least a single
// byte to read. Thus this check is for robustness:
if offset >= len(bytes) {
err = errors.New("asn1: internal error in parseTagAndLength")
return
}
b := bytes[offset]
offset++
ret.class = int(b >> 6)
ret.isCompound = b&0x20 == 0x20
ret.tag = int(b & 0x1f)
// If the bottom five bits are set, then the tag number is actually base 128
// encoded afterwards
if ret.tag == 0x1f {
ret.tag, offset, err = parseBase128Int(bytes, offset, fieldName)
if err != nil {
return
}
// Tags should be encoded in minimal form.
if ret.tag < 0x1f {
err = SyntaxError{"non-minimal tag", fieldName}
return
}
}
if offset >= len(bytes) {
err = SyntaxError{"truncated tag or length", fieldName}
return
}
b = bytes[offset]
offset++
if b&0x80 == 0 {
// The length is encoded in the bottom 7 bits.
ret.length = int(b & 0x7f)
} else {
// Bottom 7 bits give the number of length bytes to follow.
numBytes := int(b & 0x7f)
if numBytes == 0 {
err = SyntaxError{"indefinite length found (not DER)", fieldName}
return
}
ret.length = 0
for i := 0; i < numBytes; i++ {
if offset >= len(bytes) {
err = SyntaxError{"truncated tag or length", fieldName}
return
}
b = bytes[offset]
offset++
if ret.length >= 1<<23 {
// We can't shift ret.length up without
// overflowing.
err = StructuralError{"length too large", fieldName}
return
}
ret.length <<= 8
ret.length |= int(b)
if ret.length == 0 {
// DER requires that lengths be minimal.
err = StructuralError{"superfluous leading zeros in length", fieldName}
return
}
}
// Short lengths must be encoded in short form.
if ret.length < 0x80 {
err = StructuralError{"non-minimal length", fieldName}
return
}
}
return
}
// parseSequenceOf is used for SEQUENCE OF and SET OF values. It tries to parse
// a number of ASN.1 values from the given byte slice and returns them as a
// slice of Go values of the given type.
func parseSequenceOf(bytes []byte, sliceType reflect.Type, elemType reflect.Type, fieldName string) (ret reflect.Value, err error) {
matchAny, expectedTag, compoundType, ok := getUniversalType(elemType)
if !ok {
err = StructuralError{"unknown Go type for slice", fieldName}
return
}
// First we iterate over the input and count the number of elements,
// checking that the types are correct in each case.
numElements := 0
for offset := 0; offset < len(bytes); {
var t tagAndLength
t, offset, err = parseTagAndLength(bytes, offset, fieldName)
if err != nil {
return
}
switch t.tag {
case TagIA5String, TagGeneralString, TagT61String, TagUTF8String, TagNumericString:
// We pretend that various other string types are
// PRINTABLE STRINGs so that a sequence of them can be
// parsed into a []string.
t.tag = TagPrintableString
case TagGeneralizedTime, TagUTCTime:
// Likewise, both time types are treated the same.
t.tag = TagUTCTime
}
if !matchAny && (t.class != ClassUniversal || t.isCompound != compoundType || t.tag != expectedTag) {
err = StructuralError{fmt.Sprintf("sequence tag mismatch (got:%+v, want:0/%d/%t)", t, expectedTag, compoundType), fieldName}
return
}
if invalidLength(offset, t.length, len(bytes)) {
err = SyntaxError{"truncated sequence", fieldName}
return
}
offset += t.length
numElements++
}
ret = reflect.MakeSlice(sliceType, numElements, numElements)
params := fieldParameters{}
offset := 0
for i := 0; i < numElements; i++ {
offset, err = parseField(ret.Index(i), bytes, offset, params)
if err != nil {
return
}
}
return
}
var (
bitStringType = reflect.TypeOf(BitString{})
objectIdentifierType = reflect.TypeOf(ObjectIdentifier{})
enumeratedType = reflect.TypeOf(Enumerated(0))
flagType = reflect.TypeOf(Flag(false))
timeType = reflect.TypeOf(time.Time{})
rawValueType = reflect.TypeOf(RawValue{})
rawContentsType = reflect.TypeOf(RawContent(nil))
bigIntType = reflect.TypeOf(new(big.Int))
)
// invalidLength returns true iff offset + length > sliceLength, or if the
// addition would overflow.
func invalidLength(offset, length, sliceLength int) bool {
return offset+length < offset || offset+length > sliceLength
}
// Tests whether the data in |bytes| would be a valid ISO8859-1 string.
// Clearly, a sequence of bytes comprised solely of valid ISO8859-1
// codepoints does not imply that the encoding MUST be ISO8859-1, rather that
// you would not encounter an error trying to interpret the data as such.
func couldBeISO8859_1(bytes []byte) bool {
for _, b := range bytes {
if b < 0x20 || (b >= 0x7F && b < 0xA0) {
return false
}
}
return true
}
// Checks whether the data in |bytes| would be a valid T.61 string.
// Clearly, a sequence of bytes comprised solely of valid T.61
// codepoints does not imply that the encoding MUST be T.61, rather that
// you would not encounter an error trying to interpret the data as such.
func couldBeT61(bytes []byte) bool {
for _, b := range bytes {
switch b {
case 0x00:
// Since we're guessing at (incorrect) encodings for a
// PrintableString, we'll err on the side of caution and disallow
// strings with a NUL in them, don't want to re-create a PayPal NUL
// situation in monitors.
fallthrough
case 0x23, 0x24, 0x5C, 0x5E, 0x60, 0x7B, 0x7D, 0x7E, 0xA5, 0xA6, 0xAC, 0xAD, 0xAE, 0xAF,
0xB9, 0xBA, 0xC0, 0xC9, 0xD0, 0xD1, 0xD2, 0xD3, 0xD4, 0xD5, 0xD6, 0xD7, 0xD8, 0xD9,
0xDA, 0xDB, 0xDC, 0xDE, 0xDF, 0xE5, 0xFF:
// These are all invalid code points in T.61, so it can't be a T.61 string.
return false
}
}
return true
}
// Converts the data in |bytes| to the equivalent UTF-8 string.
func iso8859_1ToUTF8(bytes []byte) string {
buf := make([]rune, len(bytes))
for i, b := range bytes {
buf[i] = rune(b)
}
return string(buf)
}
// parseField is the main parsing function. Given a byte slice and an offset
// into the array, it will try to parse a suitable ASN.1 value out and store it
// in the given Value.
func parseField(v reflect.Value, bytes []byte, initOffset int, params fieldParameters) (offset int, err error) {
offset = initOffset
fieldType := v.Type()
// If we have run out of data, it may be that there are optional elements at the end.
if offset == len(bytes) {
if !setDefaultValue(v, params) {
err = SyntaxError{"sequence truncated", params.name}
}
return
}
// Deal with the ANY type.
if ifaceType := fieldType; ifaceType.Kind() == reflect.Interface && ifaceType.NumMethod() == 0 {
var t tagAndLength
t, offset, err = parseTagAndLength(bytes, offset, params.name)
if err != nil {
return
}
if invalidLength(offset, t.length, len(bytes)) {
err = SyntaxError{"data truncated", params.name}
return
}
var result interface{}
if !t.isCompound && t.class == ClassUniversal {
innerBytes := bytes[offset : offset+t.length]
switch t.tag {
case TagPrintableString:
result, err = parsePrintableString(innerBytes, params.name)
if err != nil && strings.Contains(err.Error(), "PrintableString contains invalid character") {
// Probably an ISO8859-1 string stuffed in, check if it
// would be valid and assume that's what's happened if so,
// otherwise try T.61, failing that give up and just assign
// the bytes
switch {
case couldBeISO8859_1(innerBytes):
result, err = iso8859_1ToUTF8(innerBytes), nil
case couldBeT61(innerBytes):
result, err = parseT61String(innerBytes)
default:
result = nil
err = errors.New("PrintableString contains invalid character, but couldn't determine correct String type.")
}
}
case TagNumericString:
result, err = parseNumericString(innerBytes, params.name)
case TagIA5String:
result, err = parseIA5String(innerBytes, params.name)
case TagT61String:
result, err = parseT61String(innerBytes)
case TagUTF8String:
result, err = parseUTF8String(innerBytes)
case TagInteger:
result, err = parseInt64(innerBytes, params.name)
case TagBitString:
result, err = parseBitString(innerBytes, params.name)
case TagOID:
result, err = parseObjectIdentifier(innerBytes, params.name)
case TagUTCTime:
result, err = parseUTCTime(innerBytes)
case TagGeneralizedTime:
result, err = parseGeneralizedTime(innerBytes)
case TagOctetString:
result = innerBytes
default:
// If we don't know how to handle the type, we just leave Value as nil.
}
}
offset += t.length
if err != nil {
return
}
if result != nil {
v.Set(reflect.ValueOf(result))
}
return
}
t, offset, err := parseTagAndLength(bytes, offset, params.name)
if err != nil {
return
}
if params.explicit {
expectedClass := ClassContextSpecific
if params.application {
expectedClass = ClassApplication
}
if offset == len(bytes) {
err = StructuralError{"explicit tag has no child", params.name}
return
}
if t.class == expectedClass && t.tag == *params.tag && (t.length == 0 || t.isCompound) {
if fieldType == rawValueType {
// The inner element should not be parsed for RawValues.
} else if t.length > 0 {
t, offset, err = parseTagAndLength(bytes, offset, params.name)
if err != nil {
return
}
} else {
if fieldType != flagType {
err = StructuralError{"zero length explicit tag was not an asn1.Flag", params.name}
return
}
v.SetBool(true)
return
}
} else {
// The tags didn't match, it might be an optional element.
ok := setDefaultValue(v, params)
if ok {
offset = initOffset
} else {
err = StructuralError{"explicitly tagged member didn't match", params.name}
}
return
}
}
matchAny, universalTag, compoundType, ok1 := getUniversalType(fieldType)
if !ok1 {
err = StructuralError{fmt.Sprintf("unknown Go type: %v", fieldType), params.name}
return
}
// Special case for strings: all the ASN.1 string types map to the Go
// type string. getUniversalType returns the tag for PrintableString
// when it sees a string, so if we see a different string type on the
// wire, we change the universal type to match.
if universalTag == TagPrintableString {
if t.class == ClassUniversal {
switch t.tag {
case TagIA5String, TagGeneralString, TagT61String, TagUTF8String, TagNumericString:
universalTag = t.tag
}
} else if params.stringType != 0 {
universalTag = params.stringType
}
}
// Special case for time: UTCTime and GeneralizedTime both map to the
// Go type time.Time.
if universalTag == TagUTCTime && t.tag == TagGeneralizedTime && t.class == ClassUniversal {
universalTag = TagGeneralizedTime
}
if params.set {
universalTag = TagSet
}
matchAnyClassAndTag := matchAny
expectedClass := ClassUniversal
expectedTag := universalTag
if !params.explicit && params.tag != nil {
expectedClass = ClassContextSpecific
expectedTag = *params.tag
matchAnyClassAndTag = false
}
if !params.explicit && params.application && params.tag != nil {
expectedClass = ClassApplication
expectedTag = *params.tag
matchAnyClassAndTag = false
}
// We have unwrapped any explicit tagging at this point.
if !matchAnyClassAndTag && (t.class != expectedClass || t.tag != expectedTag) ||
(!matchAny && t.isCompound != compoundType) {
// Tags don't match. Again, it could be an optional element.
ok := setDefaultValue(v, params)
if ok {
offset = initOffset
} else {
err = StructuralError{fmt.Sprintf("tags don't match (%d vs %+v) %+v %s @%d", expectedTag, t, params, fieldType.Name(), offset), params.name}
}
return
}
if invalidLength(offset, t.length, len(bytes)) {
err = SyntaxError{"data truncated", params.name}
return
}
innerBytes := bytes[offset : offset+t.length]
offset += t.length
// We deal with the structures defined in this package first.
switch fieldType {
case rawValueType:
result := RawValue{t.class, t.tag, t.isCompound, innerBytes, bytes[initOffset:offset]}
v.Set(reflect.ValueOf(result))
return
case objectIdentifierType:
newSlice, err1 := parseObjectIdentifier(innerBytes, params.name)
v.Set(reflect.MakeSlice(v.Type(), len(newSlice), len(newSlice)))
if err1 == nil {
reflect.Copy(v, reflect.ValueOf(newSlice))
}
err = err1
return
case bitStringType:
bs, err1 := parseBitString(innerBytes, params.name)
if err1 == nil {
v.Set(reflect.ValueOf(bs))
}
err = err1
return
case timeType:
var time time.Time
var err1 error
if universalTag == TagUTCTime {
time, err1 = parseUTCTime(innerBytes)
} else {
time, err1 = parseGeneralizedTime(innerBytes)
}
if err1 == nil {
v.Set(reflect.ValueOf(time))
}
err = err1
return
case enumeratedType:
parsedInt, err1 := parseInt32(innerBytes, params.name)
if err1 == nil {
v.SetInt(int64(parsedInt))
}
err = err1
return
case flagType:
v.SetBool(true)
return
case bigIntType:
parsedInt, err1 := parseBigInt(innerBytes, params.name)
if err1 == nil {
v.Set(reflect.ValueOf(parsedInt))
}
err = err1
return
}
switch val := v; val.Kind() {
case reflect.Bool:
parsedBool, err1 := parseBool(innerBytes, params.name)
if err1 == nil {
val.SetBool(parsedBool)
}
err = err1
return
case reflect.Int, reflect.Int32, reflect.Int64:
if val.Type().Size() == 4 {
parsedInt, err1 := parseInt32(innerBytes, params.name)
if err1 == nil {
val.SetInt(int64(parsedInt))
}
err = err1
} else {
parsedInt, err1 := parseInt64(innerBytes, params.name)
if err1 == nil {
val.SetInt(parsedInt)
}
err = err1
}
return
// TODO(dfc) Add support for the remaining integer types
case reflect.Struct:
structType := fieldType
for i := 0; i < structType.NumField(); i++ {
if structType.Field(i).PkgPath != "" {
err = StructuralError{"struct contains unexported fields", structType.Field(i).Name}
return
}
}
if structType.NumField() > 0 &&
structType.Field(0).Type == rawContentsType {
bytes := bytes[initOffset:offset]
val.Field(0).Set(reflect.ValueOf(RawContent(bytes)))
}
innerOffset := 0
for i := 0; i < structType.NumField(); i++ {
field := structType.Field(i)
if i == 0 && field.Type == rawContentsType {
continue
}
innerParams := parseFieldParameters(field.Tag.Get("asn1"))
innerParams.name = field.Name
innerOffset, err = parseField(val.Field(i), innerBytes, innerOffset, innerParams)
if err != nil {
return
}
}
// We allow extra bytes at the end of the SEQUENCE because
// adding elements to the end has been used in X.509 as the
// version numbers have increased.
return
case reflect.Slice:
sliceType := fieldType
if sliceType.Elem().Kind() == reflect.Uint8 {
val.Set(reflect.MakeSlice(sliceType, len(innerBytes), len(innerBytes)))
reflect.Copy(val, reflect.ValueOf(innerBytes))
return
}
newSlice, err1 := parseSequenceOf(innerBytes, sliceType, sliceType.Elem(), params.name)
if err1 == nil {
val.Set(newSlice)
}
err = err1
return
case reflect.String:
var v string
switch universalTag {
case TagPrintableString:
v, err = parsePrintableString(innerBytes, params.name)
case TagNumericString:
v, err = parseNumericString(innerBytes, params.name)
case TagIA5String:
v, err = parseIA5String(innerBytes, params.name)
case TagT61String:
v, err = parseT61String(innerBytes)
case TagUTF8String:
v, err = parseUTF8String(innerBytes)
case TagGeneralString:
// GeneralString is specified in ISO-2022/ECMA-35,
// A brief review suggests that it includes structures
// that allow the encoding to change midstring and
// such. We give up and pass it as an 8-bit string.
v, err = parseT61String(innerBytes)
default:
err = SyntaxError{fmt.Sprintf("internal error: unknown string type %d", universalTag), params.name}
}
if err == nil {
val.SetString(v)
}
return
}
err = StructuralError{"unsupported: " + v.Type().String(), params.name}
return
}
// canHaveDefaultValue reports whether k is a Kind that we will set a default
// value for. (A signed integer, essentially.)
func canHaveDefaultValue(k reflect.Kind) bool {
switch k {
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return true
}
return false
}
// setDefaultValue is used to install a default value, from a tag string, into
// a Value. It is successful if the field was optional, even if a default value
// wasn't provided or it failed to install it into the Value.
func setDefaultValue(v reflect.Value, params fieldParameters) (ok bool) {
if !params.optional {
return
}
ok = true
if params.defaultValue == nil {
return
}
if canHaveDefaultValue(v.Kind()) {
v.SetInt(*params.defaultValue)
}
return
}
// Unmarshal parses the DER-encoded ASN.1 data structure b
// and uses the reflect package to fill in an arbitrary value pointed at by val.
// Because Unmarshal uses the reflect package, the structs
// being written to must use upper case field names.
//
// An ASN.1 INTEGER can be written to an int, int32, int64,
// or *big.Int (from the math/big package).
// If the encoded value does not fit in the Go type,
// Unmarshal returns a parse error.
//
// An ASN.1 BIT STRING can be written to a BitString.
//
// An ASN.1 OCTET STRING can be written to a []byte.
//
// An ASN.1 OBJECT IDENTIFIER can be written to an
// ObjectIdentifier.
//
// An ASN.1 ENUMERATED can be written to an Enumerated.
//
// An ASN.1 UTCTIME or GENERALIZEDTIME can be written to a time.Time.
//
// An ASN.1 PrintableString, IA5String, or NumericString can be written to a string.
//
// Any of the above ASN.1 values can be written to an interface{}.
// The value stored in the interface has the corresponding Go type.
// For integers, that type is int64.
//
// An ASN.1 SEQUENCE OF x or SET OF x can be written
// to a slice if an x can be written to the slice's element type.
//
// An ASN.1 SEQUENCE or SET can be written to a struct
// if each of the elements in the sequence can be
// written to the corresponding element in the struct.
//
// The following tags on struct fields have special meaning to Unmarshal:
//
// application specifies that an APPLICATION tag is used
// default:x sets the default value for optional integer fields (only used if optional is also present)
// explicit specifies that an additional, explicit tag wraps the implicit one
// optional marks the field as ASN.1 OPTIONAL
// set causes a SET, rather than a SEQUENCE type to be expected
// tag:x specifies the ASN.1 tag number; implies ASN.1 CONTEXT SPECIFIC
//
// If the type of the first field of a structure is RawContent then the raw
// ASN1 contents of the struct will be stored in it.
//
// If the type name of a slice element ends with "SET" then it's treated as if
// the "set" tag was set on it. This can be used with nested slices where a
// struct tag cannot be given.
//
// Other ASN.1 types are not supported; if it encounters them,
// Unmarshal returns a parse error.
func Unmarshal(b []byte, val interface{}) (rest []byte, err error) {
return UnmarshalWithParams(b, val, "")
}
// UnmarshalWithParams allows field parameters to be specified for the
// top-level element. The form of the params is the same as the field tags.
func UnmarshalWithParams(b []byte, val interface{}, params string) (rest []byte, err error) {
v := reflect.ValueOf(val).Elem()
offset, err := parseField(v, b, 0, parseFieldParameters(params))
if err != nil {
return nil, err
}
return b[offset:], nil
}