SExec Class

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The SExec class is used to remotely execute a command on a Secure Shell (SSH) server.

Syntax

SExec

Remarks

The SExec class establishes a Secure Shell (SSH) connection to a server and starts up the user's default shell. Using the class is very simple. The destination is specified by the SSHHost property, and the login information is given by the SSHUser and SSHPassword properties. To execute the command, simply call the Execute command with the command you wish to execute as the parameter. Further input can be supplied to the Text parameter of the Send method.

The output of the command is returned through the Stdout event. If an error happens on the protocol level, the error message can be found in the ErrorMessage property. Errors during command execution (the stderr stream) are given by the Stderr event. Once the remote command or application terminates, the class will disconnect from the server. If the application's exit status is non-zero (success), the class will throw an exception.

Property List


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

ConnectedThis property shows whether the class is connected.
ErrorMessageThe error message returned by the server along with the ExitStatus .
ExitStatusThe exit code for the last executed command.
FirewallA set of properties related to firewall access.
LocalHostThe name of the local host or user-assigned IP interface through which connections are initiated or accepted.
LocalPortThe TCP port in the local host where the class binds.
SSHAcceptServerHostKeyInstructs the class to accept the server host key that matches the supplied key.
SSHAuthModeThe authentication method to be used with the class when calling SSHLogon .
SSHCertA certificate to be used for authenticating the SSHUser .
SSHCompressionAlgorithmsThe comma-separated list containing all allowable compression algorithms.
SSHEncryptionAlgorithmsThe comma-separated list containing all allowable encryption algorithms.
SSHHostThe address of the Secure Shell (SSH) host.
SSHPasswordThe password for Secure Shell (SSH) password-based authentication.
SSHPortThe port on the Secure Shell (SSH) server where the SSH service is running; by default, 22.
SSHUserThe username for Secure Shell (SSH) authentication.
TimeoutThis property includes the timeout for the class.

Method List


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

ConfigSets or retrieves a configuration setting.
DecodePacketDecodes a hex-encoded Secure Shell (SSH) packet.
DoEventsThis method processes events from the internal message queue.
EncodePacketHex encodes a Secure Shell (SSH) packet.
ExecuteExecutes a specified command on the remote host.
GetSSHParamReads a field from a Secure Shell (SSH) packet's payload.
GetSSHParamBytesReads a field from a Secure Shell (SSH) packet's payload.
InterruptThis method interrupts the current method.
ResetThis method will reset the class.
SendSends standard input to the program executing on the remote host.
SendStdinBytesThis method sends binary data to the remote host.
SendStdinTextThis method sends text to the remote host.
SetSSHParamWrites a field to the end of a payload.
SSHLogoffLogs off from the Secure Shell (SSH) server.
SSHLogonLogs on to the SSHHost using the current SSHUser and SSHPassword .

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.

ConnectedFired immediately after a connection completes (or fails).
ConnectionStatusFired to indicate changes in the connection state.
DisconnectedFired when a connection is closed.
ErrorFired when information is available about errors during data delivery.
LogFired once for each log message.
SSHCustomAuthFired when the class is doing a custom authentication.
SSHKeyboardInteractiveFired when the class receives a request for user input from the server.
SSHServerAuthenticationFired after the server presents its public key to the client.
SSHStatusFired to track the progress of the secure connection.
StderrFired when data (complete lines) come in through stderr.
StdoutFired when data (complete lines) come in through stdout.

Config Settings


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

DisconnectOnChannelCloseWhether to automatically close the connection when a channel is closed.
EncodedTerminalModesThe terminal mode to set when communicating with the SSH host.
StdInFileThe file to use as Stdin data.
TerminalHeightThe height of the terminal display.
TerminalModesThe terminal mode to set when communicating with the SSH host.
TerminalUsePixelWhether the terminal's dimensions are in columns/rows or pixels.
TerminalWidthThe width of the terminal display.
UseTerminalWhether to executes commands within a pseudo-terminal.
ChannelDataEOL[ChannelId]Used to break the incoming data stream into chunks.
ChannelDataEOLFound[ChannelId]Determines if ChannelDataEOL was found.
ClientSSHVersionStringThe SSH version string used by the class.
DoNotRepeatAuthMethodsWhether the class will repeat authentication methods during multifactor authentication.
EnablePageantAuthWhether to use a key stored in Pageant to perform client authentication.
KerberosDelegationIf true, asks for credentials with delegation enabled during authentication.
KerberosRealmThe fully qualified domain name of the Kerberos Realm to use for GSSAPI authentication.
KerberosSPNThe Kerberos Service Principal Name of the SSH host.
KeyRenegotiationThresholdSets the threshold for the SSH Key Renegotiation.
LogLevelSpecifies the level of detail that is logged.
MaxChannelDataLength[ChannelId]The maximum amount of data to accumulate when no ChannelDataEOL is found.
MaxPacketSizeThe maximum packet size of the channel, in bytes.
MaxWindowSizeThe maximum window size allowed for the channel, in bytes.
NegotiatedStrictKexReturns whether strict key exchange was negotiated to be used.
PasswordPromptThe text of the password prompt used in keyboard-interactive authentication.
PreferredDHGroupBitsThe size (in bits) of the preferred modulus (p) to request from the server.
RecordLengthThe length of received data records.
ServerSSHVersionStringThe remote host's SSH version string.
SignedSSHCertThe CA signed client public key used when authenticating.
SSHAcceptAnyServerHostKeyIf set the class will accept any key presented by the server.
SSHAcceptServerCAKeyThe CA public key that signed the server's host key.
SSHAcceptServerHostKeyFingerPrintThe fingerprint of the server key to accept.
SSHFingerprintHashAlgorithmThe algorithm used to calculate the fingerprint.
SSHFingerprintMD5The server hostkey's MD5 fingerprint.
SSHFingerprintSHA1The server hostkey's SHA1 fingerprint.
SSHFingerprintSHA256The server hostkey's SHA256 fingerprint.
SSHKeepAliveCountMaxThe maximum number of keep alive packets to send without a response.
SSHKeepAliveIntervalThe interval between keep alive packets.
SSHKeyExchangeAlgorithmsSpecifies the supported key exchange algorithms.
SSHKeyRenegotiateCauses the class to renegotiate the SSH keys.
SSHMacAlgorithmsSpecifies the supported Mac algorithms.
SSHPubKeyAuthSigAlgorithmsSpecifies the enabled signature algorithms that may be used when attempting public key authentication.
SSHPublicKeyAlgorithmsSpecifies the supported public key algorithms for the server's public key.
SSHVersionPatternThe pattern used to match the remote host's version string.
TryAllAvailableAuthMethodsIf set to true, the class will try all available authentication methods.
UseStrictKeyExchangeSpecifies how strict key exchange is supported.
WaitForChannelCloseWhether to wait for channels to be closed before disconnected.
WaitForServerDisconnectWhether to wait for the server to close the connection.
ConnectionTimeoutSets a separate timeout value for establishing a connection.
FirewallAutoDetectTells the class whether or not to automatically detect and use firewall system settings, if available.
FirewallHostName or IP address of firewall (optional).
FirewallPasswordPassword to be used if authentication is to be used when connecting through the firewall.
FirewallPortThe TCP port for the FirewallHost;.
FirewallTypeDetermines the type of firewall to connect through.
FirewallUserA user name if authentication is to be used connecting through a firewall.
KeepAliveIntervalThe retry interval, in milliseconds, to be used when a TCP keep-alive packet is sent and no response is received.
KeepAliveRetryCountThe number of keep-alive packets to be sent before the remotehost is considered disconnected.
KeepAliveTimeThe inactivity time in milliseconds before a TCP keep-alive packet is sent.
LingerWhen set to True, connections are terminated gracefully.
LingerTimeTime in seconds to have the connection linger.
LocalHostThe name of the local host through which connections are initiated or accepted.
LocalPortThe port in the local host where the class binds.
MaxLineLengthThe maximum amount of data to accumulate when no EOL is found.
MaxTransferRateThe transfer rate limit in bytes per second.
ProxyExceptionsListA semicolon separated list of hosts and IPs to bypass when using a proxy.
TCPKeepAliveDetermines whether or not the keep alive socket option is enabled.
TcpNoDelayWhether or not to delay when sending packets.
UseIPv6Whether to use IPv6.
AbsoluteTimeoutDetermines whether timeouts are inactivity timeouts or absolute timeouts.
FirewallDataUsed to send extra data to the firewall.
InBufferSizeThe size in bytes of the incoming queue of the socket.
OutBufferSizeThe size in bytes of the outgoing queue of the socket.
BuildInfoInformation about the product's build.
CodePageThe system code page used for Unicode to Multibyte translations.
LicenseInfoInformation about the current license.
MaskSensitiveDataWhether sensitive data is masked in log messages.
ProcessIdleEventsWhether the class uses its internal event loop to process events when the main thread is idle.
SelectWaitMillisThe length of time in milliseconds the class will wait when DoEvents is called if there are no events to process.
UseFIPSCompliantAPITells the class whether or not to use FIPS certified APIs.
UseInternalSecurityAPIWhether or not to use the system security libraries or an internal implementation.

Connected Property (SExec Class)

This property shows whether the class is connected.

Syntax

ANSI (Cross Platform)
int GetConnected();

Unicode (Windows)
BOOL GetConnected();
int ipworksssh_sexec_getconnected(void* lpObj);
bool GetConnected();

Default Value

FALSE

Remarks

This property is used to determine whether or not the class is connected to the remote host. Use the SSHLogon and SSHLogoff methods to manage the connection.

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

Data Type

Boolean

ErrorMessage Property (SExec Class)

The error message returned by the server along with the ExitStatus .

Syntax

ANSI (Cross Platform)
char* GetErrorMessage();

Unicode (Windows)
LPWSTR GetErrorMessage();
char* ipworksssh_sexec_geterrormessage(void* lpObj);
QString GetErrorMessage();

Default Value

""

Remarks

After executing a command through Execute, the server will send a notification containing the ExitStatus of the command. The server may also send a textual representation of that code, which will be stored in ErrorMessage.

This property is read-only.

Data Type

String

ExitStatus Property (SExec Class)

The exit code for the last executed command.

Syntax

ANSI (Cross Platform)
int GetExitStatus();

Unicode (Windows)
INT GetExitStatus();
int ipworksssh_sexec_getexitstatus(void* lpObj);
int GetExitStatus();

Default Value

0

Remarks

After executing a command through Execute, the server will send a notification containing the ExitStatus of the command. The server may also send a textual representation of that code, which will be stored in ErrorMessage.

This property is read-only.

Data Type

Integer

Firewall Property (SExec Class)

A set of properties related to firewall access.

Syntax

IPWorksSSHFirewall* GetFirewall();
int SetFirewall(IPWorksSSHFirewall* val);
int ipworksssh_sexec_getfirewallautodetect(void* lpObj);
int ipworksssh_sexec_setfirewallautodetect(void* lpObj, int bFirewallAutoDetect);
int ipworksssh_sexec_getfirewalltype(void* lpObj);
int ipworksssh_sexec_setfirewalltype(void* lpObj, int iFirewallType);
char* ipworksssh_sexec_getfirewallhost(void* lpObj);
int ipworksssh_sexec_setfirewallhost(void* lpObj, const char* lpszFirewallHost);
char* ipworksssh_sexec_getfirewallpassword(void* lpObj);
int ipworksssh_sexec_setfirewallpassword(void* lpObj, const char* lpszFirewallPassword);
int ipworksssh_sexec_getfirewallport(void* lpObj);
int ipworksssh_sexec_setfirewallport(void* lpObj, int iFirewallPort);
char* ipworksssh_sexec_getfirewalluser(void* lpObj);
int ipworksssh_sexec_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

IPWorksSSHFirewall

LocalHost Property (SExec 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* ipworksssh_sexec_getlocalhost(void* lpObj);
int ipworksssh_sexec_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

LocalPort Property (SExec Class)

The TCP port in the local host where the class binds.

Syntax

ANSI (Cross Platform)
int GetLocalPort();
int SetLocalPort(int iLocalPort); Unicode (Windows) INT GetLocalPort();
INT SetLocalPort(INT iLocalPort);
int ipworksssh_sexec_getlocalport(void* lpObj);
int ipworksssh_sexec_setlocalport(void* lpObj, int iLocalPort);
int GetLocalPort();
int SetLocalPort(int iLocalPort);

Default Value

0

Remarks

This property 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 property to 0 (default) enables the system to choose an open port at random. The chosen port will be returned by the LocalPort property after the connection is established.

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

This property is useful when trying to connect to services that require a trusted port on the client side.

Data Type

Integer

SSHAcceptServerHostKey Property (SExec Class)

Instructs the class to accept the server host key that matches the supplied key.

Syntax

IPWorksSSHCertificate* GetSSHAcceptServerHostKey();
int SetSSHAcceptServerHostKey(IPWorksSSHCertificate* val);
char* ipworksssh_sexec_getsshacceptserverhostkeyeffectivedate(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyexpirationdate(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyextendedkeyusage(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyfingerprint(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyfingerprintsha1(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyfingerprintsha256(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyissuer(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyprivatekey(void* lpObj);
int ipworksssh_sexec_getsshacceptserverhostkeyprivatekeyavailable(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyprivatekeycontainer(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeypublickey(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeypublickeyalgorithm(void* lpObj);
int ipworksssh_sexec_getsshacceptserverhostkeypublickeylength(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyserialnumber(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeysignaturealgorithm(void* lpObj);
int ipworksssh_sexec_getsshacceptserverhostkeystore(void* lpObj, char** lpSSHAcceptServerHostKeyStore, int* lenSSHAcceptServerHostKeyStore);
int ipworksssh_sexec_setsshacceptserverhostkeystore(void* lpObj, const char* lpSSHAcceptServerHostKeyStore, int lenSSHAcceptServerHostKeyStore);
char* ipworksssh_sexec_getsshacceptserverhostkeystorepassword(void* lpObj);
int ipworksssh_sexec_setsshacceptserverhostkeystorepassword(void* lpObj, const char* lpszSSHAcceptServerHostKeyStorePassword);
int ipworksssh_sexec_getsshacceptserverhostkeystoretype(void* lpObj);
int ipworksssh_sexec_setsshacceptserverhostkeystoretype(void* lpObj, int iSSHAcceptServerHostKeyStoreType);
char* ipworksssh_sexec_getsshacceptserverhostkeysubjectaltnames(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeythumbprintmd5(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeythumbprintsha1(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeythumbprintsha256(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyusage(void* lpObj);
int ipworksssh_sexec_getsshacceptserverhostkeyusageflags(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeyversion(void* lpObj);
char* ipworksssh_sexec_getsshacceptserverhostkeysubject(void* lpObj);
int ipworksssh_sexec_setsshacceptserverhostkeysubject(void* lpObj, const char* lpszSSHAcceptServerHostKeySubject);
int ipworksssh_sexec_getsshacceptserverhostkeyencoded(void* lpObj, char** lpSSHAcceptServerHostKeyEncoded, int* lenSSHAcceptServerHostKeyEncoded);
int ipworksssh_sexec_setsshacceptserverhostkeyencoded(void* lpObj, const char* lpSSHAcceptServerHostKeyEncoded, int lenSSHAcceptServerHostKeyEncoded);
QString GetSSHAcceptServerHostKeyEffectiveDate();

QString GetSSHAcceptServerHostKeyExpirationDate();

QString GetSSHAcceptServerHostKeyExtendedKeyUsage();

QString GetSSHAcceptServerHostKeyFingerprint();

QString GetSSHAcceptServerHostKeyFingerprintSHA1();

QString GetSSHAcceptServerHostKeyFingerprintSHA256();

QString GetSSHAcceptServerHostKeyIssuer();

QString GetSSHAcceptServerHostKeyPrivateKey();

bool GetSSHAcceptServerHostKeyPrivateKeyAvailable();

QString GetSSHAcceptServerHostKeyPrivateKeyContainer();

QString GetSSHAcceptServerHostKeyPublicKey();

QString GetSSHAcceptServerHostKeyPublicKeyAlgorithm();

int GetSSHAcceptServerHostKeyPublicKeyLength();

QString GetSSHAcceptServerHostKeySerialNumber();

QString GetSSHAcceptServerHostKeySignatureAlgorithm();

QByteArray GetSSHAcceptServerHostKeyStore();
int SetSSHAcceptServerHostKeyStore(QByteArray qbaSSHAcceptServerHostKeyStore); QString GetSSHAcceptServerHostKeyStorePassword();
int SetSSHAcceptServerHostKeyStorePassword(QString qsSSHAcceptServerHostKeyStorePassword); int GetSSHAcceptServerHostKeyStoreType();
int SetSSHAcceptServerHostKeyStoreType(int iSSHAcceptServerHostKeyStoreType); QString GetSSHAcceptServerHostKeySubjectAltNames(); QString GetSSHAcceptServerHostKeyThumbprintMD5(); QString GetSSHAcceptServerHostKeyThumbprintSHA1(); QString GetSSHAcceptServerHostKeyThumbprintSHA256(); QString GetSSHAcceptServerHostKeyUsage(); int GetSSHAcceptServerHostKeyUsageFlags(); QString GetSSHAcceptServerHostKeyVersion(); QString GetSSHAcceptServerHostKeySubject();
int SetSSHAcceptServerHostKeySubject(QString qsSSHAcceptServerHostKeySubject); QByteArray GetSSHAcceptServerHostKeyEncoded();
int SetSSHAcceptServerHostKeyEncoded(QByteArray qbaSSHAcceptServerHostKeyEncoded);

Remarks

If the host key that will be used by the server is known in advance, this property may be set to accept the expected key. Otherwise, the SSHServerAuthentication event should be trapped, and the key should be accepted or refused in the event.

If this property is not set and the SSHServerAuthentication event is not trapped, the server will not be authenticated and the connection will be terminated by the client.

Data Type

IPWorksSSHCertificate

SSHAuthMode Property (SExec Class)

The authentication method to be used with the class when calling SSHLogon .

Syntax

ANSI (Cross Platform)
int GetSSHAuthMode();
int SetSSHAuthMode(int iSSHAuthMode); Unicode (Windows) INT GetSSHAuthMode();
INT SetSSHAuthMode(INT iSSHAuthMode);

Possible Values

AM_NONE(0), 
AM_MULTI_FACTOR(1),
AM_PASSWORD(2),
AM_PUBLIC_KEY(3),
AM_KEYBOARD_INTERACTIVE(4),
AM_GSSAPIWITH_MIC(5),
AM_GSSAPIKEYEX(6),
AM_CUSTOM(99)
int ipworksssh_sexec_getsshauthmode(void* lpObj);
int ipworksssh_sexec_setsshauthmode(void* lpObj, int iSSHAuthMode);
int GetSSHAuthMode();
int SetSSHAuthMode(int iSSHAuthMode);

Default Value

2

Remarks

The Secure Shell (SSH) Authentication specification (RFC 4252) specifies multiple methods by which a user can be authenticated by an SSH server. When a call is made to SSHLogon, the class will connect to the SSH server and establish the security layer. After the connection has been secured, the client will send an authentication request to the SSHHost containing the SSHUser. The server will respond containing a list of methods by which that user may be authenticated.

The class will attempt to authenticate the user by one of those methods based on the value of SSHAuthMode and other property values supplied by the user. Currently, the class supports the following authentication methods:

amNone (0)No authentication will be performed. The current SSHUser value is ignored, and the connection will be logged as anonymous.
amMultiFactor (1)This allows the class to attempt a multistep authentication process. The class will send authentication data to the server based on the list of methods allowed for the current user and the authentication property values supplied. The class will continue to send authentication data until the server acknowledges authentication success. If the server rejects an authentication step, the class fails with an error.
amPassword (2)The class will use the values of SSHUser and SSHPassword to authenticate the user.
amPublicKey (3)The class will use the values of SSHUser and the SSHCert* properties to authenticate the user. the SSHCert* properties must have a private key available for this authentication method to succeed.
amKeyboardInteractive (4)At the time of authentication, the class will fire the SSHKeyboardInteractive event containing instructions on how to complete the authentication step.

Note: amKeyboardInteractive is not supported in SSHTunnel.

amGSSAPIWithMic (5)This allows the class to attempt Kerberos authentication using the GSSAPI-WITH-MIC scheme. The client will try Kerberos authentication using the value of SSHUser (single sign-on), or if SSHPassword is specified as well, it will try Kerberos authentication with alternate credentials. This is currently supported only on Windows, unless using the Java edition, which also provides support for Linux and macOS.
amGSSAPIKeyex (6)This allows the class to attempt Kerberos authentication using the GSSAPIKeyex scheme. The client will try Kerberos authentication using the value of SSHUser (single sign-on), or if SSHPassword is specified as well, it will try Kerberos authentication with alternate credentials. This is currently supported only on Windows, unless using the Java edition, which also provides support for Linux and macOS.
amCustom (99)This allows the class caller to take over the authentication process completely. When amCustom is set, the class will fire the SSHCustomAuth event as necessary to complete the authentication process.

Example 1. User/Password Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPassword Control.SSHUser = "username" Control.SSHPassword = "password" Control.SSHLogon("server", 22) Example 2. Public Key Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPublicKey Control.SSHUser = "username" Control.SSHCertStoreType = SSHCertStoreTypes.cstPFXFile; Control.SSHCertStore = "cert.pfx"; Control.SSHCertStorePassword = "certpassword"; Control.SSHCertSubject = "*"; Control.SSHLogon("server", 22)

Data Type

Integer

SSHCert Property (SExec Class)

A certificate to be used for authenticating the SSHUser .

Syntax

IPWorksSSHCertificate* GetSSHCert();
int SetSSHCert(IPWorksSSHCertificate* val);
char* ipworksssh_sexec_getsshcerteffectivedate(void* lpObj);
char* ipworksssh_sexec_getsshcertexpirationdate(void* lpObj);
char* ipworksssh_sexec_getsshcertextendedkeyusage(void* lpObj);
char* ipworksssh_sexec_getsshcertfingerprint(void* lpObj);
char* ipworksssh_sexec_getsshcertfingerprintsha1(void* lpObj);
char* ipworksssh_sexec_getsshcertfingerprintsha256(void* lpObj);
char* ipworksssh_sexec_getsshcertissuer(void* lpObj);
char* ipworksssh_sexec_getsshcertprivatekey(void* lpObj);
int ipworksssh_sexec_getsshcertprivatekeyavailable(void* lpObj);
char* ipworksssh_sexec_getsshcertprivatekeycontainer(void* lpObj);
char* ipworksssh_sexec_getsshcertpublickey(void* lpObj);
char* ipworksssh_sexec_getsshcertpublickeyalgorithm(void* lpObj);
int ipworksssh_sexec_getsshcertpublickeylength(void* lpObj);
char* ipworksssh_sexec_getsshcertserialnumber(void* lpObj);
char* ipworksssh_sexec_getsshcertsignaturealgorithm(void* lpObj);
int ipworksssh_sexec_getsshcertstore(void* lpObj, char** lpSSHCertStore, int* lenSSHCertStore);
int ipworksssh_sexec_setsshcertstore(void* lpObj, const char* lpSSHCertStore, int lenSSHCertStore);
char* ipworksssh_sexec_getsshcertstorepassword(void* lpObj);
int ipworksssh_sexec_setsshcertstorepassword(void* lpObj, const char* lpszSSHCertStorePassword);
int ipworksssh_sexec_getsshcertstoretype(void* lpObj);
int ipworksssh_sexec_setsshcertstoretype(void* lpObj, int iSSHCertStoreType);
char* ipworksssh_sexec_getsshcertsubjectaltnames(void* lpObj);
char* ipworksssh_sexec_getsshcertthumbprintmd5(void* lpObj);
char* ipworksssh_sexec_getsshcertthumbprintsha1(void* lpObj);
char* ipworksssh_sexec_getsshcertthumbprintsha256(void* lpObj);
char* ipworksssh_sexec_getsshcertusage(void* lpObj);
int ipworksssh_sexec_getsshcertusageflags(void* lpObj);
char* ipworksssh_sexec_getsshcertversion(void* lpObj);
char* ipworksssh_sexec_getsshcertsubject(void* lpObj);
int ipworksssh_sexec_setsshcertsubject(void* lpObj, const char* lpszSSHCertSubject);
int ipworksssh_sexec_getsshcertencoded(void* lpObj, char** lpSSHCertEncoded, int* lenSSHCertEncoded);
int ipworksssh_sexec_setsshcertencoded(void* lpObj, const char* lpSSHCertEncoded, int lenSSHCertEncoded);
QString GetSSHCertEffectiveDate();

QString GetSSHCertExpirationDate();

QString GetSSHCertExtendedKeyUsage();

QString GetSSHCertFingerprint();

QString GetSSHCertFingerprintSHA1();

QString GetSSHCertFingerprintSHA256();

QString GetSSHCertIssuer();

QString GetSSHCertPrivateKey();

bool GetSSHCertPrivateKeyAvailable();

QString GetSSHCertPrivateKeyContainer();

QString GetSSHCertPublicKey();

QString GetSSHCertPublicKeyAlgorithm();

int GetSSHCertPublicKeyLength();

QString GetSSHCertSerialNumber();

QString GetSSHCertSignatureAlgorithm();

QByteArray GetSSHCertStore();
int SetSSHCertStore(QByteArray qbaSSHCertStore); QString GetSSHCertStorePassword();
int SetSSHCertStorePassword(QString qsSSHCertStorePassword); int GetSSHCertStoreType();
int SetSSHCertStoreType(int iSSHCertStoreType); QString GetSSHCertSubjectAltNames(); QString GetSSHCertThumbprintMD5(); QString GetSSHCertThumbprintSHA1(); QString GetSSHCertThumbprintSHA256(); QString GetSSHCertUsage(); int GetSSHCertUsageFlags(); QString GetSSHCertVersion(); QString GetSSHCertSubject();
int SetSSHCertSubject(QString qsSSHCertSubject); QByteArray GetSSHCertEncoded();
int SetSSHCertEncoded(QByteArray qbaSSHCertEncoded);

Remarks

To use public key authentication, SSHCert must contain a Certificate with a valid private key. The certificate's public key value is sent to the server along with a signature produced using the private key. The server will first check to see if the public key values match what is known for the user, and then it will attempt to use those values to verify the signature.

Example 1. User/Password Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPassword Control.SSHUser = "username" Control.SSHPassword = "password" Control.SSHLogon("server", 22) Example 2. Public Key Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPublicKey Control.SSHUser = "username" Control.SSHCertStoreType = SSHCertStoreTypes.cstPFXFile; Control.SSHCertStore = "cert.pfx"; Control.SSHCertStorePassword = "certpassword"; Control.SSHCertSubject = "*"; Control.SSHLogon("server", 22)

Data Type

IPWorksSSHCertificate

SSHCompressionAlgorithms Property (SExec Class)

The comma-separated list containing all allowable compression algorithms.

Syntax

ANSI (Cross Platform)
char* GetSSHCompressionAlgorithms();
int SetSSHCompressionAlgorithms(const char* lpszSSHCompressionAlgorithms); Unicode (Windows) LPWSTR GetSSHCompressionAlgorithms();
INT SetSSHCompressionAlgorithms(LPCWSTR lpszSSHCompressionAlgorithms);
char* ipworksssh_sexec_getsshcompressionalgorithms(void* lpObj);
int ipworksssh_sexec_setsshcompressionalgorithms(void* lpObj, const char* lpszSSHCompressionAlgorithms);
QString GetSSHCompressionAlgorithms();
int SetSSHCompressionAlgorithms(QString qsSSHCompressionAlgorithms);

Default Value

"none,zlib"

Remarks

During the Secure Shell (SSH) handshake, this list will be used to negotiate the compression algorithm to be used between the client and server. This list is used for both directions: client to server and server to client. When negotiating algorithms, each side sends a list of all algorithms it supports or allows. The algorithm chosen for each direction is the first algorithm to appear in the sender's list that the receiver supports. Therefore, it is important to list multiple algorithms in preferential order. If no algorithm can be agreed on, the class will raise an error and the connection will be aborted.

At least one supported algorithm must appear in this list. The following compression algorithms are supported by the class:

  • zlib
  • zlib@openssh.com
  • none

Data Type

String

SSHEncryptionAlgorithms Property (SExec Class)

The comma-separated list containing all allowable encryption algorithms.

Syntax

ANSI (Cross Platform)
char* GetSSHEncryptionAlgorithms();
int SetSSHEncryptionAlgorithms(const char* lpszSSHEncryptionAlgorithms); Unicode (Windows) LPWSTR GetSSHEncryptionAlgorithms();
INT SetSSHEncryptionAlgorithms(LPCWSTR lpszSSHEncryptionAlgorithms);
char* ipworksssh_sexec_getsshencryptionalgorithms(void* lpObj);
int ipworksssh_sexec_setsshencryptionalgorithms(void* lpObj, const char* lpszSSHEncryptionAlgorithms);
QString GetSSHEncryptionAlgorithms();
int SetSSHEncryptionAlgorithms(QString qsSSHEncryptionAlgorithms);

Default Value

"aes256-ctr,aes192-ctr,aes128-ctr,3des-ctr,arcfour256,arcfour128,arcfour,aes256-gcm@openssh.com,aes128-gcm@openssh.com,chacha20-poly1305@openssh.com"

Remarks

During the Secure Shell (SSH) handshake, this list will be used to negotiate the encryption algorithm to be used between the client and server. This list is used for both directions: client to server and server to client. When negotiating algorithms, each side sends a list of all algorithms it supports or allows. The algorithm chosen for each direction is the first algorithm to appear in the sender's list that the receiver supports. Therefore, it is important to list multiple algorithms in preferential order. If no algorithm can be agreed on, the class will raise an error and the connection will be aborted.

At least one supported algorithm must appear in this list. The following encryption algorithms are supported by the class:

aes256-ctr256-bit AES encryption in CTR mode.
aes256-cbc256-bit AES encryption in CBC mode.
aes192-ctr192-bit AES encryption in CTR mode.
aes192-cbc192-bit AES encryption in CBC mode.
aes128-ctr128-bit AES encryption in CTR mode.
aes128-cbc128-bit AES encryption in CBC mode.
3des-ctr192-bit (3-key) triple DES encryption in CTR mode.
3des-cbc192-bit (3-key) triple DES encryption in CBC mode.
cast128-cbcCAST-128 encryption.
blowfish-cbcBlowfish encryption.
arcfourARC4 encryption.
arcfour128128-bit ARC4 encryption.
arcfour256256-bit ARC4 encryption.
aes256-gcm@openssh.com256-bit AES encryption in GCM mode.
aes128-gcm@openssh.com128-bit AES encryption in GCM mode.
chacha20-poly1305@openssh.comChaCha20 with Poly1305-AES encryption.

Data Type

String

SSHHost Property (SExec Class)

The address of the Secure Shell (SSH) host.

Syntax

ANSI (Cross Platform)
char* GetSSHHost();
int SetSSHHost(const char* lpszSSHHost); Unicode (Windows) LPWSTR GetSSHHost();
INT SetSSHHost(LPCWSTR lpszSSHHost);
char* ipworksssh_sexec_getsshhost(void* lpObj);
int ipworksssh_sexec_setsshhost(void* lpObj, const char* lpszSSHHost);
QString GetSSHHost();
int SetSSHHost(QString qsSSHHost);

Default Value

""

Remarks

The SSHHost property specifies the IP address (IP number in dotted internet format) or domain name of the remote host. It is set before a connection is attempted and cannot be changed once a connection is established.

If the SSHHost property is set to a domain name, a DNS request is initiated, and upon successful termination of the request, the SSHHost property is set to the corresponding address. If the search is not successful, an error is returned.

The SSHHost must be the same host that will be assumed for SSH as for the remote service being connected to.

Data Type

String

SSHPassword Property (SExec Class)

The password for Secure Shell (SSH) password-based authentication.

Syntax

ANSI (Cross Platform)
char* GetSSHPassword();
int SetSSHPassword(const char* lpszSSHPassword); Unicode (Windows) LPWSTR GetSSHPassword();
INT SetSSHPassword(LPCWSTR lpszSSHPassword);
char* ipworksssh_sexec_getsshpassword(void* lpObj);
int ipworksssh_sexec_setsshpassword(void* lpObj, const char* lpszSSHPassword);
QString GetSSHPassword();
int SetSSHPassword(QString qsSSHPassword);

Default Value

""

Remarks

SSHPassword specifies the password that is used to authenticate the client to the SSH server.

Data Type

String

SSHPort Property (SExec Class)

The port on the Secure Shell (SSH) server where the SSH service is running; by default, 22.

Syntax

ANSI (Cross Platform)
int GetSSHPort();
int SetSSHPort(int iSSHPort); Unicode (Windows) INT GetSSHPort();
INT SetSSHPort(INT iSSHPort);
int ipworksssh_sexec_getsshport(void* lpObj);
int ipworksssh_sexec_setsshport(void* lpObj, int iSSHPort);
int GetSSHPort();
int SetSSHPort(int iSSHPort);

Default Value

22

Remarks

The SSHPort specifies a service port on the SSH host to connect to.

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

SSHUser Property (SExec Class)

The username for Secure Shell (SSH) authentication.

Syntax

ANSI (Cross Platform)
char* GetSSHUser();
int SetSSHUser(const char* lpszSSHUser); Unicode (Windows) LPWSTR GetSSHUser();
INT SetSSHUser(LPCWSTR lpszSSHUser);
char* ipworksssh_sexec_getsshuser(void* lpObj);
int ipworksssh_sexec_setsshuser(void* lpObj, const char* lpszSSHUser);
QString GetSSHUser();
int SetSSHUser(QString qsSSHUser);

Default Value

""

Remarks

SSHUser specifies the username that is used to authenticate the client to the SSH server. This property is required.

Example 1. User/Password Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPassword Control.SSHUser = "username" Control.SSHPassword = "password" Control.SSHLogon("server", 22) Example 2. Public Key Authentication: Control.SSHAuthMode = SftpSSHAuthModes.amPublicKey Control.SSHUser = "username" Control.SSHCertStoreType = SSHCertStoreTypes.cstPFXFile; Control.SSHCertStore = "cert.pfx"; Control.SSHCertStorePassword = "certpassword"; Control.SSHCertSubject = "*"; Control.SSHLogon("server", 22)

Data Type

String

Timeout Property (SExec Class)

This property includes the timeout for the class.

Syntax

ANSI (Cross Platform)
int GetTimeout();
int SetTimeout(int iTimeout); Unicode (Windows) INT GetTimeout();
INT SetTimeout(INT iTimeout);
int ipworksssh_sexec_gettimeout(void* lpObj);
int ipworksssh_sexec_settimeout(void* lpObj, int iTimeout);
int GetTimeout();
int SetTimeout(int iTimeout);

Default Value

60

Remarks

If the Timeout property is set to 0, all operations return immediately, potentially failing with a WOULDBLOCK error if data cannot be sent immediately.

If Timeout is set to a positive value, data is sent in a blocking manner and the class will wait for the operation to complete before returning control. The class will handle any potential WOULDBLOCK errors internally and automatically retry the operation for a maximum of Timeout seconds.

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

Config Method (SExec Class)

Sets or retrieves a configuration setting.

Syntax

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

Unicode (Windows)
LPWSTR Config(LPCWSTR lpszConfigurationString);
char* ipworksssh_sexec_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.

DecodePacket Method (SExec Class)

Decodes a hex-encoded Secure Shell (SSH) packet.

Syntax

ANSI (Cross Platform)
char* DecodePacket(const char* lpszEncodedPacket, int *lpSize = NULL);

Unicode (Windows)
LPSTR DecodePacket(LPCWSTR lpszEncodedPacket, LPINT lpSize = NULL);
char* ipworksssh_sexec_decodepacket(void* lpObj, const char* lpszEncodedPacket, int *lpSize);
QByteArray DecodePacket(const QString& qsEncodedPacket);

Remarks

This method is used to decode an SSH packet created by EncodePacket.

Note: This method is applicable only for reading and creating Secure Shell (SSH) packets for use within the SSHCustomAuth event.

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.

DoEvents Method (SExec Class)

This method processes events from the internal message queue.

Syntax

ANSI (Cross Platform)
int DoEvents();

Unicode (Windows)
INT DoEvents();
int ipworksssh_sexec_doevents(void* lpObj);
int DoEvents();

Remarks

When DoEvents 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++)

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.)

EncodePacket Method (SExec Class)

Hex encodes a Secure Shell (SSH) packet.

Syntax

ANSI (Cross Platform)
char* EncodePacket(const char* lpPacket, int lenPacket);

Unicode (Windows)
LPWSTR EncodePacket(LPCSTR lpPacket, INT lenPacket);
char* ipworksssh_sexec_encodepacket(void* lpObj, const char* lpPacket, int lenPacket);
QString EncodePacket(QByteArray qbaPacket);

Remarks

This method is used to encode a raw SSH packet created by SetSSHParam.

Note: This method is applicable only for reading and creating Secure Shell (SSH) packets for use within the SSHCustomAuth event.

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.

Execute Method (SExec Class)

Executes a specified command on the remote host.

Syntax

ANSI (Cross Platform)
int Execute(const char* lpszCommand);

Unicode (Windows)
INT Execute(LPCWSTR lpszCommand);
int ipworksssh_sexec_execute(void* lpObj, const char* lpszCommand);
int Execute(const QString& qsCommand);

Remarks

This method executes a Command on the remote host.

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.)

GetSSHParam Method (SExec Class)

Reads a field from a Secure Shell (SSH) packet's payload.

Syntax

ANSI (Cross Platform)
char* GetSSHParam(const char* lpPayload, int lenPayload, const char* lpszField);

Unicode (Windows)
LPWSTR GetSSHParam(LPCSTR lpPayload, INT lenPayload, LPCWSTR lpszField);
char* ipworksssh_sexec_getsshparam(void* lpObj, const char* lpPayload, int lenPayload, const char* lpszField);
QString GetSSHParam(QByteArray qbaPayload, const QString& qsField);

Remarks

This method is used to read the value of a particular field from an SSH packet's payload. Payload should contain the full payload of a packet received by an event such as SSHChannelRequest. Field is the name of a field to be read out of the packet.

The following is a list of the names of well-known channel request field names and their encodings:

ChannelId (int32)The Id of the channel that received the packet.
RequestType (string)The type of channel requested.
WantsReply (boolean)Whether or not the client wants a reply to the request.

The remaining fields that are available in the payload are dependent on the value of RequestType.

pty-req

Pty-req is a request to open a pseudo terminal on the specified channel. The following fields are available:

TerminalType (string)The type of terminal being requested (e.g., "vt100").
TerminalWidthCharacters (int32)The width, in characters, of the terminal to be opened.
TerminalHeightRows (int32)The height, in rows, of the terminal to be opened.
TerminalWidthPixels (int32)The width, in pixels, of the terminal to be opened.
TerminalHeightPixels (int32)The height, in pixels, of the terminal to be opened.
TerminalModes (string)A list of op-val (int32-byte) encoded modes to be used by the terminal.

x11-req

X11-req is a request to forward x11 sessions over a channel. The following fields are available:

SingleConnection (boolean)Disallows more than one connection to be forwarded by the channel.
X11AuthProtocol (string)The authentication protocol to be used (e.g., "MIT-MAGIC-COOKIE-1").
X11AuthCookie (string)A hexadecimal-encoded cookie to be used for authentication.
X11ScreenNumber (int32)The x11 screen number to be used.

env

Env is a request to set an environment variable to be passed into a shell that may be started later. The following fields are available:

VariableName (string)The name of the variable to be set.
VariableValue (string)The value of the variable to be set.

exec

Exec is a request to execute a command on the channel using the authenticated user's shell. The following field is available:

Command (string)The command to be executed.

subsystem

Subsystem is a request to start a subsystem on the specified channel. The following field is available:

Subsystem (string)The name of the subsystem to be started (e.g., "sftp").

xon-xoff

Xon-xoff instructs the server to allow or disallow control-S/control-Q style flow control. The following field is available:

ClientCanDo (boolean)Whether or not the server should enable flow control.

signal

Sends a signal to the remote process/service. The following field is available:

SignalName (string)The name of the signal to be sent.

If the packet type is not well known, Field should start with the special character "%" and contain a comma-separated list of field types as defined in SetSSHParam. For example, reading out the X11AuthProtocol of an x11-req payload, you can use "%s,f".

Note: The return value is a string encoded the same way as the FieldValue param in SetSSHParam.

Note: This method is applicable only for reading and creating Secure Shell (SSH) packets for use within the SSHCustomAuth event.

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.

GetSSHParamBytes Method (SExec Class)

Reads a field from a Secure Shell (SSH) packet's payload.

Syntax

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

Unicode (Windows)
LPSTR GetSSHParamBytes(LPCSTR lpPayload, INT lenPayload, LPCWSTR lpszField, LPINT lpSize = NULL);
char* ipworksssh_sexec_getsshparambytes(void* lpObj, const char* lpPayload, int lenPayload, const char* lpszField, int *lpSize);
QByteArray GetSSHParamBytes(QByteArray qbaPayload, const QString& qsField);

Remarks

This method is the same as calling GetSSHParam, but it returns raw bytes instead of strings.

Note: This method is applicable only for reading and creating Secure Shell (SSH) packets for use within the SSHCustomAuth event.

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.

Interrupt Method (SExec Class)

This method interrupts the current method.

Syntax

ANSI (Cross Platform)
int Interrupt();

Unicode (Windows)
INT Interrupt();
int ipworksssh_sexec_interrupt(void* lpObj);
int Interrupt();

Remarks

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

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.)

Reset Method (SExec Class)

This method will reset the class.

Syntax

ANSI (Cross Platform)
int Reset();

Unicode (Windows)
INT Reset();
int ipworksssh_sexec_reset(void* lpObj);
int Reset();

Remarks

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

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.)

Send Method (SExec Class)

Sends standard input to the program executing on the remote host.

Syntax

ANSI (Cross Platform)
int Send(const char* lpText, int lenText);

Unicode (Windows)
INT Send(LPCSTR lpText, INT lenText);
int ipworksssh_sexec_send(void* lpObj, const char* lpText, int lenText);
int Send(QByteArray qbaText);

Remarks

This method sends standard input to the program executing on the remote host.

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.)

SendStdinBytes Method (SExec Class)

This method sends binary data to the remote host.

Syntax

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

Unicode (Windows)
INT SendStdinBytes(LPCSTR lpData, INT lenData);
int ipworksssh_sexec_sendstdinbytes(void* lpObj, const char* lpData, int lenData);
int SendStdinBytes(QByteArray qbaData);

Remarks

This method sends the specified binary data to the remote host. The data provided are used as input for the process on the remote host. To send text, use the SendStdinText method instead.

If you are sending data to the remote host faster than it can process it, or faster than the network bandwidth allows, the outgoing queue might fill up. When this happens the class fails with error 10035: "[10035] Operation would block" (WSAEWOULDBLOCK). You can check this error, and then try to send the data again. .

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.)

SendStdinText Method (SExec Class)

This method sends text to the remote host.

Syntax

ANSI (Cross Platform)
int SendStdinText(const char* lpszText);

Unicode (Windows)
INT SendStdinText(LPCWSTR lpszText);
int ipworksssh_sexec_sendstdintext(void* lpObj, const char* lpszText);
int SendStdinText(const QString& qsText);

Remarks

This method sends the specified text to the remote host. The text provided is used as an input for the process on the remote host. To send binary data, use the SendStdinBytes method instead.

If you are sending data to the remote host faster than it can process it, or faster than the network bandwidth allows, the outgoing queue might fill up. When this happens the class fails with error 10035: "[10035] Operation would block" (WSAEWOULDBLOCK). You can check this error, and then try to send the data again. .

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.)

SetSSHParam Method (SExec Class)

Writes a field to the end of a payload.

Syntax

ANSI (Cross Platform)
char* SetSSHParam(const char* lpPayload, int lenPayload, const char* lpszFieldType, const char* lpszFieldValue, int *lpSize = NULL);

Unicode (Windows)
LPSTR SetSSHParam(LPCSTR lpPayload, INT lenPayload, LPCWSTR lpszFieldType, LPCWSTR lpszFieldValue, LPINT lpSize = NULL);
char* ipworksssh_sexec_setsshparam(void* lpObj, const char* lpPayload, int lenPayload, const char* lpszFieldType, const char* lpszFieldValue, int *lpSize);
QByteArray SetSSHParam(QByteArray qbaPayload, const QString& qsFieldType, const QString& qsFieldValue);

Remarks

This method is used to build the payload portion of a Secure Shell (SSH) packet to be sent later by a call to SendSSHPacket. Payload should contain the result of a previous call to SetSSHParam. FieldType is a string defining the type of field to be written to the packet. FieldValue should be the string representation of the field to be written.

The following is a list of supported field types and a description of how FieldValue should be encoded:

sA plaintext string containing the default system encoding of the data.
sbA string containing the hex-encoded data (e.g., "A1B23C")
mA variable-length large integer, encoded as a textual representation of the value (e.g., "1234").
iA 32-bit integer, encoded as a textual representation of the value (e.g., "1234").
lA 64-bit integer, encoded as a textual representation of the value (e.g., "1234").
bA single byte, encoded as a textual representation of the value (e.g., "123").
fA boolean flag, encoded as a textual representation of the value (e.g., 'True' or 'False')

Note: Integer values may be hexadecimal encoded by prefixing "0x" to the beginning of the string; otherwise, the value is assumed to be Base10.

Note: This method is applicable only for reading and creating Secure Shell (SSH) packets for use within the SSHCustomAuth event.

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.

SSHLogoff Method (SExec Class)

Logs off from the Secure Shell (SSH) server.

Syntax

ANSI (Cross Platform)
int SSHLogoff();

Unicode (Windows)
INT SSHLogoff();
int ipworksssh_sexec_sshlogoff(void* lpObj);
int SSHLogoff();

Remarks

Logs off from the SSH server. If that fails, the connection is terminated by the local host.

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.)

SSHLogon Method (SExec Class)

Logs on to the SSHHost using the current SSHUser and SSHPassword .

Syntax

ANSI (Cross Platform)
int SSHLogon(const char* lpszSSHHost, int iSSHPort);

Unicode (Windows)
INT SSHLogon(LPCWSTR lpszSSHHost, INT iSSHPort);
int ipworksssh_sexec_sshlogon(void* lpObj, const char* lpszSSHHost, int iSSHPort);
int SSHLogon(const QString& qsSSHHost, int iSSHPort);

Remarks

Logs on to the Secure Shell (SSH) server using the current SSHUser and SSHPassword. This will perform the SSH handshake and authentication.

Example. Logging On:

SSHClient.SSHUser = "username" SSHClient.SSHPassword = "password" SSHClient.SSHLogon("sshHost", sshPort)

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.)

Connected Event (SExec Class)

Fired immediately after a connection completes (or fails).

Syntax

ANSI (Cross Platform)
virtual int FireConnected(SExecConnectedEventParams *e);
typedef struct {
int StatusCode;
const char *Description; int reserved; } SExecConnectedEventParams;
Unicode (Windows) virtual INT FireConnected(SExecConnectedEventParams *e);
typedef struct {
INT StatusCode;
LPCWSTR Description; INT reserved; } SExecConnectedEventParams;
#define EID_SEXEC_CONNECTED 1

virtual INT IPWORKSSSH_CALL FireConnected(INT &iStatusCode, LPSTR &lpszDescription);
class SExecConnectedEventParams {
public:
  int StatusCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Connected(SExecConnectedEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireConnected(SExecConnectedEventParams *e) {...}

Remarks

If the connection is made normally, StatusCode is 0 and Description is "OK".

If the connection fails, 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.

Please refer to the Error Codes section for more information.

ConnectionStatus Event (SExec Class)

Fired to indicate changes in the connection state.

Syntax

ANSI (Cross Platform)
virtual int FireConnectionStatus(SExecConnectionStatusEventParams *e);
typedef struct {
const char *ConnectionEvent;
int StatusCode;
const char *Description; int reserved; } SExecConnectionStatusEventParams;
Unicode (Windows) virtual INT FireConnectionStatus(SExecConnectionStatusEventParams *e);
typedef struct {
LPCWSTR ConnectionEvent;
INT StatusCode;
LPCWSTR Description; INT reserved; } SExecConnectionStatusEventParams;
#define EID_SEXEC_CONNECTIONSTATUS 2

virtual INT IPWORKSSSH_CALL FireConnectionStatus(LPSTR &lpszConnectionEvent, INT &iStatusCode, LPSTR &lpszDescription);
class SExecConnectionStatusEventParams {
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(SExecConnectionStatusEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireConnectionStatus(SExecConnectionStatusEventParams *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 (SExec Class)

Fired when a connection is closed.

Syntax

ANSI (Cross Platform)
virtual int FireDisconnected(SExecDisconnectedEventParams *e);
typedef struct {
int StatusCode;
const char *Description; int reserved; } SExecDisconnectedEventParams;
Unicode (Windows) virtual INT FireDisconnected(SExecDisconnectedEventParams *e);
typedef struct {
INT StatusCode;
LPCWSTR Description; INT reserved; } SExecDisconnectedEventParams;
#define EID_SEXEC_DISCONNECTED 3

virtual INT IPWORKSSSH_CALL FireDisconnected(INT &iStatusCode, LPSTR &lpszDescription);
class SExecDisconnectedEventParams {
public:
  int StatusCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Disconnected(SExecDisconnectedEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireDisconnected(SExecDisconnectedEventParams *e) {...}

Remarks

If the connection is broken normally, StatusCode is 0 and Description is "OK".

If the connection is broken for any other reason, StatusCode has the error code returned by the Transmission Control Protocol (TCP/IP) subsystem. Description contains a description of this code. The value of StatusCode is equal to the value of the TCP/IP error.

Please refer to the Error Codes section for more information.

Error Event (SExec Class)

Fired when information is available about errors during data delivery.

Syntax

ANSI (Cross Platform)
virtual int FireError(SExecErrorEventParams *e);
typedef struct {
int ErrorCode;
const char *Description; int reserved; } SExecErrorEventParams;
Unicode (Windows) virtual INT FireError(SExecErrorEventParams *e);
typedef struct {
INT ErrorCode;
LPCWSTR Description; INT reserved; } SExecErrorEventParams;
#define EID_SEXEC_ERROR 4

virtual INT IPWORKSSSH_CALL FireError(INT &iErrorCode, LPSTR &lpszDescription);
class SExecErrorEventParams {
public:
  int ErrorCode();

  const QString &Description();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Error(SExecErrorEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireError(SExecErrorEventParams *e) {...}

Remarks

The Error event is fired in case of exceptional conditions during message processing. Normally the class fails with an error.

The ErrorCode parameter contains an error code, and the Description parameter contains a textual description of the error. For a list of valid error codes and their descriptions, please refer to the Error Codes section.

Log Event (SExec Class)

Fired once for each log message.

Syntax

ANSI (Cross Platform)
virtual int FireLog(SExecLogEventParams *e);
typedef struct {
int LogLevel;
const char *Message;
const char *LogType; int reserved; } SExecLogEventParams;
Unicode (Windows) virtual INT FireLog(SExecLogEventParams *e);
typedef struct {
INT LogLevel;
LPCWSTR Message;
LPCWSTR LogType; INT reserved; } SExecLogEventParams;
#define EID_SEXEC_LOG 5

virtual INT IPWORKSSSH_CALL FireLog(INT &iLogLevel, LPSTR &lpszMessage, LPSTR &lpszLogType);
class SExecLogEventParams {
public:
  int LogLevel();

  const QString &Message();

  const QString &LogType();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Log(SExecLogEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireLog(SExecLogEventParams *e) {...}

Remarks

Fired once for each log message generated by the class. The verbosity is controlled by the LogLevel setting.

LogLevel indicates the detail level of the message. Possible values are as follows:

0 (None) No messages are logged.
1 (Info - Default) Informational events such as Secure Shell (SSH) handshake messages are logged.
2 (Verbose) Detailed data such as individual packet information are logged.
3 (Debug) Debug data including all relevant sent and received bytes are logged.

Message is the log message.

LogType is reserved for future use.

SSHCustomAuth Event (SExec Class)

Fired when the class is doing a custom authentication.

Syntax

ANSI (Cross Platform)
virtual int FireSSHCustomAuth(SExecSSHCustomAuthEventParams *e);
typedef struct {
char *Packet; int reserved; } SExecSSHCustomAuthEventParams;
Unicode (Windows) virtual INT FireSSHCustomAuth(SExecSSHCustomAuthEventParams *e);
typedef struct {
LPWSTR Packet; INT reserved; } SExecSSHCustomAuthEventParams;
#define EID_SEXEC_SSHCUSTOMAUTH 6

virtual INT IPWORKSSSH_CALL FireSSHCustomAuth(LPSTR &lpszPacket);
class SExecSSHCustomAuthEventParams {
public:
  const QString &Packet();
  void SetPacket(const QString &qsPacket);

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void SSHCustomAuth(SExecSSHCustomAuthEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireSSHCustomAuth(SExecSSHCustomAuthEventParams *e) {...}

Remarks

SSHCustomAuth is fired during the user authentication stage of the Secure Shell (SSH) logon process if SSHAuthMode is set to amCustom. Packet contains the last raw SSH packet sent by the server, in HEX-encoded format.

The client should create a new raw SSH packet to send to the server and set Packet to the HEX-encoded representation of the packet to send.

In all cases, Packet will start with the message type field.

To read the incoming packet, call DecodePacket and then use the GetSSHParam and GetSSHParamBytes methods. To create a packet, use the SetSSHParam method and then call EncodePacket to obtain a HEX-encoded value and assign this to the Packet parameter.

SSHKeyboardInteractive Event (SExec Class)

Fired when the class receives a request for user input from the server.

Syntax

ANSI (Cross Platform)
virtual int FireSSHKeyboardInteractive(SExecSSHKeyboardInteractiveEventParams *e);
typedef struct {
const char *Name;
const char *Instructions;
const char *Prompt;
char *Response;
int EchoResponse; int reserved; } SExecSSHKeyboardInteractiveEventParams;
Unicode (Windows) virtual INT FireSSHKeyboardInteractive(SExecSSHKeyboardInteractiveEventParams *e);
typedef struct {
LPCWSTR Name;
LPCWSTR Instructions;
LPCWSTR Prompt;
LPWSTR Response;
BOOL EchoResponse; INT reserved; } SExecSSHKeyboardInteractiveEventParams;
#define EID_SEXEC_SSHKEYBOARDINTERACTIVE 7

virtual INT IPWORKSSSH_CALL FireSSHKeyboardInteractive(LPSTR &lpszName, LPSTR &lpszInstructions, LPSTR &lpszPrompt, LPSTR &lpszResponse, BOOL &bEchoResponse);
class SExecSSHKeyboardInteractiveEventParams {
public:
  const QString &Name();

  const QString &Instructions();

  const QString &Prompt();

  const QString &Response();
  void SetResponse(const QString &qsResponse);

  bool EchoResponse();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void SSHKeyboardInteractive(SExecSSHKeyboardInteractiveEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireSSHKeyboardInteractive(SExecSSHKeyboardInteractiveEventParams *e) {...}

Remarks

SSHKeyboardInteractive is fired during the user authentication stage of the Secure Shell (SSH) logon process. During authentication, the class will request a list of available authentication methods for the SSHUser. For example, if the SSHHost responds with "keyboard-interactive", the class will fire this event to allow the client application to set the password.

During authentication, the SSH server may respond with a request for the user's authentication information. Name is a server-provided value associated with the authentication method such as "CRYPTOCard Authentication". Instructions will contain specific instructions, also supplied by the server, for how the user should respond.

Along with these values, the server will also send at least one input Prompt to be displayed to and filled out by the user. Response should be set to the user's input, and will be sent back in the user authentication information response. EchoResponse is a server recommendation for whether or not the user's response should be echoed back during input.

Note: The server may send several prompts in a single packet. The class will fire the SSHKeyboardInteractive event once for each prompt.

SSHServerAuthentication Event (SExec Class)

Fired after the server presents its public key to the client.

Syntax

ANSI (Cross Platform)
virtual int FireSSHServerAuthentication(SExecSSHServerAuthenticationEventParams *e);
typedef struct {
const char *HostKey; int lenHostKey;
const char *Fingerprint;
const char *KeyAlgorithm;
const char *CertSubject;
const char *CertIssuer;
const char *Status;
int Accept; int reserved; } SExecSSHServerAuthenticationEventParams;
Unicode (Windows) virtual INT FireSSHServerAuthentication(SExecSSHServerAuthenticationEventParams *e);
typedef struct {
LPCSTR HostKey; INT lenHostKey;
LPCWSTR Fingerprint;
LPCWSTR KeyAlgorithm;
LPCWSTR CertSubject;
LPCWSTR CertIssuer;
LPCWSTR Status;
BOOL Accept; INT reserved; } SExecSSHServerAuthenticationEventParams;
#define EID_SEXEC_SSHSERVERAUTHENTICATION 8

virtual INT IPWORKSSSH_CALL FireSSHServerAuthentication(LPSTR &lpHostKey, INT &lenHostKey, LPSTR &lpszFingerprint, LPSTR &lpszKeyAlgorithm, LPSTR &lpszCertSubject, LPSTR &lpszCertIssuer, LPSTR &lpszStatus, BOOL &bAccept);
class SExecSSHServerAuthenticationEventParams {
public:
  const QByteArray &HostKey();

  const QString &Fingerprint();

  const QString &KeyAlgorithm();

  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 SSHServerAuthentication(SExecSSHServerAuthenticationEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireSSHServerAuthentication(SExecSSHServerAuthenticationEventParams *e) {...}

Remarks

This event is fired when the client can decide whether or not to continue with the connection process. If the public key is known to be a valid key for the Secure Shell (SSH) server, Accept should be set to True within the event. Otherwise, the server will not be authenticated and the connection will be broken.

Accept will be True only if either HostKey or Fingerprint is identical to the value of SSHAcceptServerHostKey.

Accept may be set to True manually to accept the server host key.

Note: SSH's security inherently relies on client verification of the host key. Ignoring the host key and always setting Accept to True is strongly discouraged, and could cause potentially serious security vulnerabilities in your application. It is recommended that clients maintain a list of known keys for each server and check HostKey against this list each time a connection is attempted.

Host Key contains the full binary text of the key, in the same format used internally by SSH.

Fingerprint holds the SHA-256 hash of HostKey in the hex-encoded form: 0a:1b:2c:3d. To configure the hash algorithm used to calculate this value, see SSHFingerprintHashAlgorithm.

KeyAlgorithm identifies the host key algorithm. The following values are supported:

  • ssh-rsa
  • ssh-dss
  • rsa-sha2-256
  • rsa-sha2-512
  • x509v3-sign-rsa
  • x509v3-sign-dss
  • ecdsa-sha2-nistp256
  • ecdsa-sha2-nistp384
  • ecdsa-sha2-nistp521
To limit the accepted host key algorithms, refer to SSHPublicKeyAlgorithms.

CertSubject is the subject of the certificate. This is applicable only when KeyAlgorithm is "x509v3-sign-rsa" or "x509v3-sign-dss".

CertIssuer is the issuer of the certificate. This is applicable only when KeyAlgorithm is "x509v3-sign-rsa" or "x509v3-sign-dss".

Status is reserved for future use.

SSHStatus Event (SExec Class)

Fired to track the progress of the secure connection.

Syntax

ANSI (Cross Platform)
virtual int FireSSHStatus(SExecSSHStatusEventParams *e);
typedef struct {
const char *Message; int reserved; } SExecSSHStatusEventParams;
Unicode (Windows) virtual INT FireSSHStatus(SExecSSHStatusEventParams *e);
typedef struct {
LPCWSTR Message; INT reserved; } SExecSSHStatusEventParams;
#define EID_SEXEC_SSHSTATUS 9

virtual INT IPWORKSSSH_CALL FireSSHStatus(LPSTR &lpszMessage);
class SExecSSHStatusEventParams {
public:
  const QString &Message();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void SSHStatus(SExecSSHStatusEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireSSHStatus(SExecSSHStatusEventParams *e) {...}

Remarks

The event is fired for informational and logging purposes only. Used to track the progress of the connection.

Stderr Event (SExec Class)

Fired when data (complete lines) come in through stderr.

Syntax

ANSI (Cross Platform)
virtual int FireStderr(SExecStderrEventParams *e);
typedef struct {
const char *Text; int lenText; int reserved; } SExecStderrEventParams;
Unicode (Windows) virtual INT FireStderr(SExecStderrEventParams *e);
typedef struct {
LPCSTR Text; INT lenText; INT reserved; } SExecStderrEventParams;
#define EID_SEXEC_STDERR 10

virtual INT IPWORKSSSH_CALL FireStderr(LPSTR &lpText, INT &lenText);
class SExecStderrEventParams {
public:
  const QByteArray &Text();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Stderr(SExecStderrEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireStderr(SExecStderrEventParams *e) {...}

Remarks

The Stderr event is fired every time the process on the remote host outputs a line in its error output. The incoming data are provided through the Text parameter.

Stdout Event (SExec Class)

Fired when data (complete lines) come in through stdout.

Syntax

ANSI (Cross Platform)
virtual int FireStdout(SExecStdoutEventParams *e);
typedef struct {
const char *Text; int lenText; int reserved; } SExecStdoutEventParams;
Unicode (Windows) virtual INT FireStdout(SExecStdoutEventParams *e);
typedef struct {
LPCSTR Text; INT lenText; INT reserved; } SExecStdoutEventParams;
#define EID_SEXEC_STDOUT 11

virtual INT IPWORKSSSH_CALL FireStdout(LPSTR &lpText, INT &lenText);
class SExecStdoutEventParams {
public:
  const QByteArray &Text();

  int EventRetVal();
  void SetEventRetVal(int iRetVal);
};
// To handle, connect one or more slots to this signal. void Stdout(SExecStdoutEventParams *e);
// Or, subclass SExec and override this emitter function. virtual int FireStdout(SExecStdoutEventParams *e) {...}

Remarks

The Stdout event is fired every time the process on the remote host outputs a line in its standard output. The incoming data are provided through the Text parameter.

Certificate Type

This is the digital certificate being used.

Syntax

IPWorksSSHCertificate (declared in ipworksssh.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:

MYA certificate store holding personal certificates with their associated private keys.
CACertifying authority certificates.
ROOTRoot 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:

0x80Digital Signature
0x40Non-Repudiation
0x20Key Encipherment
0x10Data Encipherment
0x08Key Agreement
0x04Certificate Signing
0x02CRL Signing
0x01Encipher 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:

FieldMeaning
CNCommon Name. This is commonly a hostname like www.server.com.
OOrganization
OUOrganizational Unit
LLocality
SState
CCountry
EEmail 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

IPWorksSSHFirewall (declared in ipworksssh.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()

Config Settings (SExec 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.

SExec Config Settings

DisconnectOnChannelClose:   Whether to automatically close the connection when a channel is closed.

If this is True, then any time a channel is closed, the connection will close as well. When False, the connection will remain open any time a channel is closed.

Default is False.

EncodedTerminalModes:   The terminal mode to set when communicating with the SSH host.

This configuration setting may be set to specify a terminal mode when communicating with the SSH host. This will automatically be set if TerminalModes is set. This is provided as an alternative to TerminalModes, as follows:

class.Config("EncodedTerminalModes=" + Encoding.Default.GetString(new byte[] { 53,0,0,0,0,0 })"); In this example, the first byte is the opcode (53 for echo). The next 4 bytes represent the opcode value, which is a uint 32. The last byte is always a null character to end the string. This example sets echo to off just as in the example for TerminalModes.

StdInFile:   The file to use as Stdin data.

This configuration setting provides the contents of a file as the Stdin input to the SSH server. Set this to the full path and name of the target file.

TerminalHeight:   The height of the terminal display.

When a connection to the SSH server is made, this option specifies the height of the terminal's display in rows.

TerminalModes:   The terminal mode to set when communicating with the SSH host.

This configuration setting may be set to specify one or more terminal modes when communicating with the Secure Shell (SSH) host. The values are passed as a comma-separated list of opcode=value pairs, as follows:

class.Config("TerminalModes=53=0"); In this example, 53 is the opcode (for echo) and the value is 0. So this sets echo to off.

TerminalUsePixel:   Whether the terminal's dimensions are in columns/rows or pixels.

When this option is True, the TerminalHeight and TerminalWidth configuration options are in pixels instead of columns and rows. The default is False.

TerminalWidth:   The width of the terminal display.

When a connection to the SSH server is made, this option specifies the width of the terminal's display in columns.

UseTerminal:   Whether to executes commands within a pseudo-terminal.

If set to true, the class will create a pseudo-terminal (pty-req) and will execute commands within this terminal. When SSHLogoff is called, any ongoing processes will be terminated by the server. If set to false (default), commands are not executed within a terminal and any ongoing processes will continue to run even after SSHLogoff is called.

SSHClient Config Settings

ChannelDataEOL[ChannelId]:   Used to break the incoming data stream into chunks.

By default MaxChannelDataLength is 0 and ChannelDataEOL is an empty string. SSHChannelData fires whenever an SSH_MSG_CHANNEL_DATA packet is received.

If MaxChannelDataLength is greater than 0 and ChannelDataEOL is a nonempty string, the class will internally buffer data waiting to fire SSHChannelData until either MaxChannelDataLength is reached or ChannelDataEOL is found, whichever comes first. Query ChannelDataEOLFound to know which condition was met. The buffer is reset any time SSHChannelData fires.

ChannelDataEOL and MaxChannelDataLength must be set together or unexpected behavior could occur.

ChannelDataEOLFound[ChannelId]:   Determines if ChannelDataEOL was found.

If true,then ChannelDataEOL was found. If false, then MaxChannelDataLength was reached.

This configuration setting is valid only when queried inside SSHChannelData, MaxChannelDataLength > 0, and ChannelDataEOL is nonempty.

ClientSSHVersionString:   The SSH version string used by the class.

This configuration setting specifies the Secure Shell (SSH) version string used by the class. The default value is "SSH-2.0-IPWorks SSH Client 2024".

Most SSH servers expect the SSH version string to have the expected format "SSH-protocol version-software version". See above for an example.

DoNotRepeatAuthMethods:   Whether the class will repeat authentication methods during multifactor authentication.

The default value is true. When set to false, the class will repeat authentication methods that have already been completed during multifactor authentication.

EnablePageantAuth:   Whether to use a key stored in Pageant to perform client authentication.

This configuration setting controls whether Pageant authentication is disabled, enabled, or required. When enabled or required, the class attempts to communicate with PuTTY's ssh-agent, called "Pageant", over shared memory to perform public key authentication. Possible values and the corresponding behavior is described as follows:

ValueDescription
0 (Disabled - default) No communication with Pageant is attempted.
1 (Enabled) Pageant authentication is used if available. If Pageant is not running, or does not contain the expected key, no error is thrown.
2 (Required) Only Pageant authentication is used. If Pageant is not running, or does not contain the expected key, an error is thrown.

Example 1. Enabling Pageant: component.Config("EnablePageantAuth=1"); component.SSHUser = "sshuser"; component.SSHLogon("localhost", 22);

Note: This functionality is available only on Windows.

KerberosDelegation:   If true, asks for credentials with delegation enabled during authentication.

The default value is "True". If set to "False", the client will not ask for credentials delegation support during authentication.

Note: Even if the client asks for delegation, the server/KDC might not grant it, and authentication will still succeed.

KerberosRealm:   The fully qualified domain name of the Kerberos Realm to use for GSSAPI authentication.

This property may be set to the fully qualified (DNS) name of the kerberos realm (or Windows Active Directory domain name) to use during GSSAPI authentication. This can be used to force authentication with a given realm if the client and server machines are not part of the same domain.

KerberosSPN:   The Kerberos Service Principal Name of the SSH host.

This property can be set to specify the Service Principal Name (SPN) associated with the SSH service on the remote host. This will usually be in the form "host/fqdn.of.sshhost[@REALM]". If not specified, the class will assume the SPN is based on the value of the SSHHost property and the kerberos realm used for authentication.

KeyRenegotiationThreshold:   Sets the threshold for the SSH Key Renegotiation.

This property allows you to specify the threshold, in the number of bytes, for the Secure Shell (SSH) key renegotiation. The default value for this property is set to 1 GB.

Example. Setting the Threshold to 500 MB: SSHComponent.Config("KeyRenegotiationThreshold=524288000")

LogLevel:   Specifies the level of detail that is logged.

This configuration setting controls the level of detail that is logged through the Log event. Possible values are as follows:

0 (None) No messages are logged.
1 (Info - Default) Informational events such as Secure Shell (SSH) handshake messages are logged.
2 (Verbose) Detailed data such as individual packet information are logged.
3 (Debug) Debug data including all relevant sent and received bytes are logged.

MaxChannelDataLength[ChannelId]:   The maximum amount of data to accumulate when no ChannelDataEOL is found.

By default MaxChannelDataLength is 0 and ChannelDataEOL is an empty string. SSHChannelData fires whenever an SSH_MSG_CHANNEL_DATA packet is received.

If MaxChannelDataLength is greater than 0 and ChannelDataEOL is a nonempty string, the class will internally buffer data waiting to fire SSHChannelData until either MaxChannelDataLength is reached or ChannelDataEOL is found, whichever comes first. Query ChannelDataEOLFound to know which condition was met. The buffer is reset any time SSHChannelData fires.

ChannelDataEOL and MaxChannelDataLength must be set together or unexpected behavior could occur.

MaxPacketSize:   The maximum packet size of the channel, in bytes.

This configuration setting specifies the maximum size of an individual data packet, in bytes, that can be sent to the sender.

MaxWindowSize:   The maximum window size allowed for the channel, in bytes.

This configuration setting specifies how many bytes of channel data can be sent to the sender of this message without adjusting the window.

Note: This value may be changed during the connection, but the window size can only be increased, not decreased.

NegotiatedStrictKex:   Returns whether strict key exchange was negotiated to be used.

This configuration setting specifies whether strict key exchange (strict kex) was negotiated during the SSH handshake. If strict kex is being used, then this will return "True". If strict kex is not being used, then this will return "False".

component.Config("NegotiatedStrictKex")

PasswordPrompt:   The text of the password prompt used in keyboard-interactive authentication.

This configuration setting optionally specifies a pattern to be matched to the prompt received from the server during keyboard-interactive authentication. If a matching prompt is detected the class automatically responds to the prompt with the password specified by SSHPassword.

This provides an easy way to automatically reply to prompts with the password if one is presented by the server. The password will be autofilled in the Response parameter of the SSHKeyboardInteractive event in the case of a match.

The following special characters are supported for pattern matching:

? Any single character.
* Any characters or no characters (e.g., C*t matches Cat, Cot, Coast, Ct).
[,-] A range of characters (e.g., [a-z], [a], [0-9], [0-9,a-d,f,r-z]).
\ The slash is ignored and exact matching is performed on the next character.

If these characters need to be used as a literal in a pattern, then they must be escaped by surrounding them with brackets []. Note: "]" and "-" do not need to be escaped. See below for the escape sequences:

CharacterEscape Sequence
? [?]
* [*]
[ [[]
\ [\]

For example, to match the value [Something].txt, specify the pattern [[]Something].txt.

PreferredDHGroupBits:   The size (in bits) of the preferred modulus (p) to request from the server.

This configuration setting may be when using the diffie-hellman-group-exchange-sha1 or diffie-hellman-group-exchange-sha256 key exchange algorithms to control the preferred size, in bits, of the modulus (p) prime number to request from the server. Acceptable values are between 1024 and 8192.

RecordLength:   The length of received data records.

If set to a positive value, this configuration setting defines the length of data records to be received. The class will accumulate data until RecordLength is reached and only then will it fire the DataIn event with data of length RecordLength. This allows data to be received as records of known length. This value can be changed at any time, including within the DataIn event.

The default value is 0, meaning this setting is not used.

ServerSSHVersionString:   The remote host's SSH version string.

This configuration setting will return the remote host's SSH version string, which can help when identifying problematic servers. This configuration setting is read-only.

SignedSSHCert:   The CA signed client public key used when authenticating.

When authenticating via public key authentication, this setting may be set to the certificate authority (CA) signed client's public key. This is useful when the server has been configured to trust client keys signed by a particular CA. For instance: component.Config("SignedSSHCert=ssh-rsa-cert-v01@openssh.com AAAAB3NzaC1yc2EAAAADAQABAAAB..."); The algorithm such as ssh-rsa-cert-v01@openssh.com in the previous string is used as part of the authentication process. To use a different algorithm, simply change this value. For instance, all of the following are acceptable with the same signed public key:

  • ssh-rsa-cert-v01@openssh.com AAAAB3NzaC1yc2EAAAADAQABAAAB...
  • rsa-sha2-256-cert-v01@openssh.com AAAAB3NzaC1yc2EAAAADAQABAAAB...
  • rsa-sha2-512-cert-v01@openssh.com AAAAB3NzaC1yc2EAAAADAQABAAAB...

SSHAcceptAnyServerHostKey:   If set the class will accept any key presented by the server.

The default value is "False". Set this to "True" to accept any key presented by the server.

SSHAcceptServerCAKey:   The CA public key that signed the server's host key.

If the server's host key was signed by a CA, this configuration setting may be used to specify the CA's public key. If specified, the class will trust any server's host key that was signed by the CA. For instance: component.Config("SSHAcceptServerCAKey=ssh-rsa AAAAB3NzaC1yc2EAAAADAQAB...");

SSHAcceptServerHostKeyFingerPrint:   The fingerprint of the server key to accept.

This configuration setting may be set to a comma-delimited collection of 16-byte MD5 fingerprints that should be accepted as the host's key. You may supply it by hex- encoding the values in the form "0a:1b:2c:3d". Example 2. Accepting Fingerprints: SSHClient.Config("SSHAcceptServerHostKeyFingerprint=0a:1b:2c:3d"); If the server's fingerprint matches one of the values supplied, the class will accept the host key.

SSHFingerprintHashAlgorithm:   The algorithm used to calculate the fingerprint.

This configuration setting controls which hash algorithm is used to calculate the hostkey's fingerprint, displayed when SSHServerAuthentication fires. Valid values are as follows:

  • MD5
  • SHA1
  • SHA256 (default)
SSHFingerprintMD5:   The server hostkey's MD5 fingerprint.

This configuration setting may be queried in SSHServerAuthentication to get the server hostkey's MD5 fingerprint.

SSHFingerprintSHA1:   The server hostkey's SHA1 fingerprint.

This configuration setting may be queried in SSHServerAuthentication to get the server hostkey's SHA-1 fingerprint.

SSHFingerprintSHA256:   The server hostkey's SHA256 fingerprint.

This configuration setting may be queried in SSHServerAuthentication to get the server hostkey's SHA-256 fingerprint.

SSHKeepAliveCountMax:   The maximum number of keep alive packets to send without a response.

This configuration setting specifies the maximum number of keep-alive packets to send when no response is received. Normally a response to a keep-alive packet is received right away. If no response is received, the class will continue to send keep-alive packets until SSHKeepAliveCountMax is reached. If this is reached, the class will assume the connection is broken and disconnect. The default value is 5.

SSHKeepAliveInterval:   The interval between keep alive packets.

This configuration setting specifies the number of seconds between keep alive packets. If set to a positive value, the class will send a SSH keep-alive packet after KeepAliveInterval seconds of inactivity. This configuration setting takes effect only when there is no activity; if any data are sent or received over the connection, it will reset the timer.

The default value is 0, meaning no keep alives will be sent.

Note: The SSHReverseTunnel class uses a default value of 30.

SSHKeyExchangeAlgorithms:   Specifies the supported key exchange algorithms.

This configuration setting may be used to specify the list of supported key exchange algorithms used during Secure Shell (SSH) negotiation. The value should contain a comma-separated list of algorithms. Supported algorithms are as follows:

  • curve25519-sha256
  • curve25519-sha256@libssh.org
  • diffie-hellman-group1-sha1
  • diffie-hellman-group14-sha1
  • diffie-hellman-group14-sha256
  • diffie-hellman-group16-sha512
  • diffie-hellman-group18-sha512
  • diffie-hellman-group-exchange-sha256
  • diffie-hellman-group-exchange-sha1
  • ecdh-sha2-nistp256
  • ecdh-sha2-nistp384
  • ecdh-sha2-nistp521
  • gss-group14-sha256-toWM5Slw5Ew8Mqkay+al2g==
  • gss-group16-sha512-toWM5Slw5Ew8Mqkay+al2g==
  • gss-nistp256-sha256-toWM5Slw5Ew8Mqkay+al2g==
  • gss-curve25519-sha256-toWM5Slw5Ew8Mqkay+al2g==
  • gss-group14-sha1-toWM5Slw5Ew8Mqkay+al2g==
  • gss-gex-sha1-toWM5Slw5Ew8Mqkay+al2g==
The default value is curve25519-sha256,curve25519-sha256@libssh.org,diffie-hellman-group-exchange-sha256,diffie-hellman-group14-sha256,diffie-hellman-group16-sha512,diffie-hellman-group18-sha512,ecdh-sha2-nistp256,ecdh-sha2-nistp384,ecdh-sha2-nistp521,diffie-hellman-group-exchange-sha1,diffie-hellman-group14-sha1,diffie-hellman-group1-sha1,gss-group14-sha256-toWM5Slw5Ew8Mqkay+al2g==,gss-group16-sha512-toWM5Slw5Ew8Mqkay+al2g==,gss-nistp256-sha256-toWM5Slw5Ew8Mqkay+al2g==,gss-curve25519-sha256-toWM5Slw5Ew8Mqkay+al2g==,gss-group14-sha1-toWM5Slw5Ew8Mqkay+al2g==,gss-gex-sha1-toWM5Slw5Ew8Mqkay+al2g==.
SSHKeyRenegotiate:   Causes the component to renegotiate the SSH keys.

Once this configuration setting is queried, the component will renegotiate the SSH keys with the remote host.

Example 3. Renegotiating SSH Keys: SSHClient.Config("SSHKeyRenegotiate")

SSHMacAlgorithms:   Specifies the supported Mac algorithms.

This configuration setting may be used to specify an alternate list of supported Mac algorithms used during SSH negotiation. This also specifies the order in which the Mac algorithms are preferred. The value should contain a comma-separated list of algorithms. Supported algorithms are as follows:

  • hmac-sha1
  • hmac-md5
  • hmac-sha1-96
  • hmac-md5-96
  • hmac-sha2-256
  • hmac-sha2-256-96
  • hmac-sha2-512
  • hmac-sha2-512-96
  • hmac-ripemd160
  • hmac-ripemd160-96
  • hmac-sha2-256-etm@openssh.com
  • hmac-sha2-512-etm@openssh.com
  • hmac-sha2-256-96-etm@openssh.com
  • hmac-sha2-512-96-etm@openssh.com
  • umac-64@openssh.com
  • umac-64-etm@openssh.com
  • umac-128@openssh.com
  • umac-128-etm@openssh.com
The default value is hmac-sha2-256,hmac-sha2-512,hmac-sha1,hmac-md5,hmac-ripemd160,hmac-sha1-96,hmac-md5-96,hmac-sha2-256-96,hmac-sha2-512-96,hmac-ripemd160-96,hmac-sha2-256-etm@openssh.com,hmac-sha2-512-etm@openssh.com,umac-64@openssh.com,umac-64-etm@openssh.com,umac-128@openssh.com,umac-128-etm@openssh.com.
SSHPubKeyAuthSigAlgorithms:   Specifies the enabled signature algorithms that may be used when attempting public key authentication.

This setting specifies a list of signature algorithms that may be used when authenticating to the server using public key authentication. This applies only when public key authentication is performed by the client.

The setting should be a comma-separated list of algorithms. At runtime, the class will evaluate the specified algorithms, and if the algorithm is applicable to the certificate specified in SSHCert, it will be used. If the algorithm is not applicable, the class will evaluate the next algorithm. Possible values are as follows:

  • ssh-rsa
  • rsa-sha2-256
  • rsa-sha2-512
  • ssh-dss
  • ecdsa-sha2-nistp256
  • ecdsa-sha2-nistp384
  • ecdsa-sha2-nistp521
  • ssh-ed25519
  • x509v3-sign-rsa
  • x509v3-sign-dss

The default value in Windows is ssh-rsa,rsa-sha2-256,rsa-sha2-512,ssh-dss,ecdsa-sha2-nistp256,ecdsa-sha2-nistp384,ecdsa-sha2-nistp521,ssh-ed25519.

rsa-sha2-256 and rsa-sha2-512 notes

The class will query the server for supported algorithms when connecting. If the server indicates support for rsa-sha2-256 or rsa-sha2-512 and the algorithm is present in the list defined by this setting (as in the default value), that algorithm will be used instead of ssh-rsa even when ssh-rsa appears first in the list.

For the rsa-sha2-256 and rsa-sha2-512 algorithms to be automatically preferred, the server must support the ext-info-c mechanism. In practice, older servers do not support this, and in that case, ssh-rsa will be used because it appears first in the list. Newer servers do support this mechanism, and in that case, rsa-sha2-256 or rsa-sha2-512 will be used even though it appears after ssh-rsa.

This behavior has been carefully designed to provide maximum compatibility while automatically using more secure algorithms when connecting to servers that support them.

SSHPublicKeyAlgorithms:   Specifies the supported public key algorithms for the server's public key.

This configuration setting specifies the allowed public key algorithms for the server's public key. This list controls only the public key algorithm used when authenticating the server's public key. This list has no bearing on the public key algorithms that can be used by the client when performing public key authentication to the server. The default value is ssh-ed25519,ecdsa-sha2-nistp256,ecdsa-sha2-nistp384,ecdsa-sha2-nistp521,rsa-sha2-256,rsa-sha2-512,ssh-rsa,ssh-dss,x509v3-sign-rsa,x509v3-sign-dss.

SSHVersionPattern:   The pattern used to match the remote host's version string.

This configuration setting specifies the pattern used to accept or deny the remote host's SSH version string. It takes a comma-delimited list of patterns to match. The default value is "*SSH-1.99-*,*SSH-2.0-*" and will accept connections from SSH 1.99 and 2.0 hosts. As an example, the following value would accept connections for SSH 1.99, 2.0, and 2.99 hosts.

*SSH-1.99-*,*SSH-2.0-*,*SSH-2.99-*
TryAllAvailableAuthMethods:   If set to true, the class will try all available authentication methods.

The default value is false. When set to true, the class will try to authenticate using all methods that it has credentials for and the server supports.

UseStrictKeyExchange:   Specifies how strict key exchange is supported.

This configuration setting controls whether strict key exchange (strict kex) is enabled to mitigate the Terrapin attack. When enabled, the class will indicate support for strict key exchange by automatically including the pseudo-algorithm kex-strict-c-v00@openssh.com for client classes and kex-strict-s-v00@openssh.com for server classes in the list of supported key exchange algorithms.

Because both client and server must implement strict key exchange to effectively mitigate the Terrapin attack, the class provides options to further control the behavior in different scenarios. Possible values for this setting are as follows:

0Disabled. Strict key exchange is not supported in the class.
1 (default)Enabled, but not enforced. This setting enables strict key exchange, but if the remote host does not support strict key exchange the connection is still allowed to continue.
2Enabled, but will reject affected algorithms if the remote host does not support strict key exchange. If the remote host supports strict key exchange, all algorithms may be used. If the remote host does not support strict key exchange, the connection will continue only if the selected encryption and message authentication code (MAC) algorithms are not affected by the Terrapin attack.
3Required. If the remote host does not support strict key exchange, the connection will fail.

WaitForChannelClose:   Whether to wait for channels to be closed before disconnected.

This configuration setting controls whether the class will wait for a server response to the SSH_MSG_CHANNEL_CLOSE when disconnecting. When the class disconnects, it will first attempt to close all open channels by sending a SSH_MSG_CHANNEL_CLOSE for each channel. This configuration setting controls whether the class will wait for a server response after sending the messages.

When True (default), the class will wait for a response to the channel close message until the responses have been received, the server closes the connection, or Timeout seconds is reached.

When False, the class will still send the channel close messages, but it will not wait for a response and will proceed to close the connection.

WaitForServerDisconnect:   Whether to wait for the server to close the connection.

This configuration setting controls whether to wait for the server to close the connection when SSHLogoff is called.

When set to True, the class will initiate the disconnection sequence by sending SSH_MSG_DISCONNECT, but it will not close the connection and instead will wait for the server to close the connection. Setting this to True may be beneficial in circumstances in which many connections are being established, to avoid port exhaustion when sockets are in a TIME_WAIT state. Allowing the server to close the connection avoids the TIME_WAIT state of socket on the client machine.

When set to False (default), the client will close the connection. It is recommended to use this value unless there is a specific need to change it.

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:

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

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:

IdentifierName
037IBM EBCDIC - U.S./Canada
437OEM - United States
500IBM EBCDIC - International
708Arabic - ASMO 708
709Arabic - ASMO 449+, BCON V4
710Arabic - Transparent Arabic
720Arabic - Transparent ASMO
737OEM - Greek (formerly 437G)
775OEM - Baltic
850OEM - Multilingual Latin I
852OEM - Latin II
855OEM - Cyrillic (primarily Russian)
857OEM - Turkish
858OEM - Multilingual Latin I + Euro symbol
860OEM - Portuguese
861OEM - Icelandic
862OEM - Hebrew
863OEM - Canadian-French
864OEM - Arabic
865OEM - Nordic
866OEM - Russian
869OEM - Modern Greek
870IBM EBCDIC - Multilingual/ROECE (Latin-2)
874ANSI/OEM - Thai (same as 28605, ISO 8859-15)
875IBM EBCDIC - Modern Greek
932ANSI/OEM - Japanese, Shift-JIS
936ANSI/OEM - Simplified Chinese (PRC, Singapore)
949ANSI/OEM - Korean (Unified Hangul Code)
950ANSI/OEM - Traditional Chinese (Taiwan; Hong Kong SAR, PRC)
1026IBM EBCDIC - Turkish (Latin-5)
1047IBM EBCDIC - Latin 1/Open System
1140IBM EBCDIC - U.S./Canada (037 + Euro symbol)
1141IBM EBCDIC - Germany (20273 + Euro symbol)
1142IBM EBCDIC - Denmark/Norway (20277 + Euro symbol)
1143IBM EBCDIC - Finland/Sweden (20278 + Euro symbol)
1144IBM EBCDIC - Italy (20280 + Euro symbol)
1145IBM EBCDIC - Latin America/Spain (20284 + Euro symbol)
1146IBM EBCDIC - United Kingdom (20285 + Euro symbol)
1147IBM EBCDIC - France (20297 + Euro symbol)
1148IBM EBCDIC - International (500 + Euro symbol)
1149IBM EBCDIC - Icelandic (20871 + Euro symbol)
1200Unicode UCS-2 Little-Endian (BMP of ISO 10646)
1201Unicode UCS-2 Big-Endian
1250ANSI - Central European
1251ANSI - Cyrillic
1252ANSI - Latin I
1253ANSI - Greek
1254ANSI - Turkish
1255ANSI - Hebrew
1256ANSI - Arabic
1257ANSI - Baltic
1258ANSI/OEM - Vietnamese
1361Korean (Johab)
10000MAC - Roman
10001MAC - Japanese
10002MAC - Traditional Chinese (Big5)
10003MAC - Korean
10004MAC - Arabic
10005MAC - Hebrew
10006MAC - Greek I
10007MAC - Cyrillic
10008MAC - Simplified Chinese (GB 2312)
10010MAC - Romania
10017MAC - Ukraine
10021MAC - Thai
10029MAC - Latin II
10079MAC - Icelandic
10081MAC - Turkish
10082MAC - Croatia
12000Unicode UCS-4 Little-Endian
12001Unicode UCS-4 Big-Endian
20000CNS - Taiwan
20001TCA - Taiwan
20002Eten - Taiwan
20003IBM5550 - Taiwan
20004TeleText - Taiwan
20005Wang - Taiwan
20105IA5 IRV International Alphabet No. 5 (7-bit)
20106IA5 German (7-bit)
20107IA5 Swedish (7-bit)
20108IA5 Norwegian (7-bit)
20127US-ASCII (7-bit)
20261T.61
20269ISO 6937 Non-Spacing Accent
20273IBM EBCDIC - Germany
20277IBM EBCDIC - Denmark/Norway
20278IBM EBCDIC - Finland/Sweden
20280IBM EBCDIC - Italy
20284IBM EBCDIC - Latin America/Spain
20285IBM EBCDIC - United Kingdom
20290IBM EBCDIC - Japanese Katakana Extended
20297IBM EBCDIC - France
20420IBM EBCDIC - Arabic
20423IBM EBCDIC - Greek
20424IBM EBCDIC - Hebrew
20833IBM EBCDIC - Korean Extended
20838IBM EBCDIC - Thai
20866Russian - KOI8-R
20871IBM EBCDIC - Icelandic
20880IBM EBCDIC - Cyrillic (Russian)
20905IBM EBCDIC - Turkish
20924IBM EBCDIC - Latin-1/Open System (1047 + Euro symbol)
20932JIS X 0208-1990 & 0121-1990
20936Simplified Chinese (GB2312)
21025IBM EBCDIC - Cyrillic (Serbian, Bulgarian)
21027Extended Alpha Lowercase
21866Ukrainian (KOI8-U)
28591ISO 8859-1 Latin I
28592ISO 8859-2 Central Europe
28593ISO 8859-3 Latin 3
28594ISO 8859-4 Baltic
28595ISO 8859-5 Cyrillic
28596ISO 8859-6 Arabic
28597ISO 8859-7 Greek
28598ISO 8859-8 Hebrew
28599ISO 8859-9 Latin 5
28605ISO 8859-15 Latin 9
29001Europa 3
38598ISO 8859-8 Hebrew
50220ISO 2022 Japanese with no halfwidth Katakana
50221ISO 2022 Japanese with halfwidth Katakana
50222ISO 2022 Japanese JIS X 0201-1989
50225ISO 2022 Korean
50227ISO 2022 Simplified Chinese
50229ISO 2022 Traditional Chinese
50930Japanese (Katakana) Extended
50931US/Canada and Japanese
50933Korean Extended and Korean
50935Simplified Chinese Extended and Simplified Chinese
50936Simplified Chinese
50937US/Canada and Traditional Chinese
50939Japanese (Latin) Extended and Japanese
51932EUC - Japanese
51936EUC - Simplified Chinese
51949EUC - Korean
51950EUC - Traditional Chinese
52936HZ-GB2312 Simplified Chinese
54936Windows XP: GB18030 Simplified Chinese (4 Byte)
57002ISCII Devanagari
57003ISCII Bengali
57004ISCII Tamil
57005ISCII Telugu
57006ISCII Assamese
57007ISCII Oriya
57008ISCII Kannada
57009ISCII Malayalam
57010ISCII Gujarati
57011ISCII Punjabi
65000Unicode UTF-7
65001Unicode UTF-8
The following is a list of valid code page identifiers for Mac OS only:
IdentifierName
1ASCII
2NEXTSTEP
3JapaneseEUC
4UTF8
5ISOLatin1
6Symbol
7NonLossyASCII
8ShiftJIS
9ISOLatin2
10Unicode
11WindowsCP1251
12WindowsCP1252
13WindowsCP1253
14WindowsCP1254
15WindowsCP1250
21ISO2022JP
30MacOSRoman
10UTF16String
0x90000100UTF16BigEndian
0x94000100UTF16LittleEndian
0x8c000100UTF32String
0x98000100UTF32BigEndian
0x9c000100UTF32LittleEndian
65536Proprietary

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.

UseFIPSCompliantAPI:   Tells the class whether or not to use FIPS certified APIs.

When set to true, the class will utilize the underlying operating system's certified APIs. Java editions, regardless of OS, utilize Bouncy Castle Federal Information Processing Standards (FIPS), while all other Windows editions make use of Microsoft security libraries.

FIPS mode can be enabled by setting the UseFIPSCompliantAPI configuration setting to true. This is a static setting that applies to all instances of all classes of the toolkit within the process. It is recommended to enable or disable this setting once before the component has been used to establish a connection. Enabling FIPS while an instance of the component is active and connected may result in unexpected behavior.

For more details, please see the FIPS 140-2 Compliance article.

Note: This setting is applicable only on Windows.

Note: Enabling FIPS compliance requires a special license; please contact sales@nsoftware.com for details.

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 (SExec 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.

SExec Errors

1050   Busy performing other action.

SSHClient Errors

1001   Server has disconnected.
1002   Protocol version unsupported or other issue with version string.
1003   Cannot negotiate algorithms.
1005   Selected algorithm unsupported.
1006   Cannot set keys.
1010   Unexpected algorithm.
1011   Cannot create exchange hash.
1012   Cannot make key.
1013   Cannot sign data.
1014   Cannot encrypt packet.
1015   Cannot decrypt packet.
1016   Cannot decompress packet.
1020   Failure to open channel.
1021   Invalid channel Id.
1022   Invalid channel data.
1023   Invalid channel message.
1024   SSH message unimplemented.
1027   Server message unsupported.
1030   Server's host key was rejected. The host key may be accepted within the SSHServerAuthentication event or using the SSHAcceptServerHostKey property.
1031   Cannot verify server's host key.
1032   Authentication failed. Check description for details.
1033   Channel request failed.
1034   Diffie-Hellman exchange failed.
1036   SSH connection failed.
1037   SSH reconnect limit reached.
1038   Elliptic curve Diffie-Hellman exchange failed.
1039   SSH keep-alive limit reached.
1098   Request failure.
1130   Would block error.
1133   Would block, reason: key reExchange.

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.

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).