/// <summary>BER encode class value.</summary>
/// <param name="buffer">Target buffer. Value is appended to the end of it.</param>
public override void Encode(MutableByte buffer)
{
MutableByte tmp = new MutableByte();
byte[] b = BitConverter.GetBytes(value);
for (int i = 3; i >= 0; i--)
{
if (b[i] != 0 || tmp.Length > 0)
{
tmp.Append(b[i]);
}
}
if (tmp.Length > 0 && (tmp[0] & 0x80) != 0)
{
tmp.Prepend(0);
}
else if (tmp.Length == 0)
{
tmp.Append(0);
}
BuildHeader(buffer, Type, tmp.Length);
buffer.Append(tmp);
}
/// <summary>Encode single OID instance value</summary>
/// <param name="number">Instance value</param>
/// <returns>Encoded instance value</returns>
protected byte[] EncodeInstance(uint number)
{
MutableByte result = new MutableByte();
if (number <= 127)
{
result.Set((byte)number);
}
else
{
uint val = number;
MutableByte tmp = new MutableByte();
while (val != 0)
{
byte[] b = BitConverter.GetBytes(val);
byte bval = b[0];
if ((bval & 0x80) != 0)
{
bval = (byte)(bval & ~HighBit); // clear high bit
}
val >>= 7; // shift original value by 7 bits
tmp.Append(bval);
}
// now we need to reverse the bytes for the final encoding
for (int i = tmp.Length - 1; i >= 0; i--)
{
if (i > 0)
{
result.Append((byte)(tmp[i] | HighBit));
}
else
{
result.Append(tmp[i]);
}
}
}
return(result);
}
/// <summary>BER encode class value</summary>
/// <param name="buffer">MutableByte to append BER encoded value to.
/// </param>
public override void Encode(MutableByte buffer)
{
byte[] b = BitConverter.GetBytes(value);
MutableByte tmp = new MutableByte();
for (int i = b.Length - 1; i >= 0; i--)
{
if (b[i] != 0 || tmp.Length > 0)
{
tmp.Append(b[i]);
}
}
if (tmp.Length == 0)
{
tmp.Append(0); // value is 0. can't have an empty encoding
}
BuildHeader(buffer, Type, tmp.Length);
buffer.Append(tmp);
}
/// <summary>BER encode OctetString variable.</summary>
/// <param name="buffer"><see cref="MutableByte"/> encoding destination.</param>
public override void Encode(MutableByte buffer)
{
if (data == null || data.Length == 0)
{
BuildHeader(buffer, Type, 0);
}
else
{
BuildHeader(buffer, Type, data.Length);
buffer.Append(data);
}
}
/// <summary>
/// Convert <see cref="ScopedPdu"/> into a BER encoded byte array. Resulting byte array is appended
/// to the argument specified <see cref="MutableByte"/> class.
///
/// Privacy operations are not performed by this method. Value encoded and returned by this method is
/// suitable for sending in NoAuthNoPriv or AuthNoPriv security configurations. If privacy is required,
/// caller will have to perform encryption and decryption operations after BER encoding is performed.
///
/// In privacy protected SNMP version 3 packets, ScopedPdu is 1) encrypted using configured encryption
/// method, 2) added to a <see cref="OctetString"/> field, and 3) appended to the data buffer.
///
/// Because privacy operation is intrusive, it is recommended that BER encoding of the ScopedPdu packet
/// is stored in a temporary <see cref="MutableByte"/> class, where it can be privacy protected and
/// added to the <see cref="OctetString"/> class for final encoding into the target SNMP v3 packet.
/// </summary>
/// <param name="buffer"><see cref="MutableByte"/> class passed by reference that encoded ScopedPdu
/// value is appended to.</param>
public override void Encode(MutableByte buffer)
{
MutableByte tmp = new MutableByte();
contextEngineId.Encode(tmp);
contextName.Encode(tmp);
// Encode base
base.Encode(tmp);
BuildHeader(buffer, SnmpConstants.SmiSequence, tmp.Length);
buffer.Append(tmp);
}
/// <summary>Encodes ASN.1 object identifier and append it to the end of the passed buffer.</summary>
/// <param name="buffer">Buffer to append the encoded information to.</param>
public override void Encode(MutableByte buffer)
{
MutableByte tmpBuffer = new MutableByte();
uint[] values = data;
if (values == null || values.Length < 2)
{
values = new uint[2];
values[0] = values[1] = 0;
}
// verify that it is a valid object id!
if (values[0] < 0 || values[0] > 2)
{
throw new SnmpException("Invalid Object Identifier");
}
if (values[1] < 0 || values[1] > 40)
{
throw new SnmpException("Invalid Object Identifier");
}
// add the first oid!
tmpBuffer.Append((byte)((values[0] * 40) + values[1]));
// encode remaining instance values
for (int i = 2; i < values.Length; i++)
{
tmpBuffer.Append(EncodeInstance(values[i]));
}
// build value header
BuildHeader(buffer, Type, tmpBuffer.Length);
// Append encoded value to the result buffer
buffer.Append(tmpBuffer);
}
/// <summary>BER encode sequence</summary>
/// <param name="buffer">Target buffer</param>
public override void Encode(MutableByte buffer)
{
int dataLen = 0;
if (data != null && data.Length > 0)
{
dataLen = data.Length;
}
BuildHeader(buffer, Type, dataLen);
if (dataLen > 0)
{
buffer.Append(data);
}
}
/// <summary>ASN.1 encode SNMP version 1 trap</summary>
/// <param name="buffer"><see cref="MutableByte"/> buffer to the end of which encoded values are appended.</param>
public override void encode(MutableByte buffer)
{
MutableByte trapBuffer = new MutableByte();
// encode the enterprise id & address
_enterprise.encode(trapBuffer);
_agentAddr.encode(trapBuffer);
_generic.encode(trapBuffer);
_specific.encode(trapBuffer);
_timeStamp.encode(trapBuffer);
_variables.encode(trapBuffer);
MutableByte tmpBuffer = new MutableByte();
BuildHeader(tmpBuffer, (byte)PduType.Trap, trapBuffer.Length);
trapBuffer.Prepend(tmpBuffer);
buffer.Append(trapBuffer);
}
/// <summary>BER encode security model field.</summary>
/// <remarks>
/// USM security model is a SEQUENCE encoded inside a OCTETSTRING. To encode it, first encode the sequence
/// of class values then "wrap" it inside a OCTETSTRING field
/// </remarks>
/// <param name="buffer">Buffer to store encoded USM security model header</param>
public override void Encode(MutableByte buffer)
{
MutableByte tmp = new MutableByte();
// First encode all the values that will form the sequence
engineId.Encode(tmp);
// Encode engine boots
engineBoots.Encode(tmp);
// encode engine time
engineTime.Encode(tmp);
securityName.Encode(tmp);
if (authentication != AuthenticationDigests.None)
{
if (authenticationParameters.Length <= 0)
{
// If authentication is used, set authentication parameters field to 12 bytes set to 0x00
authenticationParameters.Set(new byte[] { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 });
}
}
else
{
authenticationParameters.Reset();
}
authenticationParameters.Encode(tmp);
if (privacy != EPrivacyProtocols.None)
{
if (privacyParameters.Length <= 0)
{
IPrivacyProtocol privProto = PrivacyProtocol.GetInstance(privacy);
if (privProto != null)
{
byte[] parameter = new byte[privProto.PrivacyParametersLength];
for (int i = 0; i < privProto.PrivacyParametersLength; i++)
{
parameter[i] = 0x00; // This is not necessary since all array members are, by default, initialized to 0
}
privacyParameters.Set(parameter);
}
else
{
throw new SnmpException(SnmpException.EErrorCode.UnsupportedPrivacyProtocol, "Unrecognized privacy protocol specified.");
}
}
}
else
{
privacyParameters.Reset();
}
privacyParameters.Encode(tmp);
MutableByte tmp1 = new MutableByte();
BuildHeader(tmp1, SnmpConstants.SmiSequence, tmp.Length);
tmp1.Append(tmp);
BuildHeader(buffer, (byte)EAsnType.OctetString, tmp1.Length);
buffer.Append(tmp1);
}
/// <summary>Decode BER encoded Oid value.</summary>
/// <param name="buffer">BER encoded buffer</param>
/// <param name="offset">The offset location to begin decoding</param>
/// <returns>Buffer position after the decoded value</returns>
public override int Decode(byte[] buffer, int offset)
{
byte asnType = ParseHeader(buffer, ref offset, out int headerLength);
if (asnType != Type)
{
throw new SnmpException("Invalid ASN.1 type.");
}
// check for sufficient data
if ((buffer.Length - offset) < headerLength)
{
throw new OverflowException("Buffer underflow error");
}
if (headerLength == 0)
{
data = null;
return(offset);
}
List <uint> list = new List <uint>();
// decode the first byte
headerLength--;
uint oid = Convert.ToUInt32(buffer[offset++]);
list.Add(oid / 40);
list.Add(oid % 40);
// decode the rest of the identifiers
while (headerLength > 0)
{
uint result = 0;
// this is where we decode individual values
{
if ((buffer[offset] & HighBit) == 0)
{
// short encoding
result = buffer[offset];
offset += 1;
headerLength--;
}
else
{
// long encoding
MutableByte tmp = new MutableByte();
bool completed = false;
do
{
tmp.Append((byte)(buffer[offset] & ~HighBit));
if ((buffer[offset] & HighBit) == 0)
{
completed = true;
}
offset += 1; // advance offset
--headerLength; // take out the processed byte from the header length
} while (!completed);
// convert byte array to integer
for (int i = 0; i < tmp.Length; i++)
{
result <<= 7;
result |= tmp[i];
}
}
}
list.Add(result);
}
data = list.ToArray();
if (data.Length == 2 && data[0] == 0 && data[1] == 0)
{
data = null;
}
return(offset);
}
/// <summary>
/// Append BER encoded length to the <see cref="MutableByte"/>
/// </summary>
/// <param name="mb">MutableArray to append BER encoded length to</param>
/// <param name="asnLength">Length value to encode.</param>
/// <exception cref="ArgumentOutOfRangeException">Thrown when length value to encode is less then 0</exception>
internal static void BuildLength(MutableByte mb, int asnLength)
{
if (asnLength < 0)
throw new ArgumentOutOfRangeException("Length cannot be less then 0.");
byte[] len = BitConverter.GetBytes(asnLength);
MutableByte buf = new MutableByte();
for (int i = 3; i >= 0; i--)
{
if (len[i] != 0 || buf.Length > 0)
buf.Append(len[i]);
}
if (buf.Length == 0)
{
// we are encoding a 0 value. Can't have a 0 byte length encoding
buf.Append(0);
}
// check for short form encoding
if (buf.Length == 1 && (buf[0] & HIGH_BIT) == 0)
mb.Append(buf); // done
else
{
// long form encoding
byte encHeader = (byte)buf.Length;
encHeader = (byte)(encHeader | HIGH_BIT);
mb.Append(encHeader);
mb.Append(buf);
}
}
/// <summary>
/// Build ASN.1 header in the MutableByte array.
/// </summary>
/// <remarks>
/// Header is the TL part of the TLV (type, length, value) BER encoded data representation.
///
/// Each value is encoded as a Type byte, length of the data field and the actual, encoded
/// data. This method will encode the type and length fields.
/// </remarks>
/// <param name="mb">MurableByte array</param>
/// <param name="asnType">ASN.1 header type</param>
/// <param name="asnLength">Length of the data contained in the header</param>
internal static void BuildHeader(MutableByte mb, byte asnType, int asnLength)
{
mb.Append(asnType);
BuildLength(mb, asnLength);
}
/// <summary>
/// Convert user password to acceptable authentication key.
/// </summary>
/// <param name="userPassword">User password</param>
/// <param name="engineID">Authoritative engine id</param>
/// <returns>Localized authentication key</returns>
/// <exception cref="SnmpAuthenticationException">Thrown when key length is less then 8 bytes</exception>
public byte[] PasswordToKey(byte[] userPassword, byte[] engineID)
{
// key length has to be at least 8 bytes long (RFC3414)
if (userPassword == null || userPassword.Length < 8)
throw new SnmpAuthenticationException("Secret key is too short.");
int password_index = 0;
int count = 0;
SHA1 sha = new SHA1CryptoServiceProvider();
/* Use while loop until we've done 1 Megabyte */
byte[] sourceBuffer = new byte[1048576];
byte[] buf = new byte[64];
while (count < 1048576)
{
for (int i = 0; i < 64; ++i)
{
// Take the next octet of the password, wrapping
// to the beginning of the password as necessary.
buf[i] = userPassword[password_index++ % userPassword.Length];
}
Buffer.BlockCopy(buf, 0, sourceBuffer, count, buf.Length);
count += 64;
}
byte[] digest = sha.ComputeHash(sourceBuffer);
MutableByte tmpbuf = new MutableByte();
tmpbuf.Append(digest);
tmpbuf.Append(engineID);
tmpbuf.Append(digest);
byte[] res = sha.ComputeHash(tmpbuf);
sha.Clear(); // release resources
return res;
}
/// <summary>
/// BER encode sequence
/// </summary>
/// <param name="buffer">Target buffer</param>
public override void encode(MutableByte buffer)
{
int dataLen = 0;
if (_data != null && _data.Length > 0)
dataLen = _data.Length;
BuildHeader(buffer, Type, dataLen);
if (dataLen > 0)
buffer.Append(_data);
}
/// <summary>
/// Convert <see cref="ScopedPdu"/> into a BER encoded byte array. Resulting byte array is appended
/// to the argument specified <see cref="MutableByte"/> class.
///
/// Privacy operations are not performed by this method. Value encoded and returned by this method is
/// suitable for sending in NoAuthNoPriv or AuthNoPriv security configurations. If privacy is required,
/// caller will have to perform encryption and decryption operations after BER encoding is performed.
///
/// In privacy protected SNMP version 3 packets, ScopedPdu is 1) encrypted using configured encryption
/// method, 2) added to a <see cref="OctetString"/> field, and 3) appended to the data buffer.
///
/// Because privacy operation is intrusive, it is recommended that BER encoding of the ScopedPdu packet
/// is stored in a temporary <see cref="MutableByte"/> class, where it can be privacy protected and
/// added to the <see cref="OctetString"/> class for final encoding into the target SNMP v3 packet.
/// </summary>
/// <param name="buffer"><see cref="MutableByte"/> class passed by reference that encoded ScopedPdu
/// value is appended to.</param>
public override void encode(MutableByte buffer)
{
MutableByte tmp = new MutableByte();
_contextEngineId.encode(tmp);
_contextName.encode(tmp);
// Encode base
base.encode(tmp);
BuildHeader(buffer, SnmpConstants.SMI_SEQUENCE, tmp.Length);
buffer.Append(tmp);
}
/// <summary>BER encode security model field.</summary>
/// <remarks>
/// USM security model is a SEQUENCE encoded inside a OCTETSTRING. To encode it, first encode the sequence
/// of class values then "wrap" it inside a OCTETSTRING field
/// </remarks>
/// <param name="buffer">Buffer to store encoded USM security model header</param>
public override void encode(MutableByte buffer)
{
MutableByte tmp = new MutableByte();
// First encode all the values that will form the sequence
_engineId.encode(tmp);
// Encode engine boots
_engineBoots.encode(tmp);
// encode engine time
_engineTime.encode(tmp);
_securityName.encode(tmp);
if (_authentication != AuthenticationDigests.None)
{
if (_authenticationParameters.Length <= 0)
{
// If authentication is used, set authentication parameters field to 12 bytes set to 0x00
_authenticationParameters.Set(new byte[] { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 });
}
}
else
{
_authenticationParameters.Reset();
}
_authenticationParameters.encode(tmp);
if (_privacy != PrivacyProtocols.None)
{
if (_privacyParameters.Length <= 0)
{
IPrivacyProtocol privProto = PrivacyProtocol.GetInstance(_privacy);
if (privProto != null)
{
byte[] parameter = new byte[privProto.PrivacyParametersLength];
for (int i = 0; i < privProto.PrivacyParametersLength; i++)
{
parameter[i] = 0x00; // This is not necessary since all array members are, by default, initialized to 0
}
_privacyParameters.Set(parameter);
}
else
throw new SnmpException(SnmpException.UnsupportedPrivacyProtocol, "Unrecognized privacy protocol specified.");
}
}
else
{
_privacyParameters.Reset();
}
_privacyParameters.encode(tmp);
MutableByte tmp1 = new MutableByte();
BuildHeader(tmp1, SnmpConstants.SMI_SEQUENCE, tmp.Length);
tmp1.Append(tmp);
BuildHeader(buffer, OCTETSTRING, tmp1.Length);
buffer.Append(tmp1);
}
/// <summary>
/// Convert user password to acceptable authentication key.
/// </summary>
/// <param name="userPassword">Authentication password</param>
/// <param name="engineID">Authoritative engine id</param>
/// <returns>Localized authentication key</returns>
/// <exception cref="SnmpAuthenticationException">Thrown when key length is less then 8 bytes</exception>
public byte[] PasswordToKey(byte[] userPassword, byte[] engineID)
{
// key length has to be at least 8 bytes long (RFC3414)
if (userPassword == null || userPassword.Length < 8)
throw new SnmpAuthenticationException("Secret key is too short.");
int password_index = 0;
int count = 0;
MD5 md5 = new MD5CryptoServiceProvider();
byte[] sourceBuffer = new byte[1048576];
byte[] buf = new byte[64];
while (count < 1048576)
{
for (int i = 0; i < 64; ++i)
{
buf[i] = userPassword[password_index++ % userPassword.Length];
}
Buffer.BlockCopy(buf, 0, sourceBuffer, count, buf.Length);
count += 64;
}
byte[] digest = md5.ComputeHash(sourceBuffer);
MutableByte tmpbuf = new MutableByte();
tmpbuf.Append(digest);
tmpbuf.Append(engineID);
tmpbuf.Append(digest);
byte[] key = md5.ComputeHash(tmpbuf);
return key;
}
/// <summary>
/// Encode SNMP version 3 packet
/// </summary>
/// <param name="authKey">Authentication key (not password)</param>
/// <param name="privKey">Privacy key (not password)</param>
/// <remarks>
/// Before encoding the packet into a byte array you need to ensure all required information is
/// set. Examples of required information is request type, Vbs (Oid + values pairs), USM settings including
/// SecretName, authentication method and secret (if needed), privacy method and secret (if needed), etc.
/// </remarks>
/// <returns>Byte array BER encoded SNMP packet.</returns>
public byte[] encode(byte[] authKey, byte[] privKey)
{
MutableByte buffer = new MutableByte();
// encode the global message data sequence header information
MutableByte globalMessageData = new MutableByte();
// if message id is 0 then generate a new, random message id
if (_messageId.Value == 0)
{
Random rand = new Random();
_messageId.Value = rand.Next(1, Int32.MaxValue);
}
// encode message id
_messageId.encode(globalMessageData);
// encode max message size
_maxMessageSize.encode(globalMessageData);
// message flags
_msgFlags.encode(globalMessageData);
// security model code
_securityModel.Value = _userSecurityModel.Type;
_securityModel.encode(globalMessageData);
// add global message data to the main buffer
// encode sequence header and add data
AsnType.BuildHeader(buffer, SnmpConstants.SMI_SEQUENCE, globalMessageData.Length);
buffer.Append(globalMessageData);
MutableByte packetHeader = new MutableByte(buffer);
// before going down this road, check if this is a discovery packet
OctetString savedUserName = new OctetString();
bool privacy = _msgFlags.Privacy;
bool authentication = _msgFlags.Authentication;
bool reportable = _msgFlags.Reportable;
if (_userSecurityModel.EngineId.Length <= 0)
{
// save USM settings prior to encoding a Discovery packet
savedUserName.Set(_userSecurityModel.SecurityName);
_userSecurityModel.SecurityName.Reset(); // delete security name for discovery packets
_msgFlags.Authentication = false;
_msgFlags.Privacy = false;
_msgFlags.Reportable = true;
}
_userSecurityModel.encode(buffer);
if (_userSecurityModel.EngineId.Length <= 0)
{
// restore saved USM values
_userSecurityModel.SecurityName.Set(savedUserName);
_msgFlags.Authentication = authentication;
_msgFlags.Privacy = privacy;
_msgFlags.Reportable = reportable;
}
// Check if privacy encryption is required
MutableByte encodedPdu = new MutableByte();
if (_msgFlags.Privacy && _userSecurityModel.EngineId.Length > 0)
{
IPrivacyProtocol privacyProtocol = PrivacyProtocol.GetInstance(_userSecurityModel.Privacy);
if (privacyProtocol == null)
throw new SnmpException(SnmpException.UnsupportedPrivacyProtocol, "Specified privacy protocol is not supported.");
// Get BER encoded ScopedPdu
MutableByte unencryptedPdu = new MutableByte();
_scopedPdu.encode(unencryptedPdu);
byte[] privacyParameters = null;
// we have to expand the key
IAuthenticationDigest auth = Authentication.GetInstance(_userSecurityModel.Authentication);
if (auth == null)
throw new SnmpException(SnmpException.UnsupportedNoAuthPriv, "Invalid authentication protocol. noAuthPriv mode not supported.");
byte[] encryptedBuffer = privacyProtocol.Encrypt(unencryptedPdu, 0, unencryptedPdu.Length, privKey, _userSecurityModel.EngineBoots, _userSecurityModel.EngineTime, out privacyParameters, auth);
_userSecurityModel.PrivacyParameters.Set(privacyParameters);
OctetString encryptedOctetString = new OctetString(encryptedBuffer);
encryptedOctetString.encode(encodedPdu);
// now redo packet encoding
buffer.Reset();
buffer.Set(packetHeader);
_userSecurityModel.encode(buffer);
int preEncodedLength = encodedPdu.Length;
buffer.Append(encodedPdu);
if (_maxMessageSize.Value != 0)
{
// verify compliance with maximum message size
if ((encodedPdu.Length - preEncodedLength) > _maxMessageSize)
{
throw new SnmpException(SnmpException.MaximumMessageSizeExceeded, "ScopedPdu exceeds maximum message size.");
}
}
}
else
{
_scopedPdu.encode(encodedPdu);
buffer.Append(encodedPdu);
}
base.encode(buffer);
if (_msgFlags.Authentication && _userSecurityModel.EngineId.Length > 0)
{
_userSecurityModel.Authenticate(authKey, ref buffer);
// Now re-encode the packet with the authentication information
_userSecurityModel.encode(packetHeader);
packetHeader.Append(encodedPdu);
base.encode(packetHeader);
buffer = packetHeader;
}
return buffer;
}
/// <summary>
/// Encode SNMP packet for sending.
/// </summary>
/// <returns>BER encoded SNMP packet.</returns>
/// <exception cref="SnmpInvalidPduTypeException">Thrown when PDU being encoded is not a valid SNMP version 1 PDU. Acceptable
/// protocol version 1 operations are GET, GET-NEXT, SET and RESPONSE.</exception>
public override byte[] encode()
{
if (this.Pdu.Type != PduType.Get && this.Pdu.Type != PduType.GetNext &&
this.Pdu.Type != PduType.Set && this.Pdu.Type != PduType.Response)
throw new SnmpInvalidVersionException("Invalid SNMP PDU type while attempting to encode PDU: " + string.Format("0x{0:x2}", this.Pdu.Type));
if (this.Pdu.RequestId == 0)
{
System.Random rand = new System.Random((System.Int32)DateTime.Now.Ticks);
this.Pdu.RequestId = rand.Next();
}
MutableByte tmpBuffer = new MutableByte();
// snmp version
_protocolVersion.encode(tmpBuffer);
// community string
_snmpCommunity.encode(tmpBuffer);
// pdu
this.Pdu.encode(tmpBuffer);
MutableByte buf = new MutableByte();
// wrap the packet into a sequence
AsnType.BuildHeader(buf, SnmpConstants.SMI_SEQUENCE, tmpBuffer.Length);
buf.Append(tmpBuffer);
return buf;
}
/// <summary>BER encode the variable binding
/// </summary>
/// <param name="buffer"><see cref="MutableByte"/> class to the end of which encoded variable
/// binding values will be added.
/// </param>
public override void encode(MutableByte buffer)
{
// encode oid to the temporary buffer
MutableByte oidbuf = new MutableByte();
_oid.encode(oidbuf);
// encode value to a temporary buffer
MutableByte valbuf = new MutableByte();
_value.encode(valbuf);
// calculate data content length of the vb
int vblen = oidbuf.Length + valbuf.Length;
// encode vb header at the end of the result
BuildHeader(buffer, Type, vblen);
// add values to the encoded arrays to the end of the result
buffer.Append(oidbuf);
buffer.Append(valbuf);
}
/// <summary>
/// Used to encode the integer value into an ASN.1 buffer.
/// The passed encoder defines the method for encoding the
/// data.
/// </summary>
/// <param name="buffer">Buffer target to write the encoded data</param>
public override void Encode(MutableByte buffer)
{
int val = value;
byte[] b = BitConverter.GetBytes(value);
MutableByte tmp = new MutableByte();
// if value is negative
if (val < 0)
{
for (int i = 3; i >= 0; i--)
{
if (tmp.Length > 0 || b[i] != 0xff)
{
tmp.Append(b[i]);
}
}
if (tmp.Length == 0)
{
// if the value is -1 then all bytes in an integer are 0xff and will be skipped above
tmp.Append(0xff);
}
// make sure value is negative
if ((tmp[0] & 0x80) == 0)
{
tmp.Prepend(0xff);
}
}
else if (val == 0)
{
// this is just a shortcut to save processing time
tmp.Append(0);
}
else
{
// byte[] b = BitConverter.GetBytes(val);
for (int i = 3; i >= 0; i--)
{
if (b[i] != 0 || tmp.Length > 0)
{
tmp.Append(b[i]);
}
}
// if buffer length is 0 then value is 0 and we have to add it to the buffer
if (tmp.Length == 0)
{
tmp.Append(0);
}
else
{
if ((tmp[0] & 0x80) != 0)
{
// first bit of the first byte has to be 0 otherwise value is negative.
tmp.Prepend(0);
}
}
}
// check for 9 1s at the beginning of the encoded value
if (tmp.Length > 1 && tmp[0] == 0xff && (tmp[1] & 0x80) != 0)
{
tmp.Prepend(0);
}
BuildHeader(buffer, Type, tmp.Length);
buffer.Append(tmp);
}
