| blob | 1cf645479bfec6b1cc7a2d2dc76d4e0e295fb8bc |
1 /*
2 * Driver for Cirrus Logic EP93xx SPI controller.
3 *
4 * Copyright (C) 2010-2011 Mika Westerberg
5 *
6 * Explicit FIFO handling code was inspired by amba-pl022 driver.
7 *
8 * Chip select support using other than built-in GPIOs by H. Hartley Sweeten.
9 *
10 * For more information about the SPI controller see documentation on Cirrus
11 * Logic web site:
12 * http://www.cirrus.com/en/pubs/manual/EP93xx_Users_Guide_UM1.pdf
13 *
14 * This program is free software; you can redistribute it and/or modify
15 * it under the terms of the GNU General Public License version 2 as
16 * published by the Free Software Foundation.
17 */
19 #include <linux/io.h>
20 #include <linux/clk.h>
21 #include <linux/err.h>
22 #include <linux/delay.h>
23 #include <linux/device.h>
24 #include <linux/dmaengine.h>
25 #include <linux/bitops.h>
26 #include <linux/interrupt.h>
27 #include <linux/platform_device.h>
28 #include <linux/workqueue.h>
29 #include <linux/sched.h>
30 #include <linux/scatterlist.h>
31 #include <linux/spi/spi.h>
33 #include <mach/dma.h>
34 #include <mach/ep93xx_spi.h>
36 #define SSPCR0 0x0000
37 #define SSPCR0_MODE_SHIFT 6
38 #define SSPCR0_SCR_SHIFT 8
40 #define SSPCR1 0x0004
41 #define SSPCR1_RIE BIT(0)
42 #define SSPCR1_TIE BIT(1)
43 #define SSPCR1_RORIE BIT(2)
44 #define SSPCR1_LBM BIT(3)
45 #define SSPCR1_SSE BIT(4)
46 #define SSPCR1_MS BIT(5)
47 #define SSPCR1_SOD BIT(6)
49 #define SSPDR 0x0008
51 #define SSPSR 0x000c
52 #define SSPSR_TFE BIT(0)
53 #define SSPSR_TNF BIT(1)
54 #define SSPSR_RNE BIT(2)
55 #define SSPSR_RFF BIT(3)
56 #define SSPSR_BSY BIT(4)
57 #define SSPCPSR 0x0010
59 #define SSPIIR 0x0014
60 #define SSPIIR_RIS BIT(0)
61 #define SSPIIR_TIS BIT(1)
62 #define SSPIIR_RORIS BIT(2)
63 #define SSPICR SSPIIR
65 /* timeout in milliseconds */
66 #define SPI_TIMEOUT 5
67 /* maximum depth of RX/TX FIFO */
68 #define SPI_FIFO_SIZE 8
70 /**
71 * struct ep93xx_spi - EP93xx SPI controller structure
72 * @lock: spinlock that protects concurrent accesses to fields @running,
73 * @current_msg and @msg_queue
74 * @pdev: pointer to platform device
75 * @clk: clock for the controller
76 * @regs_base: pointer to ioremap()'d registers
77 * @sspdr_phys: physical address of the SSPDR register
78 * @irq: IRQ number used by the driver
79 * @min_rate: minimum clock rate (in Hz) supported by the controller
80 * @max_rate: maximum clock rate (in Hz) supported by the controller
81 * @running: is the queue running
82 * @wq: workqueue used by the driver
83 * @msg_work: work that is queued for the driver
84 * @wait: wait here until given transfer is completed
85 * @msg_queue: queue for the messages
86 * @current_msg: message that is currently processed (or %NULL if none)
87 * @tx: current byte in transfer to transmit
88 * @rx: current byte in transfer to receive
89 * @fifo_level: how full is FIFO (%0..%SPI_FIFO_SIZE - %1). Receiving one
90 * frame decreases this level and sending one frame increases it.
91 * @dma_rx: RX DMA channel
92 * @dma_tx: TX DMA channel
93 * @dma_rx_data: RX parameters passed to the DMA engine
94 * @dma_tx_data: TX parameters passed to the DMA engine
95 * @rx_sgt: sg table for RX transfers
96 * @tx_sgt: sg table for TX transfers
97 * @zeropage: dummy page used as RX buffer when only TX buffer is passed in by
98 * the client
99 *
100 * This structure holds EP93xx SPI controller specific information. When
101 * @running is %true, driver accepts transfer requests from protocol drivers.
102 * @current_msg is used to hold pointer to the message that is currently
103 * processed. If @current_msg is %NULL, it means that no processing is going
104 * on.
105 *
106 * Most of the fields are only written once and they can be accessed without
107 * taking the @lock. Fields that are accessed concurrently are: @current_msg,
108 * @running, and @msg_queue.
109 */
111 spinlock_t lock;
135 };
137 /**
138 * struct ep93xx_spi_chip - SPI device hardware settings
139 * @spi: back pointer to the SPI device
140 * @rate: max rate in hz this chip supports
141 * @div_cpsr: cpsr (pre-scaler) divider
142 * @div_scr: scr divider
143 * @dss: bits per word (4 - 16 bits)
144 * @ops: private chip operations
145 *
146 * This structure is used to store hardware register specific settings for each
147 * SPI device. Settings are written to hardware by function
148 * ep93xx_spi_chip_setup().
149 */
153 u8 div_cpsr;
154 u8 div_scr;
155 u8 dss;
157 };
159 /* converts bits per word to CR0.DSS value */
160 #define bits_per_word_to_dss(bpw) ((bpw) - 1)
164 {
166 }
170 {
172 }
176 {
178 }
182 {
184 }
187 {
188 u8 regval;
200 }
203 {
204 u8 regval;
211 }
214 {
215 u8 regval;
220 }
223 {
224 u8 regval;
229 }
231 /**
232 * ep93xx_spi_calc_divisors() - calculates SPI clock divisors
233 * @espi: ep93xx SPI controller struct
234 * @chip: divisors are calculated for this chip
235 * @rate: desired SPI output clock rate
236 *
237 * Function calculates cpsr (clock pre-scaler) and scr divisors based on
238 * given @rate and places them to @chip->div_cpsr and @chip->div_scr. If,
239 * for some reason, divisors cannot be calculated nothing is stored and
240 * %-EINVAL is returned.
241 */
245 {
249 /*
250 * Make sure that max value is between values supported by the
251 * controller. Note that minimum value is already checked in
252 * ep93xx_spi_transfer().
253 */
256 /*
257 * Calculate divisors so that we can get speed according the
258 * following formula:
259 * rate = spi_clock_rate / (cpsr * (1 + scr))
260 *
261 * cpsr must be even number and starts from 2, scr can be any number
262 * between 0 and 255.
263 */
270 }
271 }
272 }
275 }
278 {
284 }
286 /**
287 * ep93xx_spi_setup() - setup an SPI device
288 * @spi: SPI device to setup
289 *
290 * This function sets up SPI device mode, speed etc. Can be called multiple
291 * times for a single device. Returns %0 in case of success, negative error in
292 * case of failure. When this function returns success, the device is
293 * deselected.
294 */
296 {
304 }
323 }
324 }
327 }
337 }
339 }
345 }
347 /**
348 * ep93xx_spi_transfer() - queue message to be transferred
349 * @spi: target SPI device
350 * @msg: message to be transferred
351 *
352 * This function is called by SPI device drivers when they are going to transfer
353 * a new message. It simply puts the message in the queue and schedules
354 * workqueue to perform the actual transfer later on.
355 *
356 * Returns %0 on success and negative error in case of failure.
357 */
359 {
367 /* first validate each transfer */
372 }
375 }
377 /*
378 * Now that we own the message, let's initialize it so that it is
379 * suitable for us. We use @msg->status to signal whether there was
380 * error in transfer and @msg->state is used to hold pointer to the
381 * current transfer (or %NULL if no active current transfer).
382 */
391 }
397 }
399 /**
400 * ep93xx_spi_cleanup() - cleans up master controller specific state
401 * @spi: SPI device to cleanup
402 *
403 * This function releases master controller specific state for given @spi
404 * device.
405 */
407 {
416 }
417 }
419 /**
420 * ep93xx_spi_chip_setup() - configures hardware according to given @chip
421 * @espi: ep93xx SPI controller struct
422 * @chip: chip specific settings
423 *
424 * This function sets up the actual hardware registers with settings given in
425 * @chip. Note that no validation is done so make sure that callers validate
426 * settings before calling this.
427 */
430 {
431 u16 cr0;
443 }
446 {
451 }
454 {
469 }
470 }
473 {
475 u16 rx_val;
482 u8 rx_val;
488 }
489 }
491 /**
492 * ep93xx_spi_read_write() - perform next RX/TX transfer
493 * @espi: ep93xx SPI controller struct
494 *
495 * This function transfers next bytes (or half-words) to/from RX/TX FIFOs. If
496 * called several times, the whole transfer will be completed. Returns
497 * %-EINPROGRESS when current transfer was not yet completed otherwise %0.
498 *
499 * When this function is finished, RX FIFO should be empty and TX FIFO should be
500 * full.
501 */
503 {
507 /* read as long as RX FIFO has frames in it */
511 }
513 /* write as long as TX FIFO has room */
517 }
523 }
526 {
527 /*
528 * Now everything is set up for the current transfer. We prime the TX
529 * FIFO, enable interrupts, and wait for the transfer to complete.
530 */
534 }
535 }
537 /**
538 * ep93xx_spi_dma_prepare() - prepares a DMA transfer
539 * @espi: ep93xx SPI controller struct
540 * @dir: DMA transfer direction
541 *
542 * Function configures the DMA, maps the buffer and prepares the DMA
543 * descriptor. Returns a valid DMA descriptor in case of success and ERR_PTR
544 * in case of failure.
545 */
548 {
562 else
582 }
588 /*
589 * We need to split the transfer into PAGE_SIZE'd chunks. This is
590 * because we are using @espi->zeropage to provide a zero RX buffer
591 * for the TX transfers and we have only allocated one page for that.
592 *
593 * For performance reasons we allocate a new sg_table only when
594 * needed. Otherwise we will re-use the current one. Eventually the
595 * last sg_table is released in ep93xx_spi_release_dma().
596 */
605 }
617 }
621 }
626 }
637 }
639 }
641 /**
642 * ep93xx_spi_dma_finish() - finishes with a DMA transfer
643 * @espi: ep93xx SPI controller struct
644 * @dir: DMA transfer direction
645 *
646 * Function finishes with the DMA transfer. After this, the DMA buffer is
647 * unmapped.
648 */
651 {
661 }
664 }
667 {
669 }
672 {
681 }
689 }
691 /* We are ready when RX is done */
695 /* Now submit both descriptors and wait while they finish */
706 }
708 /**
709 * ep93xx_spi_process_transfer() - processes one SPI transfer
710 * @espi: ep93xx SPI controller struct
711 * @msg: current message
712 * @t: transfer to process
713 *
714 * This function processes one SPI transfer given in @t. Function waits until
715 * transfer is complete (may sleep) and updates @msg->status based on whether
716 * transfer was successfully processed or not.
717 */
721 {
726 /*
727 * Handle any transfer specific settings if needed. We use
728 * temporary chip settings here and restore original later when
729 * the transfer is finished.
730 */
744 }
745 }
750 /*
751 * Set up temporary new hw settings for this transfer.
752 */
754 }
759 /*
760 * There is no point of setting up DMA for the transfers which will
761 * fit into the FIFO and can be transferred with a single interrupt.
762 * So in these cases we will be using PIO and don't bother for DMA.
763 */
766 else
769 /*
770 * In case of error during transmit, we bail out from processing
771 * the message.
772 */
778 /*
779 * After this transfer is finished, perform any possible
780 * post-transfer actions requested by the protocol driver.
781 */
785 }
788 /*
789 * In case protocol driver is asking us to drop the
790 * chipselect briefly, we let the scheduler to handle
791 * any "delay" here.
792 */
796 }
797 }
801 }
803 /*
804 * ep93xx_spi_process_message() - process one SPI message
805 * @espi: ep93xx SPI controller struct
806 * @msg: message to process
807 *
808 * This function processes a single SPI message. We go through all transfers in
809 * the message and pass them to ep93xx_spi_process_transfer(). Chipselect is
810 * asserted during the whole message (unless per transfer cs_change is set).
811 *
812 * @msg->status contains %0 in case of success or negative error code in case of
813 * failure.
814 */
817 {
822 /*
823 * Enable the SPI controller and its clock.
824 */
830 }
832 /*
833 * Just to be sure: flush any data from RX FIFO.
834 */
842 }
844 }
846 /*
847 * We explicitly handle FIFO level. This way we don't have to check TX
848 * FIFO status using %SSPSR_TNF bit which may cause RX FIFO overruns.
849 */
852 /*
853 * Update SPI controller registers according to spi device and assert
854 * the chipselect.
855 */
863 }
865 /*
866 * Now the whole message is transferred (or failed for some reason). We
867 * deselect the device and disable the SPI controller.
868 */
871 }
873 #define work_to_espi(work) (container_of((work), struct ep93xx_spi, msg_work))
875 /**
876 * ep93xx_spi_work() - EP93xx SPI workqueue worker function
877 * @work: work struct
878 *
879 * Workqueue worker function. This function is called when there are new
880 * SPI messages to be processed. Message is taken out from the queue and then
881 * passed to ep93xx_spi_process_message().
882 *
883 * After message is transferred, protocol driver is notified by calling
884 * @msg->complete(). In case of error, @msg->status is set to negative error
885 * number, otherwise it contains zero (and @msg->actual_length is updated).
886 */
888 {
897 }
905 /*
906 * Update the current message and re-schedule ourselves if there are
907 * more messages in the queue.
908 */
915 /* notify the protocol driver that we are done with this message */
917 }
920 {
924 /*
925 * If we got ROR (receive overrun) interrupt we know that something is
926 * wrong. Just abort the message.
927 */
929 /* clear the overrun interrupt */
935 /*
936 * Interrupt is either RX (RIS) or TX (TIS). For both cases we
937 * simply execute next data transfer.
938 */
940 /*
941 * In normal case, there still is some processing left
942 * for current transfer. Let's wait for the next
943 * interrupt then.
944 */
946 }
947 }
949 /*
950 * Current transfer is finished, either with error or with success. In
951 * any case we disable interrupts and notify the worker to handle
952 * any post-processing of the message.
953 */
957 }
960 {
966 }
969 {
970 dma_cap_mask_t mask;
989 }
1000 }
1004 fail_release_rx:
1007 fail_free_page:
1011 }
1014 {
1018 }
1022 }
1026 }
1029 {
1042 }
1060 }
1065 /*
1066 * Calculate maximum and minimum supported clock rates
1067 * for the controller.
1068 */
1078 }
1085 }
1092 }
1100 }
1107 }
1116 }
1121 /* make sure that the hardware is disabled */
1128 }
1135 fail_free_queue:
1137 fail_free_dma:
1140 fail_unmap_regs:
1142 fail_free_mem:
1144 fail_put_clock:
1146 fail_release_master:
1151 }
1154 {
1165 /*
1166 * Complete remaining messages with %-ESHUTDOWN status.
1167 */
1179 }
1192 }
1198 },
1200 };
1203 {
1205 }
1209 {
1211 }