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Signed-off-by: Eric Engestrom <eric@engestrom.ch> Signed-off-by: Jonathan Corbet <corbet@lwn.net>
381 lines
18 KiB
Plaintext
381 lines
18 KiB
Plaintext
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==========================================
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Xillybus driver for generic FPGA interface
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==========================================
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Author: Eli Billauer, Xillybus Ltd. (http://xillybus.com)
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Email: eli.billauer@gmail.com or as advertised on Xillybus' site.
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Contents:
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- Introduction
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-- Background
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-- Xillybus Overview
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- Usage
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-- User interface
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-- Synchronization
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-- Seekable pipes
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- Internals
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-- Source code organization
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-- Pipe attributes
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-- Host never reads from the FPGA
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-- Channels, pipes, and the message channel
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-- Data streaming
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-- Data granularity
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-- Probing
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-- Buffer allocation
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-- The "nonempty" message (supporting poll)
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INTRODUCTION
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============
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Background
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----------
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An FPGA (Field Programmable Gate Array) is a piece of logic hardware, which
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can be programmed to become virtually anything that is usually found as a
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dedicated chipset: For instance, a display adapter, network interface card,
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or even a processor with its peripherals. FPGAs are the LEGO of hardware:
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Based upon certain building blocks, you make your own toys the way you like
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them. It's usually pointless to reimplement something that is already
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available on the market as a chipset, so FPGAs are mostly used when some
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special functionality is needed, and the production volume is relatively low
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(hence not justifying the development of an ASIC).
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The challenge with FPGAs is that everything is implemented at a very low
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level, even lower than assembly language. In order to allow FPGA designers to
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focus on their specific project, and not reinvent the wheel over and over
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again, pre-designed building blocks, IP cores, are often used. These are the
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FPGA parallels of library functions. IP cores may implement certain
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mathematical functions, a functional unit (e.g. a USB interface), an entire
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processor (e.g. ARM) or anything that might come handy. Think of them as a
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building block, with electrical wires dangling on the sides for connection to
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other blocks.
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One of the daunting tasks in FPGA design is communicating with a fullblown
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operating system (actually, with the processor running it): Implementing the
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low-level bus protocol and the somewhat higher-level interface with the host
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(registers, interrupts, DMA etc.) is a project in itself. When the FPGA's
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function is a well-known one (e.g. a video adapter card, or a NIC), it can
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make sense to design the FPGA's interface logic specifically for the project.
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A special driver is then written to present the FPGA as a well-known interface
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to the kernel and/or user space. In that case, there is no reason to treat the
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FPGA differently than any device on the bus.
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It's however common that the desired data communication doesn't fit any well-
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known peripheral function. Also, the effort of designing an elegant
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abstraction for the data exchange is often considered too big. In those cases,
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a quicker and possibly less elegant solution is sought: The driver is
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effectively written as a user space program, leaving the kernel space part
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with just elementary data transport. This still requires designing some
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interface logic for the FPGA, and write a simple ad-hoc driver for the kernel.
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Xillybus Overview
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-----------------
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Xillybus is an IP core and a Linux driver. Together, they form a kit for
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elementary data transport between an FPGA and the host, providing pipe-like
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data streams with a straightforward user interface. It's intended as a low-
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effort solution for mixed FPGA-host projects, for which it makes sense to
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have the project-specific part of the driver running in a user-space program.
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Since the communication requirements may vary significantly from one FPGA
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project to another (the number of data pipes needed in each direction and
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their attributes), there isn't one specific chunk of logic being the Xillybus
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IP core. Rather, the IP core is configured and built based upon a
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specification given by its end user.
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Xillybus presents independent data streams, which resemble pipes or TCP/IP
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communication to the user. At the host side, a character device file is used
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just like any pipe file. On the FPGA side, hardware FIFOs are used to stream
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the data. This is contrary to a common method of communicating through fixed-
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sized buffers (even though such buffers are used by Xillybus under the hood).
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There may be more than a hundred of these streams on a single IP core, but
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also no more than one, depending on the configuration.
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In order to ease the deployment of the Xillybus IP core, it contains a simple
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data structure which completely defines the core's configuration. The Linux
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driver fetches this data structure during its initialization process, and sets
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up the DMA buffers and character devices accordingly. As a result, a single
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driver is used to work out of the box with any Xillybus IP core.
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The data structure just mentioned should not be confused with PCI's
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configuration space or the Flattened Device Tree.
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USAGE
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=====
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User interface
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--------------
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On the host, all interface with Xillybus is done through /dev/xillybus_*
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device files, which are generated automatically as the drivers loads. The
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names of these files depend on the IP core that is loaded in the FPGA (see
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Probing below). To communicate with the FPGA, open the device file that
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corresponds to the hardware FIFO you want to send data or receive data from,
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and use plain write() or read() calls, just like with a regular pipe. In
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particular, it makes perfect sense to go:
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$ cat mydata > /dev/xillybus_thisfifo
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$ cat /dev/xillybus_thatfifo > hisdata
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possibly pressing CTRL-C as some stage, even though the xillybus_* pipes have
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the capability to send an EOF (but may not use it).
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The driver and hardware are designed to behave sensibly as pipes, including:
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* Supporting non-blocking I/O (by setting O_NONBLOCK on open() ).
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* Supporting poll() and select().
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* Being bandwidth efficient under load (using DMA) but also handle small
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pieces of data sent across (like TCP/IP) by autoflushing.
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A device file can be read only, write only or bidirectional. Bidirectional
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device files are treated like two independent pipes (except for sharing a
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"channel" structure in the implementation code).
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Synchronization
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---------------
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Xillybus pipes are configured (on the IP core) to be either synchronous or
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asynchronous. For a synchronous pipe, write() returns successfully only after
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some data has been submitted and acknowledged by the FPGA. This slows down
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bulk data transfers, and is nearly impossible for use with streams that
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require data at a constant rate: There is no data transmitted to the FPGA
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between write() calls, in particular when the process loses the CPU.
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When a pipe is configured asynchronous, write() returns if there was enough
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room in the buffers to store any of the data in the buffers.
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For FPGA to host pipes, asynchronous pipes allow data transfer from the FPGA
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as soon as the respective device file is opened, regardless of if the data
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has been requested by a read() call. On synchronous pipes, only the amount
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of data requested by a read() call is transmitted.
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In summary, for synchronous pipes, data between the host and FPGA is
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transmitted only to satisfy the read() or write() call currently handled
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by the driver, and those calls wait for the transmission to complete before
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returning.
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Note that the synchronization attribute has nothing to do with the possibility
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that read() or write() completes less bytes than requested. There is a
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separate configuration flag ("allowpartial") that determines whether such a
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partial completion is allowed.
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Seekable pipes
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--------------
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A synchronous pipe can be configured to have the stream's position exposed
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to the user logic at the FPGA. Such a pipe is also seekable on the host API.
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With this feature, a memory or register interface can be attached on the
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FPGA side to the seekable stream. Reading or writing to a certain address in
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the attached memory is done by seeking to the desired address, and calling
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read() or write() as required.
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INTERNALS
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=========
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Source code organization
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------------------------
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The Xillybus driver consists of a core module, xillybus_core.c, and modules
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that depend on the specific bus interface (xillybus_of.c and xillybus_pcie.c).
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The bus specific modules are those probed when a suitable device is found by
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the kernel. Since the DMA mapping and synchronization functions, which are bus
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dependent by their nature, are used by the core module, a
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xilly_endpoint_hardware structure is passed to the core module on
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initialization. This structure is populated with pointers to wrapper functions
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which execute the DMA-related operations on the bus.
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Pipe attributes
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---------------
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Each pipe has a number of attributes which are set when the FPGA component
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(IP core) is built. They are fetched from the IDT (the data structure which
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defines the core's configuration, see Probing below) by xilly_setupchannels()
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in xillybus_core.c as follows:
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* is_writebuf: The pipe's direction. A non-zero value means it's an FPGA to
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host pipe (the FPGA "writes").
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* channelnum: The pipe's identification number in communication between the
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host and FPGA.
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* format: The underlying data width. See Data Granularity below.
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* allowpartial: A non-zero value means that a read() or write() (whichever
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applies) may return with less than the requested number of bytes. The common
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choice is a non-zero value, to match standard UNIX behavior.
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* synchronous: A non-zero value means that the pipe is synchronous. See
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Synchronization above.
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* bufsize: Each DMA buffer's size. Always a power of two.
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* bufnum: The number of buffers allocated for this pipe. Always a power of two.
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* exclusive_open: A non-zero value forces exclusive opening of the associated
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device file. If the device file is bidirectional, and already opened only in
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one direction, the opposite direction may be opened once.
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* seekable: A non-zero value indicates that the pipe is seekable. See
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Seekable pipes above.
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* supports_nonempty: A non-zero value (which is typical) indicates that the
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hardware will send the messages that are necessary to support select() and
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poll() for this pipe.
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Host never reads from the FPGA
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------------------------------
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Even though PCI Express is hotpluggable in general, a typical motherboard
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doesn't expect a card to go away all of the sudden. But since the PCIe card
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is based upon reprogrammable logic, a sudden disappearance from the bus is
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quite likely as a result of an accidental reprogramming of the FPGA while the
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host is up. In practice, nothing happens immediately in such a situation. But
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if the host attempts to read from an address that is mapped to the PCI Express
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device, that leads to an immediate freeze of the system on some motherboards,
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even though the PCIe standard requires a graceful recovery.
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In order to avoid these freezes, the Xillybus driver refrains completely from
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reading from the device's register space. All communication from the FPGA to
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the host is done through DMA. In particular, the Interrupt Service Routine
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doesn't follow the common practice of checking a status register when it's
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invoked. Rather, the FPGA prepares a small buffer which contains short
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messages, which inform the host what the interrupt was about.
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This mechanism is used on non-PCIe buses as well for the sake of uniformity.
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Channels, pipes, and the message channel
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----------------------------------------
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Each of the (possibly bidirectional) pipes presented to the user is allocated
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a data channel between the FPGA and the host. The distinction between channels
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and pipes is necessary only because of channel 0, which is used for interrupt-
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related messages from the FPGA, and has no pipe attached to it.
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Data streaming
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--------------
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Even though a non-segmented data stream is presented to the user at both
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sides, the implementation relies on a set of DMA buffers which is allocated
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for each channel. For the sake of illustration, let's take the FPGA to host
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direction: As data streams into the respective channel's interface in the
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FPGA, the Xillybus IP core writes it to one of the DMA buffers. When the
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buffer is full, the FPGA informs the host about that (appending a
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XILLYMSG_OPCODE_RELEASEBUF message channel 0 and sending an interrupt if
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necessary). The host responds by making the data available for reading through
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the character device. When all data has been read, the host writes on the
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the FPGA's buffer control register, allowing the buffer's overwriting. Flow
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control mechanisms exist on both sides to prevent underflows and overflows.
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This is not good enough for creating a TCP/IP-like stream: If the data flow
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stops momentarily before a DMA buffer is filled, the intuitive expectation is
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that the partial data in buffer will arrive anyhow, despite the buffer not
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being completed. This is implemented by adding a field in the
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XILLYMSG_OPCODE_RELEASEBUF message, through which the FPGA informs not just
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which buffer is submitted, but how much data it contains.
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But the FPGA will submit a partially filled buffer only if directed to do so
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by the host. This situation occurs when the read() method has been blocking
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for XILLY_RX_TIMEOUT jiffies (currently 10 ms), after which the host commands
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the FPGA to submit a DMA buffer as soon as it can. This timeout mechanism
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balances between bus bandwidth efficiency (preventing a lot of partially
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filled buffers being sent) and a latency held fairly low for tails of data.
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A similar setting is used in the host to FPGA direction. The handling of
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partial DMA buffers is somewhat different, though. The user can tell the
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driver to submit all data it has in the buffers to the FPGA, by issuing a
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write() with the byte count set to zero. This is similar to a flush request,
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but it doesn't block. There is also an autoflushing mechanism, which triggers
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an equivalent flush roughly XILLY_RX_TIMEOUT jiffies after the last write().
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This allows the user to be oblivious about the underlying buffering mechanism
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and yet enjoy a stream-like interface.
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Note that the issue of partial buffer flushing is irrelevant for pipes having
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the "synchronous" attribute nonzero, since synchronous pipes don't allow data
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to lay around in the DMA buffers between read() and write() anyhow.
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Data granularity
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----------------
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The data arrives or is sent at the FPGA as 8, 16 or 32 bit wide words, as
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configured by the "format" attribute. Whenever possible, the driver attempts
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to hide this when the pipe is accessed differently from its natural alignment.
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For example, reading single bytes from a pipe with 32 bit granularity works
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with no issues. Writing single bytes to pipes with 16 or 32 bit granularity
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will also work, but the driver can't send partially completed words to the
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FPGA, so the transmission of up to one word may be held until it's fully
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occupied with user data.
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This somewhat complicates the handling of host to FPGA streams, because
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when a buffer is flushed, it may contain up to 3 bytes don't form a word in
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the FPGA, and hence can't be sent. To prevent loss of data, these leftover
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bytes need to be moved to the next buffer. The parts in xillybus_core.c
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that mention "leftovers" in some way are related to this complication.
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Probing
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-------
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As mentioned earlier, the number of pipes that are created when the driver
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loads and their attributes depend on the Xillybus IP core in the FPGA. During
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the driver's initialization, a blob containing configuration info, the
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Interface Description Table (IDT), is sent from the FPGA to the host. The
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bootstrap process is done in three phases:
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1. Acquire the length of the IDT, so a buffer can be allocated for it. This
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is done by sending a quiesce command to the device, since the acknowledge
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for this command contains the IDT's buffer length.
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2. Acquire the IDT itself.
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3. Create the interfaces according to the IDT.
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Buffer allocation
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-----------------
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In order to simplify the logic that prevents illegal boundary crossings of
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PCIe packets, the following rule applies: If a buffer is smaller than 4kB,
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it must not cross a 4kB boundary. Otherwise, it must be 4kB aligned. The
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xilly_setupchannels() functions allocates these buffers by requesting whole
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pages from the kernel, and diving them into DMA buffers as necessary. Since
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all buffers' sizes are powers of two, it's possible to pack any set of such
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buffers, with a maximal waste of one page of memory.
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All buffers are allocated when the driver is loaded. This is necessary,
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since large continuous physical memory segments are sometimes requested,
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which are more likely to be available when the system is freshly booted.
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The allocation of buffer memory takes place in the same order they appear in
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the IDT. The driver relies on a rule that the pipes are sorted with decreasing
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buffer size in the IDT. If a requested buffer is larger or equal to a page,
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the necessary number of pages is requested from the kernel, and these are
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used for this buffer. If the requested buffer is smaller than a page, one
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single page is requested from the kernel, and that page is partially used.
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Or, if there already is a partially used page at hand, the buffer is packed
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into that page. It can be shown that all pages requested from the kernel
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(except possibly for the last) are 100% utilized this way.
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The "nonempty" message (supporting poll)
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---------------------------------------
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In order to support the "poll" method (and hence select() ), there is a small
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catch regarding the FPGA to host direction: The FPGA may have filled a DMA
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buffer with some data, but not submitted that buffer. If the host waited for
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the buffer's submission by the FPGA, there would be a possibility that the
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FPGA side has sent data, but a select() call would still block, because the
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host has not received any notification about this. This is solved with
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XILLYMSG_OPCODE_NONEMPTY messages sent by the FPGA when a channel goes from
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completely empty to containing some data.
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These messages are used only to support poll() and select(). The IP core can
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be configured not to send them for a slight reduction of bandwidth.
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