SMPP Class

Properties Methods Events Config Settings Errors

The SMPP Class implements a lightweight message transmission interface using the Short Message Peer-to-Peer protocol, most known for its use in cellular text messaging.

Syntax

SMPP

Remarks

The SMPP class supports both plaintext and Secure Sockets Layer/Transport Layer Security (SSL/TLS) connections. When connecting over Secure Sockets Layer/Transport Layer Security (SSL/TLS) the SSLServerAuthentication event allows you to check the server identity and other security attributes. The SSLStatus event provides information about the SSL handshake. Additional SSL-related settings are also supported through the Config method.

The Smpp Class will bind as a transceiver, and thus it can send and receive messages from the server. Additionally, it can send single and multirecipient messages and also can upload data.

Using Smpp is quite easy. First, simply set the SMPPServer, SMPPPort, and, if needed, the SMPPVersion properties. Second, a single call to the Connect method with a specified user Id and password will connect the class.

Transmitting messages is just as easy. You can manipulate the Recipients properties directly, or just use AddRecipient method to add recipients one at a time to the recipient list. After all recipients have been added, a single call to the SendMessage method will transmit the specified message. If the send is successful, the method will set and return the value of the MessageId property. Otherwise, an Error event will fire for each unsuccessful message destination.

The Smpp Class supports message and data transmission, as well as auxiliary operations, such as CheckMessageStatus and ReplaceMessage. All nonimplemented features of the protocol are supported through the SendCommand method and PITrail event. Because of the nature of the protocol, all methods and operations are implemented synchronously.

Property List

The following is the full list of the properties of the class with short descriptions. Click on the links for further details.


Connected	This property indicates whether the class is connected.
Firewall	A set of properties related to firewall access.
Idle	The current status of the class.
LocalHost	The name of the local host or user-assigned IP interface through which connections are initiated or accepted.
MessageExpiration	This property denotes the validity period of the current message.
MessageId	This property indicates the identifier of the most recently sent message.
MessagePriority	This property indicates the priority level of the current message.
Password	This property contains the user's password.
Protocol	This property defines the SMPP protocol to be used.
Recipients	This property includes the list of message recipients.
ScheduledDelivery	This property tells the server when to deliver the current message.
SenderAddress	This property contains the address of the External Short Messaging Entity (ESME).
ServiceType	This property indicates the type of service for the current message.
SMPPPort	This property contains the server port for secure SMPP (default 2775).
SMPPServer	This property is the SMPP entity to which the class will connect.
SMPPVersion	This property indicates the SMPP version to be used throughout the connection.
SSLAcceptServerCert	Instructs the class to unconditionally accept the server certificate that matches the supplied certificate.
SSLCert	The certificate to be used during Secure Sockets Layer (SSL) negotiation.
SSLEnabled	This property indicates whether Transport Layer Security/Secure Sockets Layer (TLS/SSL) is enabled.
SSLProvider	The Secure Sockets Layer/Transport Layer Security (SSL/TLS) implementation to use.
SSLServerCert	The server certificate for the last established connection.
SSLStartMode	This property determines how the class starts the Secure Sockets Layer (SSL) negotiation.
SystemType	This property contains a string representing the type of system during a connection.
Timeout	The timeout for the class.
UserId	This property is used for identification with the SMPP service.

Method List

The following is the full list of the methods of the class with short descriptions. Click on the links for further details.


AddRecipient	This method will add a recipient of the specified type to the recipient list.
CancelMessage	This method will cancel the specified message.
CheckLink	This method will check the connection to the server.
CheckMessageStatus	This method will retrieve the status of the specified message.
Config	Sets or retrieves a configuration setting.
Connect	This method will bind as a transceiver to the SMPP service.
ConnectTo	This method will bind as a transceiver to the SMPP service.
Disconnect	This method will disconnect from the SMPP service.
DoEvents	This method processes events from the internal message queue.
Interrupt	This method interrupts the current method.
ReplaceMessage	This method replaces a previously sent message with a new one.
Reset	This method will reset the class.
SendCommand	This method will format and send a protocol data unit (PDU) using the specified command identifier and payload.
SendData	This method sends raw data to Recipients .
SendMessage	This method sends a message to all recipients in the recipient list.

Event List

The following is the full list of the events fired by the class with short descriptions. Click on the links for further details.


Connected	This event is fired after a successful bind operation.
ConnectionStatus	Fired to indicate changes in the connection state.
Disconnected	This event is fired when connection to the SMS service is lost.
Error	This event is fired when the server detects an error.
MessageIn	This event is fired upon receipt of a message.
MessageStatus	This event is fired upon receipt of a message.
PITrail	This event is fired once for each protocol data unit (PDU) sent between the client and server.
ReadyToSend	This event is fired when the class is ready to send data.
SSLServerAuthentication	Fired after the server presents its certificate to the client.
SSLStatus	Fired when secure connection progress messages are available.

Config Settings

The following is a list of config settings for the class with short descriptions. Click on the links for further details.


AddressRange	Specifies the addr_range parameter when binding.
BinaryDataCoding	Whether or not to binary encode the message when DataCoding is set.
BindAsReceiver	Causes the class to bind as a receiver.
BindAsTransmitter	Causes the class to bind as a transmitter.
CustomTLV	Optional TLV parameters added after the mandatory parameters and before the payload.
DataCoding	The data encoding mechanism to be used for the current message.
DecodeHexStrings	Will decode an ascii hex-representation of binary data prior to transmission.
DestinationNPI	The Number Planning Indicator for the destination ESME.
DestinationTON	The Type of Number for the destination ESME.
DoSplitLargeMessages	Splits long messages and returns the UDH and Message Parts.
HexString	A hex-encoded binary string to be sent to the current recipient.
IncomingDestinationAddress	Returns the dest_addr field inside the received message.
IntermediateNotification	Causes the class to request intermediate notification.
MaxCIMDSMSLength	Indicates the maximum SMS message length for the CIMD protocol.
MaxSMSLength	Indicates the maximum SMS message length.
MCReceipt	The Type of MC Delivery Receipt requested.
MessageInReceiptedMessageId	The receipted_message_id field of an incoming deliver_sm PDU.
MessageMode	The Type of Messaging Mode requested.
MessageType	The Type of Message.
PDUFormat	The format of the PDU.
ProtocolId	The protocol identifier.
ReplaceIfPresent	Indicates whether the replace_if_present_flag is enabled when sending a message.
SMEAcknowledgement	The Type of SME originated acknowledgment requested.
SourceNPI	The Number Planning Indicator for the ESME.
SourceTON	The Type of Number for the ESME.
SplitLargeMessages	Determines whether large messages are split into multiple parts.
SplitMessageMethod	Determines how large messages are split into multiple parts.
StatusReportRequest	Defines in what cases a status report is created by the server.
SubAddr	Defines a unique index for application instance.
SynchronousSendCommand	Controls whether SendCommand behaves synchronously or asynchronously.
SynchronousSendMessage	Controls whether SendMessage behaves synchronously or asynchronously.
UseGSM7BitEncoding	Whether or not to use GSM 7-bit encoding.
UseGSM7bitEncodingCompression	Whether to compress GSM 7-bit encoded characters.
WaitForBanner	Specifies the CIMD2 banner the class will wait for when connecting.
ConnectionTimeout	Sets a separate timeout value for establishing a connection.
FirewallAutoDetect	Tells the class whether or not to automatically detect and use firewall system settings, if available.
FirewallHost	Name or IP address of firewall (optional).
FirewallPassword	Password to be used if authentication is to be used when connecting through the firewall.
FirewallPort	The TCP port for the FirewallHost;.
FirewallType	Determines the type of firewall to connect through.
FirewallUser	A user name if authentication is to be used connecting through a firewall.
KeepAliveInterval	The retry interval, in milliseconds, to be used when a TCP keep-alive packet is sent and no response is received.
KeepAliveRetryCount	The number of keep-alive packets to be sent before the remotehost is considered disconnected.
KeepAliveTime	The inactivity time in milliseconds before a TCP keep-alive packet is sent.
Linger	When set to True, connections are terminated gracefully.
LingerTime	Time in seconds to have the connection linger.
LocalHost	The name of the local host through which connections are initiated or accepted.
LocalPort	The port in the local host where the class binds.
MaxLineLength	The maximum amount of data to accumulate when no EOL is found.
MaxTransferRate	The transfer rate limit in bytes per second.
ProxyExceptionsList	A semicolon separated list of hosts and IPs to bypass when using a proxy.
TCPKeepAlive	Determines whether or not the keep alive socket option is enabled.
TcpNoDelay	Whether or not to delay when sending packets.
UseIPv6	Whether to use IPv6.
LogSSLPackets	Controls whether SSL packets are logged when using the internal security API.
OpenSSLCADir	The path to a directory containing CA certificates.
OpenSSLCAFile	Name of the file containing the list of CA's trusted by your application.
OpenSSLCipherList	A string that controls the ciphers to be used by SSL.
OpenSSLPrngSeedData	The data to seed the pseudo random number generator (PRNG).
ReuseSSLSession	Determines if the SSL session is reused.
SSLCACertFilePaths	The paths to CA certificate files on Unix/Linux.
SSLCACerts	A newline separated list of CA certificates to be included when performing an SSL handshake.
SSLCipherStrength	The minimum cipher strength used for bulk encryption.
SSLClientCACerts	A newline separated list of CA certificates to use during SSL client certificate validation.
SSLEnabledCipherSuites	The cipher suite to be used in an SSL negotiation.
SSLEnabledProtocols	Used to enable/disable the supported security protocols.
SSLEnableRenegotiation	Whether the renegotiation_info SSL extension is supported.
SSLIncludeCertChain	Whether the entire certificate chain is included in the SSLServerAuthentication event.
SSLKeyLogFile	The location of a file where per-session secrets are written for debugging purposes.
SSLNegotiatedCipher	Returns the negotiated cipher suite.
SSLNegotiatedCipherStrength	Returns the negotiated cipher suite strength.
SSLNegotiatedCipherSuite	Returns the negotiated cipher suite.
SSLNegotiatedKeyExchange	Returns the negotiated key exchange algorithm.
SSLNegotiatedKeyExchangeStrength	Returns the negotiated key exchange algorithm strength.
SSLNegotiatedVersion	Returns the negotiated protocol version.
SSLSecurityFlags	Flags that control certificate verification.
SSLServerCACerts	A newline separated list of CA certificates to use during SSL server certificate validation.
TLS12SignatureAlgorithms	Defines the allowed TLS 1.2 signature algorithms when SSLProvider is set to Internal.
TLS12SupportedGroups	The supported groups for ECC.
TLS13KeyShareGroups	The groups for which to pregenerate key shares.
TLS13SignatureAlgorithms	The allowed certificate signature algorithms.
TLS13SupportedGroups	The supported groups for (EC)DHE key exchange.
AbsoluteTimeout	Determines whether timeouts are inactivity timeouts or absolute timeouts.
FirewallData	Used to send extra data to the firewall.
InBufferSize	The size in bytes of the incoming queue of the socket.
OutBufferSize	The size in bytes of the outgoing queue of the socket.
BuildInfo	Information about the product's build.
CodePage	The system code page used for Unicode to Multibyte translations.
LicenseInfo	Information about the current license.
MaskSensitiveData	Whether sensitive data is masked in log messages.
ProcessIdleEvents	Whether the class uses its internal event loop to process events when the main thread is idle.
SelectWaitMillis	The length of time in milliseconds the class will wait when DoEvents is called if there are no events to process.
UseInternalSecurityAPI	Whether or not to use the system security libraries or an internal implementation.

Connected Property (SMPP Class)

This property indicates whether the class is connected.

Syntax

ANSI (Cross Platform)
int GetConnected();

Unicode (Windows)
BOOL GetConnected();

int ipworks_smpp_getconnected(void* lpObj);

bool GetConnected();

Default Value

FALSE

Remarks

This property indicates whether the class is connected to the remote host. Use the Connect and Disconnect methods to manage the connection.

This property is read-only and not available at design time.

Data Type

Boolean

Firewall Property (SMPP Class)

A set of properties related to firewall access.

Syntax

IPWorksFirewall* GetFirewall();
int SetFirewall(IPWorksFirewall* val);

int ipworks_smpp_getfirewallautodetect(void* lpObj);
int ipworks_smpp_setfirewallautodetect(void* lpObj, int bFirewallAutoDetect);

int ipworks_smpp_getfirewalltype(void* lpObj);
int ipworks_smpp_setfirewalltype(void* lpObj, int iFirewallType);

char* ipworks_smpp_getfirewallhost(void* lpObj);
int ipworks_smpp_setfirewallhost(void* lpObj, const char* lpszFirewallHost);

char* ipworks_smpp_getfirewallpassword(void* lpObj);
int ipworks_smpp_setfirewallpassword(void* lpObj, const char* lpszFirewallPassword);

int ipworks_smpp_getfirewallport(void* lpObj);
int ipworks_smpp_setfirewallport(void* lpObj, int iFirewallPort);

char* ipworks_smpp_getfirewalluser(void* lpObj);
int ipworks_smpp_setfirewalluser(void* lpObj, const char* lpszFirewallUser);

bool GetFirewallAutoDetect();
int SetFirewallAutoDetect(bool bFirewallAutoDetect);

int GetFirewallType();
int SetFirewallType(int iFirewallType);

QString GetFirewallHost();
int SetFirewallHost(QString qsFirewallHost);

QString GetFirewallPassword();
int SetFirewallPassword(QString qsFirewallPassword);

int GetFirewallPort();
int SetFirewallPort(int iFirewallPort);

QString GetFirewallUser();
int SetFirewallUser(QString qsFirewallUser);

Remarks

This is a Firewall-type property, which contains fields describing the firewall through which the class will attempt to connect.

Data Type

IPWorksFirewall

Idle Property (SMPP Class)

The current status of the class.

Syntax

ANSI (Cross Platform)
int GetIdle();

Unicode (Windows)
BOOL GetIdle();

int ipworks_smpp_getidle(void* lpObj);

bool GetIdle();

Default Value

TRUE

Remarks

This property will be False if the component is currently busy (communicating or waiting for an answer), and True at all other times.

This property is read-only.

Data Type

Boolean

LocalHost Property (SMPP Class)

The name of the local host or user-assigned IP interface through which connections are initiated or accepted.

Syntax

ANSI (Cross Platform)
char* GetLocalHost();
int SetLocalHost(const char* lpszLocalHost);

Unicode (Windows)
LPWSTR GetLocalHost();
INT SetLocalHost(LPCWSTR lpszLocalHost);

char* ipworks_smpp_getlocalhost(void* lpObj);
int ipworks_smpp_setlocalhost(void* lpObj, const char* lpszLocalHost);

QString GetLocalHost();
int SetLocalHost(QString qsLocalHost);

Default Value

Remarks

This property contains the name of the local host as obtained by the gethostname() system call, or if the user has assigned an IP address, the value of that address.

In multihomed hosts (machines with more than one IP interface) setting LocalHost to the IP address of an interface will make the class initiate connections (or accept in the case of server classs) only through that interface. It is recommended to provide an IP address rather than a hostname when setting this property to ensure the desired interface is used.

If the class is connected, the LocalHost property shows the IP address of the interface through which the connection is made in internet dotted format (aaa.bbb.ccc.ddd). In most cases, this is the address of the local host, except for multihomed hosts (machines with more than one IP interface).

Note: LocalHost is not persistent. You must always set it in code, and never in the property window.

Data Type

String

MessageExpiration Property (SMPP Class)

This property denotes the validity period of the current message.

Syntax

ANSI (Cross Platform)
char* GetMessageExpiration();
int SetMessageExpiration(const char* lpszMessageExpiration);

Unicode (Windows)
LPWSTR GetMessageExpiration();
INT SetMessageExpiration(LPCWSTR lpszMessageExpiration);

char* ipworks_smpp_getmessageexpiration(void* lpObj);
int ipworks_smpp_setmessageexpiration(void* lpObj, const char* lpszMessageExpiration);

QString GetMessageExpiration();
int SetMessageExpiration(QString qsMessageExpiration);

Default Value

Remarks

This property indicates the Message Center expiration time, after which the message should be discarded if not delivered to the destination. It can be set using absolute or relative time formats.

Absolute Time Format is a 16-character string represented as "YYMMDDhhmmsstnnp" where:


YY	the last two digits of the year (00-99)
MM	month (01-12)
DD	day (01-31)
hh	hour (00-23)
mm	minute (00-59)
ss	second (00-59)
t	tenths of a second (0-9)
nn	quarter-hour time difference between local time and UTC time (00-48)
p	"+" or "-" indicating the direction of the time offset in `nn`

Relative Time Format is the same 16-character string where "p" should be set to "R" for "relative". For relative time, "tnn" are ignored and thus should be set to a constant value of "000".

Data Type

String

MessageId Property (SMPP Class)

This property indicates the identifier of the most recently sent message.

Syntax

ANSI (Cross Platform)
char* GetMessageId();

Unicode (Windows)
LPWSTR GetMessageId();

char* ipworks_smpp_getmessageid(void* lpObj);

QString GetMessageId();

Default Value

Remarks

This property indicates the identifier of the most recently sent message. After a successful call to SendMessage, this property will be set to the server-assigned Id for that message.

This property is read-only and not available at design time.

Data Type

String

MessagePriority Property (SMPP Class)

This property indicates the priority level of the current message.

Syntax

ANSI (Cross Platform)
int GetMessagePriority();
int SetMessagePriority(int iMessagePriority);

Unicode (Windows)
INT GetMessagePriority();
INT SetMessagePriority(INT iMessagePriority);

Possible Values

SMPP_MESSAGE_PRIORITY_LOW(0), 
SMPP_MESSAGE_PRIORITY_NORMAL(1), 
SMPP_MESSAGE_PRIORITY_HIGH(2), 
SMPP_MESSAGE_PRIORITY_URGENT(3)

int ipworks_smpp_getmessagepriority(void* lpObj);
int ipworks_smpp_setmessagepriority(void* lpObj, int iMessagePriority);

int GetMessagePriority();
int SetMessagePriority(int iMessagePriority);

Default Value

Remarks

When sending a message, this property will tell the server what type of priority to assign to the message. The effect of the message priority setting depends on the Message Center (MC) manufacturer and the network on which the target recipient lies. For example, some MCs may immediately forward "urgent" messages, some networks may use the priority setting as a visual indicator of the message's urgency (e.g., blinking icons), and some networks may entirely ignore the priority setting.

Data Type

Integer

Password Property (SMPP Class)

This property contains the user's password.

Syntax

ANSI (Cross Platform)
char* GetPassword();
int SetPassword(const char* lpszPassword);

Unicode (Windows)
LPWSTR GetPassword();
INT SetPassword(LPCWSTR lpszPassword);

char* ipworks_smpp_getpassword(void* lpObj);
int ipworks_smpp_setpassword(void* lpObj, const char* lpszPassword);

QString GetPassword();
int SetPassword(QString qsPassword);

Default Value

Remarks

This property contains the user's password. When binding to the SMPPServer, the client must provide a known user identifier and a valid password for that Id.

The two ways to bind are (1) by calling Connect with a user identifier and password, which will set the UserId and this property before connecting; or (2) by setting those two properties and calling SendMessage while not connected.

Data Type

String

Protocol Property (SMPP Class)

This property defines the SMPP protocol to be used.

Syntax

ANSI (Cross Platform)
int GetProtocol();
int SetProtocol(int iProtocol);

Unicode (Windows)
INT GetProtocol();
INT SetProtocol(INT iProtocol);

Possible Values

SMPP_SMPP(0), 
SMPP_CIMD2(1)

int ipworks_smpp_getprotocol(void* lpObj);
int ipworks_smpp_setprotocol(void* lpObj, int iProtocol);

int GetProtocol();
int SetProtocol(int iProtocol);

Default Value

Remarks

This property defines the protocol to be used when connecting to the server. Possible values are as follows:


0 (smppSMPP - default)	SMPP for traditional SMPP servers
1 (smppCIMD2)	CIMD2 for Nokia Short Message Service Center servers

Data Type

Integer

Recipients Property (SMPP Class)

This property includes the list of message recipients.

Syntax

IPWorksList<IPWorksSMPPRecipient>* GetRecipients();
int SetRecipients(IPWorksList<IPWorksSMPPRecipient>* val);

int ipworks_smpp_getrecipientcount(void* lpObj);
int ipworks_smpp_setrecipientcount(void* lpObj, int iRecipientCount);

char* ipworks_smpp_getrecipientaddress(void* lpObj, int recipientindex);
int ipworks_smpp_setrecipientaddress(void* lpObj, int recipientindex, const char* lpszRecipientAddress);

int ipworks_smpp_getrecipienttype(void* lpObj, int recipientindex);
int ipworks_smpp_setrecipienttype(void* lpObj, int recipientindex, int iRecipientType);

int GetRecipientCount();
int SetRecipientCount(int iRecipientCount);

QString GetRecipientAddress(int iRecipientIndex);
int SetRecipientAddress(int iRecipientIndex, QString qsRecipientAddress);

int GetRecipientType(int iRecipientIndex);
int SetRecipientType(int iRecipientIndex, int iRecipientType);

Remarks

This property is used to specify the recipient(s) of the message. Each recipient is represented by an SMPPRecipient type, which contains fields for the address and type of address for the recipient.

An AddRecipient method also may be used to add recipients to this collection property.

Data Type

IPWorksSMPPRecipient

ScheduledDelivery Property (SMPP Class)

This property tells the server when to deliver the current message.

Syntax

ANSI (Cross Platform)
char* GetScheduledDelivery();
int SetScheduledDelivery(const char* lpszScheduledDelivery);

Unicode (Windows)
LPWSTR GetScheduledDelivery();
INT SetScheduledDelivery(LPCWSTR lpszScheduledDelivery);

char* ipworks_smpp_getscheduleddelivery(void* lpObj);
int ipworks_smpp_setscheduleddelivery(void* lpObj, const char* lpszScheduledDelivery);

QString GetScheduledDelivery();
int SetScheduledDelivery(QString qsScheduledDelivery);

Default Value

Remarks

This property is used by the class when sending a message to inform the Message Center to forward the message to the intended recipients at a specific time. It can be set using absolute or relative time formats.

Absolute Time Format is a 16-character string represented as "YYMMDDhhmmsstnnp" where:


YY	the last two digits of the year (00-99)
MM	month (01-12)
DD	day (01-31)
hh	hour (00-23)
mm	minute (00-59)
ss	second (00-59)
t	tenths of a second (0-9)
nn	quarter-hour time difference between local time and UTC time (00-48)
p	"+" or "-" indicating the direction of the time offset in `nn`

Relative Time Format is the same 16-character string where "p" should be set to "R" for "relative". For relative time, "tnn" are ignored and thus should be set to a constant value of "000".

Data Type

String

SenderAddress Property (SMPP Class)

This property contains the address of the External Short Messaging Entity (ESME).

Syntax

ANSI (Cross Platform)
char* GetSenderAddress();
int SetSenderAddress(const char* lpszSenderAddress);

Unicode (Windows)
LPWSTR GetSenderAddress();
INT SetSenderAddress(LPCWSTR lpszSenderAddress);

char* ipworks_smpp_getsenderaddress(void* lpObj);
int ipworks_smpp_setsenderaddress(void* lpObj, const char* lpszSenderAddress);

QString GetSenderAddress();
int SetSenderAddress(QString qsSenderAddress);

Default Value

Remarks

This property contains the address of the External Short Messaging Entity (ESME). The SMPP protocol allows an ESME to specify its address, whether it is a phone number or an IP address. If this property is not set, the class will default to the value in LocalHost.

Data Type

String

ServiceType Property (SMPP Class)

This property indicates the type of service for the current message.

Syntax

ANSI (Cross Platform)
int GetServiceType();
int SetServiceType(int iServiceType);

Unicode (Windows)
INT GetServiceType();
INT SetServiceType(INT iServiceType);

Possible Values

SMPP_SERVICE_DEFAULT(0), 
SMPP_SERVICE_CMT(1), 
SMPP_SERVICE_CPT(2), 
SMPP_SERVICE_VMN(3), 
SMPP_SERVICE_VMA(4), 
SMPP_SERVICE_WAP(5), 
SMPP_SERVICE_USSD(6), 
SMPP_SERVICE_CBS(7)

int ipworks_smpp_getservicetype(void* lpObj);
int ipworks_smpp_setservicetype(void* lpObj, int iServiceType);

int GetServiceType();
int SetServiceType(int iServiceType);

Default Value

Remarks

When sending messages, this property is used to define the SMS application service to be associated with the message. The Message Center (MC) will use the value to determine the availability of enhanced messaging services and to control the teleservice used on the air interface.

The values are defined in the SMPP 5.0 specification as follows:


"" (NULL)	MC Default
CMT	Cellular Messaging
CPT	Cellular Paging
VMN	Voice Mail Notification
VMA	Voice Mail Alerting
WAP	Wireless Application Protocol
USSD	Unstructured Supplementary Services Data
CBS	Cell Broadcast Service

Data Type

Integer

SMPPPort Property (SMPP Class)

This property contains the server port for secure SMPP (default 2775).

Syntax

ANSI (Cross Platform)
int GetSMPPPort();
int SetSMPPPort(int iSMPPPort);

Unicode (Windows)
INT GetSMPPPort();
INT SetSMPPPort(INT iSMPPPort);

int ipworks_smpp_getsmppport(void* lpObj);
int ipworks_smpp_setsmppport(void* lpObj, int iSMPPPort);

int GetSMPPPort();
int SetSMPPPort(int iSMPPPort);

Default Value

2775

Remarks

For an implicit Secure Sockets Layer (SSL), use port 3551 (please refer to the SSLStartMode property for more information).

A valid port number (a value between 1 and 65535) is required for the connection to take place. The property must be set before a connection is attempted and cannot be changed once a connection is established. Any attempt to change this property while connected will fail with an error.

Data Type

Integer

SMPPServer Property (SMPP Class)

This property is the SMPP entity to which the class will connect.

Syntax

ANSI (Cross Platform)
char* GetSMPPServer();
int SetSMPPServer(const char* lpszSMPPServer);

Unicode (Windows)
LPWSTR GetSMPPServer();
INT SetSMPPServer(LPCWSTR lpszSMPPServer);

char* ipworks_smpp_getsmppserver(void* lpObj);
int ipworks_smpp_setsmppserver(void* lpObj, const char* lpszSMPPServer);

QString GetSMPPServer();
int SetSMPPServer(QString qsSMPPServer);

Default Value

Remarks

This property is the instant messaging server to which the class will connect when the Connect method is called. This property must contain a valid SMPP service application address.

Data Type

String

SMPPVersion Property (SMPP Class)

This property indicates the SMPP version to be used throughout the connection.

Syntax

ANSI (Cross Platform)
int GetSMPPVersion();
int SetSMPPVersion(int iSMPPVersion);

Unicode (Windows)
INT GetSMPPVersion();
INT SetSMPPVersion(INT iSMPPVersion);

Possible Values

SMPP_VERSION_50(0), 
SMPP_VERSION_34(1), 
SMPP_VERSION_33(2)

int ipworks_smpp_getsmppversion(void* lpObj);
int ipworks_smpp_setsmppversion(void* lpObj, int iSMPPVersion);

int GetSMPPVersion();
int SetSMPPVersion(int iSMPPVersion);

Default Value

Remarks

This property contains the SMPP version to be used throughout the connection.

The default value is version 3.4 because it is the most widely used version of the protocol.

Choosing the highest mutually supported version is generally recommended. Version 3.4 is the default value; however, if version 5.0 is supported, it is recommended.

Data Type

Integer

SSLAcceptServerCert Property (SMPP Class)

Instructs the class to unconditionally accept the server certificate that matches the supplied certificate.

Syntax

IPWorksCertificate* GetSSLAcceptServerCert();
int SetSSLAcceptServerCert(IPWorksCertificate* val);

char* ipworks_smpp_getsslacceptservercerteffectivedate(void* lpObj);

char* ipworks_smpp_getsslacceptservercertexpirationdate(void* lpObj);

char* ipworks_smpp_getsslacceptservercertextendedkeyusage(void* lpObj);

char* ipworks_smpp_getsslacceptservercertfingerprint(void* lpObj);

char* ipworks_smpp_getsslacceptservercertfingerprintsha1(void* lpObj);

char* ipworks_smpp_getsslacceptservercertfingerprintsha256(void* lpObj);

char* ipworks_smpp_getsslacceptservercertissuer(void* lpObj);

char* ipworks_smpp_getsslacceptservercertprivatekey(void* lpObj);

int ipworks_smpp_getsslacceptservercertprivatekeyavailable(void* lpObj);

char* ipworks_smpp_getsslacceptservercertprivatekeycontainer(void* lpObj);

char* ipworks_smpp_getsslacceptservercertpublickey(void* lpObj);

char* ipworks_smpp_getsslacceptservercertpublickeyalgorithm(void* lpObj);

int ipworks_smpp_getsslacceptservercertpublickeylength(void* lpObj);

char* ipworks_smpp_getsslacceptservercertserialnumber(void* lpObj);

char* ipworks_smpp_getsslacceptservercertsignaturealgorithm(void* lpObj);

int ipworks_smpp_getsslacceptservercertstore(void* lpObj, char** lpSSLAcceptServerCertStore, int* lenSSLAcceptServerCertStore);
int ipworks_smpp_setsslacceptservercertstore(void* lpObj, const char* lpSSLAcceptServerCertStore, int lenSSLAcceptServerCertStore);

char* ipworks_smpp_getsslacceptservercertstorepassword(void* lpObj);
int ipworks_smpp_setsslacceptservercertstorepassword(void* lpObj, const char* lpszSSLAcceptServerCertStorePassword);

int ipworks_smpp_getsslacceptservercertstoretype(void* lpObj);
int ipworks_smpp_setsslacceptservercertstoretype(void* lpObj, int iSSLAcceptServerCertStoreType);

char* ipworks_smpp_getsslacceptservercertsubjectaltnames(void* lpObj);

char* ipworks_smpp_getsslacceptservercertthumbprintmd5(void* lpObj);

char* ipworks_smpp_getsslacceptservercertthumbprintsha1(void* lpObj);

char* ipworks_smpp_getsslacceptservercertthumbprintsha256(void* lpObj);

char* ipworks_smpp_getsslacceptservercertusage(void* lpObj);

int ipworks_smpp_getsslacceptservercertusageflags(void* lpObj);

char* ipworks_smpp_getsslacceptservercertversion(void* lpObj);

char* ipworks_smpp_getsslacceptservercertsubject(void* lpObj);
int ipworks_smpp_setsslacceptservercertsubject(void* lpObj, const char* lpszSSLAcceptServerCertSubject);

int ipworks_smpp_getsslacceptservercertencoded(void* lpObj, char** lpSSLAcceptServerCertEncoded, int* lenSSLAcceptServerCertEncoded);
int ipworks_smpp_setsslacceptservercertencoded(void* lpObj, const char* lpSSLAcceptServerCertEncoded, int lenSSLAcceptServerCertEncoded);

QString GetSSLAcceptServerCertEffectiveDate();

QString GetSSLAcceptServerCertExpirationDate();

QString GetSSLAcceptServerCertExtendedKeyUsage();

QString GetSSLAcceptServerCertFingerprint();

QString GetSSLAcceptServerCertFingerprintSHA1();

QString GetSSLAcceptServerCertFingerprintSHA256();

QString GetSSLAcceptServerCertIssuer();

QString GetSSLAcceptServerCertPrivateKey();

bool GetSSLAcceptServerCertPrivateKeyAvailable();

QString GetSSLAcceptServerCertPrivateKeyContainer();

QString GetSSLAcceptServerCertPublicKey();

QString GetSSLAcceptServerCertPublicKeyAlgorithm();

int GetSSLAcceptServerCertPublicKeyLength();

QString GetSSLAcceptServerCertSerialNumber();

QString GetSSLAcceptServerCertSignatureAlgorithm();

QByteArray GetSSLAcceptServerCertStore();
int SetSSLAcceptServerCertStore(QByteArray qbaSSLAcceptServerCertStore);

QString GetSSLAcceptServerCertStorePassword();
int SetSSLAcceptServerCertStorePassword(QString qsSSLAcceptServerCertStorePassword);

int GetSSLAcceptServerCertStoreType();
int SetSSLAcceptServerCertStoreType(int iSSLAcceptServerCertStoreType);

QString GetSSLAcceptServerCertSubjectAltNames();

QString GetSSLAcceptServerCertThumbprintMD5();

QString GetSSLAcceptServerCertThumbprintSHA1();

QString GetSSLAcceptServerCertThumbprintSHA256();

QString GetSSLAcceptServerCertUsage();

int GetSSLAcceptServerCertUsageFlags();

QString GetSSLAcceptServerCertVersion();

QString GetSSLAcceptServerCertSubject();
int SetSSLAcceptServerCertSubject(QString qsSSLAcceptServerCertSubject);

QByteArray GetSSLAcceptServerCertEncoded();
int SetSSLAcceptServerCertEncoded(QByteArray qbaSSLAcceptServerCertEncoded);

Remarks

If it finds any issues with the certificate presented by the server, the class will normally terminate the connection with an error.

You may override this behavior by supplying a value for SSLAcceptServerCert. If the certificate supplied in SSLAcceptServerCert is the same as the certificate presented by the server, then the server certificate is accepted unconditionally, and the connection will continue normally.

Note: This functionality is provided only for cases in which you otherwise know that you are communicating with the right server. If used improperly, this property may create a security breach. Use it at your own risk.

Data Type

IPWorksCertificate

SSLCert Property (SMPP Class)

The certificate to be used during Secure Sockets Layer (SSL) negotiation.

Syntax

IPWorksCertificate* GetSSLCert();
int SetSSLCert(IPWorksCertificate* val);

char* ipworks_smpp_getsslcerteffectivedate(void* lpObj);

char* ipworks_smpp_getsslcertexpirationdate(void* lpObj);

char* ipworks_smpp_getsslcertextendedkeyusage(void* lpObj);

char* ipworks_smpp_getsslcertfingerprint(void* lpObj);

char* ipworks_smpp_getsslcertfingerprintsha1(void* lpObj);

char* ipworks_smpp_getsslcertfingerprintsha256(void* lpObj);

char* ipworks_smpp_getsslcertissuer(void* lpObj);

char* ipworks_smpp_getsslcertprivatekey(void* lpObj);

int ipworks_smpp_getsslcertprivatekeyavailable(void* lpObj);

char* ipworks_smpp_getsslcertprivatekeycontainer(void* lpObj);

char* ipworks_smpp_getsslcertpublickey(void* lpObj);

char* ipworks_smpp_getsslcertpublickeyalgorithm(void* lpObj);

int ipworks_smpp_getsslcertpublickeylength(void* lpObj);

char* ipworks_smpp_getsslcertserialnumber(void* lpObj);

char* ipworks_smpp_getsslcertsignaturealgorithm(void* lpObj);

int ipworks_smpp_getsslcertstore(void* lpObj, char** lpSSLCertStore, int* lenSSLCertStore);
int ipworks_smpp_setsslcertstore(void* lpObj, const char* lpSSLCertStore, int lenSSLCertStore);

char* ipworks_smpp_getsslcertstorepassword(void* lpObj);
int ipworks_smpp_setsslcertstorepassword(void* lpObj, const char* lpszSSLCertStorePassword);

int ipworks_smpp_getsslcertstoretype(void* lpObj);
int ipworks_smpp_setsslcertstoretype(void* lpObj, int iSSLCertStoreType);

char* ipworks_smpp_getsslcertsubjectaltnames(void* lpObj);

char* ipworks_smpp_getsslcertthumbprintmd5(void* lpObj);

char* ipworks_smpp_getsslcertthumbprintsha1(void* lpObj);

char* ipworks_smpp_getsslcertthumbprintsha256(void* lpObj);

char* ipworks_smpp_getsslcertusage(void* lpObj);

int ipworks_smpp_getsslcertusageflags(void* lpObj);

char* ipworks_smpp_getsslcertversion(void* lpObj);

char* ipworks_smpp_getsslcertsubject(void* lpObj);
int ipworks_smpp_setsslcertsubject(void* lpObj, const char* lpszSSLCertSubject);

int ipworks_smpp_getsslcertencoded(void* lpObj, char** lpSSLCertEncoded, int* lenSSLCertEncoded);
int ipworks_smpp_setsslcertencoded(void* lpObj, const char* lpSSLCertEncoded, int lenSSLCertEncoded);

QString GetSSLCertEffectiveDate();

QString GetSSLCertExpirationDate();

QString GetSSLCertExtendedKeyUsage();

QString GetSSLCertFingerprint();

QString GetSSLCertFingerprintSHA1();

QString GetSSLCertFingerprintSHA256();

QString GetSSLCertIssuer();

QString GetSSLCertPrivateKey();

bool GetSSLCertPrivateKeyAvailable();

QString GetSSLCertPrivateKeyContainer();

QString GetSSLCertPublicKey();

QString GetSSLCertPublicKeyAlgorithm();

int GetSSLCertPublicKeyLength();

QString GetSSLCertSerialNumber();

QString GetSSLCertSignatureAlgorithm();

QByteArray GetSSLCertStore();
int SetSSLCertStore(QByteArray qbaSSLCertStore);

QString GetSSLCertStorePassword();
int SetSSLCertStorePassword(QString qsSSLCertStorePassword);

int GetSSLCertStoreType();
int SetSSLCertStoreType(int iSSLCertStoreType);

QString GetSSLCertSubjectAltNames();

QString GetSSLCertThumbprintMD5();

QString GetSSLCertThumbprintSHA1();

QString GetSSLCertThumbprintSHA256();

QString GetSSLCertUsage();

int GetSSLCertUsageFlags();

QString GetSSLCertVersion();

QString GetSSLCertSubject();
int SetSSLCertSubject(QString qsSSLCertSubject);

QByteArray GetSSLCertEncoded();
int SetSSLCertEncoded(QByteArray qbaSSLCertEncoded);

Remarks

This property includes the digital certificate that the class will use during SSL negotiation. Set this property to a valid certificate before starting SSL negotiation. To set a certificate, you may set the Encoded field to the encoded certificate. To select a certificate, use the store and subject fields.

Data Type

IPWorksCertificate

SSLEnabled Property (SMPP Class)

This property indicates whether Transport Layer Security/Secure Sockets Layer (TLS/SSL) is enabled.

Syntax

ANSI (Cross Platform)
int GetSSLEnabled();
int SetSSLEnabled(int bSSLEnabled);

Unicode (Windows)
BOOL GetSSLEnabled();
INT SetSSLEnabled(BOOL bSSLEnabled);

int ipworks_smpp_getsslenabled(void* lpObj);
int ipworks_smpp_setsslenabled(void* lpObj, int bSSLEnabled);

bool GetSSLEnabled();
int SetSSLEnabled(bool bSSLEnabled);

Default Value

FALSE

Remarks

This property specifies whether TLS/SSL is enabled in the class. When False (default), the class operates in plaintext mode. When True, TLS/SSL is enabled.

TLS/SSL may also be enabled by setting SSLStartMode. Setting SSLStartMode will automatically update this property value.

This property is not available at design time.

Data Type

Boolean

SSLProvider Property (SMPP Class)

The Secure Sockets Layer/Transport Layer Security (SSL/TLS) implementation to use.

Syntax

ANSI (Cross Platform)
int GetSSLProvider();
int SetSSLProvider(int iSSLProvider);

Unicode (Windows)
INT GetSSLProvider();
INT SetSSLProvider(INT iSSLProvider);

Possible Values

SSLP_AUTOMATIC(0), 
SSLP_PLATFORM(1), 
SSLP_INTERNAL(2)

int ipworks_smpp_getsslprovider(void* lpObj);
int ipworks_smpp_setsslprovider(void* lpObj, int iSSLProvider);

int GetSSLProvider();
int SetSSLProvider(int iSSLProvider);

Default Value

Remarks

This property specifies the SSL/TLS implementation to use. In most cases the default value of 0 (Automatic) is recommended and should not be changed. When set to 0 (Automatic), the class will select whether to use the platform implementation or the internal implementation depending on the operating system as well as the TLS version being used.

Possible values are as follows:


0 (sslpAutomatic - default)	Automatically selects the appropriate implementation.
1 (sslpPlatform)	Uses the platform/system implementation.
2 (sslpInternal)	Uses the internal implementation.

Additional Notes

In most cases using the default value (Automatic) is recommended. The class will select a provider depending on the current platform.

When Automatic is selected, on Windows, the class will use the platform implementation. On Linux/macOS, the class will use the internal implementation. When TLS 1.3 is enabled via SSLEnabledProtocols, the internal implementation is used on all platforms.

Data Type

Integer

SSLServerCert Property (SMPP Class)

The server certificate for the last established connection.

Syntax

IPWorksCertificate* GetSSLServerCert();

char* ipworks_smpp_getsslservercerteffectivedate(void* lpObj);

char* ipworks_smpp_getsslservercertexpirationdate(void* lpObj);

char* ipworks_smpp_getsslservercertextendedkeyusage(void* lpObj);

char* ipworks_smpp_getsslservercertfingerprint(void* lpObj);

char* ipworks_smpp_getsslservercertfingerprintsha1(void* lpObj);

char* ipworks_smpp_getsslservercertfingerprintsha256(void* lpObj);

char* ipworks_smpp_getsslservercertissuer(void* lpObj);

char* ipworks_smpp_getsslservercertprivatekey(void* lpObj);

int ipworks_smpp_getsslservercertprivatekeyavailable(void* lpObj);

char* ipworks_smpp_getsslservercertprivatekeycontainer(void* lpObj);

char* ipworks_smpp_getsslservercertpublickey(void* lpObj);

char* ipworks_smpp_getsslservercertpublickeyalgorithm(void* lpObj);

int ipworks_smpp_getsslservercertpublickeylength(void* lpObj);

char* ipworks_smpp_getsslservercertserialnumber(void* lpObj);

char* ipworks_smpp_getsslservercertsignaturealgorithm(void* lpObj);

int ipworks_smpp_getsslservercertstore(void* lpObj, char** lpSSLServerCertStore, int* lenSSLServerCertStore);

char* ipworks_smpp_getsslservercertstorepassword(void* lpObj);

int ipworks_smpp_getsslservercertstoretype(void* lpObj);

char* ipworks_smpp_getsslservercertsubjectaltnames(void* lpObj);

char* ipworks_smpp_getsslservercertthumbprintmd5(void* lpObj);

char* ipworks_smpp_getsslservercertthumbprintsha1(void* lpObj);

char* ipworks_smpp_getsslservercertthumbprintsha256(void* lpObj);

char* ipworks_smpp_getsslservercertusage(void* lpObj);

int ipworks_smpp_getsslservercertusageflags(void* lpObj);

char* ipworks_smpp_getsslservercertversion(void* lpObj);

char* ipworks_smpp_getsslservercertsubject(void* lpObj);

int ipworks_smpp_getsslservercertencoded(void* lpObj, char** lpSSLServerCertEncoded, int* lenSSLServerCertEncoded);

QString GetSSLServerCertEffectiveDate();

QString GetSSLServerCertExpirationDate();

QString GetSSLServerCertExtendedKeyUsage();

QString GetSSLServerCertFingerprint();

QString GetSSLServerCertFingerprintSHA1();

QString GetSSLServerCertFingerprintSHA256();

QString GetSSLServerCertIssuer();

QString GetSSLServerCertPrivateKey();

bool GetSSLServerCertPrivateKeyAvailable();

QString GetSSLServerCertPrivateKeyContainer();

QString GetSSLServerCertPublicKey();

QString GetSSLServerCertPublicKeyAlgorithm();

int GetSSLServerCertPublicKeyLength();

QString GetSSLServerCertSerialNumber();

QString GetSSLServerCertSignatureAlgorithm();

QByteArray GetSSLServerCertStore();

QString GetSSLServerCertStorePassword();

int GetSSLServerCertStoreType();

QString GetSSLServerCertSubjectAltNames();

QString GetSSLServerCertThumbprintMD5();

QString GetSSLServerCertThumbprintSHA1();

QString GetSSLServerCertThumbprintSHA256();

QString GetSSLServerCertUsage();

int GetSSLServerCertUsageFlags();

QString GetSSLServerCertVersion();

QString GetSSLServerCertSubject();

QByteArray GetSSLServerCertEncoded();

Remarks

This property contains the server certificate for the last established connection.

SSLServerCert is reset every time a new connection is attempted.

This property is read-only.

Data Type

IPWorksCertificate

SSLStartMode Property (SMPP Class)

This property determines how the class starts the Secure Sockets Layer (SSL) negotiation.

Syntax

ANSI (Cross Platform)
int GetSSLStartMode();
int SetSSLStartMode(int iSSLStartMode);

Unicode (Windows)
INT GetSSLStartMode();
INT SetSSLStartMode(INT iSSLStartMode);

Possible Values

SSL_AUTOMATIC(0), 
SSL_IMPLICIT(1), 
SSL_EXPLICIT(2), 
SSL_NONE(3)

int ipworks_smpp_getsslstartmode(void* lpObj);
int ipworks_smpp_setsslstartmode(void* lpObj, int iSSLStartMode);

int GetSSLStartMode();
int SetSSLStartMode(int iSSLStartMode);

Default Value

Remarks

The SSLStartMode property may have one of the following values:


0 (sslAutomatic)	If the remote port is set to the standard plaintext port of the protocol (where applicable), the class will behave the same as if SSLStartMode is set to sslExplicit. In all other cases, SSL negotiation will be implicit (sslImplicit).
1 (sslImplicit)	The SSL negotiation will start immediately after the connection is established.
2 (sslExplicit)	The class will first connect in plaintext, and then will explicitly start SSL negotiation through a protocol command such as STARTTLS.
3 (sslNone - default)	No SSL negotiation; no SSL security. All communication will be in plaintext mode.

Data Type

Integer

SystemType Property (SMPP Class)

This property contains a string representing the type of system during a connection.

Syntax

ANSI (Cross Platform)
char* GetSystemType();
int SetSystemType(const char* lpszSystemType);

Unicode (Windows)
LPWSTR GetSystemType();
INT SetSystemType(LPCWSTR lpszSystemType);

char* ipworks_smpp_getsystemtype(void* lpObj);
int ipworks_smpp_setsystemtype(void* lpObj, const char* lpszSystemType);

QString GetSystemType();
int SetSystemType(QString qsSystemType);

Default Value

Remarks

This property contains a string representing the type of system during a connection. Some SMS servers require that a system type be supplied during connection. The system type is a string representation, usually as an abbreviation, of a particular kind of system. The string cannot exceed 12 bytes.

Data Type

String

Timeout Property (SMPP Class)

The timeout for the class.

Syntax

ANSI (Cross Platform)
int GetTimeout();
int SetTimeout(int iTimeout);

Unicode (Windows)
INT GetTimeout();
INT SetTimeout(INT iTimeout);

int ipworks_smpp_gettimeout(void* lpObj);
int ipworks_smpp_settimeout(void* lpObj, int iTimeout);

int GetTimeout();
int SetTimeout(int iTimeout);

Default Value

Remarks

If the Timeout property is set to 0, all operations will run uninterrupted until successful completion or an error condition is encountered.

If Timeout is set to a positive value, the class will wait for the operation to complete before returning control.

The class will use DoEvents to enter an efficient wait loop during any potential waiting period, making sure that all system events are processed immediately as they arrive. This ensures that the host application does not freeze and remains responsive.

If Timeout expires, and the operation is not yet complete, the class fails with an error.

Note: By default, all timeouts are inactivity timeouts, that is, the timeout period is extended by Timeout seconds when any amount of data is successfully sent or received.

The default value for the Timeout property is 60 seconds.

Data Type

Integer

UserId Property (SMPP Class)

This property is used for identification with the SMPP service.

Syntax

ANSI (Cross Platform)
char* GetUserId();
int SetUserId(const char* lpszUserId);

Unicode (Windows)
LPWSTR GetUserId();
INT SetUserId(LPCWSTR lpszUserId);

char* ipworks_smpp_getuserid(void* lpObj);
int ipworks_smpp_setuserid(void* lpObj, const char* lpszUserId);

QString GetUserId();
int SetUserId(QString qsUserId);

Default Value

Remarks

This property is used for identification with the SMPP service. When binding to the SMPPServer, the client must provide a known user identifier and a valid password for that Id.

The two ways to bind are (1) by calling Connect with a user Id and password, which will set the UserId and Password properties before connecting; or (2) by setting those two properties and calling SendMessage while not connected.

Data Type

String

AddRecipient Method (SMPP Class)

This method will add a recipient of the specified type to the recipient list.

Syntax

ANSI (Cross Platform)
int AddRecipient(int iRecipientType, const char* lpszRecipientAddress);

Unicode (Windows)
INT AddRecipient(INT iRecipientType, LPCWSTR lpszRecipientAddress);

int ipworks_smpp_addrecipient(void* lpObj, int iRecipientType, const char* lpszRecipientAddress);

int AddRecipient(int iRecipientType, const QString& qsRecipientAddress);

Remarks

This method will add a recipient of the specified type to the recipient list. For normal-type recipients, the addresses should be either a dotted IPv4 address (for sending messages to other SMS-enabled applications) or the directory number of a mobile phone. To send messages to distributed lists, the name of the list should be used.

Valid values for RecipientType are as follows:


0 (smppRecipientTypeNormal)	Normal SME (Short Message Entity) Address
1 (smppRecipientTypeList)	Distribution List

Error Handling (C++)

This method returns a result code; 0 indicates success, while a non-zero error code indicates that this method encountered an error during its execution. If an error occurs, the GetLastError() method can be called to retrieve the associated error message. (Note: This method's result code can also be obtained by calling the GetLastErrorCode() method after it returns.)

CancelMessage Method (SMPP Class)

This method will cancel the specified message.

Syntax

ANSI (Cross Platform)
int CancelMessage(const char* lpszMessageId);

Unicode (Windows)
INT CancelMessage(LPCWSTR lpszMessageId);

int ipworks_smpp_cancelmessage(void* lpObj, const char* lpszMessageId);

int CancelMessage(const QString& qsMessageId);

Remarks

This method will cancel the message stored on the SMPPServer under the value in MessageId.

Error Handling (C++)

CheckLink Method (SMPP Class)

This method will check the connection to the server.

Syntax

ANSI (Cross Platform)
int CheckLink();

Unicode (Windows)
INT CheckLink();

int ipworks_smpp_checklink(void* lpObj);

int CheckLink();

Remarks

This method will check the connection to the server. This method is used to ensure that the host on the other end of the connection is still active, or that it is still available. Although a socket connection may still be available between the client and server, the SMS application on the server may have been taken offline without releasing the socket or the CPU may be bogged down. This method will send a PDU to the server and wait the length of Timeout for a response.

Error Handling (C++)

CheckMessageStatus Method (SMPP Class)

This method will retrieve the status of the specified message.

Syntax

ANSI (Cross Platform)
int CheckMessageStatus(const char* lpszMessageId);

Unicode (Windows)
INT CheckMessageStatus(LPCWSTR lpszMessageId);

int ipworks_smpp_checkmessagestatus(void* lpObj, const char* lpszMessageId);

int CheckMessageStatus(const QString& qsMessageId);

Remarks

This method will retrieve the last known status of the message stored on the server under MessageId. The class will fire a MessageStatus containing the parsed response from the server.

Error Handling (C++)

Config Method (SMPP Class)

Sets or retrieves a configuration setting.

Syntax

ANSI (Cross Platform)
char* Config(const char* lpszConfigurationString);

Unicode (Windows)
LPWSTR Config(LPCWSTR lpszConfigurationString);

char* ipworks_smpp_config(void* lpObj, const char* lpszConfigurationString);

QString Config(const QString& qsConfigurationString);

Remarks

Config is a generic method available in every class. It is used to set and retrieve configuration settings for the class.

These settings are similar in functionality to properties, but they are rarely used. In order to avoid "polluting" the property namespace of the class, access to these internal properties is provided through the Config method.

To set a configuration setting named PROPERTY, you must call Config("PROPERTY=VALUE"), where VALUE is the value of the setting expressed as a string. For boolean values, use the strings "True", "False", "0", "1", "Yes", or "No" (case does not matter).

To read (query) the value of a configuration setting, you must call Config("PROPERTY"). The value will be returned as a string.

Error Handling (C++)

This method returns a String value; after it returns, call the GetLastErrorCode() method to obtain its result code; 0 indicates success, while a non-zero error code indicates that this method encountered an error during its execution. If an error occurs, the GetLastError() method can be called to retrieve the associated error message.

Connect Method (SMPP Class)

This method will bind as a transceiver to the SMPP service.

Syntax

ANSI (Cross Platform)
int Connect();

Unicode (Windows)
INT Connect();

int ipworks_smpp_connect(void* lpObj);

int Connect();

Remarks

This method will establish a socket connection to the SMPPServer and attempt to bind as a transceiver. Once the bind operation has been completed, a Connected event will be fired containing the status of the connection.

Error Handling (C++)

ConnectTo Method (SMPP Class)

This method will bind as a transceiver to the SMPP service.

Syntax

ANSI (Cross Platform)
int ConnectTo(const char* lpszUserId, const char* lpszPassword);

Unicode (Windows)
INT ConnectTo(LPCWSTR lpszUserId, LPCWSTR lpszPassword);

int ipworks_smpp_connectto(void* lpObj, const char* lpszUserId, const char* lpszPassword);

int ConnectTo(const QString& qsUserId, const QString& qsPassword);

Remarks

This method will establish a socket connection to the SMPPServer and attempt to bind as a transceiver. Once the bind operation has completed, a Connected event will be fired containing the status of the connection.

Error Handling (C++)

Disconnect Method (SMPP Class)

This method will disconnect from the SMPP service.

Syntax

ANSI (Cross Platform)
int Disconnect();

Unicode (Windows)
INT Disconnect();

int ipworks_smpp_disconnect(void* lpObj);

int Disconnect();

Remarks

This method will send an unbind command and close the socket connection to the SMPPServer. After an unbind operation and socket closing, a Disconnected event will be fired containing the status of the unbind operation.

Error Handling (C++)

DoEvents Method (SMPP Class)

This method processes events from the internal message queue.

Syntax

ANSI (Cross Platform)
int DoEvents();

Unicode (Windows)
INT DoEvents();

int ipworks_smpp_doevents(void* lpObj);

int DoEvents();

Remarks

When this method is called, the class processes any available events. If no events are available, it waits for a preset period of time, and then returns.

Error Handling (C++)

Interrupt Method (SMPP Class)

This method interrupts the current method.

Syntax

ANSI (Cross Platform)
int Interrupt();

Unicode (Windows)
INT Interrupt();

int ipworks_smpp_interrupt(void* lpObj);

int Interrupt();

Remarks

If there is no method in progress, Interrupt simply returns, doing nothing.

Error Handling (C++)

ReplaceMessage Method (SMPP Class)

This method replaces a previously sent message with a new one.

Syntax

ANSI (Cross Platform)
int ReplaceMessage(const char* lpszMessageId, const char* lpszNewMessage);

Unicode (Windows)
INT ReplaceMessage(LPCWSTR lpszMessageId, LPCWSTR lpszNewMessage);

int ipworks_smpp_replacemessage(void* lpObj, const char* lpszMessageId, const char* lpszNewMessage);

int ReplaceMessage(const QString& qsMessageId, const QString& qsNewMessage);

Remarks

Assuming that a message on the SMPPServer is being stored under the value in MessageId, this method will replace that message with the value in NewMessage.

If no message corresponds to MessageId, the SMS service will respond with an error message.

Error Handling (C++)

Reset Method (SMPP Class)

This method will reset the class.

Syntax

ANSI (Cross Platform)
int Reset();

Unicode (Windows)
INT Reset();

int ipworks_smpp_reset(void* lpObj);

int Reset();

Remarks

This method will reset the class's properties to their default values.

Error Handling (C++)

SendCommand Method (SMPP Class)

This method will format and send a protocol data unit (PDU) using the specified command identifier and payload.

Syntax

ANSI (Cross Platform)
char* SendCommand(int iCommandId, const char* lpPayload, int lenPayload, int *lpSize = NULL);

Unicode (Windows)
LPSTR SendCommand(INT iCommandId, LPCSTR lpPayload, INT lenPayload, LPINT lpSize = NULL);

char* ipworks_smpp_sendcommand(void* lpObj, int iCommandId, const char* lpPayload, int lenPayload, int *lpSize);

QByteArray SendCommand(int iCommandId, QByteArray qbaPayload);

Remarks

This method offers a way to do more with the class than is directly supported. This method takes a command identifier and a payload, which includes every required and optional field after the header, and creates the 16-byte header for it before sending it to the server. The response PDU is returned both in the PITrail and by this method.

Error Handling (C++)

This method returns a Binary String value (with length lpSize); after it returns, call the GetLastErrorCode() method to obtain its result code; 0 indicates success, while a non-zero error code indicates that this method encountered an error during its execution. If an error occurs, the GetLastError() method can be called to retrieve the associated error message.

SendData Method (SMPP Class)

This method sends raw data to Recipients .

Syntax

ANSI (Cross Platform)
char* SendData(const char* lpData, int lenData);

Unicode (Windows)
LPWSTR SendData(LPCSTR lpData, INT lenData);

char* ipworks_smpp_senddata(void* lpObj, const char* lpData, int lenData);

QString SendData(QByteArray qbaData);

Remarks

This method sends raw data to Recipients. Up to 64 KB of additional data can be supplied at a time for transmission to the SMPPServer. Unlike the SendMessage method, this method can send to only one destination at a time. The target is whatever value is in the Recipients properties.

Error Handling (C++)

SendMessage Method (SMPP Class)

This method sends a message to all recipients in the recipient list.

Syntax

ANSI (Cross Platform)
char* SendMessage(const char* lpszMessage);

Unicode (Windows)
LPWSTR SendMessage(LPCWSTR lpszMessage);

char* ipworks_smpp_sendmessage(void* lpObj, const char* lpszMessage);

QString SendMessage(const QString& qsMessage);

Remarks

This method sends a message to all recipients in the recipient list. The return value of this method is the server-assigned identifier of the message. The maximum size of the message sent is 256 bytes.

Error Handling (C++)

Connected Event (SMPP Class)

This event is fired after a successful bind operation.

Syntax

ANSI (Cross Platform)
virtual int FireConnected(SMPPConnectedEventParams *e);

typedef struct {
  int StatusCode;
  const char *Description;
  int reserved;
} SMPPConnectedEventParams;


Unicode (Windows)
virtual INT FireConnected(SMPPConnectedEventParams *e);

typedef struct {
  INT StatusCode;
  LPCWSTR Description;
  INT reserved;
} SMPPConnectedEventParams;

#define EID_SMPP_CONNECTED 1

virtual INT IPWORKS_CALL FireConnected(INT &iStatusCode, LPSTR &lpszDescription);

class SMPPConnectedEventParams {
public:
  int StatusCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void Connected(SMPPConnectedEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireConnected(SMPPConnectedEventParams *e) {...}

Remarks

After establishing a socket connection to the SMPPServer, the class will attempt to send a bind as a transmitter command. Upon completion of this operation, the server will respond with either a success or failure state, which will be reflected in the Connected event's parameters.

StatusCode will contain the command status (error code) returned by the server. For a StatusCode of 0, Description will be OK. Otherwise, it will contain a standard interpretation of the error.

ConnectionStatus Event (SMPP Class)

Fired to indicate changes in the connection state.

Syntax

ANSI (Cross Platform)
virtual int FireConnectionStatus(SMPPConnectionStatusEventParams *e);

typedef struct {
  const char *ConnectionEvent;
  int StatusCode;
  const char *Description;
  int reserved;
} SMPPConnectionStatusEventParams;


Unicode (Windows)
virtual INT FireConnectionStatus(SMPPConnectionStatusEventParams *e);

typedef struct {
  LPCWSTR ConnectionEvent;
  INT StatusCode;
  LPCWSTR Description;
  INT reserved;
} SMPPConnectionStatusEventParams;

#define EID_SMPP_CONNECTIONSTATUS 2

virtual INT IPWORKS_CALL FireConnectionStatus(LPSTR &lpszConnectionEvent, INT &iStatusCode, LPSTR &lpszDescription);

class SMPPConnectionStatusEventParams {
public:
  const QString &ConnectionEvent();

  int StatusCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void ConnectionStatus(SMPPConnectionStatusEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireConnectionStatus(SMPPConnectionStatusEventParams *e) {...}

Remarks

This event is fired when the connection state changes: for example, completion of a firewall or proxy connection or completion of a security handshake.

The ConnectionEvent parameter indicates the type of connection event. Values may include the following:


	Firewall connection complete.
	Secure Sockets Layer (SSL) or S/Shell handshake complete (where applicable).
	Remote host connection complete.
	Remote host disconnected.
	SSL or S/Shell connection broken.
	Firewall host disconnected.

StatusCode has the error code returned by the Transmission Control Protocol (TCP)/IP stack. Description contains a description of this code. The value of StatusCode is equal to the value of the error.

Disconnected Event (SMPP Class)

This event is fired when connection to the SMS service is lost.

Syntax

ANSI (Cross Platform)
virtual int FireDisconnected(SMPPDisconnectedEventParams *e);

typedef struct {
  int StatusCode;
  const char *Description;
  int reserved;
} SMPPDisconnectedEventParams;


Unicode (Windows)
virtual INT FireDisconnected(SMPPDisconnectedEventParams *e);

typedef struct {
  INT StatusCode;
  LPCWSTR Description;
  INT reserved;
} SMPPDisconnectedEventParams;

#define EID_SMPP_DISCONNECTED 3

virtual INT IPWORKS_CALL FireDisconnected(INT &iStatusCode, LPSTR &lpszDescription);

class SMPPDisconnectedEventParams {
public:
  int StatusCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void Disconnected(SMPPDisconnectedEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireDisconnected(SMPPDisconnectedEventParams *e) {...}

Remarks

After sending an unbind operation to the server, this event will be fired containing the results of that operation. This event may also be fired if the socket connection to the service is lost.

If the event was fired because of an unbind operation, StatusCode will contain the command status set by the server. Otherwise, it will contain the socket code for the type of disconnection. For a status code value of 0, Description will contain OK. Otherwise, it will contain a standard interpretation of the value in StatusCode.

Error Event (SMPP Class)

This event is fired when the server detects an error.

Syntax

ANSI (Cross Platform)
virtual int FireError(SMPPErrorEventParams *e);

typedef struct {
  int ErrorCode;
  const char *Description;
  int reserved;
} SMPPErrorEventParams;


Unicode (Windows)
virtual INT FireError(SMPPErrorEventParams *e);

typedef struct {
  INT ErrorCode;
  LPCWSTR Description;
  INT reserved;
} SMPPErrorEventParams;

#define EID_SMPP_ERROR 4

virtual INT IPWORKS_CALL FireError(INT &iErrorCode, LPSTR &lpszDescription);

class SMPPErrorEventParams {
public:
  int ErrorCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void Error(SMPPErrorEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireError(SMPPErrorEventParams *e) {...}

Remarks

If the server sends an error not related to a command sent from the class, the class will fire an Error event containing information related to the error.

ErrorCode will contain the code sent by the server, and Description will contain a standard interpretation of that code.

MessageIn Event (SMPP Class)

This event is fired upon receipt of a message.

Syntax

ANSI (Cross Platform)
virtual int FireMessageIn(SMPPMessageInEventParams *e);

typedef struct {
  const char *SourceAddress;
  const char *ScheduleDeliveryTime;
  const char *ValidityPeriod;
  const char *Message;
  int MessagePart;
  int MessagePartCount;
  int MessagePartReference;
  const char *DestinationAddress;
  int ResponseErrorCode;
  int reserved;
} SMPPMessageInEventParams;


Unicode (Windows)
virtual INT FireMessageIn(SMPPMessageInEventParams *e);

typedef struct {
  LPCWSTR SourceAddress;
  LPCWSTR ScheduleDeliveryTime;
  LPCWSTR ValidityPeriod;
  LPCWSTR Message;
  INT MessagePart;
  INT MessagePartCount;
  INT MessagePartReference;
  LPCWSTR DestinationAddress;
  INT ResponseErrorCode;
  INT reserved;
} SMPPMessageInEventParams;

#define EID_SMPP_MESSAGEIN 5

virtual INT IPWORKS_CALL FireMessageIn(LPSTR &lpszSourceAddress, LPSTR &lpszScheduleDeliveryTime, LPSTR &lpszValidityPeriod, LPSTR &lpszMessage, INT &iMessagePart, INT &iMessagePartCount, INT &iMessagePartReference, LPSTR &lpszDestinationAddress, INT &iResponseErrorCode);

class SMPPMessageInEventParams {
public:
  const QString &SourceAddress();

  const QString &ScheduleDeliveryTime();

  const QString &ValidityPeriod();

  const QString &Message();

  int MessagePart();

  int MessagePartCount();

  int MessagePartReference();

  const QString &DestinationAddress();

  int ResponseErrorCode();
  void SetResponseErrorCode(int iResponseErrorCode);

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void MessageIn(SMPPMessageInEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireMessageIn(SMPPMessageInEventParams *e) {...}

Remarks

When a message is received, the SMPP class will parse the sender's message into the SourceAddress, ScheduleDeliveryTime, ValidityPeriod, and Message fields.

The SourceAddress parameter is the address of the originator of the message.

The DestinationAddress parameter holds the address of the recipient.

The ScheduleDeliveryTime parameter is the delivery time at which the short message is scheduled to be forwarded to another Message Center (MC). This will be an empty string if it is not scheduled.

The ValidityPeriod parameter is applicable only if this short message is being forwarded to another MC. When this occurs, it specifies how long the receiving MC should retain the Short Message (SM) and continue trying to deliver it. This will be an empty string if the current validity period is unavailable.

The Message parameter is the plaintext portion of the message body.

If the incoming message is a part of a larger message (the message was split up into several parts), the MessagePartCount, MessagePart, and MessagePartReference parameters will be set. MessagePartCount will hold the total number of parts for the message. MessagePart will indicate the current part's location in the message to determine the order when reassembling the message. This will be a value from 1 to MessagePartCount. MessagePartReference holds a reference value that will be the same across all parts for the message.

The ResponseErrorCode parameter may be set to return an error condition to the server. This corresponds to the command_status protocol-level field of the response.

MessageStatus Event (SMPP Class)

This event is fired upon receipt of a message.

Syntax

ANSI (Cross Platform)
virtual int FireMessageStatus(SMPPMessageStatusEventParams *e);

typedef struct {
  const char *MessageId;
  int MessageState;
  int MessageError;
  const char *FinalDate;
  int reserved;
} SMPPMessageStatusEventParams;


Unicode (Windows)
virtual INT FireMessageStatus(SMPPMessageStatusEventParams *e);

typedef struct {
  LPCWSTR MessageId;
  INT MessageState;
  INT MessageError;
  LPCWSTR FinalDate;
  INT reserved;
} SMPPMessageStatusEventParams;

#define EID_SMPP_MESSAGESTATUS 6

virtual INT IPWORKS_CALL FireMessageStatus(LPSTR &lpszMessageId, INT &iMessageState, INT &iMessageError, LPSTR &lpszFinalDate);

class SMPPMessageStatusEventParams {
public:
  const QString &MessageId();

  int MessageState();

  int MessageError();

  const QString &FinalDate();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void MessageStatus(SMPPMessageStatusEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireMessageStatus(SMPPMessageStatusEventParams *e) {...}

Remarks

When a CheckMessageStatus is called, the SMPP class will retrieve the status of the message represented by MessageId from the server, parse the response, and fire MessageStatus.

MessageState represents the last known state the message was left in on the SMPPServer. This code is version specific. For v3.4:


1	ENROUTE, the message is en route.
2	DELIVERED, the message is delivered.
3	EXPIRED, the message validity period expired.
4	DELETED, the message has been deleted.
5	UNDELIVERABLE, the message is undeliverable.
6	ACCEPTED, the message has been read on behalf of subscriber by customer service.
7	UNKNOWN, the message is in an invalid state.
8	REJECTED, the message is in a rejected state.

For v5.0:


0	SCHEDULED, the message is scheduled for delivery, but it has not yet been delivered.
1	ENROUTE, the message is en route.
2	DELIVERED, the message is delivered.
3	EXPIRED, the message validity period expired.
4	DELETED, the message has been deleted.
5	UNDELIVERABLE, the message is undeliverable.
6	ACCEPTED, the message has been read on behalf of subscriber by customer service.
7	UNKNOWN, the message is in an invalid state.
8	REJECTED, the message is in a rejected state.
9	SKIPPED, the message was accepted but not delivered.

MessageError will contain an error code representing any failure encountered during message delivery. This code may be vendor-specific.

FinalDate contains a human-readable string representing the date on which the message was delivered. If the message was not delivered, this parameter will be empty.

PITrail Event (SMPP Class)

This event is fired once for each protocol data unit (PDU) sent between the client and server.

Syntax

ANSI (Cross Platform)
virtual int FirePITrail(SMPPPITrailEventParams *e);

typedef struct {
  int Direction;
  const char *PDU;
  int lenPDU;
  int CommandLength;
  int CommandId;
  const char *CommandDescription;
  const char *CommandStatus;
  int SequenceNumber;
  int reserved;
} SMPPPITrailEventParams;


Unicode (Windows)
virtual INT FirePITrail(SMPPPITrailEventParams *e);

typedef struct {
  INT Direction;
  LPCSTR PDU;
  INT lenPDU;
  INT CommandLength;
  INT CommandId;
  LPCWSTR CommandDescription;
  LPCWSTR CommandStatus;
  INT SequenceNumber;
  INT reserved;
} SMPPPITrailEventParams;

#define EID_SMPP_PITRAIL 7

virtual INT IPWORKS_CALL FirePITrail(INT &iDirection, LPSTR &lpPDU, INT &lenPDU, INT &iCommandLength, INT &iCommandId, LPSTR &lpszCommandDescription, LPSTR &lpszCommandStatus, INT &iSequenceNumber);

class SMPPPITrailEventParams {
public:
  int Direction();

  const QByteArray &PDU();

  int CommandLength();

  int CommandId();

  const QString &CommandDescription();

  const QString &CommandStatus();

  int SequenceNumber();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void PITrail(SMPPPITrailEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FirePITrail(SMPPPITrailEventParams *e) {...}

Remarks

Whenever either the class or the SMPPServer sends any data across the connection, the class will fire a PITrail event containing that data. It will usually be in SMPP-PDU format.

A PDU will contain at least the SMPP header, which is always 16 bytes long. The first four bytes represent the total length of the PDU, including the 16-byte header. The next four bytes are the command Id associated with the PDU. The command Id of a response PDU is always the command Id to which it is responding plus 0x80000000.

The class parses the values contained in the PDU header into the appropriate fields. The CommandLength, CommandId, CommandStatus, and SequenceNumber parameters contain these parsed values.

The third set of four bytes are the command status (status code) of the command. All originating commands will have a status code of 0x00000000, which will be ignored by the receiver. The field is only set in response PDUs to indicate the status of the originating command. The final four bytes represent the sequence number of the command. All response PDUs will contain the same sequence number as the originating command.

ReadyToSend Event (SMPP Class)

This event is fired when the class is ready to send data.

Syntax

ANSI (Cross Platform)
virtual int FireReadyToSend(SMPPReadyToSendEventParams *e);

typedef struct {
  int reserved;
} SMPPReadyToSendEventParams;


Unicode (Windows)
virtual INT FireReadyToSend(SMPPReadyToSendEventParams *e);

typedef struct {
  INT reserved;
} SMPPReadyToSendEventParams;

#define EID_SMPP_READYTOSEND 8

virtual INT IPWORKS_CALL FireReadyToSend();

class SMPPReadyToSendEventParams {
public:
  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void ReadyToSend(SMPPReadyToSendEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireReadyToSend(SMPPReadyToSendEventParams *e) {...}

Remarks

The ReadyToSend event indicates that the underlying Transmission Control Protocol (TCP)/IP subsystem is ready to accept data after a failed SendBytes. This event also is fired immediately after a connection to the remote host is established.

SSLServerAuthentication Event (SMPP Class)

Fired after the server presents its certificate to the client.

Syntax

ANSI (Cross Platform)
virtual int FireSSLServerAuthentication(SMPPSSLServerAuthenticationEventParams *e);

typedef struct {
  const char *CertEncoded;
  int lenCertEncoded;
  const char *CertSubject;
  const char *CertIssuer;
  const char *Status;
  int Accept;
  int reserved;
} SMPPSSLServerAuthenticationEventParams;


Unicode (Windows)
virtual INT FireSSLServerAuthentication(SMPPSSLServerAuthenticationEventParams *e);

typedef struct {
  LPCSTR CertEncoded;
  INT lenCertEncoded;
  LPCWSTR CertSubject;
  LPCWSTR CertIssuer;
  LPCWSTR Status;
  BOOL Accept;
  INT reserved;
} SMPPSSLServerAuthenticationEventParams;

#define EID_SMPP_SSLSERVERAUTHENTICATION 9

virtual INT IPWORKS_CALL FireSSLServerAuthentication(LPSTR &lpCertEncoded, INT &lenCertEncoded, LPSTR &lpszCertSubject, LPSTR &lpszCertIssuer, LPSTR &lpszStatus, BOOL &bAccept);

class SMPPSSLServerAuthenticationEventParams {
public:
  const QByteArray &CertEncoded();

  const QString &CertSubject();

  const QString &CertIssuer();

  const QString &Status();

  bool Accept();
  void SetAccept(bool bAccept);

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void SSLServerAuthentication(SMPPSSLServerAuthenticationEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireSSLServerAuthentication(SMPPSSLServerAuthenticationEventParams *e) {...}

Remarks

During this event, the client can decide whether or not to continue with the connection process. The Accept parameter is a recommendation on whether to continue or close the connection. This is just a suggestion: application software must use its own logic to determine whether or not to continue.

When Accept is False, Status shows why the verification failed (otherwise, Status contains the string OK). If it is decided to continue, you can override and accept the certificate by setting the Accept parameter to True.

SSLStatus Event (SMPP Class)

Fired when secure connection progress messages are available.

Syntax

ANSI (Cross Platform)
virtual int FireSSLStatus(SMPPSSLStatusEventParams *e);

typedef struct {
  const char *Message;
  int reserved;
} SMPPSSLStatusEventParams;


Unicode (Windows)
virtual INT FireSSLStatus(SMPPSSLStatusEventParams *e);

typedef struct {
  LPCWSTR Message;
  INT reserved;
} SMPPSSLStatusEventParams;

#define EID_SMPP_SSLSTATUS 10

virtual INT IPWORKS_CALL FireSSLStatus(LPSTR &lpszMessage);

class SMPPSSLStatusEventParams {
public:
  const QString &Message();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};

// To handle, connect one or more slots to this signal.
void SSLStatus(SMPPSSLStatusEventParams *e);

// Or, subclass SMPP and override this emitter function.
virtual int FireSSLStatus(SMPPSSLStatusEventParams *e) {...}

Remarks

The event is fired for informational and logging purposes only. This event tracks the progress of the connection.

Certificate Type

This is the digital certificate being used.

Syntax

IPWorksCertificate (declared in ipworks.h)

Remarks

This type describes the current digital certificate. The certificate may be a public or private key. The fields are used to identify or select certificates.

The following fields are available:

Fields

EffectiveDate
char* (read-only)
Default Value: ""

The date on which this certificate becomes valid. Before this date, it is not valid. The date is localized to the system's time zone. The following example illustrates the format of an encoded date:

23-Jan-2000 15:00:00.

ExpirationDate
char* (read-only)
Default Value: ""

The date on which the certificate expires. After this date, the certificate will no longer be valid. The date is localized to the system's time zone. The following example illustrates the format of an encoded date:

23-Jan-2001 15:00:00.

ExtendedKeyUsage
char* (read-only)
Default Value: ""

A comma-delimited list of extended key usage identifiers. These are the same as ASN.1 object identifiers (OIDs).

Fingerprint
char* (read-only)
Default Value: ""

The hex-encoded, 16-byte MD5 fingerprint of the certificate. This property is primarily used for keys which do not have a corresponding X.509 public certificate, such as PEM keys that only contain a private key. It is commonly used for SSH keys.

The following example illustrates the format: bc:2a:72:af:fe:58:17:43:7a:5f:ba:5a:7c:90:f7:02

FingerprintSHA1
char* (read-only)
Default Value: ""

The hex-encoded, 20-byte SHA-1 fingerprint of the certificate. This property is primarily used for keys which do not have a corresponding X.509 public certificate, such as PEM keys that only contain a private key. It is commonly used for SSH keys.

The following example illustrates the format: 30:7b:fa:38:65:83:ff:da:b4:4e:07:3f:17:b8:a4:ed:80:be:ff:84

FingerprintSHA256
char* (read-only)
Default Value: ""

The hex-encoded, 32-byte SHA-256 fingerprint of the certificate. This property is primarily used for keys which do not have a corresponding X.509 public certificate, such as PEM keys that only contain a private key. It is commonly used for SSH keys.

The following example illustrates the format: 6a:80:5c:33:a9:43:ea:b0:96:12:8a:64:96:30:ef:4a:8a:96:86:ce:f4:c7:be:10:24:8e:2b:60:9e:f3:59:53

Issuer
char* (read-only)
Default Value: ""

The issuer of the certificate. This field contains a string representation of the name of the issuing authority for the certificate.

PrivateKey
char* (read-only)
Default Value: ""

The private key of the certificate (if available). The key is provided as PEM/Base64-encoded data.

Note: The PrivateKey may be available but not exportable. In this case, PrivateKey returns an empty string.

PrivateKeyAvailable
int (read-only)
Default Value: FALSE

Whether a PrivateKey is available for the selected certificate. If PrivateKeyAvailable is True, the certificate may be used for authentication purposes (e.g., server authentication).

PrivateKeyContainer
char* (read-only)
Default Value: ""

The name of the PrivateKey container for the certificate (if available). This functionality is available only on Windows platforms.

PublicKey
char* (read-only)
Default Value: ""

The public key of the certificate. The key is provided as PEM/Base64-encoded data.

PublicKeyAlgorithm
char* (read-only)
Default Value: ""

The textual description of the certificate's public key algorithm. The property contains either the name of the algorithm (e.g., "RSA" or "RSA_DH") or an object identifier (OID) string representing the algorithm.

PublicKeyLength
int (read-only)
Default Value: 0

The length of the certificate's public key (in bits). Common values are 512, 1024, and 2048.

SerialNumber
char* (read-only)
Default Value: ""

The serial number of the certificate encoded as a string. The number is encoded as a series of hexadecimal digits, with each pair representing a byte of the serial number.

SignatureAlgorithm
char* (read-only)
Default Value: ""

The text description of the certificate's signature algorithm. The property contains either the name of the algorithm (e.g., "RSA" or "RSA_MD5RSA") or an object identifier (OID) string representing the algorithm.

Store
char*
Default Value: "MY"

The name of the certificate store for the client certificate.

The StoreType field denotes the type of the certificate store specified by Store. If the store is password-protected, specify the password in StorePassword.

Store is used in conjunction with the Subject field to specify client certificates. If Store has a value, and Subject or Encoded is set, a search for a certificate is initiated. Please see the Subject field for details.

Designations of certificate stores are platform dependent.

The following designations are the most common User and Machine certificate stores in Windows:


MY	A certificate store holding personal certificates with their associated private keys.
CA	Certifying authority certificates.
ROOT	Root certificates.

When the certificate store type is cstPFXFile, this property must be set to the name of the file. When the type is cstPFXBlob, the property must be set to the binary contents of a PFX file (i.e., PKCS#12 certificate store).

StorePassword
char*
Default Value: ""

If the type of certificate store requires a password, this field is used to specify the password needed to open the certificate store.

StoreType
int
Default Value: 0

The type of certificate store for this certificate.

The class supports both public and private keys in a variety of formats. When the cstAuto value is used, the class will automatically determine the type. This field can take one of the following values:


0 (cstUser - default)	For Windows, this specifies that the certificate store is a certificate store owned by the current user. Note: This store type is not available in Java.
1 (cstMachine)	For Windows, this specifies that the certificate store is a machine store. Note: This store type is not available in Java.
2 (cstPFXFile)	The certificate store is the name of a PFX (PKCS#12) file containing certificates.
3 (cstPFXBlob)	The certificate store is a string (binary or Base64-encoded) representing a certificate store in PFX (PKCS#12) format.
4 (cstJKSFile)	The certificate store is the name of a Java Key Store (JKS) file containing certificates. Note: This store type is only available in Java.
5 (cstJKSBlob)	The certificate store is a string (binary or Base64-encoded) representing a certificate store in Java Key Store (JKS) format. Note: This store type is only available in Java.
6 (cstPEMKeyFile)	The certificate store is the name of a PEM-encoded file that contains a private key and an optional certificate.
7 (cstPEMKeyBlob)	The certificate store is a string (binary or Base64-encoded) that contains a private key and an optional certificate.
8 (cstPublicKeyFile)	The certificate store is the name of a file that contains a PEM- or DER-encoded public key certificate.
9 (cstPublicKeyBlob)	The certificate store is a string (binary or Base64-encoded) that contains a PEM- or DER-encoded public key certificate.
10 (cstSSHPublicKeyBlob)	The certificate store is a string (binary or Base64-encoded) that contains an SSH-style public key.
11 (cstP7BFile)	The certificate store is the name of a PKCS#7 file containing certificates.
12 (cstP7BBlob)	The certificate store is a string (binary) representing a certificate store in PKCS#7 format.
13 (cstSSHPublicKeyFile)	The certificate store is the name of a file that contains an SSH-style public key.
14 (cstPPKFile)	The certificate store is the name of a file that contains a PPK (PuTTY Private Key).
15 (cstPPKBlob)	The certificate store is a string (binary) that contains a PPK (PuTTY Private Key).
16 (cstXMLFile)	The certificate store is the name of a file that contains a certificate in XML format.
17 (cstXMLBlob)	The certificate store is a string that contains a certificate in XML format.
18 (cstJWKFile)	The certificate store is the name of a file that contains a JWK (JSON Web Key).
19 (cstJWKBlob)	The certificate store is a string that contains a JWK (JSON Web Key).
21 (cstBCFKSFile)	The certificate store is the name of a file that contains a BCFKS (Bouncy Castle FIPS Key Store). Note: This store type is only available in Java and .NET.
22 (cstBCFKSBlob)	The certificate store is a string (binary or Base64-encoded) representing a certificate store in BCFKS (Bouncy Castle FIPS Key Store) format. Note: This store type is only available in Java and .NET.
23 (cstPKCS11)	The certificate is present on a physical security key accessible via a PKCS#11 interface. To use a security key, the necessary data must first be collected using the CertMgr class. The ListStoreCertificates method may be called after setting CertStoreType to `cstPKCS11`, CertStorePassword to the PIN, and CertStore to the full path of the PKCS#11 DLL. The certificate information returned in the CertList event's `CertEncoded` parameter may be saved for later use. When using a certificate, pass the previously saved security key information as the Store and set StorePassword to the PIN. Code Example. SSH Authentication with Security Key: `certmgr.CertStoreType = CertStoreTypes.cstPKCS11; certmgr.OnCertList += (s, e) => { secKeyBlob = e.CertEncoded; }; certmgr.CertStore = @"C:\Program Files\OpenSC Project\OpenSC\pkcs11\opensc-pkcs11.dll"; certmgr.CertStorePassword = "123456"; //PIN certmgr.ListStoreCertificates(); sftp.SSHCert = new Certificate(CertStoreTypes.cstPKCS11, secKeyBlob, "123456", "*"); sftp.SSHUser = "test"; sftp.SSHLogon("myhost", 22);`
99 (cstAuto)	The store type is automatically detected from the input data. This setting may be used with both public and private keys and can detect any of the supported formats automatically.

SubjectAltNames
char* (read-only)
Default Value: ""

Comma-separated lists of alternative subject names for the certificate.

ThumbprintMD5
char* (read-only)
Default Value: ""

The MD5 hash of the certificate. It is primarily used for X.509 certificates. If the hash does not already exist, it is automatically computed.

ThumbprintSHA1
char* (read-only)
Default Value: ""

The SHA-1 hash of the certificate. It is primarily used for X.509 certificates. If the hash does not already exist, it is automatically computed.

ThumbprintSHA256
char* (read-only)
Default Value: ""

The SHA-256 hash of the certificate. It is primarily used for X.509 certificates. If the hash does not already exist, it is automatically computed.

Usage
char* (read-only)
Default Value: ""

The text description of UsageFlags.

This value will be one or more of the following strings and will be separated by commas:

Digital Signature
Non-Repudiation
Key Encipherment
Data Encipherment
Key Agreement
Certificate Signing
CRL Signing
Encipher Only

If the provider is OpenSSL, the value is a comma-separated list of X.509 certificate extension names.

UsageFlags
int (read-only)
Default Value: 0

The flags that show intended use for the certificate. The value of UsageFlags is a combination of the following flags:


0x80	Digital Signature
0x40	Non-Repudiation
0x20	Key Encipherment
0x10	Data Encipherment
0x08	Key Agreement
0x04	Certificate Signing
0x02	CRL Signing
0x01	Encipher Only

Please see the Usage field for a text representation of UsageFlags.

This functionality currently is not available when the provider is OpenSSL.

Version
char* (read-only)
Default Value: ""

The certificate's version number. The possible values are the strings "V1", "V2", and "V3".

Subject
char*
Default Value: ""

The subject of the certificate used for client authentication.

This property must be set after all other certificate properties are set. When this property is set, a search is performed in the current certificate store to locate a certificate with a matching subject.

If a matching certificate is found, the field is set to the full subject of the matching certificate.

If an exact match is not found, the store is searched for subjects containing the value of the property.

If a match is still not found, the property is set to an empty string, and no certificate is selected.

The special value "*" picks a random certificate in the certificate store.

The certificate subject is a comma-separated list of distinguished name fields and values. For instance, "CN=www.server.com, OU=test, C=US, E=support@nsoftware.com". Common fields and their meanings are as follows:


Field	Meaning
CN	Common Name. This is commonly a hostname like www.server.com.
O	Organization
OU	Organizational Unit
L	Locality
S	State
C	Country
E	Email Address

If a field value contains a comma, it must be quoted.

Encoded
char*
Default Value: ""

The certificate (PEM/Base64 encoded). This field is used to assign a specific certificate. The Store and Subject fields also may be used to specify a certificate.

When Encoded is set, a search is initiated in the current Store for the private key of the certificate. If the key is found, Subject is updated to reflect the full subject of the selected certificate; otherwise, Subject is set to an empty string.

Constructors

Certificate()

Creates a instance whose properties can be set. This is useful for use with when generating new certificates.

Certificate(const char* lpEncoded, int lenEncoded)

Parses Encoded as an X.509 public key.

Certificate(int iStoreType, const char* lpStore, int lenStore, const char* lpszStorePassword, const char* lpszSubject)

StoreType identifies the type of certificate store to use. See for descriptions of the different certificate stores. Store is a byte array containing the certificate data. StorePassword is the password used to protect the store.

After the store has been successfully opened, the component will attempt to find the certificate identified by Subject . This can be either a complete or a substring match of the X.509 certificate's subject Distinguished Name (DN). The Subject parameter can also take an MD5, SHA-1, or SHA-256 thumbprint of the certificate to load in a "Thumbprint=value" format.

Firewall Type

The firewall the component will connect through.

Syntax

IPWorksFirewall (declared in ipworks.h)

Remarks

When connecting through a firewall, this type is used to specify different properties of the firewall, such as the firewall Host and the FirewallType.

The following fields are available:

Fields

AutoDetect
int
Default Value: FALSE

Whether to automatically detect and use firewall system settings, if available.

FirewallType
int
Default Value: 0

The type of firewall to connect through. The applicable values are as follows:


fwNone (0)	No firewall (default setting).
fwTunnel (1)	Connect through a tunneling proxy. Port is set to 80.
fwSOCKS4 (2)	Connect through a SOCKS4 Proxy. Port is set to 1080.
fwSOCKS5 (3)	Connect through a SOCKS5 Proxy. Port is set to 1080.
fwSOCKS4A (10)	Connect through a SOCKS4A Proxy. Port is set to 1080.

Host
char*
Default Value: ""

The name or IP address of the firewall (optional). If a Host is given, the requested connections will be authenticated through the specified firewall when connecting.

If this field is set to a Domain Name, a DNS request is initiated. Upon successful termination of the request, this field is set to the corresponding address. If the search is not successful, the class fails with an error.

Password
char*
Default Value: ""

A password if authentication is to be used when connecting through the firewall. If Host is specified, the User and Password fields are used to connect and authenticate to the given firewall. If the authentication fails, the class fails with an error.

Port
int
Default Value: 0

The Transmission Control Protocol (TCP) port for the firewall Host. See the description of the Host field for details.

Note: This field is set automatically when FirewallType is set to a valid value. See the description of the FirewallType field for details.

User
char*
Default Value: ""

A username if authentication is to be used when connecting through a firewall. If Host is specified, this field and the Password field are used to connect and authenticate to the given Firewall. If the authentication fails, the class fails with an error.

Constructors

Firewall()

SMPPRecipient Type

This type describes a recipient of the SMPP message.

Syntax

IPWorksSMPPRecipient (declared in ipworks.h)

Remarks

This type describes a recipient of the SMPP message that is being sent. The fields describe the RecipientType of recipient and the Address of the recipient of the message.

The following fields are available:

Address

RecipientType

Fields

Address
char*
Default Value: ""

This field contains the email address of a particular recipient. This can be used to set single or multiple recipients. The RecipientType contains the corresponding type.

For a recipient type of normal, the value in the Address should be either the dotted IPv4 of an SMS-enabled device or the directory number of a target mobile phone. For distributed lists, the value should be the name of the list as it is stored on the SMPPServer.

RecipientType
int
Default Value: 0

This field contains the type of a particular recipient. This field is used only for multiple recipient messages. The Address contains the corresponding recipient's address.

For a recipient type of normal, the value in Address should be either the dotted IPv4 of an SMS-enabled device or the directory number of a target mobile phone. For distributed lists, the value should be the name of the list as it is stored on the SMPPServer.

Valid values for RecipientType are as follows:


0 (smppRecipientTypeNormal)	Normal SME (Short Message Entity) Address
1 (smppRecipientTypeList)	Distribution List

Constructors

SMPPRecipient()

SMPPRecipient(const char* lpszAddress)

IPWorksList Type

Syntax

IPWorksList<T> (declared in ipworks.h)

Remarks

IPWorksList is a generic class that is used to hold a collection of objects of type T, where T is one of the custom types supported by the SMPP class.

Methods

GetCount	This method returns the current size of the collection. int GetCount() {}
SetCount	This method sets the size of the collection. This method returns `0` if setting the size was successful; or `-1` if the collection is `ReadOnly`. When adding additional objects to a collection call this method to specify the new size. Increasing the size of the collection preserves existing objects in the collection. int SetCount(int count) {}
Get	This method gets the item at the specified position. The `index` parameter specifies the index of the item in the collection. This method returns `NULL` if an invalid `index` is specified. T* Get(int index) {}
Set	This method sets the item at the specified position. The `index` parameter specifies the index of the item in the collection that is being set. This method returns `-1` if an invalid `index` is specified. Note: Objects created using the `new` operator must be freed using the `delete` operator; they will not be automatically freed by the class. T* Set(int index, T* value) {}

Config Settings (SMPP Class)

The class accepts one or more of the following configuration settings. Configuration settings are similar in functionality to properties, but they are rarely used. In order to avoid "polluting" the property namespace of the class, access to these internal properties is provided through the Config method.

SMPP Config Settings

AddressRange: Specifies the addr_range parameter when binding.

The addr_range parameter is used when binding as a receiver or transceiver to specify a set of short message entity (SME) addresses serviced by the external SME (ESME) client. A single SME address may be specified in the address_range parameter. UNIX Regular Expression notation should be used to specify a range of addresses. Messages addressed to any destination in this range shall be routed to the ESME.

Note 1: For IP addresses, it is only possible to specify a single IP address. A range of IP addresses is not allowed. IP version 6.0 is not currently supported in this version of the protocol.

Note 2: It is likely that the addr_range field is not supported or deliberately ignored on most Message Centers (MCs). Most carriers will not allow an ESME to control the message routing because this can carry the risk of incorrectly routing messages. In such circumstances, the ESME will be requested to set the field to NULL.

BinaryDataCoding: Whether or not to binary encode the message when DataCoding is set.

By default, when the DataCoding configuration setting is used, the component will treat the message as binary. This configuration setting can be set to false to send the text user data instead.

BindAsReceiver: Causes the component to bind as a receiver.

This configuration setting will instruct the component to bind to the SMPP service as a receiver instead of a transceiver.

BindAsTransmitter: Causes the component to bind as a transmitter.

This configuration setting will instruct the component to bind to the SMPP service as a transmitter instead of a transceiver.

CustomTLV: Optional TLV parameters added after the mandatory parameters and before the payload.

The format of the tag length value (TLV) parameter is as follows:

One two-byte integer containing the parameter type (tag).
One two-byte integer indicating the length of the data contained in this parameter.
The variable-length parameter data itself.

All of these values must be hex-encoded before setting the CustomTLV configuration setting.

For instance, to add a gn_lookup_userdata parameter, the type/tag is decimal 5633 (that's 0x1601 in hex), and the data in this example is "Hello World", which is 11 characters in length. So the TLV is as follows: 5633 + 11 + "Hello World", or 0x16 0x01 0x00 0x0b and then the ASCII text "Hello World". When hex-encoded, this yields the string "1601000b48656c6c6f20576f726c64". This is the value you would then use to set the CustomTLV configuration setting. You are not restricted to only one optional parameter. Multiple TLV parameters may be concatenated together.

Note: This is advanced functionality, and the class does not verify the data in this configuration setting before transmission. After the class internally decodes the string back into binary, it is passed on inside the protocol data unit (PDU) as-is without validation or modification.

This configuration setting is applicable only when using the SendMessage or SendData methods.

DataCoding: The data encoding mechanism to be used for the current message.

This configuration setting informs the message recipient about how data were encoded. The possible values are as follows:


0	MC Specific encoding
1	IA5 (CCITT T.50)/ASCII (ANSI X3.4)
2	Octet unspecified (8-bit binary)
3	Latin 1 (ISO-8859-1)
4	Octet unspecified (8-bit binary)
5	JIS (X 0208-1990)
6	Cyrillic (ISO-8859-5)
7	Latin/Hebrew (ISO-8859-8)
8	UCS2 (ISO/IEC-10646)
9	Pictogram Encoding
10	ISO-2022-JP (Music Codes)
11	Reserved
12	Reserved 2
13	Extended Kanji JIS (X 0212-1990)
14	KS C 5601

DecodeHexStrings: Will decode an ascii hex-representation of binary data prior to transmission.

When this configuration setting is True, data sent in the SendCommand method's Payload parameter, SendData method's Data parameter, or SendMessage method's Message parameter will be treated as an ASCII hex-representation of binary data, and will be decoded into raw binary before transmission. For instance, the string "48656C6C6F20576F726C64" will be decoded to "Hello World" when this configuration setting is True. If the string passed to the method parameter is not correctly hex-encoded, the class will transmit unexpected results. This setting is False by default.

DestinationNPI: The Number Planning Indicator for the destination ESME.

When sending messages, this configuration setting is used to indicate the numbering plan the destination ESME. For a list of possible values, please see SourceNPI.

DestinationTON: The Type of Number for the destination ESME.

When sending messages, this configuration setting is used to indicate the Type of Number for the destination ESME. For a list of possible values, please see SourceTON.

DoSplitLargeMessages: Splits long messages and returns the UDH and Message Parts.

This configuration setting accepts a string that will be the long message to be split into parts. The user data header (UDH) and Message Parts will be returned in hex, in the following format:

[UDH1],[MessagePart1];[UDH2],[MessagePart2];[UDH3],[MessagePart3]

HexString: A hex-encoded binary string to be sent to the current recipient.

When set, this configuration setting will cause the component to internally call SendMessage with the binary contents of the hex-encoded string. The return value when setting this property is the server-assigned Id of the message. Querying this property will result in an empty string.

Note: When using HexString, DataCoding must be set to 8, and the value provided to this configuration setting should be the UTF-16 hex-encoded message.

IncomingDestinationAddress: Returns the dest_addr field inside the received message.

This configuration setting is read-only, and it is valid only inside the MessageIn event.

IntermediateNotification: Causes the component to request intermediate notification.

This configuration setting will request intermediate notification. By default, intermediate notification is not requested.

MaxCIMDSMSLength: Indicates the maximum SMS message length for the CIMD protocol.

This configuration setting is applicable only when SplitLargeMessages is True and Protocol is set to CIMD2. The configuration setting controls the maximum size of SMS messages before they are split and has a default value of 160.

MaxSMSLength: Indicates the maximum SMS message length.

This configuration setting is applicable only when SplitLargeMessages is True. The setting controls the maximum size of SMS messages before they are split and has a default value of 140.

MCReceipt: The Type of MC Delivery Receipt requested.

When sending a message, this configuration setting is used to determine whether or not an MC delivery receipt is requested. This value is 0 by default, and no receipt is requested. The possible values are as follows:


0	No MC Delivery Receipt requested (default).
1	MC Delivery Receipt is requested after final delivery (success or failure).
2	MC Delivery Receipt is requested after a failed delivery.
3	MC Delivery Receipt is requested after a successful delivery.

MessageInReceiptedMessageId: The receipted_message_id field of an incoming deliver_sm PDU.

This configuration setting indicates the Id of the message being receipted in an MC delivery receipt.

Note: This is applicable only within the MessageIn event.

MessageMode: The Type of Messaging Mode requested.

When sending a message, this configuration setting is used to specify the Messaging Mode in the outgoing request. For incoming messages, this value can be queried from within the MessageIn event. The possible values are as follows:


0	Default SMSC Mode (e.g., Store and Forward).
1	Datagram mode.
2	Forward (i.e., Transaction) mode.
3	Store and Forward mode.

MessageType: The Type of Message.

When sending a message, this configuration setting is used to specify the Message Type in the outgoing request. For incoming messages, this value can be queried from within the MessageIn event. The possible values are as follows:


0	Default message Type (i.e., normal message).
1	Short Message contains MC Delivery Receipt.
2	Short Message contains Intermediate Delivery Notification.

PDUFormat: The format of the PDU.

Decides the format of the PDU parameter when decoding a PDU for the PITrail event. When set to Hex (1), the PDU will be encoded as a hex string. When set to Verbose (2) the PDU will be a longer hex dump.


0	Raw (Default)
1	Hex string
2	Verbose

ProtocolId: The protocol identifier.

This configuration setting allows control of the protocol identifier field value used in the outgoing messages.

ReplaceIfPresent: Indicates whether the replace_if_present_flag is enabled when sending a message.

This configuration indicates whether the replace_if_present_flag is enabled when sending a message. By default, this value is False, and the flag is disabled. When enabled (True), this indicates to the SMSC that the user wishes to replace a previously submitted message that is still pending delivery. If the previous message is still pending delivery, the new message will replace it. If the previous message has already been delivered or does not exist, the new message will also be delivered.

SMEAcknowledgement: The Type of SME originated acknowledgment requested.

When sending a message, this configuration setting is used to determine whether or not an SME acknowledgment is requested. This value is 0 by default, and no acknowledgment is requested. The possible values are as follows:


0	No SME acknowledgment requested (default).
1	SME delivery acknowledgment is requested.
2	SME manual/user acknowledgment is requested.
3	Both delivery and manual/user acknowledgment is requested.

SourceNPI: The Number Planning Indicator for the ESME.

When binding, this configuration setting is used to specify the numbering plan of the ESME. Mobiles tend to set this value to 1. Because most ESMEs are mobiles, the default value for SourceNPI is 1. The possible value are as follows:


Unknown (0)
ISDN (1)
Data (3)
Telex (4)
LandMobile (6)
National (8)
Private (9)
ERMES (10)
Internet (14)
WAP (18)

SourceTON: The Type of Number for the ESME.

When binding, this configuration setting is used to indicate the Type of Number for the ESME address. The possible values are as follows:


Unknown (0)	The number type is unknown
International (1)	The number includes the international trunk prefix
National (2)	The number includes the national trunk prefix
NetworkSpecific (3)	The number exists on a network that uses a specific delivery protocol
SubscriberNumber (4)	The number is just the subscriber number, without prefixes
Alphanumeric (5)	The address is human-readable (contains letters and digits)
Abbreviated (6)	The number is abbreviated

SplitLargeMessages: Determines whether large messages are split into multiple parts.

The default value is False. If set to true and the message is larger than MaxSMSLength (or MaxCIMDSMSLength), the message will automatically be split into parts when SendMessage is called.

Note: This is valid only for GSM networks.

When receiving a message that has been split, the MessageIn event provides parameters to reassemble the message.

SplitMessageMethod: Determines how large messages are split into multiple parts.

The component can split large messages using either the UDH or segmentation and reassembly (SAR) method. The mode used is determined by this configuration setting. The possible values are as follows:


0	UDH (Default)
1	SAR

StatusReportRequest: Defines in what cases a status report is created by the server.

This configuration setting is applicable only when Protocol is set to smppCIMD2. This may be set to request that the server create a status report for the given conditions. The assigned value should be the sum of all desired conditions. For instance, a value of 62 means that a report should be created for all events except for a temporary error. Possible flags are as follows:


1	Temporary Error
2	Validity Period Expired
4	Delivery Failed
8	Delivery Successful
16	Message Canceled
32	Message Deleted By The Operator

SubAddr: Defines a unique index for application instance.

This configuration setting is useful for correct delivery of status reports when multiple instances of the same application are connected.

This configuration setting is applicable only when Protocol is set to smppCIMD2.

SynchronousSendCommand: Controls whether SendCommand behaves synchronously or asynchronously.

The default value is True, which means SendCommand will not return until a response has been received. If set to False, the class returns and does not wait for a response from the server.

SynchronousSendMessage: Controls whether SendMessage behaves synchronously or asynchronously.

The default value is True, which means SendMessage will not return until a response has been received. If set to False, the class returns the sequence number used and does not wait for a response from the server. You may then monitor the PITrail event to match the response from the server to the sent message.

UseGSM7BitEncoding: Whether or not to use GSM 7-bit encoding.

When set to True (False by default), this will instruct the component to use 7-bit GSM encoding.

UseGSM7bitEncodingCompression: Whether to compress GSM 7-bit encoded characters.

When set to True (True by default), the component will compress GSM 7-bit encoded characters. Some devices do not support compression. Setting this to False may allow them to be displayed.

This configuration setting applies only when UseGSM7BitEncoding is True.

WaitForBanner: Specifies the CIMD2 banner the class will wait for when connecting.

This configuration setting is applicable only when Protocol is set to smppCIMD2. If set, the class will wait for a banner containing this string to be returned by the server before proceeding with the connection.

TCPClient Config Settings

ConnectionTimeout: Sets a separate timeout value for establishing a connection.

When set, this configuration setting allows you to specify a different timeout value for establishing a connection. Otherwise, the class will use Timeout for establishing a connection and transmitting/receiving data.

FirewallAutoDetect: Tells the class whether or not to automatically detect and use firewall system settings, if available.

This configuration setting is provided for use by classs that do not directly expose Firewall properties.

FirewallHost: Name or IP address of firewall (optional).

If a FirewallHost is given, requested connections will be authenticated through the specified firewall when connecting.

If the FirewallHost setting is set to a Domain Name, a DNS request is initiated. Upon successful termination of the request, the FirewallHost setting is set to the corresponding address. If the search is not successful, an error is returned.

Note: This setting is provided for use by classs that do not directly expose Firewall properties.

FirewallPassword: Password to be used if authentication is to be used when connecting through the firewall.

If FirewallHost is specified, the FirewallUser and FirewallPassword settings are used to connect and authenticate to the given firewall. If the authentication fails, the class fails with an error.

Note: This setting is provided for use by classs that do not directly expose Firewall properties.

FirewallPort: The TCP port for the FirewallHost;.

The FirewallPort is set automatically when FirewallType is set to a valid value.

Note: This configuration setting is provided for use by classs that do not directly expose Firewall properties.

FirewallType: Determines the type of firewall to connect through.

Possible values are as follows:


0	No firewall (default setting).
1	Connect through a tunneling proxy. FirewallPort is set to 80.
2	Connect through a SOCKS4 Proxy. FirewallPort is set to 1080.
3	Connect through a SOCKS5 Proxy. FirewallPort is set to 1080.
10	Connect through a SOCKS4A Proxy. FirewallPort is set to 1080.

Note: This setting is provided for use by classs that do not directly expose Firewall properties.

FirewallUser: A user name if authentication is to be used connecting through a firewall.

If the FirewallHost is specified, the FirewallUser and FirewallPassword settings are used to connect and authenticate to the Firewall. If the authentication fails, the class fails with an error.

Note: This setting is provided for use by classs that do not directly expose Firewall properties.

KeepAliveInterval: The retry interval, in milliseconds, to be used when a TCP keep-alive packet is sent and no response is received.

When set, TCPKeepAlive will automatically be set to True. A TCP keep-alive packet will be sent after a period of inactivity as defined by KeepAliveTime. If no acknowledgment is received from the remote host, the keep-alive packet will be sent again. This configuration setting specifies the interval at which the successive keep-alive packets are sent in milliseconds. This system default if this value is not specified here is 1 second.

Note: This value is not applicable in macOS.

KeepAliveRetryCount: The number of keep-alive packets to be sent before the remotehost is considered disconnected.

When set, TCPKeepAlive will automatically be set to True. A TCP keep-alive packet will be sent after a period of inactivity as defined by KeepAliveTime. If no acknowledgment is received from the remote host, the keep-alive packet will be sent again. This configuration setting specifies the number of times that the keep-alive packets will be sent before the remote host is considered disconnected. The system default if this value is not specified here is 9.

Note: This configuration setting is only available in the Unix platform. It is not supported in masOS or FreeBSD.

KeepAliveTime: The inactivity time in milliseconds before a TCP keep-alive packet is sent.

When set, TCPKeepAlive will automatically be set to True. By default, the operating system will determine the time a connection is idle before a Transmission Control Protocol (TCP) keep-alive packet is sent. This system default if this value is not specified here is 2 hours. In many cases, a shorter interval is more useful. Set this value to the desired interval in milliseconds.

Linger: When set to True, connections are terminated gracefully.

This property controls how a connection is closed. The default is True.

In the case that Linger is True (default), two scenarios determine how long the connection will linger. In the first, if LingerTime is 0 (default), the system will attempt to send pending data for a connection until the default IP timeout expires.

In the second scenario, if LingerTime is a positive value, the system will attempt to send pending data until the specified LingerTime is reached. If this attempt fails, then the system will reset the connection.

The default behavior (which is also the default mode for stream sockets) might result in a long delay in closing the connection. Although the class returns control immediately, the system could hold system resources until all pending data are sent (even after your application closes).

Setting this property to False forces an immediate disconnection. If you know that the other side has received all the data you sent (e.g., by a client acknowledgment), setting this property to False might be the appropriate course of action.

LingerTime: Time in seconds to have the connection linger.

LingerTime is the time, in seconds, the socket connection will linger. This value is 0 by default, which means it will use the default IP timeout.

LocalHost: The name of the local host through which connections are initiated or accepted.

The LocalHost setting contains the name of the local host as obtained by the gethostname() system call, or if the user has assigned an IP address, the value of that address.

In multihomed hosts (machines with more than one IP interface), setting LocalHost to the value of an interface will make the class initiate connections (or accept in the case of server classs) only through that interface.

If the class is connected, the LocalHost setting shows the IP address of the interface through which the connection is made in internet dotted format (aaa.bbb.ccc.ddd). In most cases, this is the address of the local host, except for multihomed hosts (machines with more than one IP interface).

LocalPort: The port in the local host where the class binds.

This configuration setting must be set before a connection is attempted. It instructs the class to bind to a specific port (or communication endpoint) in the local machine.

Setting this to 0 (default) enables the system to choose a port at random. The chosen port will be shown by LocalPort after the connection is established.

LocalPort cannot be changed once a connection is made. Any attempt to set this when a connection is active will generate an error.

This configuration setting is useful when trying to connect to services that require a trusted port on the client side. An example is the remote shell (rsh) service in UNIX systems.

MaxLineLength: The maximum amount of data to accumulate when no EOL is found.

MaxLineLength is the size of an internal buffer, which holds received data while waiting for an EOL string.

If an EOL string is found in the input stream before MaxLineLength bytes are received, the DataIn event is fired with the EOL parameter set to True, and the buffer is reset.

If no EOL is found, and MaxLineLength bytes are accumulated in the buffer, the DataIn event is fired with the EOL parameter set to False, and the buffer is reset.

The minimum value for MaxLineLength is 256 bytes. The default value is 2048 bytes.

MaxTransferRate: The transfer rate limit in bytes per second.

This configuration setting can be used to throttle outbound TCP traffic. Set this to the number of bytes to be sent per second. By default, this is not set and there is no limit.

ProxyExceptionsList: A semicolon separated list of hosts and IPs to bypass when using a proxy.

This configuration setting optionally specifies a semicolon-separated list of hostnames or IP addresses to bypass when a proxy is in use. When requests are made to hosts specified in this property, the proxy will not be used. For instance:

www.google.com;www.nsoftware.com

TCPKeepAlive: Determines whether or not the keep alive socket option is enabled.

If set to True, the socket's keep-alive option is enabled and keep-alive packets will be sent periodically to maintain the connection. Set KeepAliveTime and KeepAliveInterval to configure the timing of the keep-alive packets.

Note: This value is not applicable in Java.

TcpNoDelay: Whether or not to delay when sending packets.

When set to True, the socket will send all data that are ready to send at once. When set to False, the socket will send smaller buffered packets of data at small intervals. This is known as the Nagle algorithm.

By default, this configuration setting is set to False.

UseIPv6: Whether to use IPv6.

When set to 0 (default), the class will use IPv4 exclusively. When set to 1, the class will use IPv6 exclusively. To instruct the class to prefer IPv6 addresses, but use IPv4 if IPv6 is not supported on the system, this setting should be set to 2. The default value is 0. Possible values are as follows:


0	IPv4 only
1	IPv6 only
2	IPv6 with IPv4 fallback

SSL Config Settings

LogSSLPackets: Controls whether SSL packets are logged when using the internal security API.

When SSLProvider is set to Internal, this configuration setting controls whether Secure Sockets Layer (SSL) packets should be logged. By default, this configuration setting is False, as it is useful only for debugging purposes.

When enabled, SSL packet logs are output using the SSLStatus event, which will fire each time an SSL packet is sent or received.

Enabling this configuration setting has no effect if SSLProvider is set to Platform.

OpenSSLCADir: The path to a directory containing CA certificates.

This functionality is available only when the provider is OpenSSL.

The path set by this property should point to a directory containing CA certificates in PEM format. The files each contain one CA certificate. The files are looked up by the CA subject name hash value, which must hence be available. If more than one CA certificate with the same name hash value exist, the extension must be different (e.g., 9d66eef0.0, 9d66eef0.1). OpenSSL recommends the use of the c_rehash utility to create the necessary links. Please refer to the OpenSSL man page SSL_CTX_load_verify_locations(3) for details.

OpenSSLCAFile: Name of the file containing the list of CA's trusted by your application.

This functionality is available only when the provider is OpenSSL.

The file set by this property should contain a list of CA certificates in PEM format. The file can contain several CA certificates identified by the following sequences:

-----BEGIN CERTIFICATE-----

... (CA certificate in base64 encoding) ...

-----END CERTIFICATE-----

Before, between, and after the certificate text is allowed, which can be used, for example, for descriptions of the certificates. Refer to the OpenSSL man page SSL_CTX_load_verify_locations(3) for details.

OpenSSLCipherList: A string that controls the ciphers to be used by SSL.

This functionality is available only when the provider is OpenSSL.

The format of this string is described in the OpenSSL man page ciphers(1) section "CIPHER LIST FORMAT". Please refer to it for details. The default string "DEFAULT" is determined at compile time and is normally equivalent to "ALL:!ADH:RC4+RSA:+SSLv2:@STRENGTH".

OpenSSLPrngSeedData: The data to seed the pseudo random number generator (PRNG).

This functionality is available only when the provider is OpenSSL.

By default, OpenSSL uses the device file "/dev/urandom" to seed the PRNG, and setting OpenSSLPrngSeedData is not required. If set, the string specified is used to seed the PRNG.

ReuseSSLSession: Determines if the SSL session is reused.

If set to True, the class will reuse the context if and only if the following criteria are met:

The target host name is the same.
The system cache entry has not expired (default timeout is 10 hours).
The application process that calls the function is the same.
The logon session is the same.
The instance of the class is the same.

SSLCACertFilePaths: The paths to CA certificate files on Unix/Linux.

This configuration setting specifies the paths on disk to CA certificate files on Unix/Linux.

The value is formatted as a list of paths separated by semicolons. The class will check for the existence of each file in the order specified. When a file is found, the CA certificates within the file will be loaded and used to determine the validity of server or client certificates.

The default value is as follows:

/etc/ssl/ca-bundle.pem;/etc/pki/tls/certs/ca-bundle.crt;/etc/ssl/certs/ca-certificates.crt;/etc/pki/tls/cacert.pem

SSLCACerts: A newline separated list of CA certificates to be included when performing an SSL handshake.

When SSLProvider is set to Internal, this configuration setting specifies one or more CA certificates to be included with the SSLCert property. Some servers or clients require the entire chain, including CA certificates, to be presented when performing SSL authentication. The value of this configuration setting is a newline-separated (CR/LF) list of certificates. For instance:

-----BEGIN CERTIFICATE-----
MIIEKzCCAxOgAwIBAgIRANTET4LIkxdH6P+CFIiHvTowDQYJKoZIhvcNAQELBQAw
... Intermediate Cert ...
eWHV5OW1K53o/atv59sOiW5K3crjFhsBOd5Q+cJJnU+SWinPKtANXMht+EDvYY2w
F0I1XhM+pKj7FjDr+XNj
-----END CERTIFICATE-----
\r \n
-----BEGIN CERTIFICATE-----
MIIEFjCCAv6gAwIBAgIQetu1SMxpnENAnnOz1P+PtTANBgkqhkiG9w0BAQUFADBp
... Root Cert ...
d8q23djXZbVYiIfE9ebr4g3152BlVCHZ2GyPdjhIuLeH21VbT/dyEHHA
-----END CERTIFICATE-----

SSLCipherStrength: The minimum cipher strength used for bulk encryption.

This minimum cipher strength is largely dependent on the security modules installed on the system. If the cipher strength specified is not supported, an error will be returned when connections are initiated.

Note: This configuration setting contains the minimum cipher strength requested from the security library. The actual cipher strength used for the connection is shown by the SSLStatus event.

Use this configuration setting with caution. Requesting a lower cipher strength than necessary could potentially cause serious security vulnerabilities in your application.

When the provider is OpenSSL, SSLCipherStrength is currently not supported. This functionality is instead made available through the OpenSSLCipherList configuration setting.

SSLClientCACerts: A newline separated list of CA certificates to use during SSL client certificate validation.

This configuration setting is only applicable to server components (e.g., TCPServer) see SSLServerCACerts for client components (e.g., TCPClient). This setting can be used to optionally specify one or more CA certificates to be used when verifying the client certificate that is presented by the client during the SSL handshake when SSLAuthenticateClients is enabled. When verifying the client's certificate, the certificates trusted by the system will be used as part of the verification process. If the client's CA certificates are not installed to the trusted system store, they may be specified here so they are included when performing the verification process. This configuration setting should be set only if the client's CA certificates are not already trusted on the system and cannot be installed to the trusted system store.

The value of this configuration setting is a newline-separated (CR/LF) list of certificates. For instance:

-----BEGIN CERTIFICATE-----
MIIEKzCCAxOgAwIBAgIRANTET4LIkxdH6P+CFIiHvTowDQYJKoZIhvcNAQELBQAw
... Intermediate Cert ...
eWHV5OW1K53o/atv59sOiW5K3crjFhsBOd5Q+cJJnU+SWinPKtANXMht+EDvYY2w
F0I1XhM+pKj7FjDr+XNj
-----END CERTIFICATE-----
\r \n
-----BEGIN CERTIFICATE-----
MIIEFjCCAv6gAwIBAgIQetu1SMxpnENAnnOz1P+PtTANBgkqhkiG9w0BAQUFADBp
... Root Cert ...
d8q23djXZbVYiIfE9ebr4g3152BlVCHZ2GyPdjhIuLeH21VbT/dyEHHA
-----END CERTIFICATE-----

SSLEnabledCipherSuites: The cipher suite to be used in an SSL negotiation.

This configuration setting enables the cipher suites to be used in SSL negotiation.

By default, the enabled cipher suites will include all available ciphers ("*").

The special value "*" means that the class will pick all of the supported cipher suites. If SSLEnabledCipherSuites is set to any other value, only the specified cipher suites will be considered.

Multiple cipher suites are separated by semicolons.

Example values when SSLProvider is set to Platform include the following: obj.config("SSLEnabledCipherSuites=*"); obj.config("SSLEnabledCipherSuites=CALG_AES_256"); obj.config("SSLEnabledCipherSuites=CALG_AES_256;CALG_3DES"); Possible values when SSLProvider is set to Platform include the following:

CALG_3DES
CALG_3DES_112
CALG_AES
CALG_AES_128
CALG_AES_192
CALG_AES_256
CALG_AGREEDKEY_ANY
CALG_CYLINK_MEK
CALG_DES
CALG_DESX
CALG_DH_EPHEM
CALG_DH_SF
CALG_DSS_SIGN
CALG_ECDH
CALG_ECDH_EPHEM
CALG_ECDSA
CALG_ECMQV
CALG_HASH_REPLACE_OWF
CALG_HUGHES_MD5
CALG_HMAC
CALG_KEA_KEYX
CALG_MAC
CALG_MD2
CALG_MD4
CALG_MD5
CALG_NO_SIGN
CALG_OID_INFO_CNG_ONLY
CALG_OID_INFO_PARAMETERS
CALG_PCT1_MASTER
CALG_RC2
CALG_RC4
CALG_RC5
CALG_RSA_KEYX
CALG_RSA_SIGN
CALG_SCHANNEL_ENC_KEY
CALG_SCHANNEL_MAC_KEY
CALG_SCHANNEL_MASTER_HASH
CALG_SEAL
CALG_SHA
CALG_SHA1
CALG_SHA_256
CALG_SHA_384
CALG_SHA_512
CALG_SKIPJACK
CALG_SSL2_MASTER
CALG_SSL3_MASTER
CALG_SSL3_SHAMD5
CALG_TEK
CALG_TLS1_MASTER
CALG_TLS1PRF

Example values when SSLProvider is set to Internalinclude the following:

obj.config("SSLEnabledCipherSuites=*");
obj.config("SSLEnabledCipherSuites=TLS_DHE_DSS_WITH_AES_128_CBC_SHA");
obj.config("SSLEnabledCipherSuites=TLS_DHE_DSS_WITH_AES_128_CBC_SHA;TLS_ECDH_RSA_WITH_AES_128_CBC_SHA");

Possible values when SSLProvider is set to Internal include the following:

TLS_ECDHE_ECDSA_WITH_AES_256_GCM_SHA384
TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256
TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256
TLS_ECDHE_RSA_WITH_AES_256_GCM_SHA384
TLS_ECDH_ECDSA_WITH_AES_256_GCM_SHA384
TLS_RSA_WITH_AES_256_GCM_SHA384
TLS_RSA_WITH_AES_128_GCM_SHA256
TLS_ECDH_ECDSA_WITH_AES_128_GCM_SHA256
TLS_DHE_DSS_WITH_AES_256_GCM_SHA384
TLS_DHE_RSA_WITH_AES_256_GCM_SHA384
TLS_ECDH_RSA_WITH_AES_256_GCM_SHA384
TLS_ECDH_RSA_WITH_AES_128_GCM_SHA256
TLS_DHE_RSA_WITH_AES_128_GCM_SHA256
TLS_DHE_DSS_WITH_AES_128_GCM_SHA256
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA384
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA256
TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA384
TLS_DHE_DSS_WITH_AES_256_CBC_SHA256
TLS_RSA_WITH_AES_256_CBC_SHA256
TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA384
TLS_ECDH_RSA_WITH_AES_256_CBC_SHA384
TLS_DHE_RSA_WITH_AES_256_CBC_SHA256
TLS_DHE_RSA_WITH_AES_128_CBC_SHA256
TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA256
TLS_RSA_WITH_AES_128_CBC_SHA256
TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA256
TLS_ECDH_RSA_WITH_AES_128_CBC_SHA256
TLS_DHE_DSS_WITH_AES_128_CBC_SHA256
TLS_RSA_WITH_AES_256_CBC_SHA
TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA
TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA
TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA
TLS_DHE_RSA_WITH_AES_256_CBC_SHA
TLS_ECDH_RSA_WITH_AES_256_CBC_SHA
TLS_DHE_DSS_WITH_AES_256_CBC_SHA
TLS_RSA_WITH_AES_128_CBC_SHA
TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA
TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA
TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA
TLS_ECDH_RSA_WITH_AES_128_CBC_SHA
TLS_DHE_RSA_WITH_AES_128_CBC_SHA
TLS_DHE_DSS_WITH_AES_128_CBC_SHA
TLS_ECDHE_ECDSA_WITH_3DES_EDE_CBC_SHA
TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA
TLS_ECDH_ECDSA_WITH_3DES_EDE_CBC_SHA
TLS_ECDH_RSA_WITH_3DES_EDE_CBC_SHA
TLS_DHE_RSA_WITH_3DES_EDE_CBC_SHA
TLS_DHE_DSS_WITH_3DES_EDE_CBC_SHA
TLS_RSA_WITH_3DES_EDE_CBC_SHA
TLS_RSA_WITH_DES_CBC_SHA
TLS_DHE_RSA_WITH_DES_CBC_SHA
TLS_DHE_DSS_WITH_DES_CBC_SHA
TLS_RSA_WITH_RC4_128_MD5
TLS_RSA_WITH_RC4_128_SHA

When TLS 1.3 is negotiated (see SSLEnabledProtocols), only the following cipher suites are supported:

TLS_AES_256_GCM_SHA384
TLS_CHACHA20_POLY1305_SHA256
TLS_AES_128_GCM_SHA256

SSLEnabledCipherSuites is used together with SSLCipherStrength.

SSLEnabledProtocols: Used to enable/disable the supported security protocols.

This configuration setting is used to enable or disable the supported security protocols.

Not all supported protocols are enabled by default. The default value is 4032 for client components, and 3072 for server components. To specify a combination of enabled protocol versions set this config to the binary OR of one or more of the following values:


TLS1.3	12288 (Hex 3000)
TLS1.2	3072 (Hex C00) (Default - Client and Server)
TLS1.1	768 (Hex 300) (Default - Client)
TLS1	192 (Hex C0) (Default - Client)
SSL3	48 (Hex 30)
SSL2	12 (Hex 0C)

Note that only TLS 1.2 is enabled for server components that accept incoming connections. This adheres to industry standards to ensure a secure connection. Client components enable TLS 1.0, TLS 1.1, and TLS 1.2 by default and will negotiate the highest mutually supported version when connecting to a server, which should be TLS 1.2 in most cases.

SSLEnabledProtocols: Transport Layer Security (TLS) 1.3 Notes:

By default when TLS 1.3 is enabled, the class will use the internal TLS implementation when the SSLProvider is set to Automatic for all editions.

In editions that are designed to run on Windows, SSLProvider can be set to Platform to use the platform implementation instead of the internal implementation. When configured in this manner, please note that the platform provider is supported only on Windows 11/Windows Server 2022 and up. The default internal provider is available on all platforms and is not restricted to any specific OS version.

If set to 1 (Platform provider), please be aware of the following notes:

The platform provider is available only on Windows 11/Windows Server 2022 and up.
SSLEnabledCipherSuites and other similar SSL configuration settings are not supported.
If SSLEnabledProtocols includes both TLS 1.3 and TLS 1.2, these restrictions are still applicable even if TLS 1.2 is negotiated. Enabling TLS 1.3 with the platform provider changes the implementation used for all TLS versions.

SSLEnabledProtocols: SSL2 and SSL3 Notes:

SSL 2.0 and 3.0 are not supported by the class when the SSLProvider is set to internal. To use SSL 2.0 or SSL 3.0, the platform security API must have the protocols enabled and SSLProvider needs to be set to platform.

SSLEnableRenegotiation: Whether the renegotiation_info SSL extension is supported.

This configuration setting specifies whether the renegotiation_info SSL extension will be used in the request when using the internal security API. This configuration setting is false by default, but it can be set to true to enable the extension.

This configuration setting is applicable only when SSLProvider is set to Internal.

SSLIncludeCertChain: Whether the entire certificate chain is included in the SSLServerAuthentication event.

This configuration setting specifies whether the Encoded parameter of the SSLServerAuthentication event contains the full certificate chain. By default this value is False and only the leaf certificate will be present in the Encoded parameter of the SSLServerAuthentication event.

If set to True, all certificates returned by the server will be present in the Encoded parameter of the SSLServerAuthentication event. This includes the leaf certificate, any intermediate certificate, and the root certificate.

SSLKeyLogFile: The location of a file where per-session secrets are written for debugging purposes.

This configuration setting optionally specifies the full path to a file on disk where per-session secrets are stored for debugging purposes.

When set, the class will save the session secrets in the same format as the SSLKEYLOGFILE environment variable functionality used by most major browsers and tools, such as Chrome, Firefox, and cURL. This file can then be used in tools such as Wireshark to decrypt TLS traffic for debugging purposes. When writing to this file, the class will only append, it will not overwrite previous values.

Note: This configuration setting is applicable only when SSLProvider is set to Internal.

SSLNegotiatedCipher: Returns the negotiated cipher suite.

This configuration setting returns the cipher suite negotiated during the SSL handshake.

Note: For server components (e.g., TCPServer), this is a per-connection configuration setting accessed by passing the ConnectionId. For example: server.Config("SSLNegotiatedCipher[connId]");

SSLNegotiatedCipherStrength: Returns the negotiated cipher suite strength.

This configuration setting returns the strength of the cipher suite negotiated during the SSL handshake.

Note: For server components (e.g., TCPServer), this is a per-connection configuration setting accessed by passing the ConnectionId. For example: server.Config("SSLNegotiatedCipherStrength[connId]");

SSLNegotiatedCipherSuite: Returns the negotiated cipher suite.

This configuration setting returns the cipher suite negotiated during the SSL handshake represented as a single string.

SSLNegotiatedKeyExchange: Returns the negotiated key exchange algorithm.

This configuration setting returns the key exchange algorithm negotiated during the SSL handshake.

SSLNegotiatedKeyExchangeStrength: Returns the negotiated key exchange algorithm strength.

This configuration setting returns the strength of the key exchange algorithm negotiated during the SSL handshake.

SSLNegotiatedVersion: Returns the negotiated protocol version.

This configuration setting returns the protocol version negotiated during the SSL handshake.

Note: For server components (e.g., TCPServer), this is a per-connection configuration setting accessed by passing the ConnectionId. For example: server.Config("SSLNegotiatedVersion[connId]");

SSLSecurityFlags: Flags that control certificate verification.

The following flags are defined (specified in hexadecimal notation). They can be ORed together to exclude multiple conditions:


0x00000001	Ignore time validity status of certificate.
0x00000002	Ignore time validity status of CTL.
0x00000004	Ignore non-nested certificate times.
0x00000010	Allow unknown certificate authority.
0x00000020	Ignore wrong certificate usage.
0x00000100	Ignore unknown certificate revocation status.
0x00000200	Ignore unknown CTL signer revocation status.
0x00000400	Ignore unknown certificate authority revocation status.
0x00000800	Ignore unknown root revocation status.
0x00008000	Allow test root certificate.
0x00004000	Trust test root certificate.
0x80000000	Ignore non-matching CN (certificate CN non-matching server name).

This functionality is currently not available when the provider is OpenSSL.

SSLServerCACerts: A newline separated list of CA certificates to use during SSL server certificate validation.

This configuration setting is only used by client components (e.g., TCPClient) see SSLClientCACerts for server components (e.g., TCPServer). This configuration setting can be used to optionally specify one or more CA certificates to be used when connecting to the server and verifying the server certificate. When verifying the server's certificate, the certificates trusted by the system will be used as part of the verification process. If the server's CA certificates are not installed to the trusted system store, they may be specified here so they are included when performing the verification process. This configuration setting should be set only if the server's CA certificates are not already trusted on the system and cannot be installed to the trusted system store.

The value of this configuration setting is a newline-separated (CR/LF) list of certificates. For instance:

-----BEGIN CERTIFICATE-----
MIIEKzCCAxOgAwIBAgIRANTET4LIkxdH6P+CFIiHvTowDQYJKoZIhvcNAQELBQAw
... Intermediate Cert...
eWHV5OW1K53o/atv59sOiW5K3crjFhsBOd5Q+cJJnU+SWinPKtANXMht+EDvYY2w
F0I1XhM+pKj7FjDr+XNj
-----END CERTIFICATE-----
\r \n
-----BEGIN CERTIFICATE-----
MIIEFjCCAv6gAwIBAgIQetu1SMxpnENAnnOz1P+PtTANBgkqhkiG9w0BAQUFADBp
... Root Cert...
d8q23djXZbVYiIfE9ebr4g3152BlVCHZ2GyPdjhIuLeH21VbT/dyEHHA
-----END CERTIFICATE-----

TLS12SignatureAlgorithms: Defines the allowed TLS 1.2 signature algorithms when SSLProvider is set to Internal.

This configuration setting specifies the allowed server certificate signature algorithms when SSLProvider is set to Internal and SSLEnabledProtocols is set to allow TLS 1.2.

When specified the class will verify that the server certificate signature algorithm is among the values specified in this configuration setting. If the server certificate signature algorithm is unsupported, the class fails with an error.

The format of this value is a comma-separated list of hash-signature combinations. For instance: component.SSLProvider = TCPClientSSLProviders.sslpInternal; component.Config("SSLEnabledProtocols=3072"); //TLS 1.2 component.Config("TLS12SignatureAlgorithms=sha256-rsa,sha256-dsa,sha1-rsa,sha1-dsa"); The default value for this configuration setting is sha512-ecdsa,sha512-rsa,sha512-dsa,sha384-ecdsa,sha384-rsa,sha384-dsa,sha256-ecdsa,sha256-rsa,sha256-dsa,sha224-ecdsa,sha224-rsa,sha224-dsa,sha1-ecdsa,sha1-rsa,sha1-dsa.

To not restrict the server's certificate signature algorithm, specify an empty string as the value for this configuration setting, which will cause the signature_algorithms TLS 1.2 extension to not be sent.

TLS12SupportedGroups: The supported groups for ECC.

This configuration setting specifies a comma-separated list of named groups used in TLS 1.2 for ECC.

The default value is ecdhe_secp256r1,ecdhe_secp384r1,ecdhe_secp521r1.

When using TLS 1.2 and SSLProvider is set to Internal, the values refer to the supported groups for ECC. The following values are supported:

"ecdhe_secp256r1" (default)
"ecdhe_secp384r1" (default)
"ecdhe_secp521r1" (default)

TLS13KeyShareGroups: The groups for which to pregenerate key shares.

This configuration setting specifies a comma-separated list of named groups used in TLS 1.3 for key exchange. The groups specified here will have key share data pregenerated locally before establishing a connection. This can prevent an additional roundtrip during the handshake if the group is supported by the server.

The default value is set to balance common supported groups and the computational resources required to generate key shares. As a result, only some groups are included by default in this configuration setting.

Note: All supported groups can always be used during the handshake even if not listed here, but if a group is used that is not present in this list, it will incur an additional roundtrip and time to generate the key share for that group.

In most cases, this configuration setting does not need to be modified. This should be modified only if there is a specific reason to do so.

The default value is ecdhe_x25519,ecdhe_secp256r1,ecdhe_secp384r1,ffdhe_2048,ffdhe_3072

The values are ordered from most preferred to least preferred. The following values are supported:

"ecdhe_x25519" (default)
"ecdhe_x448"
"ecdhe_secp256r1" (default)
"ecdhe_secp384r1" (default)
"ecdhe_secp521r1"
"ffdhe_2048" (default)
"ffdhe_3072" (default)
"ffdhe_4096"
"ffdhe_6144"
"ffdhe_8192"

TLS13SignatureAlgorithms: The allowed certificate signature algorithms.

This configuration setting holds a comma-separated list of allowed signature algorithms. Possible values include the following:

"ed25519" (default)
"ed448" (default)
"ecdsa_secp256r1_sha256" (default)
"ecdsa_secp384r1_sha384" (default)
"ecdsa_secp521r1_sha512" (default)
"rsa_pkcs1_sha256" (default)
"rsa_pkcs1_sha384" (default)
"rsa_pkcs1_sha512" (default)
"rsa_pss_sha256" (default)
"rsa_pss_sha384" (default)
"rsa_pss_sha512" (default)

The default value is rsa_pss_sha256,rsa_pss_sha384,rsa_pss_sha512,rsa_pkcs1_sha256,rsa_pkcs1_sha384,rsa_pkcs1_sha512,ecdsa_secp256r1_sha256,ecdsa_secp384r1_sha384,ecdsa_secp521r1_sha512,ed25519,ed448. This configuration setting is applicable only when SSLEnabledProtocols includes TLS 1.3.

TLS13SupportedGroups: The supported groups for (EC)DHE key exchange.

This configuration setting specifies a comma-separated list of named groups used in TLS 1.3 for key exchange. This configuration setting should be modified only if there is a specific reason to do so.

The default value is ecdhe_x25519,ecdhe_x448,ecdhe_secp256r1,ecdhe_secp384r1,ecdhe_secp521r1,ffdhe_2048,ffdhe_3072,ffdhe_4096,ffdhe_6144,ffdhe_8192

The values are ordered from most preferred to least preferred. The following values are supported:

"ecdhe_x25519" (default)
"ecdhe_x448" (default)
"ecdhe_secp256r1" (default)
"ecdhe_secp384r1" (default)
"ecdhe_secp521r1" (default)
"ffdhe_2048" (default)
"ffdhe_3072" (default)
"ffdhe_4096" (default)
"ffdhe_6144" (default)
"ffdhe_8192" (default)

Socket Config Settings

AbsoluteTimeout: Determines whether timeouts are inactivity timeouts or absolute timeouts.

If AbsoluteTimeout is set to True, any method that does not complete within Timeout seconds will be aborted. By default, AbsoluteTimeout is False, and the timeout is an inactivity timeout.

Note: This option is not valid for User Datagram Protocol (UDP) ports.

FirewallData: Used to send extra data to the firewall.

When the firewall is a tunneling proxy, use this property to send custom (additional) headers to the firewall (e.g., headers for custom authentication schemes).

InBufferSize: The size in bytes of the incoming queue of the socket.

This is the size of an internal queue in the Transmission Control Protocol (TCP)/IP stack. You can increase or decrease its size depending on the amount of data that you will be receiving. In some cases, increasing the value of the InBufferSize setting can provide significant improvements in performance.

Some TCP/IP implementations do not support variable buffer sizes. If that is the case, when the class is activated the InBufferSize reverts to its defined size. The same happens if you attempt to make it too large or too small.

OutBufferSize: The size in bytes of the outgoing queue of the socket.

This is the size of an internal queue in the TCP/IP stack. You can increase or decrease its size depending on the amount of data that you will be sending. In some cases, increasing the value of the OutBufferSize setting can provide significant improvements in performance.

Some TCP/IP implementations do not support variable buffer sizes. If that is the case, when the class is activated the OutBufferSize reverts to its defined size. The same happens if you attempt to make it too large or too small.

Base Config Settings

BuildInfo: Information about the product's build.

When queried, this setting will return a string containing information about the product's build.

CodePage: The system code page used for Unicode to Multibyte translations.

The default code page is Unicode UTF-8 (65001).

The following is a list of valid code page identifiers:


Identifier	Name
037	IBM EBCDIC - U.S./Canada
437	OEM - United States
500	IBM EBCDIC - International
708	Arabic - ASMO 708
709	Arabic - ASMO 449+, BCON V4
710	Arabic - Transparent Arabic
720	Arabic - Transparent ASMO
737	OEM - Greek (formerly 437G)
775	OEM - Baltic
850	OEM - Multilingual Latin I
852	OEM - Latin II
855	OEM - Cyrillic (primarily Russian)
857	OEM - Turkish
858	OEM - Multilingual Latin I + Euro symbol
860	OEM - Portuguese
861	OEM - Icelandic
862	OEM - Hebrew
863	OEM - Canadian-French
864	OEM - Arabic
865	OEM - Nordic
866	OEM - Russian
869	OEM - Modern Greek
870	IBM EBCDIC - Multilingual/ROECE (Latin-2)
874	ANSI/OEM - Thai (same as 28605, ISO 8859-15)
875	IBM EBCDIC - Modern Greek
932	ANSI/OEM - Japanese, Shift-JIS
936	ANSI/OEM - Simplified Chinese (PRC, Singapore)
949	ANSI/OEM - Korean (Unified Hangul Code)
950	ANSI/OEM - Traditional Chinese (Taiwan; Hong Kong SAR, PRC)
1026	IBM EBCDIC - Turkish (Latin-5)
1047	IBM EBCDIC - Latin 1/Open System
1140	IBM EBCDIC - U.S./Canada (037 + Euro symbol)
1141	IBM EBCDIC - Germany (20273 + Euro symbol)
1142	IBM EBCDIC - Denmark/Norway (20277 + Euro symbol)
1143	IBM EBCDIC - Finland/Sweden (20278 + Euro symbol)
1144	IBM EBCDIC - Italy (20280 + Euro symbol)
1145	IBM EBCDIC - Latin America/Spain (20284 + Euro symbol)
1146	IBM EBCDIC - United Kingdom (20285 + Euro symbol)
1147	IBM EBCDIC - France (20297 + Euro symbol)
1148	IBM EBCDIC - International (500 + Euro symbol)
1149	IBM EBCDIC - Icelandic (20871 + Euro symbol)
1200	Unicode UCS-2 Little-Endian (BMP of ISO 10646)
1201	Unicode UCS-2 Big-Endian
1250	ANSI - Central European
1251	ANSI - Cyrillic
1252	ANSI - Latin I
1253	ANSI - Greek
1254	ANSI - Turkish
1255	ANSI - Hebrew
1256	ANSI - Arabic
1257	ANSI - Baltic
1258	ANSI/OEM - Vietnamese
1361	Korean (Johab)
10000	MAC - Roman
10001	MAC - Japanese
10002	MAC - Traditional Chinese (Big5)
10003	MAC - Korean
10004	MAC - Arabic
10005	MAC - Hebrew
10006	MAC - Greek I
10007	MAC - Cyrillic
10008	MAC - Simplified Chinese (GB 2312)
10010	MAC - Romania
10017	MAC - Ukraine
10021	MAC - Thai
10029	MAC - Latin II
10079	MAC - Icelandic
10081	MAC - Turkish
10082	MAC - Croatia
12000	Unicode UCS-4 Little-Endian
12001	Unicode UCS-4 Big-Endian
20000	CNS - Taiwan
20001	TCA - Taiwan
20002	Eten - Taiwan
20003	IBM5550 - Taiwan
20004	TeleText - Taiwan
20005	Wang - Taiwan
20105	IA5 IRV International Alphabet No. 5 (7-bit)
20106	IA5 German (7-bit)
20107	IA5 Swedish (7-bit)
20108	IA5 Norwegian (7-bit)
20127	US-ASCII (7-bit)
20261	T.61
20269	ISO 6937 Non-Spacing Accent
20273	IBM EBCDIC - Germany
20277	IBM EBCDIC - Denmark/Norway
20278	IBM EBCDIC - Finland/Sweden
20280	IBM EBCDIC - Italy
20284	IBM EBCDIC - Latin America/Spain
20285	IBM EBCDIC - United Kingdom
20290	IBM EBCDIC - Japanese Katakana Extended
20297	IBM EBCDIC - France
20420	IBM EBCDIC - Arabic
20423	IBM EBCDIC - Greek
20424	IBM EBCDIC - Hebrew
20833	IBM EBCDIC - Korean Extended
20838	IBM EBCDIC - Thai
20866	Russian - KOI8-R
20871	IBM EBCDIC - Icelandic
20880	IBM EBCDIC - Cyrillic (Russian)
20905	IBM EBCDIC - Turkish
20924	IBM EBCDIC - Latin-1/Open System (1047 + Euro symbol)
20932	JIS X 0208-1990 & 0121-1990
20936	Simplified Chinese (GB2312)
21025	IBM EBCDIC - Cyrillic (Serbian, Bulgarian)
21027	Extended Alpha Lowercase
21866	Ukrainian (KOI8-U)
28591	ISO 8859-1 Latin I
28592	ISO 8859-2 Central Europe
28593	ISO 8859-3 Latin 3
28594	ISO 8859-4 Baltic
28595	ISO 8859-5 Cyrillic
28596	ISO 8859-6 Arabic
28597	ISO 8859-7 Greek
28598	ISO 8859-8 Hebrew
28599	ISO 8859-9 Latin 5
28605	ISO 8859-15 Latin 9
29001	Europa 3
38598	ISO 8859-8 Hebrew
50220	ISO 2022 Japanese with no halfwidth Katakana
50221	ISO 2022 Japanese with halfwidth Katakana
50222	ISO 2022 Japanese JIS X 0201-1989
50225	ISO 2022 Korean
50227	ISO 2022 Simplified Chinese
50229	ISO 2022 Traditional Chinese
50930	Japanese (Katakana) Extended
50931	US/Canada and Japanese
50933	Korean Extended and Korean
50935	Simplified Chinese Extended and Simplified Chinese
50936	Simplified Chinese
50937	US/Canada and Traditional Chinese
50939	Japanese (Latin) Extended and Japanese
51932	EUC - Japanese
51936	EUC - Simplified Chinese
51949	EUC - Korean
51950	EUC - Traditional Chinese
52936	HZ-GB2312 Simplified Chinese
54936	Windows XP: GB18030 Simplified Chinese (4 Byte)
57002	ISCII Devanagari
57003	ISCII Bengali
57004	ISCII Tamil
57005	ISCII Telugu
57006	ISCII Assamese
57007	ISCII Oriya
57008	ISCII Kannada
57009	ISCII Malayalam
57010	ISCII Gujarati
57011	ISCII Punjabi
65000	Unicode UTF-7
65001	Unicode UTF-8

The following is a list of valid code page identifiers for Mac OS only:


Identifier	Name
1	ASCII
2	NEXTSTEP
3	JapaneseEUC
4	UTF8
5	ISOLatin1
6	Symbol
7	NonLossyASCII
8	ShiftJIS
9	ISOLatin2
10	Unicode
11	WindowsCP1251
12	WindowsCP1252
13	WindowsCP1253
14	WindowsCP1254
15	WindowsCP1250
21	ISO2022JP
30	MacOSRoman
10	UTF16String
0x90000100	UTF16BigEndian
0x94000100	UTF16LittleEndian
0x8c000100	UTF32String
0x98000100	UTF32BigEndian
0x9c000100	UTF32LittleEndian
65536	Proprietary

LicenseInfo: Information about the current license.

When queried, this setting will return a string containing information about the license this instance of a class is using. It will return the following information:

Product: The product the license is for.
Product Key: The key the license was generated from.
License Source: Where the license was found (e.g., RuntimeLicense, License File).
License Type: The type of license installed (e.g., Royalty Free, Single Server).
Last Valid Build: The last valid build number for which the license will work.

MaskSensitiveData: Whether sensitive data is masked in log messages.

In certain circumstances it may be beneficial to mask sensitive data, like passwords, in log messages. Set this to true to mask sensitive data. The default is true.

This setting only works on these classes: AS3Receiver, AS3Sender, Atom, Client(3DS), FTP, FTPServer, IMAP, OFTPClient, SSHClient, SCP, Server(3DS), Sexec, SFTP, SFTPServer, SSHServer, TCPClient, TCPServer.

ProcessIdleEvents: Whether the class uses its internal event loop to process events when the main thread is idle.

If set to False, the class will not fire internal idle events. Set this to False to use the class in a background thread on Mac OS. By default, this setting is True.

SelectWaitMillis: The length of time in milliseconds the class will wait when DoEvents is called if there are no events to process.

If there are no events to process when DoEvents is called, the class will wait for the amount of time specified here before returning. The default value is 20.

UseInternalSecurityAPI: Whether or not to use the system security libraries or an internal implementation.

When set to false, the class will use the system security libraries by default to perform cryptographic functions where applicable.

Setting this configuration setting to true tells the class to use the internal implementation instead of using the system security libraries.

On Windows, this setting is set to false by default. On Linux/macOS, this setting is set to true by default.

To use the system security libraries for Linux, OpenSSL support must be enabled. For more information on how to enable OpenSSL, please refer to the OpenSSL Notes section.

Trappable Errors (SMPP Class)

Error Handling (C++)

Call the GetLastErrorCode() method to obtain the last called method's result code; 0 indicates success, while a non-zero error code indicates that this method encountered an error during its execution. Known error codes are listed below. If an error occurs, the GetLastError() method can be called to retrieve the associated error message.

SMPP Errors

620	SMPP protocol error
621	You cannot change this property while connected
622	Server disconnected before responding
623	Field value out of range
624	Unsupported SMPP version
625	Message parameter too long

The class may also return one of the following error codes, which are inherited from other classes.

TCPClient Errors

100	You cannot change the RemotePort at this time. A connection is in progress.
101	You cannot change the RemoteHost (Server) at this time. A connection is in progress.
102	The RemoteHost address is invalid (0.0.0.0).
104	Already connected. If you want to reconnect, close the current connection first.
106	You cannot change the LocalPort at this time. A connection is in progress.
107	You cannot change the LocalHost at this time. A connection is in progress.
112	You cannot change MaxLineLength at this time. A connection is in progress.
116	RemotePort cannot be zero. Please specify a valid service port number.
117	You cannot change the UseConnection option while the class is active.
135	Operation would block.
201	Timeout.
211	Action impossible in control's present state.
212	Action impossible while not connected.
213	Action impossible while listening.
301	Timeout.
302	Could not open file.
434	Unable to convert string to selected CodePage.
1105	Already connecting. If you want to reconnect, close the current connection first.
1117	You need to connect first.
1119	You cannot change the LocalHost at this time. A connection is in progress.
1120	Connection dropped by remote host.

SSL Errors

270	Cannot load specified security library.
271	Cannot open certificate store.
272	Cannot find specified certificate.
273	Cannot acquire security credentials.
274	Cannot find certificate chain.
275	Cannot verify certificate chain.
276	Error during handshake.
280	Error verifying certificate.
281	Could not find client certificate.
282	Could not find server certificate.
283	Error encrypting data.
284	Error decrypting data.

TCP/IP Errors

10004	[10004] Interrupted system call.
10009	[10009] Bad file number.
10013	[10013] Access denied.
10014	[10014] Bad address.
10022	[10022] Invalid argument.
10024	[10024] Too many open files.
10035	[10035] Operation would block.
10036	[10036] Operation now in progress.
10037	[10037] Operation already in progress.
10038	[10038] Socket operation on nonsocket.
10039	[10039] Destination address required.
10040	[10040] Message is too long.
10041	[10041] Protocol wrong type for socket.
10042	[10042] Bad protocol option.
10043	[10043] Protocol is not supported.
10044	[10044] Socket type is not supported.
10045	[10045] Operation is not supported on socket.
10046	[10046] Protocol family is not supported.
10047	[10047] Address family is not supported by protocol family.
10048	[10048] Address already in use.
10049	[10049] Cannot assign requested address.
10050	[10050] Network is down.
10051	[10051] Network is unreachable.
10052	[10052] Net dropped connection or reset.
10053	[10053] Software caused connection abort.
10054	[10054] Connection reset by peer.
10055	[10055] No buffer space available.
10056	[10056] Socket is already connected.
10057	[10057] Socket is not connected.
10058	[10058] Cannot send after socket shutdown.
10059	[10059] Too many references, cannot splice.
10060	[10060] Connection timed out.
10061	[10061] Connection refused.
10062	[10062] Too many levels of symbolic links.
10063	[10063] File name is too long.
10064	[10064] Host is down.
10065	[10065] No route to host.
10066	[10066] Directory is not empty
10067	[10067] Too many processes.
10068	[10068] Too many users.
10069	[10069] Disc Quota Exceeded.
10070	[10070] Stale NFS file handle.
10071	[10071] Too many levels of remote in path.
10091	[10091] Network subsystem is unavailable.
10092	[10092] WINSOCK DLL Version out of range.
10093	[10093] Winsock is not loaded yet.
11001	[11001] Host not found.
11002	[11002] Nonauthoritative 'Host not found' (try again or check DNS setup).
11003	[11003] Nonrecoverable errors: FORMERR, REFUSED, NOTIMP.
11004	[11004] Valid name, no data record (check DNS setup).