Eli Billauer | 48bae05 | 2013-06-24 18:55:47 +0300 | [diff] [blame] | 1 | |
| 2 | ========================================== |
| 3 | Xillybus driver for generic FPGA interface |
| 4 | ========================================== |
| 5 | |
| 6 | Author: Eli Billauer, Xillybus Ltd. (http://xillybus.com) |
| 7 | Email: eli.billauer@gmail.com or as advertised on Xillybus' site. |
| 8 | |
| 9 | Contents: |
| 10 | |
| 11 | - Introduction |
| 12 | -- Background |
| 13 | -- Xillybus Overview |
| 14 | |
| 15 | - Usage |
| 16 | -- User interface |
| 17 | -- Synchronization |
| 18 | -- Seekable pipes |
| 19 | |
| 20 | - Internals |
| 21 | -- Source code organization |
| 22 | -- Pipe attributes |
| 23 | -- Host never reads from the FPGA |
| 24 | -- Channels, pipes, and the message channel |
| 25 | -- Data streaming |
| 26 | -- Data granularity |
| 27 | -- Probing |
| 28 | -- Buffer allocation |
Eli Billauer | 48bae05 | 2013-06-24 18:55:47 +0300 | [diff] [blame] | 29 | -- The "nonempty" message (supporting poll) |
| 30 | |
| 31 | |
| 32 | INTRODUCTION |
| 33 | ============ |
| 34 | |
| 35 | Background |
| 36 | ---------- |
| 37 | |
| 38 | An FPGA (Field Programmable Gate Array) is a piece of logic hardware, which |
| 39 | can be programmed to become virtually anything that is usually found as a |
| 40 | dedicated chipset: For instance, a display adapter, network interface card, |
| 41 | or even a processor with its peripherals. FPGAs are the LEGO of hardware: |
| 42 | Based upon certain building blocks, you make your own toys the way you like |
| 43 | them. It's usually pointless to reimplement something that is already |
| 44 | available on the market as a chipset, so FPGAs are mostly used when some |
| 45 | special functionality is needed, and the production volume is relatively low |
| 46 | (hence not justifying the development of an ASIC). |
| 47 | |
| 48 | The challenge with FPGAs is that everything is implemented at a very low |
| 49 | level, even lower than assembly language. In order to allow FPGA designers to |
| 50 | focus on their specific project, and not reinvent the wheel over and over |
| 51 | again, pre-designed building blocks, IP cores, are often used. These are the |
| 52 | FPGA parallels of library functions. IP cores may implement certain |
| 53 | mathematical functions, a functional unit (e.g. a USB interface), an entire |
| 54 | processor (e.g. ARM) or anything that might come handy. Think of them as a |
| 55 | building block, with electrical wires dangling on the sides for connection to |
| 56 | other blocks. |
| 57 | |
| 58 | One of the daunting tasks in FPGA design is communicating with a fullblown |
| 59 | operating system (actually, with the processor running it): Implementing the |
| 60 | low-level bus protocol and the somewhat higher-level interface with the host |
| 61 | (registers, interrupts, DMA etc.) is a project in itself. When the FPGA's |
| 62 | function is a well-known one (e.g. a video adapter card, or a NIC), it can |
| 63 | make sense to design the FPGA's interface logic specifically for the project. |
| 64 | A special driver is then written to present the FPGA as a well-known interface |
| 65 | to the kernel and/or user space. In that case, there is no reason to treat the |
| 66 | FPGA differently than any device on the bus. |
| 67 | |
| 68 | It's however common that the desired data communication doesn't fit any well- |
| 69 | known peripheral function. Also, the effort of designing an elegant |
| 70 | abstraction for the data exchange is often considered too big. In those cases, |
| 71 | a quicker and possibly less elegant solution is sought: The driver is |
| 72 | effectively written as a user space program, leaving the kernel space part |
| 73 | with just elementary data transport. This still requires designing some |
| 74 | interface logic for the FPGA, and write a simple ad-hoc driver for the kernel. |
| 75 | |
| 76 | Xillybus Overview |
| 77 | ----------------- |
| 78 | |
| 79 | Xillybus is an IP core and a Linux driver. Together, they form a kit for |
| 80 | elementary data transport between an FPGA and the host, providing pipe-like |
| 81 | data streams with a straightforward user interface. It's intended as a low- |
| 82 | effort solution for mixed FPGA-host projects, for which it makes sense to |
| 83 | have the project-specific part of the driver running in a user-space program. |
| 84 | |
| 85 | Since the communication requirements may vary significantly from one FPGA |
| 86 | project to another (the number of data pipes needed in each direction and |
| 87 | their attributes), there isn't one specific chunk of logic being the Xillybus |
| 88 | IP core. Rather, the IP core is configured and built based upon a |
| 89 | specification given by its end user. |
| 90 | |
| 91 | Xillybus presents independent data streams, which resemble pipes or TCP/IP |
| 92 | communication to the user. At the host side, a character device file is used |
| 93 | just like any pipe file. On the FPGA side, hardware FIFOs are used to stream |
| 94 | the data. This is contrary to a common method of communicating through fixed- |
| 95 | sized buffers (even though such buffers are used by Xillybus under the hood). |
| 96 | There may be more than a hundred of these streams on a single IP core, but |
| 97 | also no more than one, depending on the configuration. |
| 98 | |
| 99 | In order to ease the deployment of the Xillybus IP core, it contains a simple |
| 100 | data structure which completely defines the core's configuration. The Linux |
| 101 | driver fetches this data structure during its initialization process, and sets |
| 102 | up the DMA buffers and character devices accordingly. As a result, a single |
| 103 | driver is used to work out of the box with any Xillybus IP core. |
| 104 | |
| 105 | The data structure just mentioned should not be confused with PCI's |
| 106 | configuration space or the Flattened Device Tree. |
| 107 | |
| 108 | USAGE |
| 109 | ===== |
| 110 | |
| 111 | User interface |
| 112 | -------------- |
| 113 | |
| 114 | On the host, all interface with Xillybus is done through /dev/xillybus_* |
| 115 | device files, which are generated automatically as the drivers loads. The |
| 116 | names of these files depend on the IP core that is loaded in the FPGA (see |
| 117 | Probing below). To communicate with the FPGA, open the device file that |
| 118 | corresponds to the hardware FIFO you want to send data or receive data from, |
| 119 | and use plain write() or read() calls, just like with a regular pipe. In |
| 120 | particular, it makes perfect sense to go: |
| 121 | |
| 122 | $ cat mydata > /dev/xillybus_thisfifo |
| 123 | |
| 124 | $ cat /dev/xillybus_thatfifo > hisdata |
| 125 | |
| 126 | possibly pressing CTRL-C as some stage, even though the xillybus_* pipes have |
| 127 | the capability to send an EOF (but may not use it). |
| 128 | |
| 129 | The driver and hardware are designed to behave sensibly as pipes, including: |
| 130 | |
| 131 | * Supporting non-blocking I/O (by setting O_NONBLOCK on open() ). |
| 132 | |
| 133 | * Supporting poll() and select(). |
| 134 | |
| 135 | * Being bandwidth efficient under load (using DMA) but also handle small |
| 136 | pieces of data sent across (like TCP/IP) by autoflushing. |
| 137 | |
| 138 | A device file can be read only, write only or bidirectional. Bidirectional |
| 139 | device files are treated like two independent pipes (except for sharing a |
| 140 | "channel" structure in the implementation code). |
| 141 | |
| 142 | Synchronization |
| 143 | --------------- |
| 144 | |
| 145 | Xillybus pipes are configured (on the IP core) to be either synchronous or |
| 146 | asynchronous. For a synchronous pipe, write() returns successfully only after |
| 147 | some data has been submitted and acknowledged by the FPGA. This slows down |
| 148 | bulk data transfers, and is nearly impossible for use with streams that |
| 149 | require data at a constant rate: There is no data transmitted to the FPGA |
| 150 | between write() calls, in particular when the process loses the CPU. |
| 151 | |
| 152 | When a pipe is configured asynchronous, write() returns if there was enough |
| 153 | room in the buffers to store any of the data in the buffers. |
| 154 | |
| 155 | For FPGA to host pipes, asynchronous pipes allow data transfer from the FPGA |
| 156 | as soon as the respective device file is opened, regardless of if the data |
| 157 | has been requested by a read() call. On synchronous pipes, only the amount |
| 158 | of data requested by a read() call is transmitted. |
| 159 | |
| 160 | In summary, for synchronous pipes, data between the host and FPGA is |
| 161 | transmitted only to satisfy the read() or write() call currently handled |
| 162 | by the driver, and those calls wait for the transmission to complete before |
| 163 | returning. |
| 164 | |
| 165 | Note that the synchronization attribute has nothing to do with the possibility |
| 166 | that read() or write() completes less bytes than requested. There is a |
| 167 | separate configuration flag ("allowpartial") that determines whether such a |
| 168 | partial completion is allowed. |
| 169 | |
| 170 | Seekable pipes |
| 171 | -------------- |
| 172 | |
| 173 | A synchronous pipe can be configured to have the stream's position exposed |
| 174 | to the user logic at the FPGA. Such a pipe is also seekable on the host API. |
| 175 | With this feature, a memory or register interface can be attached on the |
| 176 | FPGA side to the seekable stream. Reading or writing to a certain address in |
| 177 | the attached memory is done by seeking to the desired address, and calling |
| 178 | read() or write() as required. |
| 179 | |
| 180 | |
| 181 | INTERNALS |
| 182 | ========= |
| 183 | |
| 184 | Source code organization |
| 185 | ------------------------ |
| 186 | |
| 187 | The Xillybus driver consists of a core module, xillybus_core.c, and modules |
| 188 | that depend on the specific bus interface (xillybus_of.c and xillybus_pcie.c). |
| 189 | |
| 190 | The bus specific modules are those probed when a suitable device is found by |
| 191 | the kernel. Since the DMA mapping and synchronization functions, which are bus |
| 192 | dependent by their nature, are used by the core module, a |
| 193 | xilly_endpoint_hardware structure is passed to the core module on |
| 194 | initialization. This structure is populated with pointers to wrapper functions |
| 195 | which execute the DMA-related operations on the bus. |
| 196 | |
| 197 | Pipe attributes |
| 198 | --------------- |
| 199 | |
| 200 | Each pipe has a number of attributes which are set when the FPGA component |
| 201 | (IP core) is built. They are fetched from the IDT (the data structure which |
| 202 | defines the core's configuration, see Probing below) by xilly_setupchannels() |
| 203 | in xillybus_core.c as follows: |
| 204 | |
| 205 | * is_writebuf: The pipe's direction. A non-zero value means it's an FPGA to |
| 206 | host pipe (the FPGA "writes"). |
| 207 | |
| 208 | * channelnum: The pipe's identification number in communication between the |
| 209 | host and FPGA. |
| 210 | |
| 211 | * format: The underlying data width. See Data Granularity below. |
| 212 | |
| 213 | * allowpartial: A non-zero value means that a read() or write() (whichever |
| 214 | applies) may return with less than the requested number of bytes. The common |
| 215 | choice is a non-zero value, to match standard UNIX behavior. |
| 216 | |
| 217 | * synchronous: A non-zero value means that the pipe is synchronous. See |
| 218 | Syncronization above. |
| 219 | |
| 220 | * bufsize: Each DMA buffer's size. Always a power of two. |
| 221 | |
| 222 | * bufnum: The number of buffers allocated for this pipe. Always a power of two. |
| 223 | |
| 224 | * exclusive_open: A non-zero value forces exclusive opening of the associated |
| 225 | device file. If the device file is bidirectional, and already opened only in |
| 226 | one direction, the opposite direction may be opened once. |
| 227 | |
| 228 | * seekable: A non-zero value indicates that the pipe is seekable. See |
| 229 | Seekable pipes above. |
| 230 | |
| 231 | * supports_nonempty: A non-zero value (which is typical) indicates that the |
| 232 | hardware will send the messages that are necessary to support select() and |
| 233 | poll() for this pipe. |
| 234 | |
| 235 | Host never reads from the FPGA |
| 236 | ------------------------------ |
| 237 | |
| 238 | Even though PCI Express is hotpluggable in general, a typical motherboard |
| 239 | doesn't expect a card to go away all of the sudden. But since the PCIe card |
| 240 | is based upon reprogrammable logic, a sudden disappearance from the bus is |
| 241 | quite likely as a result of an accidental reprogramming of the FPGA while the |
| 242 | host is up. In practice, nothing happens immediately in such a situation. But |
| 243 | if the host attempts to read from an address that is mapped to the PCI Express |
| 244 | device, that leads to an immediate freeze of the system on some motherboards, |
| 245 | even though the PCIe standard requires a graceful recovery. |
| 246 | |
| 247 | In order to avoid these freezes, the Xillybus driver refrains completely from |
| 248 | reading from the device's register space. All communication from the FPGA to |
| 249 | the host is done through DMA. In particular, the Interrupt Service Routine |
| 250 | doesn't follow the common practice of checking a status register when it's |
| 251 | invoked. Rather, the FPGA prepares a small buffer which contains short |
| 252 | messages, which inform the host what the interrupt was about. |
| 253 | |
| 254 | This mechanism is used on non-PCIe buses as well for the sake of uniformity. |
| 255 | |
| 256 | |
| 257 | Channels, pipes, and the message channel |
| 258 | ---------------------------------------- |
| 259 | |
| 260 | Each of the (possibly bidirectional) pipes presented to the user is allocated |
| 261 | a data channel between the FPGA and the host. The distinction between channels |
| 262 | and pipes is necessary only because of channel 0, which is used for interrupt- |
| 263 | related messages from the FPGA, and has no pipe attached to it. |
| 264 | |
| 265 | Data streaming |
| 266 | -------------- |
| 267 | |
| 268 | Even though a non-segmented data stream is presented to the user at both |
| 269 | sides, the implementation relies on a set of DMA buffers which is allocated |
| 270 | for each channel. For the sake of illustration, let's take the FPGA to host |
| 271 | direction: As data streams into the respective channel's interface in the |
| 272 | FPGA, the Xillybus IP core writes it to one of the DMA buffers. When the |
| 273 | buffer is full, the FPGA informs the host about that (appending a |
| 274 | XILLYMSG_OPCODE_RELEASEBUF message channel 0 and sending an interrupt if |
| 275 | necessary). The host responds by making the data available for reading through |
| 276 | the character device. When all data has been read, the host writes on the |
| 277 | the FPGA's buffer control register, allowing the buffer's overwriting. Flow |
| 278 | control mechanisms exist on both sides to prevent underflows and overflows. |
| 279 | |
| 280 | This is not good enough for creating a TCP/IP-like stream: If the data flow |
| 281 | stops momentarily before a DMA buffer is filled, the intuitive expectation is |
| 282 | that the partial data in buffer will arrive anyhow, despite the buffer not |
| 283 | being completed. This is implemented by adding a field in the |
| 284 | XILLYMSG_OPCODE_RELEASEBUF message, through which the FPGA informs not just |
| 285 | which buffer is submitted, but how much data it contains. |
| 286 | |
| 287 | But the FPGA will submit a partially filled buffer only if directed to do so |
| 288 | by the host. This situation occurs when the read() method has been blocking |
| 289 | for XILLY_RX_TIMEOUT jiffies (currently 10 ms), after which the host commands |
| 290 | the FPGA to submit a DMA buffer as soon as it can. This timeout mechanism |
| 291 | balances between bus bandwidth efficiency (preventing a lot of partially |
| 292 | filled buffers being sent) and a latency held fairly low for tails of data. |
| 293 | |
| 294 | A similar setting is used in the host to FPGA direction. The handling of |
| 295 | partial DMA buffers is somewhat different, though. The user can tell the |
| 296 | driver to submit all data it has in the buffers to the FPGA, by issuing a |
| 297 | write() with the byte count set to zero. This is similar to a flush request, |
| 298 | but it doesn't block. There is also an autoflushing mechanism, which triggers |
| 299 | an equivalent flush roughly XILLY_RX_TIMEOUT jiffies after the last write(). |
| 300 | This allows the user to be oblivious about the underlying buffering mechanism |
| 301 | and yet enjoy a stream-like interface. |
| 302 | |
| 303 | Note that the issue of partial buffer flushing is irrelevant for pipes having |
| 304 | the "synchronous" attribute nonzero, since synchronous pipes don't allow data |
| 305 | to lay around in the DMA buffers between read() and write() anyhow. |
| 306 | |
| 307 | Data granularity |
| 308 | ---------------- |
| 309 | |
| 310 | The data arrives or is sent at the FPGA as 8, 16 or 32 bit wide words, as |
| 311 | configured by the "format" attribute. Whenever possible, the driver attempts |
| 312 | to hide this when the pipe is accessed differently from its natural alignment. |
| 313 | For example, reading single bytes from a pipe with 32 bit granularity works |
| 314 | with no issues. Writing single bytes to pipes with 16 or 32 bit granularity |
| 315 | will also work, but the driver can't send partially completed words to the |
| 316 | FPGA, so the transmission of up to one word may be held until it's fully |
| 317 | occupied with user data. |
| 318 | |
| 319 | This somewhat complicates the handling of host to FPGA streams, because |
| 320 | when a buffer is flushed, it may contain up to 3 bytes don't form a word in |
| 321 | the FPGA, and hence can't be sent. To prevent loss of data, these leftover |
| 322 | bytes need to be moved to the next buffer. The parts in xillybus_core.c |
| 323 | that mention "leftovers" in some way are related to this complication. |
| 324 | |
| 325 | Probing |
| 326 | ------- |
| 327 | |
| 328 | As mentioned earlier, the number of pipes that are created when the driver |
| 329 | loads and their attributes depend on the Xillybus IP core in the FPGA. During |
| 330 | the driver's initialization, a blob containing configuration info, the |
| 331 | Interface Description Table (IDT), is sent from the FPGA to the host. The |
| 332 | bootstrap process is done in three phases: |
| 333 | |
| 334 | 1. Acquire the length of the IDT, so a buffer can be allocated for it. This |
| 335 | is done by sending a quiesce command to the device, since the acknowledge |
| 336 | for this command contains the IDT's buffer length. |
| 337 | |
| 338 | 2. Acquire the IDT itself. |
| 339 | |
| 340 | 3. Create the interfaces according to the IDT. |
| 341 | |
| 342 | Buffer allocation |
| 343 | ----------------- |
| 344 | |
| 345 | In order to simplify the logic that prevents illegal boundary crossings of |
| 346 | PCIe packets, the following rule applies: If a buffer is smaller than 4kB, |
| 347 | it must not cross a 4kB boundary. Otherwise, it must be 4kB aligned. The |
| 348 | xilly_setupchannels() functions allocates these buffers by requesting whole |
| 349 | pages from the kernel, and diving them into DMA buffers as necessary. Since |
| 350 | all buffers' sizes are powers of two, it's possible to pack any set of such |
| 351 | buffers, with a maximal waste of one page of memory. |
| 352 | |
| 353 | All buffers are allocated when the driver is loaded. This is necessary, |
| 354 | since large continuous physical memory segments are sometimes requested, |
| 355 | which are more likely to be available when the system is freshly booted. |
| 356 | |
| 357 | The allocation of buffer memory takes place in the same order they appear in |
| 358 | the IDT. The driver relies on a rule that the pipes are sorted with decreasing |
| 359 | buffer size in the IDT. If a requested buffer is larger or equal to a page, |
| 360 | the necessary number of pages is requested from the kernel, and these are |
| 361 | used for this buffer. If the requested buffer is smaller than a page, one |
| 362 | single page is requested from the kernel, and that page is partially used. |
| 363 | Or, if there already is a partially used page at hand, the buffer is packed |
| 364 | into that page. It can be shown that all pages requested from the kernel |
| 365 | (except possibly for the last) are 100% utilized this way. |
| 366 | |
Eli Billauer | 48bae05 | 2013-06-24 18:55:47 +0300 | [diff] [blame] | 367 | The "nonempty" message (supporting poll) |
| 368 | --------------------------------------- |
| 369 | |
| 370 | In order to support the "poll" method (and hence select() ), there is a small |
| 371 | catch regarding the FPGA to host direction: The FPGA may have filled a DMA |
| 372 | buffer with some data, but not submitted that buffer. If the host waited for |
| 373 | the buffer's submission by the FPGA, there would be a possibility that the |
| 374 | FPGA side has sent data, but a select() call would still block, because the |
| 375 | host has not received any notification about this. This is solved with |
| 376 | XILLYMSG_OPCODE_NONEMPTY messages sent by the FPGA when a channel goes from |
| 377 | completely empty to containing some data. |
| 378 | |
| 379 | These messages are used only to support poll() and select(). The IP core can |
| 380 | be configured not to send them for a slight reduction of bandwidth. |