| blob | f37cdf6f21796dd4b960ce6fc9489f2a41942819 |
1 // SPDX-License-Identifier: GPL-2.0-or-later
2 /*
3 * Copyright (C) 2014 Emilio López
4 * Emilio López <emilio@elopez.com.ar>
5 */
7 #include <linux/bitmap.h>
8 #include <linux/bitops.h>
9 #include <linux/clk.h>
10 #include <linux/dma-mapping.h>
11 #include <linux/dmaengine.h>
12 #include <linux/dmapool.h>
13 #include <linux/interrupt.h>
14 #include <linux/module.h>
15 #include <linux/of_dma.h>
16 #include <linux/platform_device.h>
17 #include <linux/slab.h>
18 #include <linux/spinlock.h>
22 /** Common macros to normal and dedicated DMA registers **/
24 #define SUN4I_DMA_CFG_LOADING BIT(31)
25 #define SUN4I_DMA_CFG_DST_DATA_WIDTH(width) ((width) << 25)
26 #define SUN4I_DMA_CFG_DST_BURST_LENGTH(len) ((len) << 23)
27 #define SUN4I_DMA_CFG_DST_ADDR_MODE(mode) ((mode) << 21)
28 #define SUN4I_DMA_CFG_DST_DRQ_TYPE(type) ((type) << 16)
29 #define SUN4I_DMA_CFG_SRC_DATA_WIDTH(width) ((width) << 9)
30 #define SUN4I_DMA_CFG_SRC_BURST_LENGTH(len) ((len) << 7)
31 #define SUN4I_DMA_CFG_SRC_ADDR_MODE(mode) ((mode) << 5)
32 #define SUN4I_DMA_CFG_SRC_DRQ_TYPE(type) (type)
34 /** Normal DMA register values **/
36 /* Normal DMA source/destination data request type values */
37 #define SUN4I_NDMA_DRQ_TYPE_SDRAM 0x16
38 #define SUN4I_NDMA_DRQ_TYPE_LIMIT (0x1F + 1)
40 /** Normal DMA register layout **/
42 /* Dedicated DMA source/destination address mode values */
43 #define SUN4I_NDMA_ADDR_MODE_LINEAR 0
44 #define SUN4I_NDMA_ADDR_MODE_IO 1
46 /* Normal DMA configuration register layout */
47 #define SUN4I_NDMA_CFG_CONT_MODE BIT(30)
48 #define SUN4I_NDMA_CFG_WAIT_STATE(n) ((n) << 27)
49 #define SUN4I_NDMA_CFG_DST_NON_SECURE BIT(22)
50 #define SUN4I_NDMA_CFG_BYTE_COUNT_MODE_REMAIN BIT(15)
51 #define SUN4I_NDMA_CFG_SRC_NON_SECURE BIT(6)
53 /** Dedicated DMA register values **/
55 /* Dedicated DMA source/destination address mode values */
56 #define SUN4I_DDMA_ADDR_MODE_LINEAR 0
57 #define SUN4I_DDMA_ADDR_MODE_IO 1
58 #define SUN4I_DDMA_ADDR_MODE_HORIZONTAL_PAGE 2
59 #define SUN4I_DDMA_ADDR_MODE_VERTICAL_PAGE 3
61 /* Dedicated DMA source/destination data request type values */
62 #define SUN4I_DDMA_DRQ_TYPE_SDRAM 0x1
63 #define SUN4I_DDMA_DRQ_TYPE_LIMIT (0x1F + 1)
65 /** Dedicated DMA register layout **/
67 /* Dedicated DMA configuration register layout */
68 #define SUN4I_DDMA_CFG_BUSY BIT(30)
69 #define SUN4I_DDMA_CFG_CONT_MODE BIT(29)
70 #define SUN4I_DDMA_CFG_DST_NON_SECURE BIT(28)
71 #define SUN4I_DDMA_CFG_BYTE_COUNT_MODE_REMAIN BIT(15)
72 #define SUN4I_DDMA_CFG_SRC_NON_SECURE BIT(12)
74 /* Dedicated DMA parameter register layout */
75 #define SUN4I_DDMA_PARA_DST_DATA_BLK_SIZE(n) (((n) - 1) << 24)
76 #define SUN4I_DDMA_PARA_DST_WAIT_CYCLES(n) (((n) - 1) << 16)
77 #define SUN4I_DDMA_PARA_SRC_DATA_BLK_SIZE(n) (((n) - 1) << 8)
78 #define SUN4I_DDMA_PARA_SRC_WAIT_CYCLES(n) (((n) - 1) << 0)
80 /** DMA register offsets **/
82 /* General register offsets */
83 #define SUN4I_DMA_IRQ_ENABLE_REG 0x0
84 #define SUN4I_DMA_IRQ_PENDING_STATUS_REG 0x4
86 /* Normal DMA register offsets */
87 #define SUN4I_NDMA_CHANNEL_REG_BASE(n) (0x100 + (n) * 0x20)
88 #define SUN4I_NDMA_CFG_REG 0x0
89 #define SUN4I_NDMA_SRC_ADDR_REG 0x4
90 #define SUN4I_NDMA_DST_ADDR_REG 0x8
91 #define SUN4I_NDMA_BYTE_COUNT_REG 0xC
93 /* Dedicated DMA register offsets */
94 #define SUN4I_DDMA_CHANNEL_REG_BASE(n) (0x300 + (n) * 0x20)
95 #define SUN4I_DDMA_CFG_REG 0x0
96 #define SUN4I_DDMA_SRC_ADDR_REG 0x4
97 #define SUN4I_DDMA_DST_ADDR_REG 0x8
98 #define SUN4I_DDMA_BYTE_COUNT_REG 0xC
99 #define SUN4I_DDMA_PARA_REG 0x18
101 /** DMA Driver **/
103 /*
104 * Normal DMA has 8 channels, and Dedicated DMA has another 8, so
105 * that's 16 channels. As for endpoints, there's 29 and 21
106 * respectively. Given that the Normal DMA endpoints (other than
107 * SDRAM) can be used as tx/rx, we need 78 vchans in total
108 */
109 #define SUN4I_NDMA_NR_MAX_CHANNELS 8
110 #define SUN4I_DDMA_NR_MAX_CHANNELS 8
111 #define SUN4I_DMA_NR_MAX_CHANNELS \
112 (SUN4I_NDMA_NR_MAX_CHANNELS + SUN4I_DDMA_NR_MAX_CHANNELS)
113 #define SUN4I_NDMA_NR_MAX_VCHANS (29 * 2 - 1)
114 #define SUN4I_DDMA_NR_MAX_VCHANS 21
115 #define SUN4I_DMA_NR_MAX_VCHANS \
116 (SUN4I_NDMA_NR_MAX_VCHANS + SUN4I_DDMA_NR_MAX_VCHANS)
118 /* This set of SUN4I_DDMA timing parameters were found experimentally while
119 * working with the SPI driver and seem to make it behave correctly */
120 #define SUN4I_DDMA_MAGIC_SPI_PARAMETERS \
121 (SUN4I_DDMA_PARA_DST_DATA_BLK_SIZE(1) | \
122 SUN4I_DDMA_PARA_SRC_DATA_BLK_SIZE(1) | \
123 SUN4I_DDMA_PARA_DST_WAIT_CYCLES(2) | \
124 SUN4I_DDMA_PARA_SRC_WAIT_CYCLES(2))
126 /*
127 * Normal DMA supports individual transfers (segments) up to 128k.
128 * Dedicated DMA supports transfers up to 16M. We can only report
129 * one size limit, so we have to use the smaller value.
130 */
131 #define SUN4I_NDMA_MAX_SEG_SIZE SZ_128K
132 #define SUN4I_DDMA_MAX_SEG_SIZE SZ_16M
133 #define SUN4I_DMA_MAX_SEG_SIZE SUN4I_NDMA_MAX_SEG_SIZE
136 /* Register base of channel */
138 /* vchan currently being serviced */
140 /* Is this a dedicated pchan? */
142 };
150 u8 endpoint;
152 };
155 u32 cfg;
156 u32 para;
157 dma_addr_t src;
158 dma_addr_t dst;
161 };
163 /* A contract is a set of promises */
170 };
180 spinlock_t lock;
181 };
184 {
186 }
189 {
191 }
194 {
196 }
199 {
201 }
204 {
208 /* 1 -> 0, 4 -> 1, 8 -> 2 */
210 }
213 {
217 /* 8 (1 byte) -> 0, 16 (2 bytes) -> 1, 32 (4 bytes) -> 2 */
219 }
222 {
226 }
230 {
235 /*
236 * pchans 0-SUN4I_NDMA_NR_MAX_CHANNELS are normal, and
237 * SUN4I_NDMA_NR_MAX_CHANNELS+ are dedicated ones
238 */
245 }
253 }
257 }
261 {
271 }
275 {
276 /*
277 * Configure addresses and misc parameters depending on type
278 * SUN4I_DDMA has an extra field with timing parameters
279 */
291 }
292 }
297 {
298 u32 reg;
308 else
313 else
319 }
321 /*
322 * Execute pending operations on a vchan
323 *
324 * When given a vchan, this function will try to acquire a suitable
325 * pchan and, if successful, will configure it to fulfill a promise
326 * from the next pending contract.
327 *
328 * This function must be called with &vchan->vc.lock held.
329 */
332 {
341 /* We need a pchan to do anything, so secure one if available */
346 /*
347 * Channel endpoints must not be repeated, so if this vchan
348 * has already submitted some work, we can't do anything else
349 */
355 }
358 /* Figure out which contract we're working with today */
365 }
369 /* The contract has been completed so mark it as such */
374 }
377 /* Now find out what we need to do */
382 /* ... and make it reality */
388 }
392 release_pchan:
395 }
399 {
428 }
431 }
433 /*
434 * Generate a promise, to be used in a normal DMA contract.
435 *
436 * A NDMA promise contains all the information required to program the
437 * normal part of the DMA Engine and get data copied. A non-executed
438 * promise will live in the demands list on a contract. Once it has been
439 * completed, it will be moved to the completed demands list for later freeing.
440 * All linked promises will be freed when the corresponding contract is freed
441 */
446 {
462 SUN4I_NDMA_CFG_BYTE_COUNT_MODE_REMAIN;
469 /* Source burst */
475 /* Destination burst */
481 /* Source bus width */
487 /* Destination bus width */
495 fail:
498 }
500 /*
501 * Generate a promise, to be used in a dedicated DMA contract.
502 *
503 * A DDMA promise contains all the information required to program the
504 * Dedicated part of the DMA Engine and get data copied. A non-executed
505 * promise will live in the demands list on a contract. Once it has been
506 * completed, it will be moved to the completed demands list for later freeing.
507 * All linked promises will be freed when the corresponding contract is freed
508 */
512 {
524 SUN4I_DDMA_CFG_BYTE_COUNT_MODE_REMAIN;
526 /* Source burst */
532 /* Destination burst */
538 /* Source bus width */
544 /* Destination bus width */
552 fail:
555 }
557 /*
558 * Generate a contract
559 *
560 * Contracts function as DMA descriptors. As our hardware does not support
561 * linked lists, we need to implement SG via software. We use a contract
562 * to hold all the pieces of the request and process them serially one
563 * after another. Each piece is represented as a promise.
564 */
566 {
577 }
579 /*
580 * Get next promise on a cyclic transfer
581 *
582 * Cyclic contracts contain a series of promises which are executed on a
583 * loop. This function returns the next promise from a cyclic contract,
584 * so it can be programmed into the hardware.
585 */
588 {
598 }
601 }
603 /*
604 * Free a contract and all its associated promises
605 */
607 {
611 /* Free all the demands and completed demands */
619 }
624 {
634 /*
635 * We can only do the copy to bus aligned addresses, so
636 * choose the best one so we get decent performance. We also
637 * maximize the burst size for this same reason.
638 */
646 else
648 DMA_MEM_TO_MEM);
653 }
655 /* Configure memcpy mode */
662 }
664 /* Fill the contract with our only promise */
667 /* And add it to the vchan */
669 }
675 {
681 u32 endpoints;
688 }
704 }
720 }
722 /*
723 * We will be using half done interrupts to make two periods
724 * out of a promise, so we need to program the DMA engine less
725 * often
726 */
728 /*
729 * The engine can interrupt on half-transfer, so we can use
730 * this feature to program the engine half as often as if we
731 * didn't use it (keep in mind the hardware doesn't support
732 * linked lists).
733 *
734 * Say you have a set of periods (| marks the start/end, I for
735 * interrupt, P for programming the engine to do a new
736 * transfer), the easy but slow way would be to do
737 *
738 * |---|---|---|---| (periods / promises)
739 * P I,P I,P I,P I
740 *
741 * Using half transfer interrupts you can do
742 *
743 * |-------|-------| (promises as configured on hw)
744 * |---|---|---|---| (periods)
745 * P I I,P I I
746 *
747 * Which requires half the engine programming for the same
748 * functionality.
749 *
750 * This only works if two periods fit in a single promise. That will
751 * always be the case for dedicated DMA, where the hardware has a much
752 * larger maximum transfer size than advertised to clients.
753 */
757 }
761 /* Calculate the offset in the buffer and the length needed */
766 else
769 /* Make the promise */
773 else
778 /* TODO: should we free everything? */
780 }
783 /* Then add it to the contract */
785 }
787 /* And add it to the vchan */
789 }
795 {
812 }
826 }
833 else
840 /* Figure out addresses */
847 }
849 /*
850 * These are the magic DMA engine timings that keep SPI going.
851 * I haven't seen any interface on DMAEngine to configure
852 * timings, and so far they seem to work for everything we
853 * support, so I've kept them here. I don't know if other
854 * devices need different timings because, as usual, we only
855 * have the "para" bitfield meanings, but no comment on what
856 * the values should be when doing a certain operation :|
857 */
860 /* And make a suitable promise */
864 sconfig);
865 else
876 /* Then add it to the contract */
878 }
880 /*
881 * Once we've got all the promises ready, add the contract
882 * to the pending list on the vchan
883 */
885 }
888 {
899 /*
900 * Clearing the configuration register will halt the pchan. Interrupts
901 * may still trigger, so don't forget to disable them.
902 */
906 else
910 }
913 /* Clear these so the vchan is usable again */
921 }
925 {
931 }
935 {
942 /* Check if type is Normal or Dedicated */
946 /* Make sure the endpoint looks sane */
955 /* Assign the endpoint to the vchan */
961 }
964 dma_cookie_t cookie,
966 {
989 /*
990 * The hardware is configured to return the remaining byte
991 * quantity. If possible, replace the first listed element's
992 * full size with the actual remaining amount
993 */
1000 else
1002 }
1004 exit:
1010 }
1013 {
1020 /*
1021 * If there are pending transactions for this vchan, push one of
1022 * them into the engine to get the ball rolling.
1023 */
1028 }
1031 {
1042 handle_pending:
1054 /*
1055 * Disable the IRQ and free the pchan if it's an end
1056 * interrupt (odd bit)
1057 */
1061 /*
1062 * Move the promise into the completed list now that
1063 * we're done with it
1064 */
1068 /*
1069 * Cyclic DMA transfers are special:
1070 * - There's always something we can dispatch
1071 * - We need to run the callback
1072 * - Latency is very important, as this is used by audio
1073 * We therefore just cycle through the list and dispatch
1074 * whatever we have here, reusing the pchan. There's
1075 * no need to run the thread after this.
1076 *
1077 * For non-cyclic transfers we need to look around,
1078 * so we can program some more work, or notify the
1079 * client that their transfers have been completed.
1080 */
1093 }
1097 /* Half done interrupt */
1100 else
1102 }
1103 }
1105 /* Disable the IRQs for events we handled */
1112 /* Writing 1 to the pending field will clear the pending interrupt */
1115 /*
1116 * If a pchan was freed, we may be able to schedule something else,
1117 * so have a look around
1118 */
1125 }
1126 }
1128 /*
1129 * Handle newer interrupts if some showed up, but only do it once
1130 * to avoid a too long a loop
1131 */
1134 SUN4I_DMA_IRQ_PENDING_STATUS_REG);
1138 }
1139 }
1142 }
1145 {
1165 }
1207 /*
1208 * [0..SUN4I_NDMA_NR_MAX_CHANNELS) are normal pchans, and
1209 * [SUN4I_NDMA_NR_MAX_CHANNELS..SUN4I_DMA_NR_MAX_CHANNELS) are
1210 * dedicated ones
1211 */
1220 }
1228 }
1234 }
1236 /*
1237 * Make sure the IRQs are all disabled and accounted for. The bootloader
1238 * likes to leave these dirty
1239 */
1248 }
1254 }
1257 priv);
1261 }
1267 err_dma_unregister:
1269 err_clk_disable:
1272 }
1275 {
1278 /* Disable IRQ so no more work is scheduled */
1285 }
1290 };
1299 },
1300 };