| blob | b827fa095f1b324231e3916bc2e22f2315ec8bbf |
1 /*
2 * linux/drivers/misc/xillybus_core.c
3 *
4 * Copyright 2011 Xillybus Ltd, http://xillybus.com
5 *
6 * Driver for the Xillybus FPGA/host framework.
7 *
8 * This driver interfaces with a special IP core in an FPGA, setting up
9 * a pipe between a hardware FIFO in the programmable logic and a device
10 * file in the host. The number of such pipes and their attributes are
11 * set up on the logic. This driver detects these automatically and
12 * creates the device files accordingly.
13 *
14 * This program is free software; you can redistribute it and/or modify
15 * it under the smems of the GNU General Public License as published by
16 * the Free Software Foundation; version 2 of the License.
17 */
19 #include <linux/list.h>
20 #include <linux/device.h>
21 #include <linux/module.h>
22 #include <linux/io.h>
23 #include <linux/dma-mapping.h>
24 #include <linux/interrupt.h>
25 #include <linux/sched.h>
26 #include <linux/fs.h>
27 #include <linux/cdev.h>
28 #include <linux/spinlock.h>
29 #include <linux/mutex.h>
30 #include <linux/crc32.h>
31 #include <linux/poll.h>
32 #include <linux/delay.h>
33 #include <linux/slab.h>
34 #include <linux/workqueue.h>
43 /* General timeout is 100 ms, rx timeout is 10 ms */
44 #define XILLY_RX_TIMEOUT (10*HZ/1000)
45 #define XILLY_TIMEOUT (100*HZ/1000)
47 #define fpga_msg_ctrl_reg 0x0008
48 #define fpga_dma_control_reg 0x0020
49 #define fpga_dma_bufno_reg 0x0024
50 #define fpga_dma_bufaddr_lowaddr_reg 0x0028
51 #define fpga_dma_bufaddr_highaddr_reg 0x002c
52 #define fpga_buf_ctrl_reg 0x0030
53 #define fpga_buf_offset_reg 0x0034
54 #define fpga_endian_reg 0x0040
56 #define XILLYMSG_OPCODE_RELEASEBUF 1
57 #define XILLYMSG_OPCODE_QUIESCEACK 2
58 #define XILLYMSG_OPCODE_FIFOEOF 3
59 #define XILLYMSG_OPCODE_FATAL_ERROR 4
60 #define XILLYMSG_OPCODE_NONEMPTY 5
66 /*
67 * ep_list_lock is the last lock to be taken; No other lock requests are
68 * allowed while holding it. It merely protects list_of_endpoints, and not
69 * the endpoints listed in it.
70 */
76 /*
77 * Locking scheme: Mutexes protect invocations of character device methods.
78 * If both locks are taken, wr_mutex is taken first, rd_mutex second.
79 *
80 * wr_spinlock protects wr_*_buf_idx, wr_empty, wr_sleepy, wr_ready and the
81 * buffers' end_offset fields against changes made by IRQ handler (and in
82 * theory, other file request handlers, but the mutex handles that). Nothing
83 * else.
84 * They are held for short direct memory manipulations. Needless to say,
85 * no mutex locking is allowed when a spinlock is held.
86 *
87 * rd_spinlock does the same with rd_*_buf_idx, rd_empty and end_offset.
88 *
89 * register_mutex is endpoint-specific, and is held when non-atomic
90 * register operations are performed. wr_mutex and rd_mutex may be
91 * held when register_mutex is taken, but none of the spinlocks. Note that
92 * register_mutex doesn't protect against sporadic buf_ctrl_reg writes
93 * which are unrelated to buf_offset_reg, since they are harmless.
94 *
95 * Blocking on the wait queues is allowed with mutexes held, but not with
96 * spinlocks.
97 *
98 * Only interruptible blocking is allowed on mutexes and wait queues.
99 *
100 * All in all, the locking order goes (with skips allowed, of course):
101 * wr_mutex -> rd_mutex -> register_mutex -> wr_spinlock -> rd_spinlock
102 */
105 {
118 }
120 /*
121 * xillybus_isr assumes the interrupt is allocated exclusively to it,
122 * which is the natural case MSI and several other hardware-oriented
123 * interrupts. Sharing is not allowed.
124 */
127 {
142 DMA_FROM_DEVICE);
158 ep,
161 DMA_FROM_DEVICE);
165 }
169 }
174 }
192 }
200 }
203 msg_data;
212 /* Read channel */
217 }
227 xillybus_wq,
229 XILLY_RX_TIMEOUT);
230 }
239 }
246 }
266 }
284 "FPGA reported a fatal error. This means that the low-level communication with the device has failed. This hardware problem is most likely unrelated to Xillybus (neither kernel module nor FPGA core), but reports are still welcome. All I/O is aborted.\n");
289 }
290 }
295 DMA_FROM_DEVICE);
302 }
305 /*
306 * A few trivial memory management functions.
307 * NOTE: These functions are used only on probe and remove, and therefore
308 * no locks are applied!
309 */
318 u32 regdirection;
319 };
325 {
327 dma_addr_t dma_addr;
334 GFP_KERNEL);
337 }
340 /*
341 * Buffers are expected in descending size order, so there
342 * is either enough space for this buffer or none at all.
343 */
350 }
359 allocorder++;
360 }
363 dev,
365 allocorder);
370 }
397 }
401 }
403 }
408 {
424 };
432 };
441 GFP_KERNEL);
447 /* Initialize all channels with defaults */
483 }
504 }
517 GFP_KERNEL);
522 }
550 msg_buf_done++;
551 }
555 }
561 }
563 }
567 {
582 count++;
583 }
585 scan++;
591 }
600 }
606 }
609 {
624 XILLY_TIMEOUT);
633 }
639 DMA_FROM_DEVICE);
646 }
652 }
656 /* Check version number. Accept anything below 0x82 for now. */
662 }
665 }
669 {
670 ssize_t rc;
678 /* Initializations are there only to silence warnings */
707 /* Update wr_host_* to its post-operation state */
722 }
726 else
728 }
729 }
731 /*
732 * Marking our situation after the possible changes above,
733 * for use after releasing the spinlock.
734 *
735 * empty = empty before change
736 * exhasted = empty after possible change
737 */
754 DMA_FROM_DEVICE);
757 userbuf,
770 DMA_FROM_DEVICE);
772 /*
773 * Tell FPGA the buffer is done with. It's an
774 * atomic operation to the FPGA, so what
775 * happens with other channels doesn't matter,
776 * and the certain channel is protected with
777 * the channel-specific mutex.
778 */
783 fpga_buf_ctrl_reg);
784 }
789 }
790 }
792 /* This includes a zero-count return = EOF */
804 /*
805 * Nonblocking read: The "ready" flag tells us that the FPGA
806 * has data to send. In non-blocking mode, if it isn't on,
807 * just return. But if there is, we jump directly to the point
808 * where we ask for the FPGA to send all it has, and wait
809 * until that data arrives. So in a sense, we *do* block in
810 * nonblocking mode, but only for a very short time.
811 */
822 }
825 /*
826 * Note that in case of an element-misaligned read
827 * request, offsetlimit will include the last element,
828 * which will be partially read from.
829 */
835 /*
836 * In synchronous mode, always send an offset limit.
837 * Just don't send a value too big.
838 */
841 /* Don't request more than one buffer */
846 /* Don't request more than all buffers */
852 }
854 /*
855 * In asynchronous mode, force early flush of a buffer
856 * only if that will allow returning a full count. The
857 * "offsetlimit < ( ... )" rather than "<=" excludes
858 * requesting a full buffer, which would obviously
859 * cause a buffer transmission anyhow
860 */
868 fpga_buf_offset_reg);
874 fpga_buf_ctrl_reg);
877 register_mutex);
878 }
879 }
881 /*
882 * If partial completion is disallowed, there is no point in
883 * timeout sleeping. Neither if no_time_left is set and
884 * there's no data.
885 */
889 /*
890 * This do-loop will run more than once if another
891 * thread reasserted wr_sleepy before we got the mutex
892 * back, so we try again.
893 */
918 }
922 /*
923 * If our time is out, skip the waiting. We may miss wr_sleepy
924 * being deasserted but hey, almost missing the train is like
925 * missing it.
926 */
929 left_to_sleep =
933 left_to_sleep);
945 }
946 }
948 desperate:
952 /*
953 * Reaching here means that we allow partial return,
954 * that we've run out of time, and that we have
955 * nothing to return.
956 * So tell the FPGA to send anything it has or gets.
957 */
963 fpga_buf_ctrl_reg);
964 }
966 /*
967 * Reaching here means that we *do* have data in the buffer,
968 * but the "partial" flag disallows returning less than
969 * required. And we don't have as much. So loop again,
970 * which is likely to end up blocking indefinitely until
971 * enough data has arrived.
972 */
973 }
984 }
986 /*
987 * The timeout argument takes values as follows:
988 * >0 : Flush with timeout
989 * ==0 : Flush, and wait idefinitely for the flush to complete
990 * <0 : Autoflush: Flush only if there's a single buffer occupied
991 */
994 {
1010 /*
1011 * Don't flush a closed channel. This can happen when the work queued
1012 * autoflush thread fires off after the file has closed. This is not
1013 * an error, just something to dismiss.
1014 */
1031 /* Submit the current buffer if it's nonempty */
1036 /* Copy unflushed data, so we can put it in next buffer */
1042 /* Autoflush only if a single buffer is occupied */
1048 /*
1049 * A new work item may be queued by the ISR exactly
1050 * now, since the execution of a work item allows the
1051 * queuing of a new one while it's running.
1052 */
1054 }
1056 /* The 4th element is never needed for data, so it's a flag */
1059 /* Set up rd_full to reflect a certain moment's state */
1067 else
1074 DMA_TO_DEVICE);
1090 bufidx--;
1091 }
1098 /*
1099 * bufidx is now the last buffer written to (or equal to
1100 * rd_fpga_buf_idx if buffer was never written to), and
1101 * channel->rd_host_buf_idx the one after it.
1102 *
1103 * If bufidx == channel->rd_fpga_buf_idx we're either empty or full.
1104 */
1111 * Not really full,
1112 * but needs waiting.
1113 */
1122 /*
1123 * Indefinite sleep with mutex taken. With data waiting for
1124 * flushing user should not be surprised if open() for write
1125 * sleeps.
1126 */
1140 }
1145 }
1146 }
1148 done:
1155 }
1158 {
1163 }
1166 {
1180 }
1184 {
1185 ssize_t rc;
1191 /* Initializations are there only to silence warnings */
1215 /*
1216 * Update rd_host_* to its state after this operation.
1217 * count=0 means committing the buffer immediately,
1218 * which is like flushing, but not necessarily block.
1219 */
1232 end_offset_plus1 =
1244 end_offset_plus1 <<
1254 i++)
1257 }
1264 else
1266 }
1267 }
1269 /*
1270 * Marking our situation after the possible changes above,
1271 * for use after releasing the spinlock.
1272 *
1273 * full = full before change
1274 * exhasted = full after possible change
1275 */
1292 DMA_TO_DEVICE);
1294 /* Virgin, but leftovers are due */
1299 }
1314 DMA_TO_DEVICE);
1320 fpga_buf_offset_reg);
1326 fpga_buf_ctrl_reg);
1329 register_mutex);
1333 }
1343 xillybus_wq,
1345 XILLY_RX_TIMEOUT);
1348 }
1349 }
1360 /*
1361 * Indefinite sleep with mutex taken. With data waiting for
1362 * flushing, user should not be surprised if open() for write
1363 * sleeps.
1364 */
1369 }
1381 }
1382 }
1389 XILLY_RX_TIMEOUT);
1402 }
1405 }
1408 {
1425 }
1426 }
1433 }
1441 /*
1442 * It gets complicated because:
1443 * 1. We don't want to take a mutex we don't have to
1444 * 2. We don't want to open one direction if the other will fail.
1445 */
1459 }
1466 }
1468 /*
1469 * Note: open() may block on getting mutexes despite O_NONBLOCK.
1470 * This shouldn't occur normally, since multiple open of the same
1471 * file descriptor is almost always prohibited anyhow
1472 * (*_exclusive_open is normally set in real-life systems).
1473 */
1479 }
1485 }
1492 }
1499 }
1503 /* Move the host to first buffer */
1520 fpga_buf_ctrl_reg);
1521 }
1524 }
1528 /* Move the host to first buffer */
1541 fpga_buf_ctrl_reg);
1542 }
1545 }
1547 unlock:
1550 unlock_wr:
1558 }
1561 {
1577 /*
1578 * We rely on the kernel calling flush()
1579 * before we get here.
1580 */
1585 fpga_buf_ctrl_reg);
1586 }
1588 }
1599 fpga_buf_ctrl_reg);
1601 /*
1602 * This is crazily cautious: We make sure that not
1603 * only that we got an EOF (be it because we closed
1604 * the channel or because of a user's EOF), but verify
1605 * that it's one beyond the last buffer arrived, so
1606 * we have no leftover buffers pending before wrapping
1607 * up (which can only happen in asynchronous channels,
1608 * BTW)
1609 */
1613 flags);
1618 flags);
1620 /*
1621 * Check if eof points at the buffer after
1622 * the last one the FPGA submitted. Note that
1623 * no EOF is marked by negative eof.
1624 */
1626 buf_idx++;
1633 /*
1634 * Steal extra 100 ms if awaken by interrupt.
1635 * This is a simple workaround for an
1636 * interrupt pending when entering, which would
1637 * otherwise result in declaring the hardware
1638 * non-responsive.
1639 */
1651 }
1652 }
1653 }
1656 }
1659 }
1662 {
1667 /*
1668 * Take both mutexes not allowing interrupts, since it seems like
1669 * common applications don't expect an -EINTR here. Besides, multiple
1670 * access to a single file descriptor on seekable devices is a mess
1671 * anyhow.
1672 */
1693 }
1695 /* In any case, we must finish on an element boundary */
1699 }
1712 end:
1721 /*
1722 * Since seekable devices are allowed only when the channel is
1723 * synchronous, we assume that there is no data pending in either
1724 * direction (which holds true as long as no concurrent access on the
1725 * file descriptor takes place).
1726 * The only thing we may need to throw away is leftovers from partial
1727 * write() flush.
1728 */
1733 }
1736 {
1743 /*
1744 * poll() won't play ball regarding read() channels which
1745 * aren't asynchronous and support the nonempty message. Allowing
1746 * that will create situations where data has been delivered at
1747 * the FPGA, and users expecting select() to wake up, which it may
1748 * not.
1749 */
1760 /*
1761 * Not POLLHUP, because its behavior is in the
1762 * mist, and POLLIN does what we want: Wake up
1763 * the read file descriptor so it sees EOF.
1764 */
1767 }
1769 /*
1770 * If partial data write is disallowed on a write() channel,
1771 * it's pointless to ever signal OK to write, because is could
1772 * block despite some space being available.
1773 */
1782 }
1788 }
1799 };
1803 {
1805 dev_t dev;
1812 xillyname);
1816 }
1828 }
1830 idt++;
1843 NULL,
1845 NULL,
1851 devname);
1854 }
1855 }
1861 unroll_device_create:
1867 unregister_chrdev:
1871 }
1874 {
1879 minor++)
1888 }
1892 struct xilly_endpoint_hardware
1894 {
1912 }
1916 {
1926 XILLY_TIMEOUT);
1931 }
1933 }
1936 {
1944 /*
1945 * The bogus IDT is used during bootstrap for allocating the initial
1946 * message buffer, and then the message buffer and space for the IDT
1947 * itself. The initial message buffer is of a single page's size, but
1948 * it's soon replaced with a more modest one (and memory is freed).
1949 */
1955 /*
1956 * Writing the value 0x00000001 to Endianness register signals which
1957 * endianness this processor is using, so the FPGA can swap words as
1958 * necessary.
1959 */
1963 /* Bootstrap phase I: Allocate temporary message buffer */
1975 /* Clear the message subsystem (and counter in particular) */
1980 /*
1981 * Set DMA 32/64 bit mode, quiesce the device (?!) and get IDT
1982 * buffer size.
1983 */
1989 XILLY_TIMEOUT);
1993 }
1995 /* Enable DMA */
1999 /* Bootstrap phase II: Allocate buffer for IDT and obtain it */
2003 }
2021 /* Bootstrap phase III: Allocate buffers according to IDT */
2029 /*
2030 * endpoint is now completely configured. We put it on the list
2031 * available to open() before registering the char device(s)
2032 */
2046 failed_chrdevs:
2051 failed_idt:
2056 }
2060 {
2069 /*
2070 * Flushing is done upon endpoint release to prevent access to memory
2071 * just about to be released. This makes the quiesce complete.
2072 */
2074 }
2078 {
2089 }
2092 }
2095 {
2096 /* flush_workqueue() was called for each endpoint released */
2100 }