Free driver 1.0 software for linux

HDBC ODBC Driver is the Haskell ODBC backend driver for HDBC. This driver has been tested on Windows and on Linux with unixODBC. It should also be compatible with iODBC, though this has not been tested. It should be portable to any platform supported by both Haskell and unixODBC.

This driver is the preferred method of communicating with MySQL from Haskell.

MYSQL NOTE

Important note for MySQL users:

Unless you are going to use InnoDB tables, you are strongly encouraged to set

Option = 262144

in your odbc.ini (for Unix users), or to disable transaction support in your DSN setup for Windows users.

If you fail to do this, the MySQL ODBC driver will incorrectly state that it
supports transactions. dbTransactionSupport will incorrectly return True. commit and rollback will then silently fail. This is certainly /NOT/ what you want. It is a bug (or misfeature) in the MySQL driver, not in HDBC.

You should ignore this advice if you are using InnoDB tables.

Bind9 LDAP sdb driver is an attempt at an LDAP back-end for BIND 9 using the new simplified database interface "sdb". Using this you can store zones in LDAP rather than in files.

Note that when using sdb, the zones are not cached in memory, BIND will do a database lookup whenever it gets a query. If you want to store zones in LDAP but still have BIND do caching, you may be interested in the ldap2zone tool.

EXAMPLE

# This is a really long synopsis, but hopefully it will give you an idea...

package MyPackage;

use Class::Driver;
use base q(Class::Driver);

our %drivers;

return 1;

sub new {
my($class, %args) = @_;
die "mime_type is required" unless($args{mime_type});
die "no driver to handle type $args{mime_type}"
unless($drivers{$args{mime_type}});
return $class->driver_load($drivers{$args{mime_type}}, %args);
}

sub driver_new {
my($class, %args) = @_;
return bless %args, $class;
}

sub driver_required { 1; }
sub driver_requied_here { 0; }

package MyPackage::avi;

use MyPackage;
use base q(MyPackage);
use Video::Info;

$MyPackage::drivers{video/x-msvideo} = avi;

return 1;

sub driver { "avi"; }

sub driver_new {
my($class, %args) = @_;
die "file is a required parameter for $args{mime_type} files"
unless($args{file});
$args{info} = Video::Info->new(-file => $args{file})
or die "Failed to create a Video::Info object for $args{file}";
return $class->SUPER::driver_new(%args);
}

sub duration {
my $self = shift;
return $args{info}->duration;
}

package MyPackage::mp3;
use base q(MyPackage);
use MP3::Info;

$MyPackage::drivers{audio/mpeg} = mp3;

## (etc...)

package main;

my $foo = MyPackage->new(file => foobar.mp3, mime_type => audio/mpeg);
print "foobar.mp3 is ", $foo->duration, " seconds long.n";

uLan Driver provides 9-bit message oriented communication protocol, which is transferred over RS-485 link.
Characters are transferred same way as for RS-232 asynchronous transfer except parity bit, which is used to distinguish between data characters and protocol control information. A physical layer consists of one twisted pair of leads and RS-485 transceivers.
Use of 9-bit character simplifies transfer of binary data and for intelligent controllers can lower the CPU load, because of the CPU need not to care about data characters send to other node. Producers of most microcontrollers for embedded applications know that and have implemented 9-bit extension in UARTs of most of todays MCUs. There is the list below to mention some of them:
- all Intel 8051 and 8096 based MCUs with UART
- members of Motorola 683xx family ( 68332, 68376, ... )
- Hitachi H8 microcontrollers
The driver is implemented as relatively independent layers and subsystems. Messages are prepared and received in the driver dedicated memory. This memory is divided into blocks with uniform size with atomic allocation routines.
When message is being stored into blocks, head of message with couple of data bytes is stored in the first allocated memory block. If all data cannot be stored in the first block, next blocks are allocated and linked together.
The message heads are linked in bidirectional linked lists of messages prepared for sending, processed messages and messages prepared for client notification. These lists or queues are main mechanism for transferring of messages between subsystems.
Link protocol is programmed as finite state automata with state stack, which state routines are executed by interrupt handler. State routine can return positive integer information, negative error notification or zero, which leads to wait for next interrupt. Information or error is used as input parameter when state routine is called.
When the state routine wants initiate transfer to another state routine it changes pointer to the actual state routine. If previous state routine returns nonzero value new routine is called immediately, in other case next interrupt invokes new state routine.
There is stack of callers of actual state routines which enables to constructs automata subsystems, which can be used in more places in main automata loop. Main purpose of this automata is to send or process messages coming in list of messages prepared for sending and if specified, move these messages onto list of messages prepared for client notification.
Received messages are put onto this list too. Subsystem is supervised by timeout handler, which can revitalize communication in case of die of other node. The interrupt and timeout handlers are fully SMP reentrant.
The automata subsystem uses pointers to chip driver routines for hardware port manipulation. This is only part dependent on used chip, today 82510, 16450 and OX16C950PCI. These routines can send and receive 9 bit character, connect to RS-485 line by the arbitration sequence, wait for specified time for character and initialize and close port.
File operation subsystem makes interface between OS kernel VFS and client message queues. It enables to prepare single or multi-frame messages and stores notifications of received or processed messages in clients private state structures. This part is heavily operating system dependent.
Enhancements:
- This release enables you to build the driver within the WDF framework for Windows.
- Updates to support the latest Linux 2.6.x kernels are included (tested to 2.6.19).
- Changes to allow stand-alone system-less build for ARM targets (LPC21xx) are included.
- The OMK has been selected as the default build.
- The "switch2std" script allows you to switch to the old build system.

TAP provides packet reception and transmission for user-space programs. It can be viewed as a simple Ethernet device, which instead of receiving packets from a physical medium, receives them from a user-space program and instead of sending packets via physical media, writes them to the user-space program.
When a program opens /dev/tunX or /dev/tapX, driver creates and registers corresponding net device tunX or tapX. After a program closed above devices, driver will automatically delete tunXX or tapXX device and all routes corresponding to it.
This package(http://vtun.sourceforge.net/tun) contains two simple example programs that shows you how to use tun and tap devices. Both programs work like bridge between two network interfaces. br_select.c - bridge based on select system call. br_sigio.c - bridge based on async io and SIGIO signal. However the best example is VTun http://vtun.sourceforge.net
Enhancements:
- Massive Linux driver update: 2.4.x kernel support. New cloning interface, protocol indication. Statistics counting fixes.
- Solaris driver update: Correct Ethernet header substitution.
- Configure and Makefile updates. RPM package update.
- Documentation update.

FreeBoB project aims to provide a free driver implementation for the BeBoB platform. The BeBoB is used in many available IEEE 1394 based break-out boxes.

BeBoB devices are audio breakout boxes. BeBoB devices are attached with IEEE1394, a.k.a FireWire or i.Link, a high performance serial bus. FreeBoB is a generic Linux driver for BeBoB devices and supports JACK.