| blob | 69295ba9d99ae12f29738533fb15f5a7b4cce046 |
1 /* linux/drivers/usb/gadget/s3c-hsotg.c
2 *
3 * Copyright (c) 2011 Samsung Electronics Co., Ltd.
4 * http://www.samsung.com
5 *
6 * Copyright 2008 Openmoko, Inc.
7 * Copyright 2008 Simtec Electronics
8 * Ben Dooks <ben@simtec.co.uk>
9 * http://armlinux.simtec.co.uk/
10 *
11 * S3C USB2.0 High-speed / OtG driver
12 *
13 * This program is free software; you can redistribute it and/or modify
14 * it under the terms of the GNU General Public License version 2 as
15 * published by the Free Software Foundation.
16 */
18 #include <linux/kernel.h>
19 #include <linux/module.h>
20 #include <linux/spinlock.h>
21 #include <linux/interrupt.h>
22 #include <linux/platform_device.h>
23 #include <linux/dma-mapping.h>
24 #include <linux/debugfs.h>
25 #include <linux/seq_file.h>
26 #include <linux/delay.h>
27 #include <linux/io.h>
28 #include <linux/slab.h>
29 #include <linux/clk.h>
31 #include <linux/usb/ch9.h>
32 #include <linux/usb/gadget.h>
34 #include <mach/map.h>
36 #include <plat/regs-usb-hsotg-phy.h>
37 #include <plat/regs-usb-hsotg.h>
38 #include <mach/regs-sys.h>
39 #include <plat/udc-hs.h>
40 #include <plat/cpu.h>
42 #define DMA_ADDR_INVALID (~((dma_addr_t)0))
44 /* EP0_MPS_LIMIT
45 *
46 * Unfortunately there seems to be a limit of the amount of data that can
47 * be transferred by IN transactions on EP0. This is either 127 bytes or 3
48 * packets (which practically means 1 packet and 63 bytes of data) when the
49 * MPS is set to 64.
50 *
51 * This means if we are wanting to move >127 bytes of data, we need to
52 * split the transactions up, but just doing one packet at a time does
53 * not work (this may be an implicit DATA0 PID on first packet of the
54 * transaction) and doing 2 packets is outside the controller's limits.
55 *
56 * If we try to lower the MPS size for EP0, then no transfers work properly
57 * for EP0, and the system will fail basic enumeration. As no cause for this
58 * has currently been found, we cannot support any large IN transfers for
59 * EP0.
60 */
61 #define EP0_MPS_LIMIT 64
66 /**
67 * struct s3c_hsotg_ep - driver endpoint definition.
68 * @ep: The gadget layer representation of the endpoint.
69 * @name: The driver generated name for the endpoint.
70 * @queue: Queue of requests for this endpoint.
71 * @parent: Reference back to the parent device structure.
72 * @req: The current request that the endpoint is processing. This is
73 * used to indicate an request has been loaded onto the endpoint
74 * and has yet to be completed (maybe due to data move, or simply
75 * awaiting an ack from the core all the data has been completed).
76 * @debugfs: File entry for debugfs file for this endpoint.
77 * @lock: State lock to protect contents of endpoint.
78 * @dir_in: Set to true if this endpoint is of the IN direction, which
79 * means that it is sending data to the Host.
80 * @index: The index for the endpoint registers.
81 * @name: The name array passed to the USB core.
82 * @halted: Set if the endpoint has been halted.
83 * @periodic: Set if this is a periodic ep, such as Interrupt
84 * @sent_zlp: Set if we've sent a zero-length packet.
85 * @total_data: The total number of data bytes done.
86 * @fifo_size: The size of the FIFO (for periodic IN endpoints)
87 * @fifo_load: The amount of data loaded into the FIFO (periodic IN)
88 * @last_load: The offset of data for the last start of request.
89 * @size_loaded: The last loaded size for DxEPTSIZE for periodic IN
90 *
91 * This is the driver's state for each registered enpoint, allowing it
92 * to keep track of transactions that need doing. Each endpoint has a
93 * lock to protect the state, to try and avoid using an overall lock
94 * for the host controller as much as possible.
95 *
96 * For periodic IN endpoints, we have fifo_size and fifo_load to try
97 * and keep track of the amount of data in the periodic FIFO for each
98 * of these as we don't have a status register that tells us how much
99 * is in each of them. (note, this may actually be useless information
100 * as in shared-fifo mode periodic in acts like a single-frame packet
101 * buffer than a fifo)
102 */
110 spinlock_t lock;
126 };
130 /**
131 * struct s3c_hsotg - driver state.
132 * @dev: The parent device supplied to the probe function
133 * @driver: USB gadget driver
134 * @plat: The platform specific configuration data.
135 * @regs: The memory area mapped for accessing registers.
136 * @regs_res: The resource that was allocated when claiming register space.
137 * @irq: The IRQ number we are using
138 * @dedicated_fifos: Set if the hardware has dedicated IN-EP fifos.
139 * @debug_root: root directrory for debugfs.
140 * @debug_file: main status file for debugfs.
141 * @debug_fifo: FIFO status file for debugfs.
142 * @ep0_reply: Request used for ep0 reply.
143 * @ep0_buff: Buffer for EP0 reply data, if needed.
144 * @ctrl_buff: Buffer for EP0 control requests.
145 * @ctrl_req: Request for EP0 control packets.
146 * @eps: The endpoints being supplied to the gadget framework
147 */
171 };
173 /**
174 * struct s3c_hsotg_req - data transfer request
175 * @req: The USB gadget request
176 * @queue: The list of requests for the endpoint this is queued for.
177 * @in_progress: Has already had size/packets written to core
178 * @mapped: DMA buffer for this request has been mapped via dma_map_single().
179 */
185 };
187 /* conversion functions */
189 {
191 }
194 {
196 }
199 {
201 }
204 {
206 }
209 {
211 }
213 /* forward decleration of functions */
216 /**
217 * using_dma - return the DMA status of the driver.
218 * @hsotg: The driver state.
219 *
220 * Return true if we're using DMA.
221 *
222 * Currently, we have the DMA support code worked into everywhere
223 * that needs it, but the AMBA DMA implementation in the hardware can
224 * only DMA from 32bit aligned addresses. This means that gadgets such
225 * as the CDC Ethernet cannot work as they often pass packets which are
226 * not 32bit aligned.
227 *
228 * Unfortunately the choice to use DMA or not is global to the controller
229 * and seems to be only settable when the controller is being put through
230 * a core reset. This means we either need to fix the gadgets to take
231 * account of DMA alignment, or add bounce buffers (yuerk).
232 *
233 * Until this issue is sorted out, we always return 'false'.
234 */
236 {
238 }
240 /**
241 * s3c_hsotg_en_gsint - enable one or more of the general interrupt
242 * @hsotg: The device state
243 * @ints: A bitmask of the interrupts to enable
244 */
246 {
248 u32 new_gsintmsk;
255 }
256 }
258 /**
259 * s3c_hsotg_disable_gsint - disable one or more of the general interrupt
260 * @hsotg: The device state
261 * @ints: A bitmask of the interrupts to enable
262 */
264 {
266 u32 new_gsintmsk;
272 }
274 /**
275 * s3c_hsotg_ctrl_epint - enable/disable an endpoint irq
276 * @hsotg: The device state
277 * @ep: The endpoint index
278 * @dir_in: True if direction is in.
279 * @en: The enable value, true to enable
280 *
281 * Set or clear the mask for an individual endpoint's interrupt
282 * request.
283 */
287 {
290 u32 daint;
299 else
303 }
305 /**
306 * s3c_hsotg_init_fifo - initialise non-periodic FIFOs
307 * @hsotg: The device instance.
308 */
310 {
315 u32 val;
317 /* the ryu 2.6.24 release ahs
318 writel(0x1C0, hsotg->regs + S3C_GRXFSIZ);
319 writel(S3C_GNPTXFSIZ_NPTxFStAddr(0x200) |
320 S3C_GNPTXFSIZ_NPTxFDep(0x1C0),
321 hsotg->regs + S3C_GNPTXFSIZ);
322 */
324 /* set FIFO sizes to 2048/1024 */
331 /* arange all the rest of the TX FIFOs, as some versions of this
332 * block have overlapping default addresses. This also ensures
333 * that if the settings have been changed, then they are set to
334 * known values. */
336 /* start at the end of the GNPTXFSIZ, rounded up */
340 /* currently we allocate TX FIFOs for all possible endpoints,
341 * and assume that they are all the same size. */
349 }
351 /* according to p428 of the design guide, we need to ensure that
352 * all fifos are flushed before continuing */
357 /* wait until the fifos are both flushed */
369 }
372 }
375 }
377 /**
378 * @ep: USB endpoint to allocate request for.
379 * @flags: Allocation flags
380 *
381 * Allocate a new USB request structure appropriate for the specified endpoint
382 */
384 gfp_t flags)
385 {
396 }
398 /**
399 * is_ep_periodic - return true if the endpoint is in periodic mode.
400 * @hs_ep: The endpoint to query.
401 *
402 * Returns true if the endpoint is in periodic mode, meaning it is being
403 * used for an Interrupt or ISO transfer.
404 */
406 {
408 }
410 /**
411 * s3c_hsotg_unmap_dma - unmap the DMA memory being used for the request
412 * @hsotg: The device state.
413 * @hs_ep: The endpoint for the request
414 * @hs_req: The request being processed.
415 *
416 * This is the reverse of s3c_hsotg_map_dma(), called for the completion
417 * of a request to ensure the buffer is ready for access by the caller.
418 */
422 {
428 /* ignore this if we're not moving any data */
433 /* we mapped this, so unmap and remove the dma */
441 }
442 }
444 /**
445 * s3c_hsotg_write_fifo - write packet Data to the TxFIFO
446 * @hsotg: The controller state.
447 * @hs_ep: The endpoint we're going to write for.
448 * @hs_req: The request to write data for.
449 *
450 * This is called when the TxFIFO has some space in it to hold a new
451 * transmission and we have something to give it. The actual setup of
452 * the data size is done elsewhere, so all we have to do is to actually
453 * write the data.
454 *
455 * The return value is zero if there is more space (or nothing was done)
456 * otherwise -ENOSPC is returned if the FIFO space was used up.
457 *
458 * This routine is only needed for PIO
459 */
463 {
474 /* if there's nothing to write, get out early */
483 /* work out how much data was loaded so we can calculate
484 * how much data is left in the fifo. */
488 /* if shared fifo, we cannot write anything until the
489 * previous data has been completely sent.
490 */
494 }
500 /* how much of the data has moved */
503 /* how much data is left in the fifo */
515 }
529 }
533 }
538 /* limit to 512 bytes of data, it seems at least on the non-periodic
539 * FIFO, requests of >512 cause the endpoint to get stuck with a
540 * fragment of the end of the transfer in it.
541 */
545 /* limit the write to one max-packet size worth of data, but allow
546 * the transfer to return that it did not run out of fifo space
547 * doing it. */
553 S3C_GINTSTS_NPTxFEmp);
554 }
556 /* see if we can write data */
562 /* Not sure, but we probably shouldn't be writing partial
563 * packets into the FIFO, so round the write down to an
564 * exact number of packets.
565 *
566 * Note, we do not currently check to see if we can ever
567 * write a full packet or not to the FIFO.
568 */
573 /* enable correct FIFO interrupt to alert us when there
574 * is more room left. */
578 S3C_GINTSTS_NPTxFEmp);
579 }
599 }
601 /**
602 * get_ep_limit - get the maximum data legnth for this endpoint
603 * @hs_ep: The endpoint
604 *
605 * Return the maximum data that can be queued in one go on a given endpoint
606 * so that transfers that are too long can be split.
607 */
609 {
621 else
623 }
625 /* we made the constant loading easier above by using +1 */
626 maxpkt--;
627 maxsize--;
629 /* constrain by packet count if maxpkts*pktsize is greater
630 * than the length register size. */
636 }
638 /**
639 * s3c_hsotg_start_req - start a USB request from an endpoint's queue
640 * @hsotg: The controller state.
641 * @hs_ep: The endpoint to process a request for
642 * @hs_req: The request to start.
643 * @continuing: True if we are doing more for the current request.
644 *
645 * Start the given request running by setting the endpoint registers
646 * appropriately, and writing any data to the FIFOs.
647 */
652 {
656 u32 epctrl_reg;
657 u32 epsize_reg;
658 u32 epsize;
659 u32 ctrl;
674 }
675 }
684 /* If endpoint is stalled, we will restart request later */
690 }
707 /* round down to multiple of packets */
712 }
716 else
721 else
725 /* test for the packets being exactly right for the
726 * transfer */
729 packets++;
730 }
738 /* store the request as the current one we're doing */
741 /* write size / packets */
747 /* write DMA address to control register, buffer already
748 * synced by s3c_hsotg_ep_queue(). */
755 }
764 /* set these, it seems that DMA support increments past the end
765 * of the packet buffer so we need to calculate the length from
766 * this information. */
771 /* set these anyway, we may need them for non-periodic in */
775 }
777 /* clear the INTknTXFEmpMsk when we start request, more as a aide
778 * to debugging to see what is going on. */
783 /* Note, trying to clear the NAK here causes problems with transmit
784 * on the S3C6400 ending up with the TXFIFO becoming full. */
786 /* check ep is enabled */
794 }
796 /**
797 * s3c_hsotg_map_dma - map the DMA memory being used for the request
798 * @hsotg: The device state.
799 * @hs_ep: The endpoint the request is on.
800 * @req: The request being processed.
801 *
802 * We've been asked to queue a request, so ensure that the memory buffer
803 * is correctly setup for DMA. If we've been passed an extant DMA address
804 * then ensure the buffer has been synced to memory. If our buffer has no
805 * DMA memory, then we map the memory and mark our request to allow us to
806 * cleanup on completion.
807 */
811 {
817 /* if the length is zero, ignore the DMA data */
822 dma_addr_t dma;
831 __func__);
835 }
842 }
846 dma_error:
851 }
854 gfp_t gfp_flags)
855 {
866 /* initialise status of the request */
871 /* if we're using DMA, sync the buffers as necessary */
876 }
889 }
893 {
897 }
899 /**
900 * s3c_hsotg_complete_oursetup - setup completion callback
901 * @ep: The endpoint the request was on.
902 * @req: The request completed.
903 *
904 * Called on completion of any requests the driver itself
905 * submitted that need cleaning up.
906 */
909 {
916 }
918 /**
919 * ep_from_windex - convert control wIndex value to endpoint
920 * @hsotg: The driver state.
921 * @windex: The control request wIndex field (in host order).
922 *
923 * Convert the given wIndex into a pointer to an driver endpoint
924 * structure, or return NULL if it is not a valid endpoint.
925 */
927 u32 windex)
928 {
943 }
945 /**
946 * s3c_hsotg_send_reply - send reply to control request
947 * @hsotg: The device state
948 * @ep: Endpoint 0
949 * @buff: Buffer for request
950 * @length: Length of reply.
951 *
952 * Create a request and queue it on the given endpoint. This is useful as
953 * an internal method of sending replies to certain control requests, etc.
954 */
959 {
970 }
979 else
986 }
989 }
991 /**
992 * s3c_hsotg_process_req_status - process request GET_STATUS
993 * @hsotg: The device state
994 * @ctrl: USB control request
995 */
998 {
1001 __le16 reply;
1009 }
1014 * bit 1 => remote wakeup */
1018 /* currently, the data result should be zero */
1032 }
1041 }
1044 }
1048 /**
1049 * get_ep_head - return the first request on the endpoint
1050 * @hs_ep: The controller endpoint to get
1051 *
1052 * Get the first request on the endpoint.
1053 */
1055 {
1060 }
1062 /**
1063 * s3c_hsotg_process_req_featire - process request {SET,CLEAR}_FEATURE
1064 * @hsotg: The device state
1065 * @ctrl: USB control request
1066 */
1069 {
1086 }
1097 }
1100 /*
1101 * If we have request in progress,
1102 * then complete it
1103 */
1110 }
1112 /* If we have pending request, then start it */
1118 }
1119 }
1125 }
1130 }
1132 /**
1133 * s3c_hsotg_process_control - process a control request
1134 * @hsotg: The device state
1135 * @ctrl: The control request received
1136 *
1137 * The controller has received the SETUP phase of a control request, and
1138 * needs to work out what to do next (and whether to pass it on to the
1139 * gadget driver).
1140 */
1143 {
1146 u32 dcfg;
1154 /* record the direction of the request, for later use when enquing
1155 * packets onto EP0. */
1160 /* if we've no data with this request, then the last part of the
1161 * transaction is going to implicitly be IN. */
1186 }
1187 }
1189 /* as a fallback, try delivering it to the driver to deal with */
1195 }
1197 /* the request is either unhandlable, or is not formatted correctly
1198 * so respond with a STALL for the status stage to indicate failure.
1199 */
1202 u32 reg;
1203 u32 ctrl;
1208 /* S3C_DxEPCTL_Stall will be cleared by EP once it has
1209 * taken effect, so no need to clear later. */
1220 /* don't believe we need to anything more to get the EP
1221 * to reply with a STALL packet */
1222 }
1223 }
1227 /**
1228 * s3c_hsotg_complete_setup - completion of a setup transfer
1229 * @ep: The endpoint the request was on.
1230 * @req: The request completed.
1231 *
1232 * Called on completion of any requests the driver itself submitted for
1233 * EP0 setup packets
1234 */
1237 {
1244 }
1248 else
1250 }
1252 /**
1253 * s3c_hsotg_enqueue_setup - start a request for EP0 packets
1254 * @hsotg: The device state.
1255 *
1256 * Enqueue a request on EP0 if necessary to received any SETUP packets
1257 * received from the host.
1258 */
1260 {
1275 }
1282 /* Don't think there's much we can do other than watch the
1283 * driver fail. */
1284 }
1285 }
1287 /**
1288 * s3c_hsotg_complete_request - complete a request given to us
1289 * @hsotg: The device state.
1290 * @hs_ep: The endpoint the request was on.
1291 * @hs_req: The request to complete.
1292 * @result: The result code (0 => Ok, otherwise errno)
1293 *
1294 * The given request has finished, so call the necessary completion
1295 * if it has one and then look to see if we can start a new request
1296 * on the endpoint.
1297 *
1298 * Note, expects the ep to already be locked as appropriate.
1299 */
1304 {
1310 }
1315 /* only replace the status if we've not already set an error
1316 * from a previous transaction */
1327 /* call the complete request with the locks off, just in case the
1328 * request tries to queue more work for this endpoint. */
1334 }
1336 /* Look to see if there is anything else to do. Note, the completion
1337 * of the previous request may have caused a new request to be started
1338 * so be careful when doing this. */
1345 }
1346 }
1347 }
1349 /**
1350 * s3c_hsotg_complete_request_lock - complete a request given to us (locked)
1351 * @hsotg: The device state.
1352 * @hs_ep: The endpoint the request was on.
1353 * @hs_req: The request to complete.
1354 * @result: The result code (0 => Ok, otherwise errno)
1355 *
1356 * See s3c_hsotg_complete_request(), but called with the endpoint's
1357 * lock held.
1358 */
1363 {
1369 }
1371 /**
1372 * s3c_hsotg_rx_data - receive data from the FIFO for an endpoint
1373 * @hsotg: The device state.
1374 * @ep_idx: The endpoint index for the data
1375 * @size: The size of data in the fifo, in bytes
1376 *
1377 * The FIFO status shows there is data to read from the FIFO for a given
1378 * endpoint, so sort out whether we need to read the data into a request
1379 * that has been made for that endpoint.
1380 */
1382 {
1398 /* dump the data from the FIFO, we've nothing we can do */
1403 }
1415 /* more data appeared than we where willing
1416 * to deal with in this request.
1417 */
1419 /* currently we don't deal this */
1421 }
1427 /* note, we might over-write the buffer end by 3 bytes depending on
1428 * alignment of the data. */
1432 }
1434 /**
1435 * s3c_hsotg_send_zlp - send zero-length packet on control endpoint
1436 * @hsotg: The device instance
1437 * @req: The request currently on this endpoint
1438 *
1439 * Generate a zero-length IN packet request for terminating a SETUP
1440 * transaction.
1441 *
1442 * Note, since we don't write any data to the TxFIFO, then it is
1443 * currently believed that we do not need to wait for any space in
1444 * the TxFIFO.
1445 */
1448 {
1449 u32 ctrl;
1454 }
1460 }
1467 /* issue a zero-sized packet to terminate this */
1476 }
1478 /**
1479 * s3c_hsotg_handle_outdone - handle receiving OutDone/SetupDone from RXFIFO
1480 * @hsotg: The device instance
1481 * @epnum: The endpoint received from
1482 * @was_setup: Set if processing a SetupDone event.
1483 *
1484 * The RXFIFO has delivered an OutDone event, which means that the data
1485 * transfer for an OUT endpoint has been completed, either by a short
1486 * packet or by the finish of a transfer.
1487 */
1490 {
1501 }
1506 /* Calculate the size of the transfer by checking how much
1507 * is left in the endpoint size register and then working it
1508 * out from the amount we loaded for the transfer.
1509 *
1510 * We need to do this as DMA pointers are always 32bit aligned
1511 * so may overshoot/undershoot the transfer.
1512 */
1518 }
1520 /* if there is more request to do, schedule new transfer */
1524 }
1530 /* todo - what should we return here? there's no one else
1531 * even bothering to check the status. */
1532 }
1537 }
1540 }
1542 /**
1543 * s3c_hsotg_read_frameno - read current frame number
1544 * @hsotg: The device instance
1545 *
1546 * Return the current frame number
1547 */
1549 {
1550 u32 dsts;
1557 }
1559 /**
1560 * s3c_hsotg_handle_rx - RX FIFO has data
1561 * @hsotg: The device instance
1562 *
1563 * The IRQ handler has detected that the RX FIFO has some data in it
1564 * that requires processing, so find out what is in there and do the
1565 * appropriate read.
1566 *
1567 * The RXFIFO is a true FIFO, the packets coming out are still in packet
1568 * chunks, so if you have x packets received on an endpoint you'll get x
1569 * FIFO events delivered, each with a packet's worth of data in it.
1570 *
1571 * When using DMA, we should not be processing events from the RXFIFO
1572 * as the actual data should be sent to the memory directly and we turn
1573 * on the completion interrupts to get notifications of transfer completion.
1574 */
1576 {
1592 #define __status(x) ((x) >> S3C_GRXSTS_PktSts_SHIFT)
1635 }
1636 }
1638 /**
1639 * s3c_hsotg_ep0_mps - turn max packet size into register setting
1640 * @mps: The maximum packet size in bytes.
1641 */
1643 {
1653 }
1655 /* bad max packet size, warn and return invalid result */
1658 }
1660 /**
1661 * s3c_hsotg_set_ep_maxpacket - set endpoint's max-packet field
1662 * @hsotg: The driver state.
1663 * @ep: The index number of the endpoint
1664 * @mps: The maximum packet size in bytes
1665 *
1666 * Configure the maximum packet size for the given endpoint, updating
1667 * the hardware control registers to reflect this.
1668 */
1671 {
1674 u32 mpsval;
1675 u32 reg;
1678 /* EP0 is a special case */
1687 }
1691 /* update both the in and out endpoint controldir_ registers, even
1692 * if one of the directions may not be in use. */
1706 bad_mps:
1708 }
1710 /**
1711 * s3c_hsotg_txfifo_flush - flush Tx FIFO
1712 * @hsotg: The driver state
1713 * @idx: The index for the endpoint (0..15)
1714 */
1716 {
1723 /* wait until the fifo is flushed */
1736 }
1739 }
1740 }
1742 /**
1743 * s3c_hsotg_trytx - check to see if anything needs transmitting
1744 * @hsotg: The driver state
1745 * @hs_ep: The driver endpoint to check.
1746 *
1747 * Check to see if there is a request that has data to send, and if so
1748 * make an attempt to write data into the FIFO.
1749 */
1752 {
1762 }
1765 }
1767 /**
1768 * s3c_hsotg_complete_in - complete IN transfer
1769 * @hsotg: The device state.
1770 * @hs_ep: The endpoint that has just completed.
1771 *
1772 * An IN transfer has been completed, update the transfer's state and then
1773 * call the relevant completion routines.
1774 */
1777 {
1785 }
1787 /* Calculate the size of the transfer by checking how much is left
1788 * in the endpoint size register and then working it out from
1789 * the amount we loaded for the transfer.
1790 *
1791 * We do this even for DMA, as the transfer may have incremented
1792 * past the end of the buffer (DMA transfers are always 32bit
1793 * aligned).
1794 */
1807 /* if we did all of the transfer, and there is more data left
1808 * around, then try restarting the rest of the request */
1815 }
1817 /**
1818 * s3c_hsotg_epint - handle an in/out endpoint interrupt
1819 * @hsotg: The driver state
1820 * @idx: The index for the endpoint (0..15)
1821 * @dir_in: Set if this is an IN endpoint
1822 *
1823 * Process and clear any interrupt pending for an individual endpoint
1824 */
1827 {
1832 u32 ints;
1836 /* Clear endpoint interrupts */
1848 /* we get OutDone from the FIFO, so we only need to look
1849 * at completing IN requests here */
1856 /* We're using DMA, we need to fire an OutDone here
1857 * as we ignore the RXFIFO. */
1860 }
1861 }
1877 }
1878 }
1879 }
1888 /* this is the notification we've received a
1889 * setup packet. In non-DMA mode we'd get this
1890 * from the RXFIFO, instead we need to process
1891 * the setup here. */
1895 else
1897 }
1898 }
1904 /* not sure if this is important, but we'll clear it anyway
1905 */
1909 }
1911 /* this probably means something bad is happening */
1915 }
1917 /* FIFO has space or is empty (see GAHBCFG) */
1923 }
1924 }
1925 }
1927 /**
1928 * s3c_hsotg_irq_enumdone - Handle EnumDone interrupt (enumeration done)
1929 * @hsotg: The device state.
1930 *
1931 * Handle updating the device settings after the enumeration phase has
1932 * been completed.
1933 */
1935 {
1939 /* This should signal the finish of the enumeration phase
1940 * of the USB handshaking, so we should now know what rate
1941 * we connected at. */
1945 /* note, since we're limited by the size of transfer on EP0, and
1946 * it seems IN transfers must be a even number of packets we do
1947 * not advertise a 64byte MPS on EP0. */
1949 /* catch both EnumSpd_FS and EnumSpd_FS48 */
1966 /* note, we don't actually support LS in this driver at the
1967 * moment, and the documentation seems to imply that it isn't
1968 * supported by the PHYs on some of the devices.
1969 */
1971 }
1975 /* we should now know the maximum packet size for an
1976 * endpoint, so set the endpoints to a default value. */
1983 }
1985 /* ensure after enumeration our EP0 is active */
1992 }
1994 /**
1995 * kill_all_requests - remove all requests from the endpoint's queue
1996 * @hsotg: The device state.
1997 * @ep: The endpoint the requests may be on.
1998 * @result: The result code to use.
1999 * @force: Force removal of any current requests
2000 *
2001 * Go through the requests on the given endpoint and mark them
2002 * completed with the given result code.
2003 */
2007 {
2014 /* currently, we can't do much about an already
2015 * running request on an in endpoint */
2021 result);
2022 }
2025 }
2027 #define call_gadget(_hs, _entry) \
2028 if ((_hs)->gadget.speed != USB_SPEED_UNKNOWN && \
2029 (_hs)->driver && (_hs)->driver->_entry) \
2030 (_hs)->driver->_entry(&(_hs)->gadget);
2032 /**
2033 * s3c_hsotg_disconnect_irq - disconnect irq service
2034 * @hsotg: The device state.
2035 *
2036 * A disconnect IRQ has been received, meaning that the host has
2037 * lost contact with the bus. Remove all current transactions
2038 * and signal the gadget driver that this has happened.
2039 */
2041 {
2048 }
2050 /**
2051 * s3c_hsotg_irq_fifoempty - TX FIFO empty interrupt handler
2052 * @hsotg: The device state:
2053 * @periodic: True if this is a periodic FIFO interrupt
2054 */
2056 {
2060 /* look through for any more data to transmit */
2075 }
2076 }
2080 /* IRQ flags which will trigger a retry around the IRQ loop */
2081 #define IRQ_RETRY_MASK (S3C_GINTSTS_NPTxFEmp | \
2082 S3C_GINTSTS_PTxFEmp | \
2083 S3C_GINTSTS_RxFLvl)
2085 /**
2086 * s3c_hsotg_irq - handle device interrupt
2087 * @irq: The IRQ number triggered
2088 * @pw: The pw value when registered the handler.
2089 */
2091 {
2094 u32 gintsts;
2095 u32 gintmsk;
2097 irq_retry:
2112 }
2119 }
2124 }
2130 }
2138 }
2151 }
2156 }
2157 }
2168 /* it seems after a reset we can end up with a situation
2169 * where the TXFIFO still has data in it... the docs
2170 * suggest resetting all the fifos, so use the init_fifo
2171 * code to relayout and flush the fifos.
2172 */
2177 }
2179 /* check both FIFOs */
2184 /* Disable the interrupt to stop it happening again
2185 * unless one of these endpoint routines decides that
2186 * it needs re-enabling */
2190 }
2195 /* See note in S3C_GINTSTS_NPTxFEmp */
2199 }
2202 /* note, since GINTSTS_RxFLvl doubles as FIFO-not-empty,
2203 * we need to retry s3c_hsotg_handle_rx if this is still
2204 * set. */
2207 }
2212 }
2219 }
2226 }
2231 }
2233 /* these next two seem to crop-up occasionally causing the core
2234 * to shutdown the USB transfer, so try clearing them and logging
2235 * the occurrence. */
2243 }
2251 }
2253 /* if we've had fifo events, we should try and go around the
2254 * loop again to see if there's any point in returning yet. */
2260 }
2262 /**
2263 * s3c_hsotg_ep_enable - enable the given endpoint
2264 * @ep: The USB endpint to configure
2265 * @desc: The USB endpoint descriptor to configure with.
2266 *
2267 * This is called from the USB gadget code's usb_ep_enable().
2268 */
2271 {
2276 u32 epctrl_reg;
2277 u32 epctrl;
2278 u32 mps;
2287 /* not to be called for EP0 */
2294 }
2298 /* note, we handle this here instead of s3c_hsotg_set_ep_maxpacket */
2311 /* mark the endpoint as active, otherwise the core may ignore
2312 * transactions entirely for this endpoint */
2315 /* set the NAK status on the endpoint, otherwise we might try and
2316 * do something with data that we've yet got a request to process
2317 * since the RXFIFO will take data for an endpoint even if the
2318 * size register hasn't been set.
2319 */
2323 /* update the endpoint state */
2326 /* default, set to non-periodic */
2341 /* Allocate our TxFNum by simply using the index
2342 * of the endpoint for the moment. We could do
2343 * something better if the host indicates how
2344 * many FIFOs we are expecting to use. */
2348 }
2356 }
2358 /* if the hardware has dedicated fifos, we must give each IN EP
2359 * a unique tx-fifo even if it is non-periodic.
2360 */
2364 /* for non control endpoints, set PID to D0 */
2375 /* enable the endpoint interrupt */
2378 out:
2381 }
2384 {
2390 u32 epctrl_reg;
2391 u32 ctrl;
2398 }
2402 /* terminate all requests with shutdown */
2415 /* disable endpoint interrupts */
2420 }
2422 /**
2423 * on_list - check request is on the given endpoint
2424 * @ep: The endpoint to check.
2425 * @test: The request to test if it is on the endpoint.
2426 */
2428 {
2434 }
2437 }
2440 {
2453 }
2459 }
2462 {
2467 u32 epreg;
2468 u32 epctl;
2469 u32 xfertype;
2475 /* write both IN and OUT control registers */
2490 }
2505 }
2512 }
2522 /* note, don't believe we have any call for the fifo routines */
2523 };
2525 /**
2526 * s3c_hsotg_corereset - issue softreset to the core
2527 * @hsotg: The device state
2528 *
2529 * Issue a soft reset to the core, and await the core finishing it.
2530 */
2532 {
2534 u32 grstctl;
2538 /* issue soft reset */
2549 }
2561 }
2567 }
2571 }
2575 {
2582 }
2587 }
2595 }
2609 }
2618 }
2620 /* we must now enable ep0 ready for host detection and then
2621 * set configuration. */
2625 /* set the PLL on, remove the HNP/SRP and set the PHY */
2629 /* looks like soft-reset changes state of FIFOs */
2636 /* Clear any pending OTG interrupts */
2639 /* Clear any pending interrupts */
2647 S3C_GINTSTS_ErlySusp,
2652 S3C_GAHBCFG_HBstLen_Incr4,
2654 else
2657 /* Enabling INTknTXFEmpMsk here seems to be a big mistake, we end
2658 * up being flooded with interrupts if the host is polling the
2659 * endpoint to try and read data. */
2662 S3C_DIEPMSK_INTknEPMisMsk |
2667 /* don't need XferCompl, we get that from RXFIFO in slave mode. In
2668 * DMA mode we may need this. */
2670 S3C_DOEPMSK_EPDisbldMsk |
2681 /* enable in and out endpoint interrupts */
2684 /* Enable the RXFIFO when in slave mode, as this is how we collect
2685 * the data. In DMA mode, we get events from the FIFO but also
2686 * things we cannot process, so do not use it. */
2690 /* Enable interrupts for EP0 in and out */
2700 /* S3C_DxEPCTL_USBActEp says RO in manual, but seems to be set by
2701 writing to the EPCTL register.. */
2703 /* set to read 1 8byte packet */
2709 S3C_DxEPCTL_USBActEp,
2712 /* enable, but don't activate EP0in */
2722 /* clear global NAKs */
2726 /* must be at-least 3ms to allow bus to see disconnect */
2729 /* remove the soft-disconnect and let's go */
2732 /* report to the user, and return */
2737 err:
2741 }
2744 {
2754 /* all endpoints should be shutdown */
2770 }
2773 {
2775 }
2781 };
2783 /**
2784 * s3c_hsotg_initep - initialise a single endpoint
2785 * @hsotg: The device state.
2786 * @hs_ep: The endpoint to be initialised.
2787 * @epnum: The endpoint number
2788 *
2789 * Initialise the given endpoint (as part of the probe and device state
2790 * creation) to give to the gadget driver. Setup the endpoint name, any
2791 * direction information and other state that may be required.
2792 */
2796 {
2797 u32 ptxfifo;
2807 }
2818 /* add to the list of endpoints known by the gadget driver */
2827 /* Read the FIFO size for the Periodic TX FIFO, even if we're
2828 * an OUT endpoint, we may as well do this if in future the
2829 * code is changed to make each endpoint's direction changeable.
2830 */
2835 /* if we're using dma, we need to set the next-endpoint pointer
2836 * to be something valid.
2837 */
2843 }
2844 }
2846 /**
2847 * s3c_hsotg_otgreset - reset the OtG phy block
2848 * @hsotg: The host state.
2849 *
2850 * Power up the phy, set the basic configuration and start the PHY.
2851 */
2853 {
2875 /* default reference clock */
2877 }
2879 }
2883 /* issue a full set of resets to the otg and core */
2888 }
2892 {
2893 u32 cfg4;
2895 /* unmask subset of endpoint interrupts */
2907 /* Be in disconnected state until gadget is registered */
2911 /* post global nak until we're ready */
2914 }
2916 /* setup fifos */
2924 /* set the PLL on, remove the HNP/SRP and set the PHY */
2931 /* check hardware configuration */
2938 }
2941 {
2942 #ifdef DEBUG
2945 u32 val;
2958 /* show periodic fifo settings */
2965 }
2981 }
2985 #endif
2986 }
2989 /**
2990 * state_show - debugfs: show overall driver and device state.
2991 * @seq: The seq file to write to.
2992 * @v: Unused parameter.
2993 *
2994 * This debugfs entry shows the overall state of the hardware and
2995 * some general information about each of the endpoints available
2996 * to the system.
2997 */
2999 {
3042 }
3045 }
3048 {
3050 }
3058 };
3060 /**
3061 * fifo_show - debugfs: show the fifo information
3062 * @seq: The seq_file to write data to.
3063 * @v: Unused parameter.
3064 *
3065 * Show the FIFO information for the overall fifo and all the
3066 * periodic transmission FIFOs.
3067 */
3069 {
3072 u32 val;
3091 }
3094 }
3097 {
3099 }
3107 };
3111 {
3113 }
3115 /**
3116 * ep_show - debugfs: show the state of an endpoint.
3117 * @seq: The seq_file to write data to.
3118 * @v: Unused parameter.
3119 *
3120 * This debugfs entry shows the state of the given endpoint (one is
3121 * registered for each available).
3122 */
3124 {
3136 /* first show the register state */
3167 }
3174 }
3179 }
3182 {
3184 }
3192 };
3194 /**
3195 * s3c_hsotg_create_debug - create debugfs directory and files
3196 * @hsotg: The driver state
3197 *
3198 * Create the debugfs files to allow the user to get information
3199 * about the state of the system. The directory name is created
3200 * with the same name as the device itself, in case we end up
3201 * with multiple blocks in future systems.
3202 */
3204 {
3213 }
3215 /* create general state file */
3229 /* create one file for each endpoint */
3240 }
3241 }
3243 /**
3244 * s3c_hsotg_delete_debug - cleanup debugfs entries
3245 * @hsotg: The driver state
3246 *
3247 * Cleanup (remove) the debugfs files for use on module exit.
3248 */
3250 {
3256 }
3261 }
3263 /**
3264 * s3c_hsotg_gate - set the hardware gate for the block
3265 * @pdev: The device we bound to
3266 * @on: On or off.
3267 *
3268 * Set the hardware gate setting into the block. If we end up on
3269 * something other than an S3C64XX, then we might need to change this
3270 * to using a platform data callback, or some other mechanism.
3271 */
3273 {
3275 u32 others;
3282 else
3287 }
3292 {
3305 GFP_KERNEL);
3309 }
3319 }
3328 }
3336 }
3343 }
3349 }
3357 }
3372 /* setup endpoint information */
3377 /* allocate EP0 request */
3380 GFP_KERNEL);
3384 }
3386 /* reset the system */
3396 /* initialise the endpoints now the core has been initialised */
3411 err_add_udc:
3416 err_regs:
3419 err_regs_res:
3422 err_clk:
3424 err_mem:
3427 }
3430 {
3452 }
3454 #if 1
3455 #define s3c_hsotg_suspend NULL
3456 #define s3c_hsotg_resume NULL
3457 #endif
3463 },
3468 };