SIGNING¶

The process if signing has been mentioned already, but not described. Basically, you use your private key to generate a value over some given data that proves you have the private key. The certificate is ised to mathematically verify the signature.

Two things are normally done with this:

In a public key exchange, the entity wishing to be authorized sends a certificate. The authorizing entity will look through it's CA for a certificate that has signed the sent certificate. If the authorizing entity finds a certificate that can be used to validate the sent certificate, the sent certificate is valid.

After that, the authorizing entity sends some generally random data to the other entity. The other entity will take that data, perhaps some other important data that it want to make sure is not modified in the transfer, and signs that data. It sends the signature back to the authorizing entity. The authorizing entity can then use the data and the signature to validate that the sending entity has the private key associated with the certificate.

This is basically how https works. Note it is the web client that authenticates the web server, not the other way around. This proves that you are connecting to the entity you say you are connecting to. The authentication of a web client to the web server is generally done via a different mechanism (though SSL/TLS used by the ssl gensio has a way to do it, it is not generally used for that purpose).

In the web server scenario, data in the certificate (specifically the Common Name and Subject Alternate Name) must match the name of the web page to which you are connecting. The ssl and certauth gensios do not do this authentication, that is up to the user if it is necessary.

ENCRYPTING¶

The certificate can be used to encrypt data that can only be decrypted with the private key. When establishing an encrypted connection, this is generally used to transfer a symmetric cryptography key from one entity to another (the authorizing entity to the requesting entity in the case above). You could encrypt all the data with the public key, but that is very expensive and in our example above would require certificates and private keys on both ends.

SELF-SIGNED CERTIFICATES¶

It is possible to create a certificate that can act as its own certificate authority. This is how ssh works. You create a public and private key. You put the public key in the .ssh/authorized_keys directory on systems where you want to log in. The certificate acts as both the public key (as part of the initial transfer) and the CA (in the authorized_key directory) for authorizing you use of the system you are logging in to.

ssh also stores places it has connected to in .ssh/known_hosts, which is the CA in the opposite direction. This is why it asks you if you have never connected to a system before, it doesn't have the key in its CA. Or why, if you connect to a system you have connected to before and the certificates don't match or fail validation, it complains about it.

So if you are using self-signed certificates, you need to be careful to put only ones you trust in the CA. This is obviously not possible in a large system like the world wide web, thus the creation of third-party trusted CAs.

TRUST AND CRYPTOGRAPHY¶

The above discussions mention trust several times. Cryptography does not remove the need for trust. It just makes trust more convenient. If someone sends you a certificate, you need to validate that it was actually them that sent you the certificate, and that it was not modified in transit. If you add that certificate to your CA, you are trusting the certificate, and you better make sure (with fingerprints, generally, see the openssl docs for details) that it came from a trusted entity.

The hardest part of cryptography in general is key management. Breaking cryptographic algorithms is really hard. Getting people to divulge private keys or use the wrong keys is a lot easier.

For more on cryptography in general, and cryptography and trust, Bruce Schneier has some excellent books on the subject.

Dynamic Ports¶

For accepters, if the port is specified as zero, a random port in the dynamic port range specified by IANA will be chosen. If more than one address is present, the same port will be chosen for all addresses. You can fetch the port using the gensio_acc_control() function with the option GENSIO_ACC_CONTROL_LPORT.

Out Of Band Data¶

TCP supports out of band (oob) data, which is data that will be delivered out of order as soon as possible. This comes in a normal read, but with "oob" in the auxdata. You can send oob data by adding "oob" to the write auxdata, but oob writes are limited to 1 byte and writing any more than this results in undefined behavior. Note that "oobtcp" is also delivered and accepted in auxdata, so you can tell TCP oob data from other oob data.

Options¶

In addition to readbuf, the tcp gensio takes the following options:

nodelay[=true|false]

Sets nodelay on the socket.

laddr=<addr>

An address specification to bind to on the local socket to set the local address.

reuseaddr[=true|false]

Set SO_REUSEADDR on the socket, good for accepting gensios only. Defaults to true.

tcpd=on|print|off

Accepter only, sets tcpd handling on the socket. If "on", tcpd is enforced and the connection is just closed on a tcpd denial. "print" is like on, except it writes "Access Denied" on the socket before closing it. "off" disabled tcpd handling on the socket. Defaults to on. Not available if tcpd is disabled at compile time.

tcpdname=<name>

Accepter only, sets the name to use for tcpd access control. This defaults to "gensio", and the default can be overridden with gensio_set_progname(). This option allows you to override it on a per-gensio accepter basis. Not available if tcpd is disabled at compile time.

Remote Address String¶

The remote address will be in the format "[ipv4|ipv6],<addr>,<port>" where the address is in numeric format, IPv4, or IPv6.

Remote Address¶

TCP returns a standard struct sockaddr for GENSIO_CONTROL_RADDR_BIN control.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const struct gensio_addr *"

Options¶

In addition to readbuf, the udp gensio takes the following options:

laddr=<addr>

An address specification to bind to on the local socket to set the local address.

nocon[=true|false]

Don't be connection oriented, just receive all packets and deliver them without establishing connections. Only valid for the client gensio. The receive address is passed into the auxdata prefixed by "addr:", this is the address formatted by gensio_addr_to_str().

mloop[=true|false]

If false, multicast packets transmitted will not be received on the local host. If true, they will.

mttl=[1-255]

Set the multicast time-to-live value. The default is 1, meaning multicast stays in the local network. Increasing this value increases the number of hops over multicast routers a send packet will traverse.

mcast=<addr>

Add an address to receive multicast packets on. There is no port number, this is just addresses. You can specify multiple addresses in a single multicast option and/or the multicast option can be used multiple times to add multiple multicast addresses.

reuseaddr[=true|false]

Set SO_REUSEADDR on the socket, good for connecting and accepting gensios. Defaults to false.

Remote Address String¶

The remote address will be in the format "[ipv4|ipv6],<addr>,<port>" where the address is in numeric format, IPv4, or IPv6.

Remote Address¶

UDP returns a standard struct sockaddr for GENSIO_CONTROL_RADDR_BIN control.

UDP Multicast¶

Multicast can be used on UDP gensios with the nocon, maddr and laddr options. To set up a multicast, create a client UDP gensio and set the laddr for the receive port and the destination address to the multicast and enable nocon, like:

"udp(mcast='ff02::1',laddr='ipv6,3000',nocon),ff02::1,3000"

and you will receive and send data on the multicast address. The laddr option is required to set the port to receive on. It means you will have a local address, too, and will receive packets on that, too.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const struct gensio_addr *"

Nagle and SCTP¶

SCTP implements the Nagle algorithm by default, which can interact badly if sack_freq is set to more than one. At least Linux defaults sack_freq to 2, but the gensio overrides this to avoid surprising behaviour. What happens is in some situations you can get an outstanding packet that is unacked, since sack_freq is greater than one. The Nagle algorithm will not send any new data until any already sent data is acked. So one end is waiting for a new packet to send a sack, and the other end is holding data until it gets a sack. So you get stuck waiting for the sack_delay where the sack will go out and kick things back off again.

You need to be aware of this if you modify sack_freq.

Options¶

In addition to readbuf, the sctp gensio takes the following options:

instreams=<n>

ostreams=<n>

These specify the number of incoming and outgoing streams for the connection. The default is one. The stream is given in the auxdata for read and write in the format "stream=<n>".

sack_freq=<n>

sack_delay=<n>

These specify the handling of selective acknowledgements (sacks). sack_freq sets the number of outstanding packets that must be received before sending a sack. The default is 1, meaning it doesn't wait at all. sack_delay sets the maximum time before a sack is sent if outstanding packets are present, in milliseconds. The default is 10, but this is disabled if sack_freq is set to 1. Setting either of these to 0 enables the system defaults.

nodelay[=true|false]

Sets nodelay on the socket.

laddr=<addr>

An address specification to bind to on the local socket to set the local address.

reuseaddr[=true|false]

Set SO_REUSEADDR on the socket, good for accepting gensios only. Defaults to true.

Port 0 is supported just like TCP for accepters, see Dynamic Ports in the TCP section above for details.

SCTP support out of band (oob) data, which is data that will be delivered out of order as soon as possible. This comes in a normal read, but with "oob" in the auxdata. You can send oob data by adding "oob" to the write auxdata.

See documentation on SCTP for more details.

Remote Address String¶

The remote address will be in the format "[ipv4|ipv6],<addr>,<port>[;[ipv4|ipv6],<addr>,<port>[...]]" where the address is in numeric format, IPv4, or IPv6. Each remote address for the SCTP connection is listed.

Remote Address¶

SCTP returns a packed struct sockaddr for GENSIO_CONTROL_RADDR_BIN control, per SCTP semantics.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const struct gensio_addr *"

Options¶

In addition to readbuf, the unix gensio takes the following options:

delsock[=true|false]

If the socket path already exists, delete it before opening the socket.

umode=[0-7|[rwx]*]

Set the user file mode for the unix socket file. This is the usual read(4)/write(2)/execute(2) bitmask per chmod, but only for the user portion. If a mode is specified, all other modes default to "6" (rw) +unless they are specified, and the final mode is modified by the umask +per standard *nix semantics. If no mode is specified, it is set to +the default and not modified. Note that the perm option below is +probably a better way to set this.

gmode=[0-7|[rwx]*]

Set the group file mode for the unix socket file, see umode for details.

omode=[0-7|[rwx]*]

Set the other file mode for the uix socket file, see umode for details.

perm=[0-7][0-7][0-7]

Set the full mode for the unix socket file per standard *nix semantics, modified by umask as the above mode operations are.

owner=<name>

Set the owner of the unix socket file to the given user.

group=<name>

Set the group of the unix socket file to the given group.

Remote Address String¶

The remote address will be: "unix,<socket path>".

Remote Address¶

UNIX returns a standard struct sockaddr_un for GENSIO_CONTROL_RADDR_BIN control.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const struct gensio_addr *"

Options¶

In addition to readbuf, the serialdev gensio takes the following options:

nouucplock[=true|false]

disables UUCP locking on the device. Useful for /dev/tty, which shouldn't use locking. This is not available as a default.

drain_time=off|<time in 100ths of a second>

The total amount of time to wait for the data to be sent on the serial port at close time. Close will be delayed this amount of time, or until all the data is transmitted. Default is off. When setting the default value for this, "off" will not be accepted, use -1 instead.

char_drain_wait=off|<time in 100ths of a second>

At close time, if this much time elapses and no character is sent, finish the close. Default is 50 (.5 seconds). Note that if both this and drain_time are off, if the serial port is hung on flow control, it will never close. When setting the default value for this, "off" will not be accepted, use -1 instead.

There are a plethora of serialoptions, available as defaults:

[speed=]<speed><parity><databits><stopbits>

This is a normal serial port configuration specification, like "9600N81". The "speed=" at the beginning is optional, but "speed" is a default type for this.

wronly[=true|false]

Set the device to write only. No termios definition is done on the port. This can be done to talk to a line printer port, for instance. False by default.

nobreak[=true|false]

Clear the break line at start (or don't clear it). Default it to not clear it (false).

rs485=off|<delay rts before send>:<delay rts after send>[:<conf>[:<conf>]]

Set up RS-485 for the serial port. The first two parameters set the RTS delay (in milliseconds) of RTS before and after sending. The conf values can be: "rts_on_send" - RTS set when sending, "rts_after_send" - RTS set after sending, "rx_during_tx" - can receive and transmit at the same time, and "terminate_bus" - enable bus termination.

Using "off" will disable rs485; that is useful for overriding a user-defined default setting. Default is "off".

xonxoff[=true|false]

Enable/disable xon/xoff flow control. Default is false.

rtscts[=true|false]

Enable/disable rts/cts flow control. Default is false.

local[=true|false]

Ignore/don't ignore the modem control lines. The default it to not ignore them (false). However, if you don't ignore the modem control lines, it can result in long shutdown delays.

dtr[=on|off]

Force the DTR line to be on or off when the gensio is opened. Note that the order of the dtr and rts options matter. Whichever comes first in the options will be set first. This can be useful if the lines need to be sequenced in a certain order for the piece of hardware involved.

rts[=on|off]

Force the RTS line to be on or off when the gensio is opened. See the dtr section above for notes on ordering of lines.

hangup-when-done[=true|false]

Lower/don't lower the modem control lines when the gensio is closed. The default is to not lower the modem control lines on close (false). custspeed[=true|false] Allow/don't allow setting of custom baud rates. Ignored if custom baud rates are not supported. Normally only standard baud rates are supported (1200, 2400, etc). If supported by the hardware, this allows any arbitrary value to be set.

Remote Address String¶

The remote address string is the device and serial parms, in a format like "9600N81[,<option>[,<option>[...]]]". Options are one of: XONXOFF, RTSCTS, CLOCAL, HANGUP_WHEN_DONE, RTSHI, RTSLO, DTRHI, DRLO, offline.

Remote ID¶

The remote ID for the serial dev is the file descriptor returned as an integer.

Direct Allocation x¶

Allocated as a terminal gensio with gdata as a "const char *" with the device and parameters string.

Options¶

In addition to readbuf, a connecting stdio takes the following options:

self[=true|false]

Instead of starting a program, connect to the running program's stdio. This is the same as an accepting stdio gensio, except you don't have to go through the accept process.

console[=true|false]

Like self, except connect to the running program's console device, /dev/tty on Unix and CONIN$/CONOUT$ on Windows. Useful for reading passwords and such.

start-dir=path

Start the subprogram in the given path instead of the current directory.

raw[=true|false]

For a "self", console, or accepter version of the gensio, put the I/O in "raw" mode, meaning character at a time, turn off ^C, etc. This will fail on pipes or files.

stderr-to-stdout

Send standard error output to standard out instead of having a separate channel for it.

noredir-stderr

Do not modify the stderr for the program, use the calling program's stderr. This can be useful if you want to see stderr output from a program.

Channels¶

The stdio connecting gensio that start another program does not provide stderr as part of the main gensio. You must create a channel with gensio_alloc_channnel() and then open it get stderr output. The args for gensio_alloc_channel() may be an optional "readbuf=<num>" and sets the size of the input buffer.

Remote Address String¶

The remote address string is either "stdio,<args>" for the main channel or "stderr,<args>" for the error channel. The args will be a set of quoted strings with a space between each string, one for each argument, with '"' around each argument, each '"' in the string converted to '\"' and each '\' in the string converted to '\\'.

Remote ID¶

The remote ID is the pid for the remote device, only for connecting gensios that start a program, not for any other type.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const char * const args[]" for the gensio. gdata is not used for the accepter.

Options¶

In addition to readbuf, a connecting echo takes the following options:

noecho[=true|false]

Instead of echoing the data, just become a data sink.

data=<str>

Supply the given data as the data to be read. When combined with noecho, it will create a gensio that just supplies the given data then returns a GE_REMCLOSE when done.

Remote Address String¶

The remote address string is "echo".

Direct Allocation¶

Allocated as a terminal gensio, gdata is not used.

Options¶

In addition to readbuf, a connecting file takes the following options:

infile=filename

Set the input filename.

outfile=filename

Set the output filename.

read_close[=true|false]

If this is true (the default), cause a GE_REMCLOSE error on read when all the file data is ready. If false, just stop returning data and don't do the GE_REMCLOSE. This is useful if you just want to inject a bunch of data then do nothing.

create[=true|false]

Create the output file if it does not exist.

umode=[0-7|[rwx]*]

Set the user file mode for the file if the file is created. This is the usual read(4)/write(2)/execute(2) bitmask per chmod, but only for the user portion. If a mode is specified, all other modes default to "6" (rw) +unless they are specified, and the final mode is modified by the umask +per standard *nix semantics. If no mode is specified, it is set to +the default and not modified. Note that the perm option below is +probably a better way to set this.

gmode=[0-7|[rwx]*]

Set the group file mode for the file if the file is created, see umode for details.

omode=[0-7|[rwx]*]

Set the other file mode for the file if the file is created, see umode for details.

perm=[0-7][0-7][0-7]

Set the full mode for the file per standard *nix semantics, modified by umask as the above mode operations are.

Remote Address String¶

The remote address string is "file([infile=<filename][,][outfile=<filename>])".

Direct Allocation¶

Allocated as a terminal gensio, gdata is not used.

Direct Allocation¶

Allocated as a terminal gensio, gdata is not used.

Options¶

In addition to readbuf, the ipmisol gensio takes the following options:

writebuf=<n>

to set the size of the write buffer.

It also takes the following ipmisol options:

9600, 19200, 38400, 57600, 115200

Baud rate, 9600 by default. Anything after the number is ignored, for compatibility with things like "N81". You cannot set those values for ipmisol, they are fixed at "N81".

nobreak[=true|false]

Disable break processing. False by default.

authenticated[=true|false]

Enable or disable authentication. True by default.

encrypted[=true|false]

Enable or disable encrypted. True by default.

deassert-CTS-DCD-DSR-on-connect[=true|false]

False by default

shared-serial-alert=fail|deferred|succeed

Behavior of handling serial alerts. fail by default.

ack-timeout=<number>

The time (in microseconds) when an ack times out. 1000000 by default.

ack-retries=<number>

The number of times (ack-timeouts) an ack is re-sent before giving up. 10 by default.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const char *".

Options¶

In addition to readbuf, the telnet gensio takes the following options:

writebuf=<n>

set the size of the write buffer.

rfc2217[=true|false]

enable or disable RFC2217 mode for this gensio. If this is enabled and the remote end of the connection supports RFC2217 also, the gensio will be set up as a serial gensio and you can do normal serial gensio handling on it.

mode=client|server

Set the telnet mode to client or server. This lets you run a telnet server on a connecting gensio, or a telnet client on an accepter gensio.

Remote info¶

telnet passes remote id, remote address, and remote string to the child gensio.

Options¶

In addition to readbuf, the SSL gensio takes the following options:

writebuf=<n>

set the size of the write buffer.

CA=<filepath>

Set a place to look for certificates for authorization. If this ends in a "/", then this is expected to be a directory that contains files with certificates that must be hashed per OpenSSL (see the "openssl rehash" command for details. Otherwise it is a single file that contains one or more certificates. The default CA path is used if not specified. Note that setting this to an empty string disables it, so you can override a default value if necessary.

key=<filename>

Specify the file to get the private key for the server. This is required for servers. It may be specified for clients, and is required for the client if the server requires a certificate (it has CA set).

cert=<filename>

Specify the file that contains the certificate used for the connection. If this is not specified, the certificate is expected to be in the key file. Note that setting this to an empty string disables it, so you can override a default value if necessary.

mode=client|server

Normally an accepter gensio is in server mode and a connecting gensio is in client mode. This can be used to switch the roles and run in SSL server mode on a connecting gensio, or vice versa.

clientauth[=true|false]

Normally a client is not authorized by the server. This requires that the client provide a certificate and authorizes that certificate. Ignored for client mode.

allow-authfail[=true|false]

Normally if the remote end certificate is not valid, the SSL gensio will close the connection. This open allows the open to succeed with an invalid or missing certificate. Note that the user should verify that authentication is set using gensio_is_authenticated().

Verification of the common name is not done. The application should do this, it can fetch the common name and other certificate data through a control interface.

You can use self-signed certificates in this interface. Just be aware of the security ramifications. This gensio is fairly flexible, but you must use it carefully to have a secure interface.

The SSL gensio will call the gensio event callback (client) or the gensio acceptor event callback (server) after the certificate is received but before it is validated with the GENSIO_EVENT_PRECERT_VERIFY or GENSIO_ACC_EVENT_PRECERT_VERIFY events. This allows the user to validate data from the certificate (like common name) with GENSIO_CONTROL_GET_PEER_CERT_NAME or set a certificate authority for the validation with GENSIO_CONTROL_CERT_AUTH.

Remote info¶

ssl passes remote id, remote address, and remote string to the child gensio.

Options¶

The certauth gensio takes the following options:

CA=<filepath>

Set a place to look for certificates for authorization. If this ends in a "/", then this is expected to be a directory that contains files with certificates that must be hashed per OpenSSL, see the gensio-keygen(1) in the rehash section for details. Otherwise it is a single file that contains one or more certificates. The default CA path for openssl is used if not specified. This is used on the server only, it is ignored on clients. Note that setting this to an empty string disables it, so you can override a default value if necessary.

key=<filename>

Specify the file to get the private key for the client. This is required for clients. It is ignored on server.

cert=<filename>

Specify the file to get the private key for the client. This is required for clients. It is ignored on server. If this is not specified, the certificate is expected to be in the key file. Note that setting this to an empty string disables it, so you can override a default value if necessary.

username=<name>

Specify a username to authenticate with on the remote end. This is required for the client. It is ignored on the server.

service=<string>

Set the remote service requested by the client. Optional, but the other end may reject the connection if it is not supplied. Ignored on the server.

password=<string>

Specify the password to use for password authentication. This is not recommended, the callback is more secure to use.

mode=client|server

Normally an accepter gensio is in server mode and a connecting gensio is in client mode. This can be used to switch the roles and run in server mode on a connecting gensio, or vice versa.

allow-authfail[=true|false]

Normally if the remote end certificate is not valid, the certauth gensio will close the connection. This open allows the open to succeed with an invalid or missing certificate. Note that the user should verify that authentication is set using gensio_is_authenticated().

use-child-auth[=true|false]

If the child gensio is authenticated, then do not run the protocol, just go straight into passthrough mode and don't do any authentication.

enable-password[=true|false]

On the server, allow passwords for login. On the client, send a password if asked for one. By default passwords are disabled. Use of passwords is much less secure than certificates, so this is discouraged.

enable-2fa[=true|false]

On the server, request 2-factor authentication data from the client. This is only useful for situations where the 2-factor data is known before startup, like Google Authenticator or other things of that nature. It is not useful for text/email types of things that send the data after the connection is initiated. But those are usually interactive and can be handled with interactive methods.

2fa=<string>

On the client, provide the given 2-factor authentication data to the server if it asks for it.

Verification of the common name is not done. The application should do this, it can fetch the common name and other certificate data through a control interface. It may also use the username fetched through the control interface.

You can use self-signed certificates in this interface. Just be aware of the security ramifications. This gensio is fairly flexible, but you must use it carefully to have secure authentication.

The certauth gensio has 4 major callbacks dealing with authentication of the user. They may or may not be called depending on the circumstances. The normal events come in if you have allocated a gensio and are doing an open. The _ACC_ events come in if it is coming in from an accept and there is no gensio reported yet. In the _ACC_ case, be careful, do not use the given gensio for anything but checking certificate and username parameters, and do not save it.

All these calls should return 0 if they want the authentication to immediately succeed, EKEYREJECTED if they reject the authentication, ENOTSUP if they want certauth to ignore that part of the authentication, or any other errno will result in the connetion being shut down.

The callbacks are:

GENSIO_EVENT_AUTH_BEGIN / GENSIO_ACC_EVENT_AUTH_BEGIN

On the server side, this is called when to authentication is requested buy the client. The username will be available if the user provided it via GENSIO_CONTROL_USERNAME.

GENSIO_EVENT_PRECERT_VERIFY / GENSIO_ACC_EVENT_PRECERT_VERIFY

On the server side, thi is called after the certificate has been received but before it is verified. The user can use this to query the certificate and update the certificate authority based on username or certificate information.

GENSIO_EVENT_VERIFY_PASSWORD / GENSIO_ACC_EVENT_VERIFY_PASSWORD

On the server side, this is called if the certificate verification has failed and after the password has been requested from the remote end. The password is passed in, it is cleared immediately after this call.

GENSIO_EVENT_REQUEST_PASSWORD / GENSIO_ACC_EVENT_REQUEST_PASSWORD

On the client side, this is called if the server requests that a password be sent and the password is not already set for the gensio. The requested password is immediately cleared after being sent to the server.

Remote info¶

certauth passes remote id, remote address, and remote string to the child gensio.

Options¶

A mux gensio takes the following options:

max_channels=<n>

Allow at most <n> channels to be created in the mux. The default is 1000. The minimum value of <n> is 1, the maximum is 65536.

service=<string>

Set the remote service requested by the client. Optional, but the other end may reject the connection if it is not supplied. Ignored on the server.

mode=client|server

By default a mux accepter is a server and a mux connecter is a client. The protocol is mostly symmetric, but it's hard to kick things off properly if both sides try to start things. This option lets you override the default mode in case you have some special need to do so.

When the open is complete on the mux gensio, it will work just like a transparent filter with message demarcation. In effect, you have one channel open.

Creating Channels¶

To create a channel, call the gensio_alloc_channel() function on the mux gensio. This will return a new gensio that is a channel on the mux gensio. You can pass in arguments, which is an array of strings, currently readbuf, writebuf, and service are accepted. The service you set here will be set on the remote channel so the other end can fetch it. The new channel needs to be opened with gensio_open() before it can be used.

As you might imaging, the other end of a mux needs to know about the new channel. If one end (either end, doesn't matter) calls gensio_alloc_channel() and then opens the new channel, the other end will get a GENSIO_EVENT_NEW_CHANNEL event as described in the Streams and Channels section. You can call it using any mux channel. The first element in the auxdata is the service.

You can modify the service value after you allocate the channel but before you open it.

Out Of Band Messages¶

mux support out of band (oob) data, which is data that will be delivered normally. This comes in a normal read, but with "oob" in the auxdata. You can send oob data by adding "oob" to the write auxdata. You should normally use the "eom" flag so the end of the out of band messages ismarked.

This is so you can send special data outside of the normal processing of data.

Mux Events¶

As you might imaging, normal data events come through the gensio channel they are associated with. Close events will, too. If a mux gensio closes abnormally (like the underlying connection fails) you will get a read error on each channel.

New channel events (and other global events coming from lower gensios, like if you are running over ssl or telnet) come in through the original gensio normally. However, you can close that, another channel will be chosen to receive those event. In general, it's best to handle the global events on all channels and not assume.

Closing and Freeing a Mux¶

To close a mux gensio, just close all channels associated with it. There is no global close mechanism (you would not believe the complexity that adds). Once you have closed a mux gensio, you can re-open it with gensio_open(). It will not recreate all the channels for you, you will have one channel, and the channel you use to call gensio_open() will become the first channel.

You cannot re-open individual channels.

To free a mux gensio, you must free all the channels on it.

Options¶

In addition to readbuf, the pty gensio takes the following options. These options are only allowed if the pty is unattached. ptys with programs run on them need to follow the standard semantics.

link=<filename>

create a symbolic link from filename to the pty name. This way you can have a fixed reference to refer to the pty. Standard permissions apply. Without forcelink the open will file if filename already exists. Unix only.

forcelink[=true|false]

if link is specified, if a file already exists where the symbolic link is, replace it. Be careful, it deletes whatever is there indiscriminately.

start-dir=path

Start the subprogram in the given path instead of the current directory.

raw[=true|false]

causes the pty to be set in raw mode at startup. This is important for anything that will start writing immediately to the pty. If you don't set this, echo will be on and writes on the master will be echoed back. In general, this is useful for unattached ptys. It was added for testing, but will be usedful in many situations.

umode=[0-7|[rwx]*]

Set the user file mode for the pty slave. This is the usual read(4)/write(2)/execute(2) bitmask per chmod, but only for the user portion. If a mode is specified, all other modes default to "6" (rw) +unless they are specified, and the final mode is modified by the umask +per standard *nix semantics. If no mode is specified, it is set to +the default and not modified. Note that the perm option below is +probably a better way to set this.

gmode=[0-7|[rwx]*]

Set the group file mode for the pty slave, see umode for details.

omode=[0-7|[rwx]*]

Set the other file mode for the pty slave, see umode for details.

perm=[0-7][0-7][0-7]

Set the full mode for the pty per standard *nix semantics, modified by umask as the above mode operations are.

owner=<name>

Set the owner of the slave pty to the given user.

group=<name>

Set the group of the slave pty to the given group.

user=<name>

Windows only, create the process under the given user instead of the calling process' user. This generally required special privileges.

passwd=<name>

Windows only, user must be specified to use. Log on the user with the given password. If a password is not given, an S4U logon will be attempted, but that may not work so well as some things are missing from the access token of the user.

NOTE: There are significant security issues with passing a password this way. You must use proper password handling. module=<name> Windows only, user must be specified to use. Create the new user token with the given module. If not specified, "gensio" is used.

Remote Address String¶

The remote address string the program and arguments run on the pty. The argiuments will be a set of quoted strings with a space between each string, one for each argument, with '"' around each argument, each '"' in the string converted to '\"' and each '\' in the string converted to '\\'.

Remote Address¶

The address is a pointer to an integer, the ptym file descriptor is returned. addrlen must be set to sizeof(int) when passed in.

Local Address String¶

This returns the device of the pty, generally /dev/pts/<n>. This is useful for pty gensios with no program, it allows you to get the value for the other end to connect to. Note that if you close and re-open a pty gensio, you may be a different local address string.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const char * const args[]".

Options¶

In addition to readbuf, the msgdelim gensio takes the following options:

writebuf=<n>

set the size of the write buffer.

crc[=on|off]

Enable/disable the CRC at the end of the packet. Useful if you are running over a reliable protocol, and especially for testing relpkt so you can fuzz it and bypass the crc errors.

Options¶

trace does not support readbuf. It supports the following options:

dir=none|read|write|both

Sets what data is traced. "none" means no data is traced (the default), "read" traces data flowing up the gensio stack (read by the parent), write traces data flowing down the gensio stack (written by the parent), and "both" traces reads and writes.

block=none|read|write|both

Blocks data in one or both directions. "none" means data flows both directions (the default), "read" means data flowing up the gensio stack is discarded, write means data flowing down the gensio stack is discarded, and "both" discards both reads and writes. Data that is discarded is not traced.

raw[=yes|no]

If set, traced data will be written as raw bytes. If not set, traced data will be written in human-readable form.

file=<filename>

The filename to write trace data to. If not supplied, tracing is disabled. Note that unless delold is specified, the file is opened append, so it will add new trace data onto the end of an existing file.

stderr[=yes|no]

Send the trace output to standard error. Overrides file.

stdout[=yes|no]

Send the trace output to standard output. Overrides file and stderr.

delold[=yes|no]

Delete the old data in the file instead of appending to the file.

Options¶

perf does not support readbuf. It supports the following options:

writebuf=<n>

Sets the size of the buffer to write to the child gensio. Each write will be this size. This defaults to zero.

write_len=<n>

The number of bytes to write.

expect_len=<n>

The number of bytes to expect from the other end.

Options¶

The readbuf option is not accepted.

retry-time=<gtime>

Instead of restarting a closed connection immediately, this will cause a delay between the close and the re-open. Also, if the connect fails, it will not disable itself, it will wait another retry-time period and try the connect again. See the section on gtime above. The unit defaults to milliseconds. The default value is zero.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const char *". That is the specification of the gensio below it.

Options¶

The readbuf option is accepted, but if it is not specified the default value for readbuf will be taken for the sub-gensio is taken. In addition to readbuf, the mdns gensio takes the following options:

nostack[=true|false]

By default the mdns gensio will attempt to use the "gensiostack" text string from the mDNS service. If you don't want it to do this, setting this option will turn it off.

name=<mdnsstr>

Set the mdns name to search for. You generally want to set this, otherwise you will get the first thing that comes up from the search.

type=<mdnsstr>

Set the mdns type to search for.

domain=<mdnsstr>

Set the mdns domain to search for. You generally don't use this.

host=<mdnsstr>

Set the mdns host to search for. You generally don't use this.

interface=<num>

Set the network interface number to search on. The default is -1, which means all interfaces.

nettype=unspec|ipv4|ipv6

The network type to search for. unspec means any type, otherwise you can choose to limit it to ipv4 and ipv6.

nodelay[=true|false]

Sets nodelay on the socket. This will be ignored for udp. Note that the default value for mdns is ignored, if you don't set it here it will take the default value for the sub-gensio that gets chosen. laddr=<addr> An address specification to bind to on the local socket to set the local address.

Direct Allocation¶

Allocated as a terminal gensio with gdata as a "const char *". That is the specification of the mdns as a string.

Options¶

kiss supports the following options:

readbuf=<n>

Sets the maximum packet size that can be read from the TNC. Defaults to 256.

writebuf=<n>

Sets the maximum packet size that can be written to the TNC. Defaults to 256.

tncs=<n>

The number of supported TNCs. Defaults to 1.

server[=yes|no]

Is this a KISS server or client. A client will set the tunable parameters on the TNC. A server is expected to be a TNC, but this isn't fully implemented yet as you can't get the tunable parameters.

setupstr=<string>

Send the given string at startup to set up the device.

setup-delay=<n milliseconds>

Wait for the given number of milliseconds after sending the setup string before continuing operation.

d710[=yes|no]

If set to yes or just "d710" is given, set the setupstr to a value for the Kenwood D710 radio. This is the same as doing: setupstr='xflow on\rhbaud 1200\rkiss on\rrestart\r'

d710-9600[=yes|no]

If set to yes or just "d710-9600" is given, set the setupstr to a value for the Kenwood D710 radio at 9600 bps. This is the same as doing: setupstr='xflow on\rhbaud 9600\rkiss on\rrestart\r'

txdelay=<n>

The KISS txdelay parameter, in milliseconds, rounded to the nearest power of ten. The maximum values is 2550. Default is 50ms.

persist=<n>

The KISS "P" parameter, ranging from 0-255. I don't know what this means, the spec isn't clear. You'll have to figure it out on your own. Default is 63.

slottime=<n>

The KISS slot time parameter, in milliseconds, rounded to the nearest power of 10. The maximum value is 2550ms, the default is 100ms.

fullduplex[=yes|no]

Set's full duplex on the connection.

sethardware=<n>

A hardware-specific control value ranging from 0-255. It's meaning depends on the hardware. By default it is not set.

AX25 Addresses¶

A gensio AX25 address string is in the form:

[ax25:]tncport,dest[:c|r],src[:c|r][,extra1[:h]
[,extra2[:h][..]]]

tncport is a number from 0-15 specifying which TNC to use. dest and src and subaddresses specifying the destination and source addresses. Note that the source address better match an laddr, or the connection won't work. extra fields are also subaddresses. These are used for routing (a function that is deprecated and no longer use) and by APRS for it's own purposes, see the APRS spec for details. The c, r, and h values are bits in the address that you generally don't care about, except for the h field for APRS.

Subaddresses are in the form

callsign-n

where callsign is a set of alphanumeric digits (a-zA-Z0-9) and n is a number 0-15. Lower case digits are converted to upper case in the address and not converted back on receipt.

Handling unconnected packets (UI frames)¶

To receive UI frames, you must enable the GENSIO_CONTROL_ENABLE_OOB control on the gensio. If you set the value to 1, you will receive UI frames where the destination matches one of your laddrs. If you set it to 2, you will receive all UI frames (promiscuous mode). 0 disables receipt of UI frames.

UI frames are reported with the "oob" in the auxdata, like out of band data. Note that you must completely handle all the UI frame in the call. If you don't consume all the data, it will not be called again.

You can have a channel that receives both connected data and UI frames, but you would generally have a separate channel with no addr set for receiving UI frames. If you don't set the laddr field, that channel can only be used for promiscuous mode.

On received packets, the auxdata will contain a field starting with "addr:" and the rest is the gensio AX25 address in the packet. When sending a UI frame, you must set "oob" and "addr:" fields in the auxdata, with a valid address in the "addr:" field.

Options¶

Option values for channels are all inherited from the options used to create the first channel, except for addr (which must be supplied for each channel if you care) and laddr (which is only used on the first channel. ax25 supports the following options:

readbuf=<n>

Sets the maximum packet size that can be read. Defaults to 256.

writebuf=<n>

Sets the maximum packet size that can be written. Defaults to 256.

readwindow=<n>

Sets the maximum packet size that can be received and unacked. Defaults to 7 for extended and 4 for non-extended.

writewindow=<n>

Sets the maximum number of packets that can be sent unacked to the remote side. Defaults to 7 for extended and 4 for non-extended.

extended=<n>

Set the extended mode. Setting it to 1 will enable 7-bit sequence numbers, the connection will first attempt to use 7-bit sequence number. If that fails, it will fall back to 3-bit sequence numbers.

Setting the value to 2 will enable a non-standard operation that will add parameter negotiation to the connection startup. Setting the readbuf, writebuf, readwindow, and writewindow without extended=2 really isn't very useful as without the negotiation it will be forced to fall back to the defaults. If extended=2 fails, it will fall back to extended=1.

laddr=<subaddr>[;<subaddr[...]]

Set the addresses the ax25 gensio will receive packets for. Except for promiscuous UI mode, the destination of a packet must match one of these addresses to be handled. This can only be set on the accepter or on the first connection and applies to all channels.

If you do not set this, but addr is set, the laddr will be set from the source address of addr.

addr=<ax25addr>

Set the address of the remote end of the connection. Packets will be sent to this address.

crc[=yes|no]

Enable CRC checking. Default is off.

ign_emb_ua[=yes|no]

Some AX.25 stacks do not properly reset themselves when they get a second SABM (due to a timeout) but they still send a UA. If you are getting errors about receiving a UA while connected and the connection hangs, try enabling this option.

srt=<n>

The initial smoothed round trip time for the connection, in milliseconds. See the spec for details, you probably don't need to mess with it. Note that this value you set here is multiplied by the number of digipeaters between the source and the destination for the actual value. Defaults to 1500.

t2=<n>

The timer 2 value for the connection, in milliseconds. See the spec for details, you probably don't need to mess with it. Defaults to 2 seconds.

t3=<n>

The timer 3 value for the connection, in milliseconds. See the spec for details, you probably don't need to mess with it. Defaults to 300 seconds.

retries=<n>

Number of retries on a send before giving up and dropping the connection. See the spec for details, you probably don't need to mess with it. Defaults to 10.

Options¶

in=<n>:<m>

Translate character n (a number, 0xnn for hex, 0nnn for octal, or nn for decimal) to character m on data read from the gensio.

out=<n>:<m>

Like in, but translate character n to character m on data written to the gensio.

nlcr

Translate new lines to carraige returns on data read from the gensio, and carraige returns to new lines on data written to the gensio.

crnl

Translate carraige returns to new lines on data read from the gensio, and new lines to carraige returns on data written to the gensio.

Options¶

retry-time=<gtime>

Set the retry interval. See the section on gtime for detail on this. Defaults to milliseconds it no unit given. The default is 1 second.

discard-badwrites[=yes|no]

Normally this gensio will flow-control the upper layer when the lower gensio is not open. If you enable this, it will just throw write data away if the lower gensio is not open.

Options¶

script=<string>

Run the program given in the string as the external program. This is equivalent to doing: gensio=stdio(noredir-stderr),<string>, it just a shortcut.

gensio=<string>

Instead of running a program, run the given gensio. When the gensio closes, handle an error. If the gensio supported getting an error code, that is done.

Options¶

<samplerate>-<channels>-<format>

For simple applications, the sound gensio takes a compact and simple format as an option. It specifies those things for both the input and output channel. So, for instance, "sound(44100-2-float)" would be CD-rate two channel using floating point numbers.

list[=yes|no]

Instead of opening a sound device, the gensio will provide data about the various sound interfaces available. Every other option but "type" is ignored. If "type" is supplied, list the interfaces for that type. If "type" is not supplied, list the interfaces for the default one.

The data will be a string with each interfaces separated by a newline. There will be an interface name, a tab, and the interface specification.

outdev=<str>

If the output device has a different name than the input device, it must be specified separately.

inbufsize=<n>, outbufsize=<n>, bufsize=<n>

Specify the buffer size, in samples. This defaults to 1024.

innbufs=<n>, outnbufs=<n>, nbufs=<n>

Specify the number of buffers to use. This may or may not be used depending on the interface type. It's ignored for file, for instance. Defaults to 100.

chans=<n>, inchans=<n>, outchans=<n>

Set the number of input and output channels. One of these must be specified, if you say chans it will set both the input and output number of channels. If you only specify in or out, the other is not enabled.

inrate=<n>, outrate=<n>, rate=<n>

The sample rate, in samples per second. Common ones are 44100 (CD), 48000 (DAT).

intype=<n>, outtype=<n>, type=<n>

Set the interface type. Must be "alsa" (Linux only), "win" (Windows only) or "file". If not set, this default to alsa on Linux and win on Windows.

informat=<n>, outformat=<n>, format=<n>

Set the type of data to supply to the user. This is one of: float64, float, s32, s32, s16, or s8. User samples are always signed and either floating point or integer. Floating point is normalized from -1.0 to 1.0. You must specify this.

inpformat=<n>, outpformat=<n>, pformat=<n>

The data format on the PCM size. You have all the data formats specified for format above. The integer ones can be prefixed with "u" instead of "s" to make them unsigned (like u16), and all may be suffixed with "le" or "be" to make them little or big endian (like float64_le). If you do not specify this, the gensio will attempt the same format as the user format. If that doesn't work, it will attempt to pick the best matching format and convert.

Keying the Transmitter¶

By default, afskmcm will not do anything specific to turn the transmitter on and off. In this case the keying must be VOX, like a SignaLink.

If you need some other way to key the transmitter, afskmcm provide a key option. This create a gensio that is used to turn the transmitter on and off. It will send the keyon string and the keyoff string for this purpose.

For instance, you could create your own program to do the keying and add:

key="stdio,mykeyprog --parm1 --parm2",keyon="1",keyoff="0"

to your afskmdm option and it would run the mykeyprog program when opened. When it needed to transmit, it would write a "1" (no newline or anything sent) to the stdin of the program. When the transmission was complete, it would write a "0". Not numbers, these are "0" and "1" characters.

If you program sends output to stderr, you probably want to add stderr-to-stdout to the stdin so the stderr buffers doesn't fill up and block the program. Then stderr data will be ignored.

You can use rigctld with this. I have the following rigctld setup on my system:

rigctld -m 1022 -r /dev/ttyUSB0 -s 4800 -P CM108 -p /dev/hidraw1

And I use the following in my configuration:

afskmdm(key="tcp,localhost,4532",keyon="T 1\n",keyoff="T 0\n")

You have to be careful of the quoting here, as the key specification must be in quotes because it will have commas. Notice the use of "\n" in the strings for a new line. Normal C "\" escape sequences are handled.

Anything read in from the key gensio is ignored.

Options¶

readbuf=<n>

Sets the maximum packet size that can be read. Defaults to 256.

writebuf=<n>

Sets the maximum packet size that can be written. Defaults to 256.

nchans=<n>, in_nchans=<n>, out_nchans=<n>

Specify how many channels are coming from/going to the sound gensio. The sound gensio interleaves the sound for multiple channels. By default this is fetched from the sound gensio.

chan=<n>, in_chan=<n>, out_chan=<n>

Which specific channel to use. One one channel is used for input sound and output sound, the others are ignored or filled with zeros. By default this is zero.

out_chans=<n>

Specify a bitmask of which channels to output sound on. The same sound will be output for all selected channel. So n=1 will only output on channel 0, n=3 will output on channels 0 and 1, etc. By default only channel 0 is output on.

samplerate=<n>, in_samplerate=<n>, out_samplerate=<n>

The sample rate, samples per second, of the data. By default this is fetched from the sound gensio.

wmsgs=<n>

The number of working messages at the same time. If the bit fails the certainty test (see below), for every current working message, two are created, one with each bit possibility, up to the count specified in this option. These are kept until a message is correctly received (with CRC) or the series of bits is not valid.

This way, if wmsg is 2^n, a message can be correctly decoded if up to n bits are wrong. So it's sort of an error correction code without a code. Defaults to 32.

wmsg-extra=<n>

Sets the number of extra amplification levels for the mark and space frequencies to try. If set to 1, an extra complete detection is done with the space frequency amplified by 3db, then the mark frequency amplified by 3db. If set to 2, it will do this with3db then 6db, and so on. This can help compensate for filtering on the different frequencies. Defaults to 1.

min-certainty=<float>

A floating point number that specifies the minimum certainty above which a bit is considered good. The ratio of the signal power for the mark and space frequencies is calculated as the certainty. If that certainty is below min-certainty, it does the wmsgs procedure above. Defaults to 2.0.

filttype=[fir|iir|none]

A 2nd-order low-pass Butterworth IIR filter or a low-pass FIR filter is implemented on the input. This selects which filter, or no filter. The IIR filter doesn't use very much CPU, the FIR filter uses a lot of CPU at higher sample rates. This is mostly for experimentation. The default is IIR for sample rates above 30000Hz and FIR for lower sample rates. Lower sample rates don't work well with the IIR filter, but there's not much difference at higher sample rates.

lpcutoff=<n>

This sets the cutoff frequency for the input filter. Setting it to zero disables it. The default is 2500Hz.

trfreq=<n>

This sets the transition frequency width for the FIR filter. This is ignored for the IIR filter. The default is 500Hz. Smaller numbers make a sharper cutoff but result in more CPU being used.

tx-preamble=<n>

The time in milliseconds at the beginning of a message that is just flags. This lets the receiver turn on and the other end synchronize. Default is 300.

tx-tail=<n>

The time in milliseconds at the end of the message that is just flags. Default is 100.

tx-predelay=<n>

The amount of time to wait after another sender has finished sending a message before the transmit is started. Default is 500ms.

volume=<float>

Sets the transmit volume, from 0.0-1.0. Values above 1.0 will clip. Default is .75.

key=<gensio string>

This creates a gensio that will be used to key the transmitter on and

off. See the discussion above on keying for more details. If you set this, you must set keyon and keyoff. Disabled by default. keyon=<string>, keyoff=<string>

The strings to send to the key gensio to turn the transmitter on and

off. full-duplex[=yes|no]

Treat the read and write streams as completely independent. Transmit

does not check if something is being received before sending, all sends just start immediately.