- class QSslSocket#
The
QSslSocket
class provides an SSL encrypted socket for both clients and servers. More…Synopsis#
Methods#
def
__init__()
def
isEncrypted()
def
mode()
def
ocspResponses()
def
peerVerifyMode()
def
peerVerifyName()
def
privateKey()
def
protocol()
def
sessionCipher()
def
setPrivateKey()
def
setProtocol()
Slots#
Signals#
def
alertReceived()
def
alertSent()
def
encrypted()
def
modeChanged()
def
sslErrors()
Static functions#
def
activeBackend()
def
supportsSsl()
Note
This documentation may contain snippets that were automatically translated from C++ to Python. We always welcome contributions to the snippet translation. If you see an issue with the translation, you can also let us know by creating a ticket on https:/bugreports.qt.io/projects/PYSIDE
Detailed Description#
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
QSslSocket
establishes a secure, encrypted TCP connection you can use for transmitting encrypted data. It can operate in both client and server mode, and it supports modern TLS protocols, including TLS 1.3. By default,QSslSocket
uses only TLS protocols which are considered to be secure (SecureProtocols
), but you can change the TLS protocol by callingsetProtocol()
as long as you do it before the handshake has started.SSL encryption operates on top of the existing TCP stream after the socket enters the ConnectedState. There are two simple ways to establish a secure connection using
QSslSocket
: With an immediate SSL handshake, or with a delayed SSL handshake occurring after the connection has been established in unencrypted mode.The most common way to use
QSslSocket
is to construct an object and start a secure connection by callingconnectToHostEncrypted()
. This method starts an immediate SSL handshake once the connection has been established.socket = QSslSocket(self) socket.encrypted.connect(self.ready) socket.connectToHostEncrypted("imap.example.com", 993)
As with a plain
QTcpSocket
,QSslSocket
enters the HostLookupState, ConnectingState, and finally the ConnectedState, if the connection is successful. The handshake then starts automatically, and if it succeeds, theencrypted()
signal is emitted to indicate the socket has entered the encrypted state and is ready for use.Note that data can be written to the socket immediately after the return from
connectToHostEncrypted()
(i.e., before theencrypted()
signal is emitted). The data is queued inQSslSocket
until after theencrypted()
signal is emitted.An example of using the delayed SSL handshake to secure an existing connection is the case where an SSL server secures an incoming connection. Suppose you create an SSL server class as a subclass of
QTcpServer
. You would overrideincomingConnection()
with something like the example below, which first constructs an instance ofQSslSocket
and then callssetSocketDescriptor()
to set the new socket’s descriptor to the existing one passed in. It then initiates the SSL handshake by callingstartServerEncryption()
.def incomingConnection(self, socketDescriptor): serverSocket = QSslSocket() if serverSocket.setSocketDescriptor(socketDescriptor): addPendingConnection(serverSocket) serverSocket.encrypted.connect(self.ready) serverSocket.startServerEncryption() else: del serverSocket
If an error occurs,
QSslSocket
emits thesslErrors()
signal. In this case, if no action is taken to ignore the error(s), the connection is dropped. To continue, despite the occurrence of an error, you can callignoreSslErrors()
, either from within this slot after the error occurs, or any time after construction of theQSslSocket
and before the connection is attempted. This will allowQSslSocket
to ignore the errors it encounters when establishing the identity of the peer. Ignoring errors during an SSL handshake should be used with caution, since a fundamental characteristic of secure connections is that they should be established with a successful handshake.Once encrypted, you use
QSslSocket
as a regularQTcpSocket
. When readyRead() is emitted, you can call read(),canReadLine()
and readLine(), or getChar() to read decrypted data fromQSslSocket
‘s internal buffer, and you can call write() or putChar() to write data back to the peer.QSslSocket
will automatically encrypt the written data for you, and emitencryptedBytesWritten()
once the data has been written to the peer.As a convenience,
QSslSocket
supportsQTcpSocket
‘s blocking functionswaitForConnected()
,waitForReadyRead()
,waitForBytesWritten()
, andwaitForDisconnected()
. It also provideswaitForEncrypted()
, which will block the calling thread until an encrypted connection has been established.socket = QSslSocket() socket.connectToHostEncrypted("http.example.com", 443) if not socket.waitForEncrypted(): print(socket.errorString()) return False socket.write("GET / HTTP/1.0\r\n\r\n") while socket.waitForReadyRead(): print(socket.readAll().data())
QSslSocket
provides an extensive, easy-to-use API for handling cryptographic ciphers, private keys, and local, peer, and Certification Authority (CA) certificates. It also provides an API for handling errors that occur during the handshake phase.The following features can also be customized:
The socket’s cryptographic cipher suite can be customized before the handshake phase with
setCiphers()
.The socket’s local certificate and private key can be customized before the handshake phase with
setLocalCertificate()
andsetPrivateKey()
.The CA certificate database can be extended and customized with
addCaCertificate()
,addCaCertificates()
.
To extend the list of default CA certificates used by the SSL sockets during the SSL handshake you must update the default configuration, as in the snippet below:
QList<QSslCertificate> certificates = getCertificates(); QSslConfiguration configuration = QSslConfiguration::defaultConfiguration(); configuration.addCaCertificates(certificates); QSslConfiguration::setDefaultConfiguration(configuration);
Note
If available, root certificates on Unix (excluding macOS) will be loaded on demand from the standard certificate directories. If you do not want to load root certificates on demand, you need to call either
defaultConfiguration()
.setCaCertificates() before the first SSL handshake is made in your application (for example, via passing QSslSocket::systemCaCertificates() to it), or calldefaultConfiguration()
::setCaCertificates() on yourQSslSocket
instance prior to the SSL handshake.For more information about ciphers and certificates, refer to
QSslCipher
andQSslCertificate
.This product includes software developed by the OpenSSL Project for use in the OpenSSL Toolkit ( http://www.openssl.org/ ).
Note
Be aware of the difference between the bytesWritten() signal and the
encryptedBytesWritten()
signal. For aQTcpSocket
, bytesWritten() will get emitted as soon as data has been written to the TCP socket. For aQSslSocket
, bytesWritten() will get emitted when the data is being encrypted andencryptedBytesWritten()
will get emitted as soon as data has been written to the TCP socket.See also
- class SslMode#
Describes the connection modes available for
QSslSocket
.Constant
Description
QSslSocket.UnencryptedMode
The socket is unencrypted. Its behavior is identical to
QTcpSocket
.QSslSocket.SslClientMode
The socket is a client-side SSL socket. It is either already encrypted, or it is in the SSL handshake phase (see
isEncrypted()
).QSslSocket.SslServerMode
The socket is a server-side SSL socket. It is either already encrypted, or it is in the SSL handshake phase (see
isEncrypted()
).
- class PeerVerifyMode#
Describes the peer verification modes for
QSslSocket
. The default mode is AutoVerifyPeer, which selects an appropriate mode depending on the socket’s QSocket::SslMode.Constant
Description
QSslSocket.VerifyNone
QSslSocket
will not request a certificate from the peer. You can set this mode if you are not interested in the identity of the other side of the connection. The connection will still be encrypted, and your socket will still send its local certificate to the peer if it’s requested.QSslSocket.QueryPeer
QSslSocket
will request a certificate from the peer, but does not require this certificate to be valid. This is useful when you want to display peer certificate details to the user without affecting the actual SSL handshake. This mode is the default for servers. Note: In Schannel this value acts the same as VerifyNone.QSslSocket.VerifyPeer
QSslSocket
will request a certificate from the peer during the SSL handshake phase, and requires that this certificate is valid. On failure,QSslSocket
will emit thesslErrors()
signal. This mode is the default for clients.QSslSocket.AutoVerifyPeer
QSslSocket
will automatically use QueryPeer for server sockets and VerifyPeer for client sockets.See also
Constructs a
QSslSocket
object.parent
is passed to QObject’s constructor. The new socket’scipher
suite is set to the one returned by the static method defaultCiphers().- static activeBackend()#
- Return type:
str
Returns the name of the backend that
QSslSocket
and related classes use. If the active backend was not set explicitly, this function returns the name of a default backend thatQSslSocket
selects implicitly from the list of available backends.Note
When selecting a default backend implicitly,
QSslSocket
prefers the OpenSSL backend if available.See also
- alertReceived(level, type, description)#
- Parameters:
level –
AlertLevel
type –
AlertType
description – str
QSslSocket
emits this signal if an alert message was received from a peer.level
tells if the alert was fatal or it was a warning.type
is the code explaining why the alert was sent. When a textual description of the alert message is available, it is supplied indescription
.Note
The signal is mostly for informational and debugging purposes and does not require any handling in the application. If the alert was fatal, underlying backend will handle it and close the connection.
- alertSent(level, type, description)#
- Parameters:
level –
AlertLevel
type –
AlertType
description – str
QSslSocket
emits this signal if an alert message was sent to a peer.level
describes if it was a warning or a fatal error.type
gives the code of the alert message. When a textual description of the alert message is available, it is supplied indescription
.Note
This signal is mostly informational and can be used for debugging purposes, normally it does not require any actions from the application.
- static availableBackends()#
- Return type:
.list of QString
Returns the names of the currently available backends. These names are in lower case, e.g. “openssl”, “securetransport”, “schannel” (similar to the already existing feature names for TLS backends in Qt).
See also
- connectToHostEncrypted(hostName, port[, mode=QIODeviceBase.OpenModeFlag.ReadWrite[, protocol=QAbstractSocket.NetworkLayerProtocol.AnyIPProtocol]])#
- Parameters:
hostName – str
port – int
mode – Combination of
OpenModeFlag
protocol –
NetworkLayerProtocol
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Starts an encrypted connection to the device
hostName
onport
, usingmode
as the OpenMode. This is equivalent to callingconnectToHost()
to establish the connection, followed by a call tostartClientEncryption()
. Theprotocol
parameter can be used to specify which network protocol to use (eg. IPv4 or IPv6).QSslSocket
first enters the HostLookupState. Then, after entering either the event loop or one of the waitFor…() functions, it enters the ConnectingState, emitsconnected()
, and then initiates the SSL client handshake. At each state change,QSslSocket
emits signalstateChanged()
.After initiating the SSL client handshake, if the identity of the peer can’t be established, signal
sslErrors()
is emitted. If you want to ignore the errors and continue connecting, you must callignoreSslErrors()
, either from inside a slot function connected to thesslErrors()
signal, or prior to entering encrypted mode. IfignoreSslErrors()
is not called, the connection is dropped, signaldisconnected()
is emitted, andQSslSocket
returns to the UnconnectedState.If the SSL handshake is successful,
QSslSocket
emitsencrypted()
.socket = QSslSocket() socket.encrypted.connect(receiver.socketEncrypted) socket.connectToHostEncrypted("imap", 993) socket.write("1 CAPABILITY\r\n")
Note
The example above shows that text can be written to the socket immediately after requesting the encrypted connection, before the
encrypted()
signal has been emitted. In such cases, the text is queued in the object and written to the socket after the connection is established and theencrypted()
signal has been emitted.The default for
mode
is ReadWrite.If you want to create a
QSslSocket
on the server side of a connection, you should instead callstartServerEncryption()
upon receiving the incoming connection throughQTcpServer
.See also
connectToHost()
startClientEncryption()
waitForConnected()
waitForEncrypted()
- connectToHostEncrypted(hostName, port, sslPeerName[, mode=QIODeviceBase.OpenModeFlag.ReadWrite[, protocol=QAbstractSocket.NetworkLayerProtocol.AnyIPProtocol]])
- Parameters:
hostName – str
port – int
sslPeerName – str
mode – Combination of
OpenModeFlag
protocol –
NetworkLayerProtocol
This is an overloaded function.
In addition to the original behaviour of
connectToHostEncrypted
, this overloaded method enables the usage of a different hostname (sslPeerName
) for the certificate validation instead of the one used for the TCP connection (hostName
).See also
- continueInterruptedHandshake()#
If an application wants to conclude a handshake even after receiving
handshakeInterruptedOnError()
signal, it must call this function. This call must be done from a slot function attached to the signal. The signal-slot connection must be direct.- encrypted()#
This signal is emitted when
QSslSocket
enters encrypted mode. After this signal has been emitted,isEncrypted()
will return true, and all further transmissions on the socket will be encrypted.See also
- encryptedBytesAvailable()#
- Return type:
int
Returns the number of encrypted bytes that are awaiting decryption. Normally, this function will return 0 because
QSslSocket
decrypts its incoming data as soon as it can.- encryptedBytesToWrite()#
- Return type:
int
Returns the number of encrypted bytes that are waiting to be written to the network.
- encryptedBytesWritten(totalBytes)#
- Parameters:
totalBytes – int
This signal is emitted when
QSslSocket
writes its encrypted data to the network. Thewritten
parameter contains the number of bytes that were successfully written.See also
QSslSocket
emits this signal if a certificate verification error was found and if early error reporting was enabled inQSslConfiguration
. An application is expected to inspect theerror
and decide if it wants to continue the handshake, or abort it and send an alert message to the peer. The signal-slot connection must be direct.- ignoreSslErrors()#
This slot tells
QSslSocket
to ignore errors duringQSslSocket
‘s handshake phase and continue connecting. If you want to continue with the connection even if errors occur during the handshake phase, then you must call this slot, either from a slot connected tosslErrors()
, or before the handshake phase. If you don’t call this slot, either in response to errors or before the handshake, the connection will be dropped after thesslErrors()
signal has been emitted.If there are no errors during the SSL handshake phase (i.e., the identity of the peer is established with no problems),
QSslSocket
will not emit thesslErrors()
signal, and it is unnecessary to call this function.Warning
Be sure to always let the user inspect the errors reported by the
sslErrors()
signal, and only call this method upon confirmation from the user that proceeding is ok. If there are unexpected errors, the connection should be aborted. Calling this method without inspecting the actual errors will most likely pose a security risk for your application. Use it with great care!See also
- ignoreSslErrors(errors)
- Parameters:
errors – .list of QSslError
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
This is an overloaded function.
This method tells
QSslSocket
to ignore only the errors given inerrors
.Note
Because most SSL errors are associated with a certificate, for most of them you must set the expected certificate this SSL error is related to. If, for instance, you want to connect to a server that uses a self-signed certificate, consider the following snippet:
cert = QSslCertificate.fromPath("server-certificate.pem") error = QSslError(QSslError.SelfSignedCertificate, cert.at(0)) expectedSslErrors = QList() expectedSslErrors.append(error) socket = QSslSocket() socket.ignoreSslErrors(expectedSslErrors) socket.connectToHostEncrypted("server.tld", 443)
Multiple calls to this function will replace the list of errors that were passed in previous calls. You can clear the list of errors you want to ignore by calling this function with an empty list.
See also
- static implementedClasses([backendName={}])#
- Parameters:
backendName – str
- Return type:
.list of QSsl.ImplementedClass
This function returns backend-specific classes implemented by the backend named
backendName
. An emptybackendName
is understood as a query about the currently active backend.See also
ImplementedClass
activeBackend()
isClassImplemented()
- static isClassImplemented(cl[, backendName={}])#
- Parameters:
cl –
ImplementedClass
backendName – str
- Return type:
bool
Returns true if a class
cl
is implemented by the backend namedbackendName
. An emptybackendName
is understood as a query about the currently active backend.See also
- isEncrypted()#
- Return type:
bool
Returns
true
if the socket is encrypted; otherwise, false is returned.An encrypted socket encrypts all data that is written by calling write() or putChar() before the data is written to the network, and decrypts all incoming data as the data is received from the network, before you call read(), readLine() or getChar().
QSslSocket
emitsencrypted()
when it enters encrypted mode.You can call
sessionCipher()
to find which cryptographic cipher is used to encrypt and decrypt your data.See also
- static isFeatureSupported(feat[, backendName={}])#
- Parameters:
feat –
SupportedFeature
backendName – str
- Return type:
bool
Returns true if a feature
ft
is supported by a backend namedbackendName
. An emptybackendName
is understood as a query about the currently active backend.See also
SupportedFeature
supportedFeatures()
- static isProtocolSupported(protocol[, backendName={}])#
- Parameters:
protocol –
SslProtocol
backendName – str
- Return type:
bool
Returns true if
protocol
is supported by a backend namedbackendName
. An emptybackendName
is understood as a query about the currently active backend.See also
- localCertificate()#
- Return type:
Returns the socket’s local
certificate
, or an empty certificate if no local certificate has been assigned.See also
- localCertificateChain()#
- Return type:
.list of QSslCertificate
Returns the socket’s local
certificate
chain, or an empty list if no local certificates have been assigned.See also
Returns the current mode for the socket; either
UnencryptedMode
, whereQSslSocket
behaves identially toQTcpSocket
, or one ofSslClientMode
orSslServerMode
, where the client is either negotiating or in encrypted mode.When the mode changes,
QSslSocket
emitsmodeChanged()
See also
This signal is emitted when
QSslSocket
changes fromUnencryptedMode
to eitherSslClientMode
orSslServerMode
.mode
is the new mode.See also
- newSessionTicketReceived()#
If TLS 1.3 protocol was negotiated during a handshake,
QSslSocket
emits this signal after receiving NewSessionTicket message. Session and session ticket’s lifetime hint are updated in the socket’s configuration. The session can be used for session resumption (and a shortened handshake) in future TLS connections.Note
This functionality enabled only with OpenSSL backend and requires OpenSSL v 1.1.1 or above.
- ocspResponses()#
- Return type:
.list of QOcspResponse
This function returns Online Certificate Status Protocol responses that a server may send during a TLS handshake using OCSP stapling. The list is empty if no definitive response or no response at all was received.
See also
- peerCertificate()#
- Return type:
Returns the peer’s digital certificate (i.e., the immediate certificate of the host you are connected to), or a null certificate, if the peer has not assigned a certificate.
The peer certificate is checked automatically during the handshake phase, so this function is normally used to fetch the certificate for display or for connection diagnostic purposes. It contains information about the peer, including its host name, the certificate issuer, and the peer’s public key.
Because the peer certificate is set during the handshake phase, it is safe to access the peer certificate from a slot connected to the
sslErrors()
signal or theencrypted()
signal.If a null certificate is returned, it can mean the SSL handshake failed, or it can mean the host you are connected to doesn’t have a certificate, or it can mean there is no connection.
If you want to check the peer’s complete chain of certificates, use
peerCertificateChain()
to get them all at once.See also
- peerCertificateChain()#
- Return type:
.list of QSslCertificate
Returns the peer’s chain of digital certificates, or an empty list of certificates.
Peer certificates are checked automatically during the handshake phase. This function is normally used to fetch certificates for display, or for performing connection diagnostics. Certificates contain information about the peer and the certificate issuers, including host name, issuer names, and issuer public keys.
The peer certificates are set in
QSslSocket
during the handshake phase, so it is safe to call this function from a slot connected to thesslErrors()
signal or theencrypted()
signal.If an empty list is returned, it can mean the SSL handshake failed, or it can mean the host you are connected to doesn’t have a certificate, or it can mean there is no connection.
If you want to get only the peer’s immediate certificate, use
peerCertificate()
.See also
- peerVerifyDepth()#
- Return type:
int
Returns the maximum number of certificates in the peer’s certificate chain to be checked during the SSL handshake phase, or 0 (the default) if no maximum depth has been set, indicating that the whole certificate chain should be checked.
The certificates are checked in issuing order, starting with the peer’s own certificate, then its issuer’s certificate, and so on.
See also
QSslSocket
can emit this signal several times during the SSL handshake, before encryption has been established, to indicate that an error has occurred while establishing the identity of the peer. Theerror
is usually an indication thatQSslSocket
is unable to securely identify the peer.This signal provides you with an early indication when something’s wrong. By connecting to this signal, you can manually choose to tear down the connection from inside the connected slot before the handshake has completed. If no action is taken,
QSslSocket
will proceed to emittingsslErrors()
.See also
- peerVerifyMode()#
- Return type:
Returns the socket’s verify mode. This mode decides whether
QSslSocket
should request a certificate from the peer (i.e., the client requests a certificate from the server, or a server requesting a certificate from the client), and whether it should require that this certificate is valid.The default mode is
AutoVerifyPeer
, which tellsQSslSocket
to useVerifyPeer
for clients andQueryPeer
for servers.See also
- peerVerifyName()#
- Return type:
str
Returns the different hostname for the certificate validation, as set by
setPeerVerifyName
or byconnectToHostEncrypted
.- Parameters:
authenticator –
QSslPreSharedKeyAuthenticator
QSslSocket
emits this signal when it negotiates a PSK ciphersuite, and therefore a PSK authentication is then required.When using PSK, the client must send to the server a valid identity and a valid pre shared key, in order for the SSL handshake to continue. Applications can provide this information in a slot connected to this signal, by filling in the passed
authenticator
object according to their needs.Note
Ignoring this signal, or failing to provide the required credentials, will cause the handshake to fail, and therefore the connection to be aborted.
Note
The
authenticator
object is owned by the socket and must not be deleted by the application.See also
Returns this socket’s private key.
See also
- protocol()#
- Return type:
Returns the socket’s SSL protocol. By default,
SecureProtocols
is used.See also
- sessionCipher()#
- Return type:
Returns the socket’s cryptographic
cipher
, or a null cipher if the connection isn’t encrypted. The socket’s cipher for the session is set during the handshake phase. The cipher is used to encrypt and decrypt data transmitted through the socket.QSslSocket
also provides functions for setting the ordered list of ciphers from which the handshake phase will eventually select the session cipher. This ordered list must be in place before the handshake phase begins.- sessionProtocol()#
- Return type:
Returns the socket’s SSL/TLS protocol or UnknownProtocol if the connection isn’t encrypted. The socket’s protocol for the session is set during the handshake phase.
See also
- static setActiveBackend(backendName)#
- Parameters:
backendName – str
- Return type:
bool
Returns true if a backend with name
backendName
was set as active backend.backendName
must be one of names returned byavailableBackends()
.Note
An application cannot mix different backends simultaneously. This implies that a non-default backend must be selected prior to any use of
QSslSocket
or related classes, e.g.QSslCertificate
orQSslKey
.See also
- setLocalCertificate(certificate)#
- Parameters:
certificate –
QSslCertificate
Sets the socket’s local certificate to
certificate
. The local certificate is necessary if you need to confirm your identity to the peer. It is used together with the private key; if you set the local certificate, you must also set the private key.The local certificate and private key are always necessary for server sockets, but are also rarely used by client sockets if the server requires the client to authenticate.
Note
Secure Transport SSL backend on macOS may update the default keychain (the default is probably your login keychain) by importing your local certificates and keys. This can also result in system dialogs showing up and asking for permission when your application is using these private keys. If such behavior is undesired, set the QT_SSL_USE_TEMPORARY_KEYCHAIN environment variable to a non-zero value; this will prompt
QSslSocket
to use its own temporary keychain.See also
- setLocalCertificate(fileName[, format=QSsl.Pem])
- Parameters:
fileName – str
format –
EncodingFormat
This is an overloaded function.
Sets the socket’s local
certificate
to the first one found in filepath
, which is parsed according to the specifiedformat
.- setLocalCertificateChain(localChain)#
- Parameters:
localChain – .list of QSslCertificate
Sets the certificate chain to be presented to the peer during the SSL handshake to be
localChain
.- setPeerVerifyDepth(depth)#
- Parameters:
depth – int
Sets the maximum number of certificates in the peer’s certificate chain to be checked during the SSL handshake phase, to
depth
. Setting a depth of 0 means that no maximum depth is set, indicating that the whole certificate chain should be checked.The certificates are checked in issuing order, starting with the peer’s own certificate, then its issuer’s certificate, and so on.
See also
- setPeerVerifyMode(mode)#
- Parameters:
mode –
PeerVerifyMode
Sets the socket’s verify mode to
mode
. This mode decides whetherQSslSocket
should request a certificate from the peer (i.e., the client requests a certificate from the server, or a server requesting a certificate from the client), and whether it should require that this certificate is valid.The default mode is
AutoVerifyPeer
, which tellsQSslSocket
to useVerifyPeer
for clients andQueryPeer
for servers.Setting this mode after encryption has started has no effect on the current connection.
See also
- setPeerVerifyName(hostName)#
- Parameters:
hostName – str
Sets a different host name, given by
hostName
, for the certificate validation instead of the one used for the TCP connection.See also
Sets the socket’s private
key
tokey
. The private key and the localcertificate
are used by clients and servers that must prove their identity to SSL peers.Both the key and the local certificate are required if you are creating an SSL server socket. If you are creating an SSL client socket, the key and local certificate are required if your client must identify itself to an SSL server.
See also
- setPrivateKey(fileName[, algorithm=QSsl.Rsa[, format=QSsl.Pem[, passPhrase=QByteArray()]]])
- Parameters:
fileName – str
algorithm –
KeyAlgorithm
format –
EncodingFormat
passPhrase –
QByteArray
This is an overloaded function.
Reads the string in file
fileName
and decodes it using a specifiedalgorithm
and encodingformat
to construct anSSL key
. If the encoded key is encrypted,passPhrase
is used to decrypt it.The socket’s private key is set to the constructed key. The private key and the local
certificate
are used by clients and servers that must prove their identity to SSL peers.Both the key and the local certificate are required if you are creating an SSL server socket. If you are creating an SSL client socket, the key and local certificate are required if your client must identify itself to an SSL server.
See also
- setProtocol(protocol)#
- Parameters:
protocol –
SslProtocol
Sets the socket’s SSL protocol to
protocol
. This will affect the next initiated handshake; calling this function on an already-encrypted socket will not affect the socket’s protocol.See also
- setSslConfiguration(config)#
- Parameters:
config –
QSslConfiguration
Sets the socket’s SSL configuration to be the contents of
configuration
. This function sets the local certificate, the ciphers, the private key and the CA certificates to those stored inconfiguration
.It is not possible to set the SSL-state related fields.
- sslConfiguration()#
- Return type:
Returns the socket’s SSL configuration state. The default SSL configuration of a socket is to use the default ciphers, default CA certificates, no local private key or certificate.
The SSL configuration also contains fields that can change with time without notice.
- sslErrors(errors)#
- Parameters:
errors – .list of QSslError
QSslSocket
emits this signal after the SSL handshake to indicate that one or more errors have occurred while establishing the identity of the peer. The errors are usually an indication thatQSslSocket
is unable to securely identify the peer. Unless any action is taken, the connection will be dropped after this signal has been emitted.If you want to continue connecting despite the errors that have occurred, you must call
ignoreSslErrors()
from inside a slot connected to this signal. If you need to access the error list at a later point, you can callsslHandshakeErrors()
.errors
contains one or more errors that preventQSslSocket
from verifying the identity of the peer.Note
You cannot use Qt::QueuedConnection when connecting to this signal, or calling
ignoreSslErrors()
will have no effect.See also
Returns a list of the last SSL errors that occurred. This is the same list as
QSslSocket
passes via thesslErrors()
signal. If the connection has been encrypted with no errors, this function will return an empty list.See also
- static sslLibraryBuildVersionNumber()#
- Return type:
int
Returns the version number of the SSL library in use at compile time. If no SSL support is available then this will return -1.
See also
- static sslLibraryBuildVersionString()#
- Return type:
str
Returns the version string of the SSL library in use at compile time. If no SSL support is available then this will return an empty value.
See also
- static sslLibraryVersionNumber()#
- Return type:
int
Returns the version number of the SSL library in use. Note that this is the version of the library in use at run-time not compile time. If no SSL support is available then this will return -1.
- static sslLibraryVersionString()#
- Return type:
str
Returns the version string of the SSL library in use. Note that this is the version of the library in use at run-time not compile time. If no SSL support is available then this will return an empty value.
- startClientEncryption()#
Starts a delayed SSL handshake for a client connection. This function can be called when the socket is in the
ConnectedState
but still in theUnencryptedMode
. If it is not yet connected, or if it is already encrypted, this function has no effect.Clients that implement STARTTLS functionality often make use of delayed SSL handshakes. Most other clients can avoid calling this function directly by using
connectToHostEncrypted()
instead, which automatically performs the handshake.- startServerEncryption()#
Starts a delayed SSL handshake for a server connection. This function can be called when the socket is in the
ConnectedState
but still inUnencryptedMode
. If it is not connected or it is already encrypted, the function has no effect.For server sockets, calling this function is the only way to initiate the SSL handshake. Most servers will call this function immediately upon receiving a connection, or as a result of having received a protocol-specific command to enter SSL mode (e.g, the server may respond to receiving the string “STARTTLS\r\n” by calling this function).
The most common way to implement an SSL server is to create a subclass of
QTcpServer
and reimplementincomingConnection()
. The returned socket descriptor is then passed tosetSocketDescriptor()
.- static supportedFeatures([backendName={}])#
- Parameters:
backendName – str
- Return type:
.list of QSsl.SupportedFeature
This function returns features supported by a backend named
backendName
. An emptybackendName
is understood as a query about the currently active backend.See also
SupportedFeature
activeBackend()
- static supportedProtocols([backendName={}])#
- Parameters:
backendName – str
- Return type:
.list of QSsl.SslProtocol
If a backend with name
backendName
is available, this function returns the list of TLS protocol versions supported by this backend. An emptybackendName
is understood as a query about the currently active backend. Otherwise, this function returns an empty list.- static supportsSsl()#
- Return type:
bool
Returns
true
if this platform supports SSL; otherwise, returns false. If the platform doesn’t support SSL, the socket will fail in the connection phase.- waitForEncrypted([msecs=30000])#
- Parameters:
msecs – int
- Return type:
bool
Warning
This section contains snippets that were automatically translated from C++ to Python and may contain errors.
Waits until the socket has completed the SSL handshake and has emitted
encrypted()
, ormsecs
milliseconds, whichever comes first. Ifencrypted()
has been emitted, this function returns true; otherwise (e.g., the socket is disconnected, or the SSL handshake fails), false is returned.The following example waits up to one second for the socket to be encrypted:
socket.connectToHostEncrypted("imap", 993) if socket.waitForEncrypted(1000): qDebug("Encrypted!")
If msecs is -1, this function will not time out.