767 lines
28 KiB
Plaintext
767 lines
28 KiB
Plaintext
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<!DOCTYPE book PUBLIC "-//OASIS//DTD DocBook V3.1//EN"[]>
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<book>
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<bookinfo>
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<title>libraw1394</title>
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<subtitle>version 0.9</subtitle>
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<copyright>
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<year>2001</year>
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<holder>Andreas Bombe</holder>
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</copyright>
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</bookinfo>
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<toc></toc>
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<chapter id="introduction">
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<title>Introduction</title>
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<para>
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The Linux kernel's IEEE 1394 subsystem provides access to the raw 1394 bus
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through the raw1394 module. This includes the standard 1394 transactions
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(read, write, lock) on the active side, isochronous stream receiving and
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sending and dumps of data written to the FCP_COMMAND and FCP_RESPONSE
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registers. raw1394 uses a character device to communicate to user
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programs using a special protocol.
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</para>
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<para>
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libraw1394 was created with the intent to hide that protocol from
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applications so that
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<orderedlist numeration="arabic">
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<listitem>
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<para>
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the protocol has to be implemented correctly only once.
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</para>
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</listitem>
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<listitem>
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<para>
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all work can be done using easy to understand functions instead of
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handling a complicated command structure.
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</para>
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</listitem>
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<listitem>
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<para>
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only libraw1394 has to be changed when raw1394's interface changes.
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</para>
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</listitem>
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</orderedlist>
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</para>
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<para>
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To fully achieve the goals (especially 3) libraw1394 is distributed under
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the LGPL (Lesser General Public License - see file COPYING.LIB for more
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information.) to allow linking with any program, be it open source or
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binary only. The requirements are that the libraw1394 part can be
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replaced (relinked) with another version of the library and that changes
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to libraw1394 itself fall under LGPL again. Refer to the LGPL text for
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details.
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</para>
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</chapter>
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<chapter id="intro1394">
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<title>Short Introduction into IEEE 1394</title>
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<para>
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IEEE 1394 in fact defines two types of hardware implementations for this
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bus system, cable and backplane. The only one described here and
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supported by the Linux subsystem is the cable implementation. Most people
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not familiar with the standard probably don't even know that there is
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something else than the 1394 cable specification.
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</para>
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<para>
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If you are familiar with CSR architectures (as defined in --FIXME--), then
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you already know most of 1394, which is a CSR implementation.
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</para>
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<sect1>
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<title>Bus Structure</title>
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<para>
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The basic data structures defined in the standard and used in this
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document are the quadlet (32 bit quantity) and the octlet (64 bit
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quantity) and blocks (any quantity of bytes). The bus byte ordering is
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big endian. A transmission can be sent at one of multiple possible
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speeds, from the slowest 100 Mbit/s over 200 and 400 Mbit/s up to 3.2
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Gbit/s in the future (these speeds are also referred to as S100, S200,
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...).
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</para>
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<para>
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A 1394 bus consists of up to 64 nodes (with multiple buses possibly
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being connected, but that is outside of the scope of this document and
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not completely standardized yet), each having a local address space with
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48 bit wide addressing. Each node is addressed with a 16 bit address,
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which is further divided into a 10 bit bus ID and a 6 bit local node ID.
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The highest value for both is a special value. Bus ID equal to 1023
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means "local bus" (the bus the node is connected to), node ID equal to
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63 means "all nodes" (broadcast).
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</para>
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<para>
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The whole bus can thus be seen as a linear 64 bit address space by
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concatenating the node address (most significant bits) and and node
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address (least significant bits). libraw1394 treats them separately in
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function arguments to save the application some fiddling with the bits.
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The node IDs are completely dynamic and determined during the bus reset.
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</para>
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<para>
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Unlike other buses there aren't many transactions or commands defined,
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higher level commands are defined in terms of addresses accessed instead
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of separate transaction types (comparable to memory mapped registers in
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hardware). The 1394 transactions are:
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<itemizedlist>
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<listitem>
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<para>read (quadlets and blocks)</para>
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</listitem>
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<listitem>
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<para>write (quadlets and blocks)</para>
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</listitem>
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<listitem>
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<para>lock (some atomic modifications)</para>
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</listitem>
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</itemizedlist>
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There is also the isochronous transaction (the above three are called
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asynchronous transactions), which is a broadcast stream with guaranteed
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bandwidth. It doesn't contain any address but is distinguished by a 6
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bit channel number.
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</para>
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<para>
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The bus view is only logical, physically it consists of many
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point-to-point connections between nodes with every node forwarding data
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it receives to every other port which is capable of the speed the
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transaction is sent at (thus a S200 node in the path between two S400
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nodes would limit their communication speed to S200). It forms a tree
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structure with all but one node having a parent and a number of
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children. One node is the root node and has no parents.
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</para>
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</sect1>
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<sect1>
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<title>Bus Reset</title>
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<para>
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A bus reset occurs whenever the state of any node changes (including
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addition and removal of nodes). At the beginning a root node is chosen,
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then the tree identification determines for every node which port is
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connected to a parent, child or nothing. Then the SelfID phase begins.
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The root node sends a SelfID grant on its first port connected to a
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child. If that is not a leaf node, it will itself forward the grant to
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its first child. When a leaf node gets a grant, it will pick the lowest
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node ID not yet in use (starting with 0) and send out a SelfID packet
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with its node ID and more information, then acknowledge the SelfID grant
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to its parent, which will send a grant to its next child until it
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configured all its children, then pick a node ID itself, send SelfID
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packet and ack to parent.
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</para>
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<para>
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After bus reset the used node IDs are in a sequential range with no
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holes starting from 0 with the root node having the highest ID. This
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also means that node IDs can change for many or all nodes with the
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insertion of a new node or moving the role of root to another node. In
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libraw1394 all transactions are tagged automatically with a generation
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number which is increased in every bus reset and transactions with an
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obsolete generation will fail in order to avoid targetting the wrong
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node. Nodes have to be identified in a different way than their
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volatile node IDs, namely by reading their globally unique ID (GUID)
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contained in the configuration ROM.
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</para>
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</sect1>
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<sect1>
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<title>Transactions</title>
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<para>
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The packets transmitted on the bus are acknowledged by the receiving end
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unless they are broadcast packets (broadcast writes and isochronous
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packets). The acknowledge code contains an error code, which either
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signifies error, success or packet pending. In the first two cases the
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transaction completes, in the last a response packet will follow at a
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later time from the targetted node to the source node (this is called a
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split transaction). Only writes can succeed and complete in the ack
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code, reads and locks require a response. Error and packet pending can
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happen for every transaction.
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</para>
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<para>
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The response packets contain a response code (rcode) which signifies
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success or type of error. libraw1394 contains a function to convert
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ack/rcode pairs into errno codes which convey roughly the same meaning.
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This is done automatically for the synchronous read/write/lock wrapper
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functions, i.e. they return a negative value for failure and a standard
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error code can be found in the global variable <symbol>errno</symbol>.
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</para>
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<para>
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For read and write there are two different types, quadlet and block.
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The quadlet types have all their payload (exactly one quadlet) in the
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packet header, the block types have a variable length data block
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appended to the header. Programs using libraw1394 don't have to care
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about that, quadlet transactions are automatically used when the data
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length is 4 bytes and block transactions otherwise.
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</para>
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<para>
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The lock transaction has several extended transaction codes defined
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which choose the atomic operation to perform, the most used being the
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compare-and-swap (code 0x2). The transaction passes the data value and
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(depending on the operation) the arg value to the target node and
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returns the old value at the target address, but only when the
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transaction does not have an error. All three values are of the same
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size, either one quadlet or one octlet.
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</para>
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<para>
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In the compare-and-swap case, the data value is written to the target
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address if the old value is identical to the arg value. The old value
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is returned in any case and can be used to find out whether the swap
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succeeded by repeating the compare locally. Isochronous resource
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allocation is done using compare-and-swap, as described below. Since
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the old value is always returned, it more efficient to do the first
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attempt with the reset value of the target register as arg instead of
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reading it first. Repeat with the returned old value as new arg value
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if it didn't succeed.
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</para>
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</sect1>
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<sect1>
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<title>Bus Management</title>
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<para>
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There are three basic bus service nodes defined in IEEE 1394 (higher
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level protocols may define more): cycle master, isochronous resource
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manager and bus manager. These positions are contended for in and
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shortly after the bus reset and may all be taken by a single node. A
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node does not have to support being any of those but if it is bus
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manager capable it also has to be iso manager capable, if it is iso
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manager capable it also has to be cycle master capable.
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</para>
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<para>
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The cycle master sends 8000 cycle start packets per second, which
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initiate an iso cycle. Without that, no isochronous transmission is
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possible. Only the root node is allowed to be cycle master, if it is
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not capable then no iso transmissions can occur (and the iso or bus
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manager have to select another node to become root and initiate a bus
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reset).
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</para>
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<para>
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The isochronous resource manager is the central point where channel and
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bandwidth allocations are stored. A bit in the SelfID shows whether a
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node is iso manager capable or not, the iso manager capable node with
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the highest ID wins the position after a bus reset. Apart from
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containing allocation registers, this one doesn't do much. Only if
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there is no bus manager, it may determine a cycle master capable node to
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become root and initiate a bus reset.
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</para>
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<para>
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The bus manager has more responsibilities: power management (calculate
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power provision and consumption on the bus and turn on disabled nodes if
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enough power is available), bus optimization (calculate an effective gap
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count, optimize the topology by selecting a better positioned node for
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root) and some registers relevant to topology (topology map containing
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the SelfIDs of the last reset and a speed map, which is obsoleted in
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IEEE 1394a). The bus manager capable nodes contend for the role by
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doing a lock transaction on the bus manager ID register in the iso
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manager, the first to successfully complete the transaction wins the
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role.
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</para>
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</sect1>
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<sect1>
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<title>Isochronous Transmissions</title>
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<para>
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Nodes can allocate a channel and bandwidth for isochronous transmissions
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at the iso manager to broadcast timing critical data (e.g. multimedia
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streams) on the bus. However these transmissions are unreliable, there
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is no guarantee that every packet reaches the intended recipients (the
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software and hardware involved also take iso packets a bit more
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lightly). After a cycle start packet, the isochronous cycle begins and
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every node can transmit iso packets, however only one packet per channel
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is allowed. As soon as a gap of a certain length appears (i.e. no node
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sends anymore), the iso cycle ends and the rest of the time until the
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next cycle start is reserved for asynchronous packets.
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</para>
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<para>
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The channel register on the iso manager consists of 64 bits, each of
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which signifies one channel. A channel can be allocated by any node by
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doing a compare-swap lock request with the new bitmask. Likewise the
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bandwidth can be allocated by doing a lock request with the new value.
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The bandwidth register contains the remaining time available for every
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iso cycle. Since you allocate time, the maximum data you are allowed to
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put into an iso packet depends on the speed you will send at.
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</para>
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<para>
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On every bus reset, the resource registers are resetted to their initial
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values (all channels free, all bandwidth minus some amount set aside for
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asynchronous communication available), this has to happen since the
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isochronous manager may have moved to another node. Isochronous
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transmissions may continue with the old allocations for a certain
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(FIXME) amount of time. During that time, the nodes have to reallocate
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their resources and no new allocations are allowed to occur. Only after
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this period new allocations may be done, this avoids nodes losing their
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allocations over a bus reset.
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</para>
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<para>
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libraw1394 does not provide special functions for allocating iso
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resources nor does it clean up after programs when they exit. Protocols
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exist that require the first node to use some resources to allocate it
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and then leave it for the last node using it to deallocate it. This may
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be different nodes, so automatic behaviour would be very undesirable in
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these cases.
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</para>
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</chapter>
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<chapter id="general">
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<title>Data Structures and Program Flow</title>
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<sect1>
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<title>Overview</title>
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<para>
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The 1394 subsystem in Linux is divided into the classical three layers,
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like most other interface subsystems in Linux. The subsystem consists
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of the core, which provides basic services like handling of the 1394
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protocol (converting the abstract transactions into packets and back),
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collecting information about bus and nodes and providing some services
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to the bus that are required to be available for standards conformant
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node (e.g. CSR registers). Below that are the hardware drivers, which
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handle converting packets and bus events to and from hardware accesses.
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</para>
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<para>
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Above the core are the highlevel drivers, which use the services
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provided by the core to implement protocols for certain devices and act
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as drivers to these. raw1394 is one such driver, however it is not
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specialized to handle one kind of device but is designed to accept
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commands from user space to do any transaction wanted (as far as
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possible from current core design). Using raw1394, normal applications
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can access 1394 nodes on the bus and it is not neccessary to write
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kernel code just for that.
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</para>
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<para>
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raw1394 communicates to user space like most device drivers do, through
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device files in /dev. It uses a defined protocol on that device, but
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applications don't have to and should not care about that. All of this
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is taken care of by libraw1394, which provides a set of functions that
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convert to and from raw1394 protocol packets and are a lot easier to
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handle than that underlying protocol.
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</para>
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</sect1>
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<sect1>
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<title>Handles</title>
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<para>
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The handle presented to the application for using libraw1394 is the
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raw1394handle_t, an opaque data structure (which means you don't need to
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know its internals). The handle (and with it a connection to the kernel
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side of raw1394) is obtained using
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<function>raw1394_new_handle()</function>. Insufficient permissions to
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access the kernel driver will result in failure of this function, among
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other possibilities of failure.
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</para>
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<para>
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While initializing the handle, a certain order of function calls have to
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be obeyed or undefined results will occur. This order reflects the
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various states of initialization to be done:
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</para>
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<para>
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<orderedlist>
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<listitem>
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<para><function>raw1394_new_handle()</function></para>
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</listitem>
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<listitem>
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<para><function>raw1394_get_port_info()</function></para>
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</listitem>
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<listitem>
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<para><function>raw1394_set_port()</function></para>
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</listitem>
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</orderedlist>
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</para>
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</sect1>
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<sect1>
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<title>Ports</title>
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<para>
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A computer may have multiple 1394 buses connected by having multiple
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1394 chips. Each of these is called a port, and the handle has to be
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connected to one port before it can be used for anything. Even if no
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nodes are connected to the chip in question, it forms a complete bus
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(with just one node, itself).
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</para>
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<para>
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A list of available ports together with some information about it
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(name of the hardware, number of connected nodes) is available via
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<function>raw1394_get_port_info()</function>, which is to be called
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right getting a fresh handle. The user should be presented with a
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||
|
choice of available ports if there is more than one. It may be good
|
||
|
practice to do that even if there is only one port, since that may
|
||
|
result from a normally configured port just not being available,
|
||
|
making it confusing to be dropped right into the application attached
|
||
|
to a port without a choice and notion of anything going wrong.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
The choice of port is then reported using
|
||
|
<function>raw1394_set_port()</function>. If this function fails and
|
||
|
<symbol>errno</symbol> is set to <symbol>ESTALE</symbol>, then
|
||
|
something has changed about the ports (port was added or removed)
|
||
|
between getting the port info and trying to set a port. It is
|
||
|
required that the current port list is fetched (presenting the user
|
||
|
with the choice again) and setting the port is retried with the new
|
||
|
data.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
After a successful <function>raw1394_set_port()</function>, the get and
|
||
|
set port functions must not be used anymore on this handle. Undefined
|
||
|
results occur if you do so. To make up for this, all the other
|
||
|
functions are allowed now.
|
||
|
</para>
|
||
|
</sect1>
|
||
|
|
||
|
<sect1>
|
||
|
<title>The Event Loop</title>
|
||
|
|
||
|
<para>
|
||
|
All commands in libraw1394 are asynchronous, with some synchronous
|
||
|
wrapper functions for some types of transactions. This means that there
|
||
|
are two streams of data, one going into raw1394 and one coming out.
|
||
|
With this design you can send out multiple transactions without having
|
||
|
to wait for the response before you can continue (sending out other
|
||
|
transactions, for example). The responses and other events (like bus
|
||
|
resets and received isochronous packets) are queued, and you can get
|
||
|
them with <function>raw1394_loop_iterate()</function>.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
This forms an event loop you may already know from similar systems like
|
||
|
GUI toolkits. <function>raw1394_loop_iterate()</function> gets one
|
||
|
message from the event queue in raw1394, processes it with the
|
||
|
configured callback functions and returns the value returned by the
|
||
|
callback (so you can signal to the main loop from your callback; the
|
||
|
standard callbacks all return 0). It normally blocks when there are no
|
||
|
events and always processes only one event. If you are only receiving
|
||
|
broadcast events like isochronous packets you thus have to set up a loop
|
||
|
continuously calling the iterate function to get your callbacks called.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
Often it is necessary to have multiple event loops and combine them,
|
||
|
e.g. if your application uses a GUI toolkit which also has its own event
|
||
|
loop. In that case you can use <function>raw1394_get_fd()</function> to
|
||
|
get the file descriptor used for this handle by libraw1394. The fd can
|
||
|
be used to for <function>select()</function> or
|
||
|
<function>poll()</function> calls (testing for read availability)
|
||
|
together with the other loop's fd, some event loops also allow to add
|
||
|
other fds to their own set (GTK's event loop does). If these trigger on
|
||
|
the libraw1394 fd, you can call
|
||
|
<function>raw1394_loop_iterate()</function> once and it is guaranteed
|
||
|
that it will not block since at the very least one event waits. After
|
||
|
the first call you continue the main event loop. If more events wait,
|
||
|
the <function>select()</function>/<function>poll()</function> will
|
||
|
immediately return again.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
You can also use the fd to set the <symbol>O_NONBLOCK</symbol> flag with
|
||
|
<function>fcntl()</function>. After that, the iterate function will not
|
||
|
block anymore but fail with <symbol>errno</symbol> set to
|
||
|
<symbol>EAGAIN</symbol> if no events wait. These are the only legal
|
||
|
uses for the fd returned by <function>raw1394_get_fd()</function>.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
There are some functions which provide a synchronous wrapper for
|
||
|
transactions, note that these will call
|
||
|
<function>raw1394_loop_iterate()</function> continuously until their
|
||
|
transaction is completed, thus having implicit callback invocations
|
||
|
during their execution. The standard transaction functions have names
|
||
|
of the form <function>raw1394_start_xxx</function>, the synchronous
|
||
|
wrappers are called <function>raw1394_xxx</function>.
|
||
|
</para>
|
||
|
</sect1>
|
||
|
|
||
|
<sect1>
|
||
|
<title>Handlers</title>
|
||
|
|
||
|
<para>
|
||
|
There are a number of handlers which can be set using the appropriate
|
||
|
function as described in the function reference and which libraw1394
|
||
|
will call during a <function>raw1394_loop_iterate()</function>. These
|
||
|
are:
|
||
|
|
||
|
<itemizedlist>
|
||
|
<listitem>
|
||
|
<para>tag handler (called for completed commands)</para>
|
||
|
</listitem>
|
||
|
<listitem>
|
||
|
<para>bus reset handler (called when a bus reset happens)</para>
|
||
|
</listitem>
|
||
|
<listitem>
|
||
|
<para>iso handler (called when an iso packet is received)</para>
|
||
|
</listitem>
|
||
|
<listitem>
|
||
|
<para>fcp handler (called when a FCP command or response is
|
||
|
received)</para>
|
||
|
</listitem>
|
||
|
</itemizedlist>
|
||
|
|
||
|
The bus reset handler is always called, the tag handler for every
|
||
|
command that completes, the iso handler and fcp handler are only called
|
||
|
when the application chooses to receive these packets. Handlers return
|
||
|
an integer value which is passed on by
|
||
|
<function>raw1394_loop_iterate()</function> (only one handler is called
|
||
|
per invocation), <constant>0</constant> is returned without a handler in
|
||
|
place.
|
||
|
</para>
|
||
|
|
||
|
<para>
|
||
|
The tag handler case is a bit special since the default handler is
|
||
|
actually doing something. Every command that you start can be given an
|
||
|
unsigned long tag which is passed untouched to the tag handler when the
|
||
|
event loop sees a completed command. The default handler expects this
|
||
|
value to be a pointer to a <structname>raw1394_reqhandle</structname>
|
||
|
structure, which contains a data pointer and its own callback function
|
||
|
pointer. The callback gets the untouched data pointer and error code as
|
||
|
arguments. If you want to use tags that are not
|
||
|
<structname>raw1394_reqhandle</structname> pointers you have to set up
|
||
|
your own tag handler.
|
||
|
</para>
|
||
|
</sect1>
|
||
|
|
||
|
</chapter>
|
||
|
|
||
|
<chapter id="functions">
|
||
|
<title>Function Reference</title>
|
||
|
|
||
|
<refentry>
|
||
|
<refmeta>
|
||
|
<refentrytitle>raw1394_new_handle</refentrytitle>
|
||
|
<manvolnum>3</manvolnum>
|
||
|
</refmeta>
|
||
|
|
||
|
<refnamediv>
|
||
|
<refname>raw1394_net_handle</refname>
|
||
|
<refpurpose>create new handle</refpurpose>
|
||
|
</refnamediv>
|
||
|
|
||
|
<refsynopsisdiv>
|
||
|
<funcsynopsis>
|
||
|
<funcprototype>
|
||
|
<funcdef>raw1394handle_t <function>raw1394_new_handle</function></funcdef>
|
||
|
<void>
|
||
|
</funcprototype>
|
||
|
</funcsynopsis>
|
||
|
</refsynopsisdiv>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Description</title>
|
||
|
|
||
|
<para>
|
||
|
Creates and returns a new handle. It is not allowed to use the same
|
||
|
handle in multiple threads or forked processes. It is allowed to
|
||
|
create and use multiple handles, however. Use one handle per thread
|
||
|
which needs it in the multithreaded case.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Return Value</title>
|
||
|
|
||
|
<para>
|
||
|
Returns the created handle or <constant>NULL</constant> when
|
||
|
initialization fails. In the latter case <varname>errno</varname>
|
||
|
either contains some OS specific error code or <constant>0</constant>
|
||
|
if the error is that libraw1394 and raw1394 don't support each other's
|
||
|
protocol versions.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
</refentry>
|
||
|
|
||
|
<refentry>
|
||
|
<refmeta>
|
||
|
<refentrytitle>raw1394_destroy_handle</refentrytitle>
|
||
|
<manvolnum>3</manvolnum>
|
||
|
</refmeta>
|
||
|
|
||
|
<refnamediv>
|
||
|
<refname>raw1394_destroy_handle</refname>
|
||
|
<refpurpose>deallocate handle</refpurpose>
|
||
|
</refnamediv>
|
||
|
|
||
|
<refsynopsisdiv>
|
||
|
<funcsynopsis>
|
||
|
<funcprototype>
|
||
|
<funcdef>void <function>raw1394_destroy_handle</function></funcdef>
|
||
|
<paramdef>raw1394handle_t <parameter>handle</parameter></paramdef>
|
||
|
</funcprototype>
|
||
|
</funcsynopsis>
|
||
|
</refsynopsisdiv>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Arguments</title>
|
||
|
|
||
|
<variablelist>
|
||
|
<varlistentry>
|
||
|
<term><parameter>handle</parameter></term>
|
||
|
<listitem>
|
||
|
<para>handle to be deallocated</para>
|
||
|
</listitem>
|
||
|
</varlistentry>
|
||
|
</variablelist>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Description</title>
|
||
|
|
||
|
<para>
|
||
|
Closes connection with raw1394 on this handle and deallocates
|
||
|
everything associated with it. It is safe to pass
|
||
|
<constant>NULL</constant> as handle, nothing is done in this case.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
</refentry>
|
||
|
|
||
|
<refentry>
|
||
|
<refmeta>
|
||
|
<refentrytitle>raw1394_get_fd</refentrytitle>
|
||
|
<manvolnum>3</manvolnum>
|
||
|
</refmeta>
|
||
|
|
||
|
<refnamediv>
|
||
|
<refname>raw1394_get_fd</refname>
|
||
|
<refpurpose>get the communication file descriptor</refpurpose>
|
||
|
</refnamediv>
|
||
|
|
||
|
<refsynopsisdiv>
|
||
|
<funcsynopsis>
|
||
|
<funcprototype>
|
||
|
<funcdef>int <function>raw1394_get_fd</function></funcdef>
|
||
|
<paramdef>raw1394handle_t <parameter>handle</parameter></paramdef>
|
||
|
</funcprototype>
|
||
|
</funcsynopsis>
|
||
|
</refsynopsisdiv>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Arguments</title>
|
||
|
|
||
|
<variablelist>
|
||
|
<varlistentry>
|
||
|
<term><parameter>handle</parameter></term>
|
||
|
<listitem>
|
||
|
<para>handle of which the fd is to be returned from</para>
|
||
|
</listitem>
|
||
|
</varlistentry>
|
||
|
</variablelist>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Description</title>
|
||
|
|
||
|
<para>
|
||
|
Returns the fd used for communication with the raw1394 kernel module.
|
||
|
This can be used for
|
||
|
<function>select()</function>/<function>poll()</function> calls if you
|
||
|
wait on other fds or can be integrated into another event loop
|
||
|
(e.g. from a GUI application framework). It can also be used to
|
||
|
set/remove the <constant>O_NONBLOCK</constant> flag using
|
||
|
<function>fcntl()</function> to modify the block behaviour in
|
||
|
<function>raw1394_loop_iterate()</function>. It must not be used for
|
||
|
anything else.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Return Value</title>
|
||
|
|
||
|
<para>
|
||
|
The fd of the communication stream. Invalid fds may be returned
|
||
|
before a port was set using <function>raw1394_set_port()</function>.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
</refentry>
|
||
|
|
||
|
<refentry>
|
||
|
<refmeta>
|
||
|
<refentrytitle>raw1394_(get|set)_userdata</refentrytitle>
|
||
|
<manvolnum>3</manvolnum>
|
||
|
</refmeta>
|
||
|
|
||
|
<refnamediv>
|
||
|
<refname>raw1394_get_userdata</refname>
|
||
|
<refname>raw1394_set_userdata</refname>
|
||
|
<refpurpose>associate user data with a handle</refpurpose>
|
||
|
</refnamediv>
|
||
|
|
||
|
<refsynopsisdiv>
|
||
|
<funcsynopsis>
|
||
|
<funcprototype>
|
||
|
<funcdef>void *<function>raw1394_get_userdata</function></funcdef>
|
||
|
<paramdef>raw1394handle_t <parameter>handle</parameter></paramdef>
|
||
|
</funcprototype>
|
||
|
<funcprototype>
|
||
|
<funcdef>void <function>raw1394_set_userdata</function></funcdef>
|
||
|
<paramdef>raw1394handle_t <parameter>handle</parameter></paramdef>
|
||
|
</funcprototype>
|
||
|
</funcsynopsis>
|
||
|
</refsynopsisdiv>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Arguments</title>
|
||
|
|
||
|
<variablelist>
|
||
|
<varlistentry>
|
||
|
<term><parameter>handle</parameter></term>
|
||
|
<listitem>
|
||
|
<para>handle associated with the user data</para>
|
||
|
</listitem>
|
||
|
</varlistentry>
|
||
|
</variablelist>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Description</title>
|
||
|
|
||
|
<para>
|
||
|
Allows to associate one void pointer with a handle. libraw1394 does
|
||
|
not care about the data, it just stores it in the handle allowing it
|
||
|
to be retrieved at any time. This can be useful when multiple handles
|
||
|
are used, so that callbacks can identify the handle.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
|
||
|
<refsect1>
|
||
|
<title>Return Value</title>
|
||
|
|
||
|
<para>
|
||
|
<function>raw1394_get_userdata()</function> returns the void pointer
|
||
|
associated with the handle.
|
||
|
</para>
|
||
|
</refsect1>
|
||
|
</refentry>
|
||
|
</chapter>
|
||
|
|
||
|
</book>
|