# Nim-Libp2p # Copyright (c) 2023 Status Research & Development GmbH # Licensed under either of # * Apache License, version 2.0, ([LICENSE-APACHE](LICENSE-APACHE)) # * MIT license ([LICENSE-MIT](LICENSE-MIT)) # at your option. # This file may not be copied, modified, or distributed except according to # those terms. ## This module implements minimal ASN.1 encoding/decoding primitives. {.push raises: [].} import stew/[endians2, results, ctops] export results # We use `ncrutils` for constant-time hexadecimal encoding/decoding procedures. import nimcrypto/utils as ncrutils import ../utility type Asn1Error* {.pure.} = enum Overflow Incomplete Indefinite Incorrect NoSupport Overrun Asn1Result*[T] = Result[T, Asn1Error] Asn1Class* {.pure.} = enum Universal = 0x00 Application = 0x01 ContextSpecific = 0x02 Private = 0x03 Asn1Tag* {.pure.} = enum ## Protobuf's field types enum NoSupport Boolean Integer BitString OctetString Null Oid Sequence Context Asn1Buffer* = object of RootObj ## ASN.1's message representation object buffer*: seq[byte] offset*: int length*: int Asn1Field* = object klass*: Asn1Class index*: int offset*: int length*: int buffer*: seq[byte] case kind*: Asn1Tag of Asn1Tag.Boolean: vbool*: bool of Asn1Tag.Integer: vint*: uint64 of Asn1Tag.BitString: ubits*: int else: discard Asn1Composite* = object of Asn1Buffer tag*: Asn1Tag idx*: int const Asn1OidSecp256r1* = [0x2A'u8, 0x86'u8, 0x48'u8, 0xCE'u8, 0x3D'u8, 0x03'u8, 0x01'u8, 0x07'u8] ## Encoded OID for `secp256r1` curve (1.2.840.10045.3.1.7) Asn1OidSecp384r1* = [0x2B'u8, 0x81'u8, 0x04'u8, 0x00'u8, 0x22'u8] ## Encoded OID for `secp384r1` curve (1.3.132.0.34) Asn1OidSecp521r1* = [0x2B'u8, 0x81'u8, 0x04'u8, 0x00'u8, 0x23'u8] ## Encoded OID for `secp521r1` curve (1.3.132.0.35) Asn1OidSecp256k1* = [0x2B'u8, 0x81'u8, 0x04'u8, 0x00'u8, 0x0A'u8] ## Encoded OID for `secp256k1` curve (1.3.132.0.10) Asn1OidEcPublicKey* = [0x2A'u8, 0x86'u8, 0x48'u8, 0xCE'u8, 0x3D'u8, 0x02'u8, 0x01'u8] ## Encoded OID for Elliptic Curve Public Key (1.2.840.10045.2.1) Asn1OidRsaEncryption* = [0x2A'u8, 0x86'u8, 0x48'u8, 0x86'u8, 0xF7'u8, 0x0D'u8, 0x01'u8, 0x01'u8, 0x01'u8] ## Encoded OID for RSA Encryption (1.2.840.113549.1.1.1) Asn1True* = [0x01'u8, 0x01'u8, 0xFF'u8] ## Encoded boolean ``TRUE``. Asn1False* = [0x01'u8, 0x01'u8, 0x00'u8] ## Encoded boolean ``FALSE``. Asn1Null* = [0x05'u8, 0x00'u8] ## Encoded ``NULL`` value. template toOpenArray*(ab: Asn1Buffer): untyped = toOpenArray(ab.buffer, ab.offset, ab.buffer.high) template toOpenArray*(ac: Asn1Composite): untyped = toOpenArray(ac.buffer, ac.offset, ac.buffer.high) template toOpenArray*(af: Asn1Field): untyped = toOpenArray(af.buffer, af.offset, af.offset + af.length - 1) template isEmpty*(ab: Asn1Buffer): bool = ab.offset >= len(ab.buffer) template isEnough*(ab: Asn1Buffer, length: int64): bool = len(ab.buffer) >= ab.offset + length proc len*[T: Asn1Buffer | Asn1Composite](abc: T): int {.inline.} = len(abc.buffer) - abc.offset proc len*(field: Asn1Field): int {.inline.} = field.length template getPtr*(field: untyped): pointer = cast[pointer](unsafeAddr field.buffer[field.offset]) proc extend*[T: Asn1Buffer | Asn1Composite](abc: var T, length: int) {.inline.} = ## Extend buffer or composite's internal buffer by ``length`` octets. abc.buffer.setLen(len(abc.buffer) + length) proc code*(tag: Asn1Tag): byte {.inline.} = ## Converts Nim ``tag`` enum to ASN.1 tag code. case tag of Asn1Tag.NoSupport: 0x00'u8 of Asn1Tag.Boolean: 0x01'u8 of Asn1Tag.Integer: 0x02'u8 of Asn1Tag.BitString: 0x03'u8 of Asn1Tag.OctetString: 0x04'u8 of Asn1Tag.Null: 0x05'u8 of Asn1Tag.Oid: 0x06'u8 of Asn1Tag.Sequence: 0x30'u8 of Asn1Tag.Context: 0xA0'u8 proc asn1EncodeLength*(dest: var openArray[byte], length: uint64): int = ## Encode ASN.1 DER length part of TLV triple and return number of bytes ## (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``length`` value, then result of encoding WILL NOT BE stored in ``dest`` ## but number of bytes (octets) required will be returned. if length < 0x80'u64: if len(dest) >= 1: dest[0] = byte(length and 0x7F'u64) 1 else: var res = 1'u64 var z = length while z != 0: inc(res) z = z shr 8 if uint64(len(dest)) >= res: dest[0] = byte((0x80'u64 + (res - 1'u64)) and 0xFF) var o = 1 for j in countdown(res - 2, 0): dest[o] = byte((length shr (j shl 3)) and 0xFF'u64) inc(o) # Because our `length` argument is `uint64`, `res` could not be bigger # then 9, so it is safe to convert it to `int`. int(res) proc asn1EncodeInteger*(dest: var openArray[byte], value: openArray[byte]): int = ## Encode big-endian binary representation of integer as ASN.1 DER `INTEGER` ## and return number of bytes (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding WILL NOT BE stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] var lenlen = 0 let offset = block: var o = 0 for i in 0 ..< len(value): if value[o] != 0x00: break inc(o) if o < len(value): o else: o - 1 let destlen = if len(value) > 0: if value[offset] >= 0x80'u8: lenlen = asn1EncodeLength(buffer, uint64(len(value) - offset + 1)) 1 + lenlen + 1 + (len(value) - offset) else: lenlen = asn1EncodeLength(buffer, uint64(len(value) - offset)) 1 + lenlen + (len(value) - offset) else: 2 if len(dest) >= destlen: var shift = 1 dest[0] = Asn1Tag.Integer.code() copyMem(addr dest[1], addr buffer[0], lenlen) # If ``destlen > 2`` it means that ``len(value) > 0`` too. if destlen > 2: if value[offset] >= 0x80'u8: dest[1 + lenlen] = 0x00'u8 shift = 2 copyMem(addr dest[shift + lenlen], unsafeAddr value[offset], len(value) - offset) destlen proc asn1EncodeInteger*[T: SomeUnsignedInt](dest: var openArray[byte], value: T): int = ## Encode Nim's unsigned integer as ASN.1 DER `INTEGER` and return number of ## bytes (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. dest.asn1EncodeInteger(value.toBytesBE()) proc asn1EncodeBoolean*(dest: var openArray[byte], value: bool): int = ## Encode Nim's boolean as ASN.1 DER `BOOLEAN` and return number of bytes ## (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. let res = 3 if len(dest) >= res: dest[0] = Asn1Tag.Boolean.code() dest[1] = 0x01'u8 dest[2] = if value: 0xFF'u8 else: 0x00'u8 res proc asn1EncodeNull*(dest: var openArray[byte]): int = ## Encode ASN.1 DER `NULL` and return number of bytes (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. let res = 2 if len(dest) >= res: dest[0] = Asn1Tag.Null.code() dest[1] = 0x00'u8 res proc asn1EncodeOctetString*(dest: var openArray[byte], value: openArray[byte]): int = ## Encode array of bytes as ASN.1 DER `OCTET STRING` and return number of ## bytes (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let lenlen = asn1EncodeLength(buffer, uint64(len(value))) let res = 1 + lenlen + len(value) if len(dest) >= res: dest[0] = Asn1Tag.OctetString.code() copyMem(addr dest[1], addr buffer[0], lenlen) if len(value) > 0: copyMem(addr dest[1 + lenlen], unsafeAddr value[0], len(value)) res proc asn1EncodeBitString*( dest: var openArray[byte], value: openArray[byte], bits = 0 ): int = ## Encode array of bytes as ASN.1 DER `BIT STRING` and return number of bytes ## (octets) used. ## ## ``bits`` number of unused bits in ``value``. If ``bits == 0``, all the bits ## from ``value`` will be used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let bitlen = if bits != 0: (len(value) shl 3) - bits else: (len(value) shl 3) # Number of bytes used let bytelen = (bitlen + 7) shr 3 # Number of unused bits let unused = (8 - (bitlen and 7)) and 7 let mask = not ((1'u8 shl unused) - 1'u8) var lenlen = asn1EncodeLength(buffer, uint64(bytelen + 1)) let res = 1 + lenlen + 1 + len(value) if len(dest) >= res: dest[0] = Asn1Tag.BitString.code() copyMem(addr dest[1], addr buffer[0], lenlen) dest[1 + lenlen] = byte(unused) if bytelen > 0: let lastbyte = value[bytelen - 1] copyMem(addr dest[2 + lenlen], unsafeAddr value[0], bytelen) # Set unused bits to zero dest[2 + lenlen + bytelen - 1] = lastbyte and mask res proc asn1EncodeTag[T: SomeUnsignedInt](dest: var openArray[byte], value: T): int = var v = value if value <= cast[T](0x7F): if len(dest) >= 1: dest[0] = cast[byte](value) 1 else: var s = 0 var res = 0 while v != 0: v = v shr 7 s += 7 inc(res) if len(dest) >= res: var k = 0 while s != 0: s -= 7 dest[k] = cast[byte](((value shr s) and cast[T](0x7F)) or cast[T](0x80)) inc(k) dest[k - 1] = dest[k - 1] and 0x7F'u8 res proc asn1EncodeOid*(dest: var openArray[byte], value: openArray[byte]): int = ## Encode array of bytes ``value`` as ASN.1 DER `OBJECT IDENTIFIER` and return ## number of bytes (octets) used. ## ## This procedure is useful to encode constant predefined identifiers such ## as ``asn1OidSecp256r1``, ``asn1OidRsaEncryption``. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let lenlen = asn1EncodeLength(buffer, uint64(len(value))) let res = 1 + lenlen + len(value) if len(dest) >= res: dest[0] = Asn1Tag.Oid.code() copyMem(addr dest[1], addr buffer[0], lenlen) copyMem(addr dest[1 + lenlen], unsafeAddr value[0], len(value)) res proc asn1EncodeSequence*(dest: var openArray[byte], value: openArray[byte]): int = ## Encode ``value`` as ASN.1 DER `SEQUENCE` and return number of bytes ## (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let lenlen = asn1EncodeLength(buffer, uint64(len(value))) let res = 1 + lenlen + len(value) if len(dest) >= res: dest[0] = Asn1Tag.Sequence.code() copyMem(addr dest[1], addr buffer[0], lenlen) copyMem(addr dest[1 + lenlen], unsafeAddr value[0], len(value)) res proc asn1EncodeComposite*(dest: var openArray[byte], value: Asn1Composite): int = ## Encode composite value and return number of bytes (octets) used. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let lenlen = asn1EncodeLength(buffer, uint64(len(value.buffer))) let res = 1 + lenlen + len(value.buffer) if len(dest) >= res: dest[0] = value.tag.code() copyMem(addr dest[1], addr buffer[0], lenlen) copyMem(addr dest[1 + lenlen], unsafeAddr value.buffer[0], len(value.buffer)) res proc asn1EncodeContextTag*( dest: var openArray[byte], value: openArray[byte], tag: int ): int = ## Encode ASN.1 DER `CONTEXT SPECIFIC TAG` ``tag`` for value ``value`` and ## return number of bytes (octets) used. ## ## Note: Only values in [0, 15] range can be used as context tag ``tag`` ## values. ## ## If length of ``dest`` is less then number of required bytes to encode ## ``value``, then result of encoding will not be stored in ``dest`` ## but number of bytes (octets) required will be returned. var buffer: array[16, byte] let lenlen = asn1EncodeLength(buffer, uint64(len(value))) let res = 1 + lenlen + len(value) if len(dest) >= res: dest[0] = 0xA0'u8 or (byte(tag and 0xFF) and 0x0F'u8) copyMem(addr dest[1], addr buffer[0], lenlen) copyMem(addr dest[1 + lenlen], unsafeAddr value[0], len(value)) res proc getLength(ab: var Asn1Buffer): Asn1Result[int] = ## Decode length part of ASN.1 TLV triplet. if not ab.isEmpty(): let b = ab.buffer[ab.offset] if (b and 0x80'u8) == 0x00'u8: let length = safeConvert[int](b) ab.offset += 1 return ok(length) if b == 0x80'u8: return err(Asn1Error.Indefinite) if b == 0xFF'u8: return err(Asn1Error.Incorrect) let octets = safeConvert[int](b and 0x7F'u8) if octets > 8: return err(Asn1Error.Overflow) if ab.isEnough(octets): var lengthU: uint64 = 0 for i in 0 ..< octets: lengthU = (lengthU shl 8) or safeConvert[uint64](ab.buffer[ab.offset + i + 1]) if lengthU > uint64(int64.high): return err(Asn1Error.Overflow) let length = int(lengthU) ab.offset = ab.offset + octets + 1 return ok(length) else: return err(Asn1Error.Incomplete) else: return err(Asn1Error.Incomplete) proc getTag(ab: var Asn1Buffer, tag: var int): Asn1Result[Asn1Class] = ## Decode tag part of ASN.1 TLV triplet. if not ab.isEmpty(): let b = ab.buffer[ab.offset] c = safeConvert[int]((b and 0xC0'u8) shr 6) tag = safeConvert[int](b and 0x3F) ab.offset += 1 if c >= 0 and c < 4: ok(cast[Asn1Class](c)) else: err(Asn1Error.Incorrect) else: err(Asn1Error.Incomplete) proc read*(ab: var Asn1Buffer): Asn1Result[Asn1Field] = ## Decode value part of ASN.1 TLV triplet. var field: Asn1Field tag, ttag, offset: int length, tlength: int aclass: Asn1Class inclass: bool inclass = false while true: offset = ab.offset aclass = ?ab.getTag(tag) case aclass of Asn1Class.ContextSpecific: if inclass: return err(Asn1Error.Incorrect) else: inclass = true ttag = tag tlength = ?ab.getLength() of Asn1Class.Universal: length = ?ab.getLength() if inclass: if length >= tlength: return err(Asn1Error.Incorrect) case byte(tag) of Asn1Tag.Boolean.code(): # BOOLEAN if length != 1: return err(Asn1Error.Incorrect) if not ab.isEnough(length): return err(Asn1Error.Incomplete) let b = ab.buffer[ab.offset] if b != 0xFF'u8 and b != 0x00'u8: return err(Asn1Error.Incorrect) field = Asn1Field( kind: Asn1Tag.Boolean, klass: aclass, index: ttag, offset: ab.offset, length: 1, buffer: ab.buffer, ) field.vbool = (b == 0xFF'u8) ab.offset += 1 return ok(field) of Asn1Tag.Integer.code(): # INTEGER if length == 0: return err(Asn1Error.Incorrect) if not ab.isEnough(length): return err(Asn1Error.Incomplete) # Count number of leading zeroes var zc = 0 while (zc < length) and (ab.buffer[ab.offset + zc] == 0x00'u8): inc(zc) if zc > 1: return err(Asn1Error.Incorrect) if zc == 0: # Negative or Positive integer field = Asn1Field( kind: Asn1Tag.Integer, klass: aclass, index: ttag, offset: ab.offset, length: length, buffer: ab.buffer, ) if (ab.buffer[ab.offset] and 0x80'u8) == 0x80'u8: # Negative integer if length <= 8: # We need this transformation because our field.vint is uint64. for i in 0 ..< 8: if i < 8 - length: field.vint = (field.vint shl 8) or 0xFF'u64 else: let offset = ab.offset + i - (8 - length) field.vint = (field.vint shl 8) or safeConvert[uint64](ab.buffer[offset]) else: # Positive integer if length <= 8: for i in 0 ..< length: field.vint = (field.vint shl 8) or safeConvert[uint64](ab.buffer[ab.offset + i]) ab.offset += length return ok(field) else: if length == 1: # Zero value integer field = Asn1Field( kind: Asn1Tag.Integer, klass: aclass, index: ttag, offset: ab.offset, length: length, vint: 0'u64, buffer: ab.buffer, ) ab.offset += length return ok(field) else: # Positive integer with leading zero field = Asn1Field( kind: Asn1Tag.Integer, klass: aclass, index: ttag, offset: ab.offset + 1, length: length - 1, buffer: ab.buffer, ) if length <= 9: for i in 1 ..< length: field.vint = (field.vint shl 8) or safeConvert[uint64](ab.buffer[ab.offset + i]) ab.offset += length return ok(field) of Asn1Tag.BitString.code(): # BIT STRING if length == 0: # BIT STRING should include `unused` bits field, so length should be # bigger then 1. return err(Asn1Error.Incorrect) elif length == 1: if ab.buffer[ab.offset] != 0x00'u8: return err(Asn1Error.Incorrect) else: # Zero-length BIT STRING. field = Asn1Field( kind: Asn1Tag.BitString, klass: aclass, index: ttag, offset: ab.offset + 1, length: 0, ubits: 0, buffer: ab.buffer, ) ab.offset += length return ok(field) else: if not ab.isEnough(length): return err(Asn1Error.Incomplete) let unused = ab.buffer[ab.offset] if unused > 0x07'u8: # Number of unused bits should not be bigger then `7`. return err(Asn1Error.Incorrect) let mask = (1'u8 shl safeConvert[int](unused)) - 1'u8 if (ab.buffer[ab.offset + length - 1] and mask) != 0x00'u8: ## All unused bits should be set to `0`. return err(Asn1Error.Incorrect) field = Asn1Field( kind: Asn1Tag.BitString, klass: aclass, index: ttag, offset: ab.offset + 1, length: length - 1, ubits: safeConvert[int](unused), buffer: ab.buffer, ) ab.offset += length return ok(field) of Asn1Tag.OctetString.code(): # OCTET STRING if not ab.isEnough(length): return err(Asn1Error.Incomplete) field = Asn1Field( kind: Asn1Tag.OctetString, klass: aclass, index: ttag, offset: ab.offset, length: length, buffer: ab.buffer, ) ab.offset += length return ok(field) of Asn1Tag.Null.code(): # NULL if length != 0: return err(Asn1Error.Incorrect) field = Asn1Field( kind: Asn1Tag.Null, klass: aclass, index: ttag, offset: ab.offset, length: 0, buffer: ab.buffer, ) ab.offset += length return ok(field) of Asn1Tag.Oid.code(): # OID if not ab.isEnough(length): return err(Asn1Error.Incomplete) field = Asn1Field( kind: Asn1Tag.Oid, klass: aclass, index: ttag, offset: ab.offset, length: length, buffer: ab.buffer, ) ab.offset += length return ok(field) of Asn1Tag.Sequence.code(): # SEQUENCE if not ab.isEnough(length): return err(Asn1Error.Incomplete) field = Asn1Field( kind: Asn1Tag.Sequence, klass: aclass, index: ttag, offset: ab.offset, length: length, buffer: ab.buffer, ) ab.offset += length return ok(field) else: return err(Asn1Error.NoSupport) inclass = false ttag = 0 else: return err(Asn1Error.NoSupport) proc getBuffer*(field: Asn1Field): Asn1Buffer {.inline.} = ## Return ``field`` as Asn1Buffer to enter composite types. Asn1Buffer(buffer: field.buffer, offset: field.offset, length: field.length) proc `==`*(field: Asn1Field, data: openArray[byte]): bool = ## Compares field ``field`` data with ``data`` and returns ``true`` if both ## buffers are equal. let length = len(field.buffer) if length == 0 and len(data) == 0: true else: if length > 0: if field.length == len(data): CT.isEqual( field.buffer.toOpenArray(field.offset, field.offset + field.length - 1), data.toOpenArray(0, field.length - 1), ) else: false else: false proc init*(t: typedesc[Asn1Buffer], data: openArray[byte]): Asn1Buffer = ## Initialize ``Asn1Buffer`` from array of bytes ``data``. Asn1Buffer(buffer: @data) proc init*(t: typedesc[Asn1Buffer], data: string): Asn1Buffer = ## Initialize ``Asn1Buffer`` from hexadecimal string ``data``. Asn1Buffer(buffer: ncrutils.fromHex(data)) proc init*(t: typedesc[Asn1Buffer]): Asn1Buffer = ## Initialize empty ``Asn1Buffer``. Asn1Buffer(buffer: newSeq[byte]()) proc init*(t: typedesc[Asn1Composite], tag: Asn1Tag): Asn1Composite = ## Initialize ``Asn1Composite`` with tag ``tag``. Asn1Composite(tag: tag, buffer: newSeq[byte]()) proc init*(t: typedesc[Asn1Composite], idx: int): Asn1Composite = ## Initialize ``Asn1Composite`` with tag context-specific id ``id``. Asn1Composite(tag: Asn1Tag.Context, idx: idx, buffer: newSeq[byte]()) proc `$`*(buffer: Asn1Buffer): string = ## Return string representation of ``buffer``. ncrutils.toHex(buffer.toOpenArray()) proc `$`*(field: Asn1Field): string = ## Return string representation of ``field``. var res = "[" res.add($field.kind) res.add("]") case field.kind of Asn1Tag.Boolean: res.add(" ") res.add($field.vbool) res of Asn1Tag.Integer: res.add(" ") if field.length <= 8: res.add($field.vint) else: res.add(ncrutils.toHex(field.toOpenArray())) res of Asn1Tag.BitString: res.add(" ") res.add("(") res.add($field.ubits) res.add(" bits) ") res.add(ncrutils.toHex(field.toOpenArray())) res of Asn1Tag.OctetString: res.add(" ") res.add(ncrutils.toHex(field.toOpenArray())) res of Asn1Tag.Null: res.add(" NULL") res of Asn1Tag.Oid: res.add(" ") res.add(ncrutils.toHex(field.toOpenArray())) res of Asn1Tag.Sequence: res.add(" ") res.add(ncrutils.toHex(field.toOpenArray())) res of Asn1Tag.Context: res.add(" ") res.add(ncrutils.toHex(field.toOpenArray())) res else: res.add(" ") res.add(ncrutils.toHex(field.toOpenArray())) res proc write*[T: Asn1Buffer | Asn1Composite](abc: var T, tag: Asn1Tag) = ## Write empty value to buffer or composite with ``tag``. ## ## This procedure must be used to write `NULL`, `0` or empty `BIT STRING`, ## `OCTET STRING` types. doAssert( tag in {Asn1Tag.Null, Asn1Tag.Integer, Asn1Tag.BitString, Asn1Tag.OctetString} ) var length: int if tag == Asn1Tag.Null: length = asn1EncodeNull(abc.toOpenArray()) abc.extend(length) discard asn1EncodeNull(abc.toOpenArray()) elif tag == Asn1Tag.Integer: length = asn1EncodeInteger(abc.toOpenArray(), 0'u64) abc.extend(length) discard asn1EncodeInteger(abc.toOpenArray(), 0'u64) elif tag == Asn1Tag.BitString: var tmp: array[1, byte] length = asn1EncodeBitString(abc.toOpenArray(), tmp.toOpenArray(0, -1)) abc.extend(length) discard asn1EncodeBitString(abc.toOpenArray(), tmp.toOpenArray(0, -1)) elif tag == Asn1Tag.OctetString: var tmp: array[1, byte] length = asn1EncodeOctetString(abc.toOpenArray(), tmp.toOpenArray(0, -1)) abc.extend(length) discard asn1EncodeOctetString(abc.toOpenArray(), tmp.toOpenArray(0, -1)) abc.offset += length proc write*[T: Asn1Buffer | Asn1Composite](abc: var T, value: uint64) = ## Write uint64 ``value`` to buffer or composite as ASN.1 `INTEGER`. let length = asn1EncodeInteger(abc.toOpenArray(), value) abc.extend(length) discard asn1EncodeInteger(abc.toOpenArray(), value) abc.offset += length proc write*[T: Asn1Buffer | Asn1Composite](abc: var T, value: bool) = ## Write bool ``value`` to buffer or composite as ASN.1 `BOOLEAN`. let length = asn1EncodeBoolean(abc.toOpenArray(), value) abc.extend(length) discard asn1EncodeBoolean(abc.toOpenArray(), value) abc.offset += length proc write*[T: Asn1Buffer | Asn1Composite]( abc: var T, tag: Asn1Tag, value: openArray[byte], bits = 0 ) = ## Write array ``value`` using ``tag``. ## ## This procedure is used to write ASN.1 `INTEGER`, `OCTET STRING`, ## `BIT STRING` or `OBJECT IDENTIFIER`. ## ## For `BIT STRING` you can use ``bits`` argument to specify number of used ## bits. doAssert( tag in {Asn1Tag.Integer, Asn1Tag.OctetString, Asn1Tag.BitString, Asn1Tag.Oid} ) var length: int if tag == Asn1Tag.Integer: length = asn1EncodeInteger(abc.toOpenArray(), value) abc.extend(length) discard asn1EncodeInteger(abc.toOpenArray(), value) elif tag == Asn1Tag.OctetString: length = asn1EncodeOctetString(abc.toOpenArray(), value) abc.extend(length) discard asn1EncodeOctetString(abc.toOpenArray(), value) elif tag == Asn1Tag.BitString: length = asn1EncodeBitString(abc.toOpenArray(), value, bits) abc.extend(length) discard asn1EncodeBitString(abc.toOpenArray(), value, bits) elif tag == Asn1Tag.Oid: length = asn1EncodeOid(abc.toOpenArray(), value) abc.extend(length) discard asn1EncodeOid(abc.toOpenArray(), value) abc.offset += length proc write*[T: Asn1Buffer | Asn1Composite](abc: var T, value: Asn1Composite) = doAssert(len(value) > 0, "Composite value not finished") var length: int if value.tag == Asn1Tag.Sequence: length = asn1EncodeSequence(abc.toOpenArray(), value.buffer) abc.extend(length) discard asn1EncodeSequence(abc.toOpenArray(), value.buffer) elif value.tag == Asn1Tag.BitString: length = asn1EncodeBitString(abc.toOpenArray(), value.buffer) abc.extend(length) discard asn1EncodeBitString(abc.toOpenArray(), value.buffer) elif value.tag == Asn1Tag.Context: length = asn1EncodeContextTag(abc.toOpenArray(), value.buffer, value.idx) abc.extend(length) discard asn1EncodeContextTag(abc.toOpenArray(), value.buffer, value.idx) abc.offset += length proc finish*[T: Asn1Buffer | Asn1Composite](abc: var T) {.inline.} = ## Finishes buffer or composite and prepares it for writing. abc.offset = 0