| blob | 5a72083dc67c76c4b7f9f9f2fbb4c5604cab5eca |
1 /* linux/drivers/video/s3c-fb.c
2 *
3 * Copyright 2008 Openmoko Inc.
4 * Copyright 2008 Simtec Electronics
5 * Ben Dooks <ben@simtec.co.uk>
6 * http://armlinux.simtec.co.uk/
7 *
8 * Samsung SoC Framebuffer driver
9 *
10 * This program is free software; you can redistribute it and/or modify
11 * it under the terms of the GNU General Public License version 2 as
12 * published by the Free Software Foundation.
13 */
15 #include <linux/kernel.h>
16 #include <linux/module.h>
17 #include <linux/platform_device.h>
18 #include <linux/dma-mapping.h>
19 #include <linux/init.h>
20 #include <linux/gfp.h>
21 #include <linux/clk.h>
22 #include <linux/fb.h>
23 #include <linux/io.h>
25 #include <mach/map.h>
26 #include <mach/regs-fb.h>
27 #include <plat/fb.h>
29 /* This driver will export a number of framebuffer interfaces depending
30 * on the configuration passed in via the platform data. Each fb instance
31 * maps to a hardware window. Currently there is no support for runtime
32 * setting of the alpha-blending functions that each window has, so only
33 * window 0 is actually useful.
34 *
35 * Window 0 is treated specially, it is used for the basis of the LCD
36 * output timings and as the control for the output power-down state.
37 */
39 /* note, some of the functions that get called are derived from including
40 * <mach/regs-fb.h> as they are specific to the architecture that the code
41 * is being built for.
42 */
44 #ifdef CONFIG_FB_S3C_DEBUG_REGWRITE
45 #undef writel
46 #define writel(v, r) do { \
48 __raw_writel(v, r); } while(0)
53 /**
54 * struct s3c_fb_win - per window private data for each framebuffer.
55 * @windata: The platform data supplied for the window configuration.
56 * @parent: The hardware that this window is part of.
57 * @fbinfo: Pointer pack to the framebuffer info for this window.
58 * @palette_buffer: Buffer/cache to hold palette entries.
59 * @pseudo_palette: For use in TRUECOLOUR modes for entries 0..15/
60 * @index: The window number of this window.
61 * @palette: The bitfields for changing r/g/b into a hardware palette entry.
62 */
72 };
74 /**
75 * struct s3c_fb - overall hardware state of the hardware
76 * @dev: The device that we bound to, for printing, etc.
77 * @regs_res: The resource we claimed for the IO registers.
78 * @bus_clk: The clk (hclk) feeding our interface and possibly pixclk.
79 * @regs: The mapped hardware registers.
80 * @enabled: A bitmask of enabled hardware windows.
81 * @pdata: The platform configuration data passed with the device.
82 * @windows: The hardware windows that have been claimed.
83 */
94 };
96 /**
97 * s3c_fb_win_has_palette() - determine if a mode has a palette
98 * @win: The window number being queried.
99 * @bpp: The number of bits per pixel to test.
100 *
101 * Work out if the given window supports palletised data at the specified bpp.
102 */
104 {
106 }
108 /**
109 * s3c_fb_check_var() - framebuffer layer request to verify a given mode.
110 * @var: The screen information to verify.
111 * @info: The framebuffer device.
112 *
113 * Framebuffer layer call to verify the given information and allow us to
114 * update various information depending on the hardware capabilities.
115 */
118 {
132 }
134 /* always ensure these are zero, for drop through cases below */
144 /* non palletised, A:1,R:2,G:3,B:2 mode */
158 }
162 /* 666 with one bit alpha/transparency */
168 /* 666 format */
178 /* 16 bpp, 565 format */
191 /* drop through */
193 /* our 24bpp is unpacked, so 32bpp */
206 }
210 }
212 /**
213 * s3c_fb_calc_pixclk() - calculate the divider to create the pixel clock.
214 * @id: window id.
215 * @sfb: The hardware state.
216 * @pixclock: The pixel clock wanted, in picoseconds.
217 *
218 * Given the specified pixel clock, work out the necessary divider to get
219 * close to the output frequency.
220 */
222 {
234 }
236 /**
237 * s3c_fb_align_word() - align pixel count to word boundary
238 * @bpp: The number of bits per pixel
239 * @pix: The value to be aligned.
240 *
241 * Align the given pixel count so that it will start on an 32bit word
242 * boundary.
243 */
245 {
253 }
255 /**
256 * s3c_fb_set_par() - framebuffer request to set new framebuffer state.
257 * @info: The framebuffer to change.
258 *
259 * Framebuffer layer request to set a new mode for the specified framebuffer
260 */
262 {
269 u32 data;
270 u32 pagewidth;
285 else
294 }
298 /* disable the window whilst we update it */
301 /* use window 0 as the basis for the lcd output timings */
311 else
314 /* write the timing data to the panel */
334 }
336 /* write the buffer address */
348 /* write 'OSD' registers to control position of framebuffer */
373 /* note, since we have to round up the bits-per-pixel, we end up
374 * relying on the bitfield information for r/g/b/a to work out
375 * exactly which mode of operation is intended. */
396 else
404 else
414 else
417 data |= WINCON1_BPPMODE_25BPP_A1888
420 data |= WINCON1_BPPMODE_28BPP_A4888
422 else
427 }
429 /* It has no color key control register for window0 */
434 WxKEYCON0_KEYEN_F |
441 }
447 }
449 /**
450 * s3c_fb_update_palette() - set or schedule a palette update.
451 * @sfb: The hardware information.
452 * @win: The window being updated.
453 * @reg: The palette index being changed.
454 * @value: The computed palette value.
455 *
456 * Change the value of a palette register, either by directly writing to
457 * the palette (this requires the palette RAM to be disconnected from the
458 * hardware whilst this is in progress) or schedule the update for later.
459 *
460 * At the moment, since we have no VSYNC interrupt support, we simply set
461 * the palette entry directly.
462 */
466 u32 value)
467 {
469 u32 palcon;
483 else
487 }
491 {
495 }
497 /**
498 * s3c_fb_setcolreg() - framebuffer layer request to change palette.
499 * @regno: The palette index to change.
500 * @red: The red field for the palette data.
501 * @green: The green field for the palette data.
502 * @blue: The blue field for the palette data.
503 * @trans: The transparency (alpha) field for the palette data.
504 * @info: The framebuffer being changed.
505 */
509 {
519 /* true-colour, use pseudo-palette */
529 }
539 }
545 }
548 }
550 /**
551 * s3c_fb_enable() - Set the state of the main LCD output
552 * @sfb: The main framebuffer state.
553 * @enable: The state to set.
554 */
556 {
562 /* see the note in the framebuffer datasheet about
563 * why you cannot take both of these bits down at the
564 * same time. */
571 }
574 }
576 /**
577 * s3c_fb_blank() - blank or unblank the given window
578 * @blank_mode: The blank state from FB_BLANK_*
579 * @info: The framebuffer to blank.
580 *
581 * Framebuffer layer request to change the power state.
582 */
584 {
588 u32 wincon;
598 /* fall through to FB_BLANK_NORMAL */
601 /* disable the DMA and display 0x0 (black) */
616 }
620 /* Check the enabled state to see if we need to be running the
621 * main LCD interface, as if there are no active windows then
622 * it is highly likely that we also do not need to output
623 * anything.
624 */
626 /* We could do something like the following code, but the current
627 * system of using framebuffer events means that we cannot make
628 * the distinction between just window 0 being inactive and all
629 * the windows being down.
630 *
631 * s3c_fb_enable(sfb, sfb->enabled ? 1 : 0);
632 */
634 /* we're stuck with this until we can do something about overriding
635 * the power control using the blanking event for a single fb.
636 */
641 }
652 };
654 /**
655 * s3c_fb_alloc_memory() - allocate display memory for framebuffer window
656 * @sfb: The base resources for the hardware.
657 * @win: The window to initialise memory for.
658 *
659 * Allocate memory for the given framebuffer.
660 */
663 {
667 dma_addr_t map_dma;
699 }
701 /**
702 * s3c_fb_free_memory() - free the display memory for the given window
703 * @sfb: The base resources for the hardware.
704 * @win: The window to free the display memory for.
705 *
706 * Free the display memory allocated by s3c_fb_alloc_memory().
707 */
709 {
714 }
716 /**
717 * s3c_fb_release_win() - release resources for a framebuffer window.
718 * @win: The window to cleanup the resources for.
719 *
720 * Release the resources that where claimed for the hardware window,
721 * such as the framebuffer instance and any memory claimed for it.
722 */
724 {
730 }
731 }
733 /**
734 * s3c_fb_probe_win() - register an hardware window
735 * @sfb: The base resources for the hardware
736 * @res: Pointer to where to place the resultant window.
737 *
738 * Allocate and do the basic initialisation for one of the hardware's graphics
739 * windows.
740 */
743 {
761 }
782 }
784 /* setup the r/b/g positions for the window's palette */
787 /* setup the initial video mode from the window */
799 /* prepare to actually start the framebuffer */
805 }
807 /* create initial colour map */
812 else
819 /* run the check_var and set_par on our configuration. */
825 }
831 }
833 /**
834 * s3c_fb_clear_win() - clear hardware window registers.
835 * @sfb: The base resources for the hardware.
836 * @win: The window to process.
837 *
838 * Reset the specific window registers to a known state.
839 */
841 {
851 }
854 {
866 }
872 }
881 }
890 }
898 }
905 }
909 /* setup gpio and output polarity controls */
915 /* zero all windows before we do anything */
920 /* we have the register setup, start allocating framebuffers */
932 }
933 }
939 err_ioremap:
942 err_req_region:
946 err_clk:
950 err_sfb:
953 }
955 /**
956 * s3c_fb_remove() - Cleanup on module finalisation
957 * @pdev: The platform device we are bound to.
958 *
959 * Shutdown and then release all the resources that the driver allocated
960 * on initialisation.
961 */
963 {
982 }
984 #ifdef CONFIG_PM
986 {
996 /* use the blank function to push into power-down */
998 }
1002 }
1005 {
1013 /* setup registers */
1016 /* zero all windows before we do anything */
1020 /* restore framebuffers */
1028 }
1031 }
1032 #else
1033 #define s3c_fb_suspend NULL
1034 #define s3c_fb_resume NULL
1035 #endif
1045 },
1046 };
1049 {
1051 }
1054 {
1056 }