smscufx.c source code [linux/drivers/video/fbdev/smscufx.c]

1	// SPDX-License-Identifier: GPL-2.0-only
2	/*
3	* smscufx.c -- Framebuffer driver for SMSC UFX USB controller
4	*
5	* Copyright (C) 2011 Steve Glendinning <steve.glendinning@shawell.net>
6	* Copyright (C) 2009 Roberto De Ioris <roberto@unbit.it>
7	* Copyright (C) 2009 Jaya Kumar <jayakumar.lkml@gmail.com>
8	* Copyright (C) 2009 Bernie Thompson <bernie@plugable.com>
9	*
10	* Based on udlfb, with work from Florian Echtler, Henrik Bjerregaard Pedersen,
11	* and others.
12	*
13	* Works well with Bernie Thompson's X DAMAGE patch to xf86-video-fbdev
14	* available from http://git.plugable.com
15	*
16	* Layout is based on skeletonfb by James Simmons and Geert Uytterhoeven,
17	* usb-skeleton by GregKH.
18	*/
19
20	#define pr_fmt(fmt) KBUILD_MODNAME ": " fmt
21
22	#include <linux/module.h>
23	#include <linux/kernel.h>
24	#include <linux/init.h>
25	#include <linux/usb.h>
26	#include <linux/uaccess.h>
27	#include <linux/mm.h>
28	#include <linux/fb.h>
29	#include <linux/vmalloc.h>
30	#include <linux/slab.h>
31	#include <linux/delay.h>
32	#include "edid.h"
33
34	#define check_warn(status, fmt, args...) \
35	({ if (status < 0) pr_warn(fmt, ##args); })
36
37	#define check_warn_return(status, fmt, args...) \
38	({ if (status < 0) { pr_warn(fmt, ##args); return status; } })
39
40	#define check_warn_goto_error(status, fmt, args...) \
41	({ if (status < 0) { pr_warn(fmt, ##args); goto error; } })
42
43	#define all_bits_set(x, bits) (((x) & (bits)) == (bits))
44
45	#define USB_VENDOR_REQUEST_WRITE_REGISTER 0xA0
46	#define USB_VENDOR_REQUEST_READ_REGISTER 0xA1
47
48	/*
49	* TODO: Propose standard fb.h ioctl for reporting damage,
50	* using _IOWR() and one of the existing area structs from fb.h
51	* Consider these ioctls deprecated, but they're still used by the
52	* DisplayLink X server as yet - need both to be modified in tandem
53	* when new ioctl(s) are ready.
54	*/
55	#define UFX_IOCTL_RETURN_EDID (0xAD)
56	#define UFX_IOCTL_REPORT_DAMAGE (0xAA)
57
58	/ -BULK_SIZE as per usb-skeleton. Can we get full page and avoid overhead? /
59	#define BULK_SIZE (512)
60	#define MAX_TRANSFER (PAGE_SIZE*16 - BULK_SIZE)
61	#define WRITES_IN_FLIGHT (4)
62
63	#define GET_URB_TIMEOUT (HZ)
64	#define FREE_URB_TIMEOUT (HZ*2)
65
66	#define BPP 2
67
68	#define UFX_DEFIO_WRITE_DELAY 5 /* fb_deferred_io.delay in jiffies */
69	#define UFX_DEFIO_WRITE_DISABLE (HZ60) / "disable" with long delay */
70
71	struct dloarea {
72	int x, y;
73	int w, h;
74	};
75
76	struct urb_node {
77	struct list_head entry;
78	struct ufx_data *dev;
79	struct delayed_work release_urb_work;
80	struct urb *urb;
81	};
82
83	struct urb_list {
84	struct list_head list;
85	spinlock_t lock;
86	struct semaphore limit_sem;
87	int available;
88	int count;
89	size_t size;
90	};
91
92	struct ufx_data {
93	struct usb_device *udev;
94	struct device gdev; /* &udev->dev /
95	struct fb_info *info;
96	struct urb_list urbs;
97	struct kref kref;
98	int fb_count;
99	bool virtualized; / true when physical usb device not present /
100	atomic_t usb_active; / 0 = update virtual buffer, but no usb traffic /
101	atomic_t lost_pixels; / 1 = a render op failed. Need screen refresh /
102	u8 edid; /* null until we read edid from hw or get from sysfs /
103	size_t edid_size;
104	u32 pseudo_palette[`256`];
105	};
106
107	static struct fb_fix_screeninfo ufx_fix = {
108	.id = "smscufx",
109	.type = FB_TYPE_PACKED_PIXELS,
110	.visual = FB_VISUAL_TRUECOLOR,
111	.xpanstep = `0`,
112	.ypanstep = `0`,
113	.ywrapstep = `0`,
114	.accel = FB_ACCEL_NONE,
115	};
116
117	static const u32 smscufx_info_flags = FBINFO_READS_FAST \|
118	FBINFO_VIRTFB \| FBINFO_HWACCEL_IMAGEBLIT \| FBINFO_HWACCEL_FILLRECT \|
119	FBINFO_HWACCEL_COPYAREA \| FBINFO_MISC_ALWAYS_SETPAR;
120
121	static const struct usb_device_id id_table[] = {
122	{USB_DEVICE(`0x0424`, `0x9d00`),},
123	{USB_DEVICE(`0x0424`, `0x9d01`),},
124	{},
125	};
126	MODULE_DEVICE_TABLE(usb, id_table);
127
128	/ module options /
129	static bool console; / Optionally allow fbcon to consume first framebuffer /
130	static bool fb_defio = true; / Optionally enable fb_defio mmap support /
131
132	/ ufx keeps a list of urbs for efficient bulk transfers /
133	static void ufx_urb_completion(struct urb *urb);
134	static struct urb ufx_get_urb(struct* ufx_data *dev);
135	static int ufx_submit_urb(struct ufx_data dev, struct* urb * urb, size_t len);
136	static int ufx_alloc_urb_list(struct ufx_data dev, int* count, size_t size);
137	static void ufx_free_urb_list(struct ufx_data *dev);
138
139	static DEFINE_MUTEX(disconnect_mutex);
140
141	/ reads a control register /
142	static int ufx_reg_read(struct ufx_data dev, u32 index, u32 data)
143	{
144	u32 *buf = kmalloc(size: `4`, GFP_KERNEL);
145	int ret;
146
147	BUG_ON(!dev);
148
149	if (!buf)
150	return -ENOMEM;
151
152	ret = usb_control_msg(dev: dev->udev, usb_rcvctrlpipe(dev->udev, `0`),
153	USB_VENDOR_REQUEST_READ_REGISTER,
154	USB_DIR_IN \| USB_TYPE_VENDOR \| USB_RECIP_DEVICE,
155	value: `00`, index, data: buf, size: `4`, USB_CTRL_GET_TIMEOUT);
156
157	le32_to_cpus(buf);
158	data = buf;
159	kfree(objp: buf);
160
161	if (unlikely(ret < `0`))
162	pr_warn("Failed to read register index 0x%08x\n", index);
163
164	return ret;
165	}
166
167	/ writes a control register /
168	static int ufx_reg_write(struct ufx_data *dev, u32 index, u32 data)
169	{
170	u32 *buf = kmalloc(size: `4`, GFP_KERNEL);
171	int ret;
172
173	BUG_ON(!dev);
174
175	if (!buf)
176	return -ENOMEM;
177
178	*buf = data;
179	cpu_to_le32s(buf);
180
181	ret = usb_control_msg(dev: dev->udev, usb_sndctrlpipe(dev->udev, `0`),
182	USB_VENDOR_REQUEST_WRITE_REGISTER,
183	USB_DIR_OUT \| USB_TYPE_VENDOR \| USB_RECIP_DEVICE,
184	value: `00`, index, data: buf, size: `4`, USB_CTRL_SET_TIMEOUT);
185
186	kfree(objp: buf);
187
188	if (unlikely(ret < `0`))
189	pr_warn("Failed to write register index 0x%08x with value "
190	"0x%08x\n", index, data);
191
192	return ret;
193	}
194
195	static int ufx_reg_clear_and_set_bits(struct ufx_data *dev, u32 index,
196	u32 bits_to_clear, u32 bits_to_set)
197	{
198	u32 data;
199	int status = ufx_reg_read(dev, index, data: &data);
200	check_warn_return(status, "ufx_reg_clear_and_set_bits error reading "
201	"0x%x", index);
202
203	data &= (~bits_to_clear);
204	data \|= bits_to_set;
205
206	status = ufx_reg_write(dev, index, data);
207	check_warn_return(status, "ufx_reg_clear_and_set_bits error writing "
208	"0x%x", index);
209
210	return `0`;
211	}
212
213	static int ufx_reg_set_bits(struct ufx_data *dev, u32 index, u32 bits)
214	{
215	return ufx_reg_clear_and_set_bits(dev, index, bits_to_clear: `0`, bits_to_set: bits);
216	}
217
218	static int ufx_reg_clear_bits(struct ufx_data *dev, u32 index, u32 bits)
219	{
220	return ufx_reg_clear_and_set_bits(dev, index, bits_to_clear: bits, bits_to_set: `0`);
221	}
222
223	static int ufx_lite_reset(struct ufx_data *dev)
224	{
225	int status;
226	u32 value;
227
228	status = ufx_reg_write(dev, index: `0x3008`, data: `0x00000001`);
229	check_warn_return(status, "ufx_lite_reset error writing 0x3008");
230
231	status = ufx_reg_read(dev, index: `0x3008`, data: &value);
232	check_warn_return(status, "ufx_lite_reset error reading 0x3008");
233
234	return (value == `0`) ? `0` : -EIO;
235	}
236
237	/ If display is unblanked, then blank it /
238	static int ufx_blank(struct ufx_data *dev, bool wait)
239	{
240	u32 dc_ctrl, dc_sts;
241	int i;
242
243	int status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
244	check_warn_return(status, "ufx_blank error reading 0x2004");
245
246	status = ufx_reg_read(dev, index: `0x2000`, data: &dc_ctrl);
247	check_warn_return(status, "ufx_blank error reading 0x2000");
248
249	/ return success if display is already blanked /
250	if ((dc_sts & `0x00000100`) \|\| (dc_ctrl & `0x00000100`))
251	return `0`;
252
253	/ request the DC to blank the display /
254	dc_ctrl \|= `0x00000100`;
255	status = ufx_reg_write(dev, index: `0x2000`, data: dc_ctrl);
256	check_warn_return(status, "ufx_blank error writing 0x2000");
257
258	/ return success immediately if we don't have to wait /
259	if (!wait)
260	return `0`;
261
262	for (i = `0`; i < `250`; i++) {
263	status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
264	check_warn_return(status, "ufx_blank error reading 0x2004");
265
266	if (dc_sts & `0x00000100`)
267	return `0`;
268	}
269
270	/ timed out waiting for display to blank /
271	return -EIO;
272	}
273
274	/ If display is blanked, then unblank it /
275	static int ufx_unblank(struct ufx_data *dev, bool wait)
276	{
277	u32 dc_ctrl, dc_sts;
278	int i;
279
280	int status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
281	check_warn_return(status, "ufx_unblank error reading 0x2004");
282
283	status = ufx_reg_read(dev, index: `0x2000`, data: &dc_ctrl);
284	check_warn_return(status, "ufx_unblank error reading 0x2000");
285
286	/ return success if display is already unblanked /
287	if (((dc_sts & `0x00000100`) == `0`) \|\| ((dc_ctrl & `0x00000100`) == `0`))
288	return `0`;
289
290	/ request the DC to unblank the display /
291	dc_ctrl &= ~`0x00000100`;
292	status = ufx_reg_write(dev, index: `0x2000`, data: dc_ctrl);
293	check_warn_return(status, "ufx_unblank error writing 0x2000");
294
295	/ return success immediately if we don't have to wait /
296	if (!wait)
297	return `0`;
298
299	for (i = `0`; i < `250`; i++) {
300	status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
301	check_warn_return(status, "ufx_unblank error reading 0x2004");
302
303	if ((dc_sts & `0x00000100`) == `0`)
304	return `0`;
305	}
306
307	/ timed out waiting for display to unblank /
308	return -EIO;
309	}
310
311	/ If display is enabled, then disable it /
312	static int ufx_disable(struct ufx_data *dev, bool wait)
313	{
314	u32 dc_ctrl, dc_sts;
315	int i;
316
317	int status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
318	check_warn_return(status, "ufx_disable error reading 0x2004");
319
320	status = ufx_reg_read(dev, index: `0x2000`, data: &dc_ctrl);
321	check_warn_return(status, "ufx_disable error reading 0x2000");
322
323	/ return success if display is already disabled /
324	if (((dc_sts & `0x00000001`) == `0`) \|\| ((dc_ctrl & `0x00000001`) == `0`))
325	return `0`;
326
327	/ request the DC to disable the display /
328	dc_ctrl &= ~(`0x00000001`);
329	status = ufx_reg_write(dev, index: `0x2000`, data: dc_ctrl);
330	check_warn_return(status, "ufx_disable error writing 0x2000");
331
332	/ return success immediately if we don't have to wait /
333	if (!wait)
334	return `0`;
335
336	for (i = `0`; i < `250`; i++) {
337	status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
338	check_warn_return(status, "ufx_disable error reading 0x2004");
339
340	if ((dc_sts & `0x00000001`) == `0`)
341	return `0`;
342	}
343
344	/ timed out waiting for display to disable /
345	return -EIO;
346	}
347
348	/ If display is disabled, then enable it /
349	static int ufx_enable(struct ufx_data *dev, bool wait)
350	{
351	u32 dc_ctrl, dc_sts;
352	int i;
353
354	int status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
355	check_warn_return(status, "ufx_enable error reading 0x2004");
356
357	status = ufx_reg_read(dev, index: `0x2000`, data: &dc_ctrl);
358	check_warn_return(status, "ufx_enable error reading 0x2000");
359
360	/ return success if display is already enabled /
361	if ((dc_sts & `0x00000001`) \|\| (dc_ctrl & `0x00000001`))
362	return `0`;
363
364	/ request the DC to enable the display /
365	dc_ctrl \|= `0x00000001`;
366	status = ufx_reg_write(dev, index: `0x2000`, data: dc_ctrl);
367	check_warn_return(status, "ufx_enable error writing 0x2000");
368
369	/ return success immediately if we don't have to wait /
370	if (!wait)
371	return `0`;
372
373	for (i = `0`; i < `250`; i++) {
374	status = ufx_reg_read(dev, index: `0x2004`, data: &dc_sts);
375	check_warn_return(status, "ufx_enable error reading 0x2004");
376
377	if (dc_sts & `0x00000001`)
378	return `0`;
379	}
380
381	/ timed out waiting for display to enable /
382	return -EIO;
383	}
384
385	static int ufx_config_sys_clk(struct ufx_data *dev)
386	{
387	int status = ufx_reg_write(dev, index: `0x700C`, data: `0x8000000F`);
388	check_warn_return(status, "error writing 0x700C");
389
390	status = ufx_reg_write(dev, index: `0x7014`, data: `0x0010024F`);
391	check_warn_return(status, "error writing 0x7014");
392
393	status = ufx_reg_write(dev, index: `0x7010`, data: `0x00000000`);
394	check_warn_return(status, "error writing 0x7010");
395
396	status = ufx_reg_clear_bits(dev, index: `0x700C`, bits: `0x0000000A`);
397	check_warn_return(status, "error clearing PLL1 bypass in 0x700C");
398	msleep(msecs: `1`);
399
400	status = ufx_reg_clear_bits(dev, index: `0x700C`, bits: `0x80000000`);
401	check_warn_return(status, "error clearing output gate in 0x700C");
402
403	return `0`;
404	}
405
406	static int ufx_config_ddr2(struct ufx_data *dev)
407	{
408	int status, i = `0`;
409	u32 tmp;
410
411	status = ufx_reg_write(dev, index: `0x0004`, data: `0x001F0F77`);
412	check_warn_return(status, "error writing 0x0004");
413
414	status = ufx_reg_write(dev, index: `0x0008`, data: `0xFFF00000`);
415	check_warn_return(status, "error writing 0x0008");
416
417	status = ufx_reg_write(dev, index: `0x000C`, data: `0x0FFF2222`);
418	check_warn_return(status, "error writing 0x000C");
419
420	status = ufx_reg_write(dev, index: `0x0010`, data: `0x00030814`);
421	check_warn_return(status, "error writing 0x0010");
422
423	status = ufx_reg_write(dev, index: `0x0014`, data: `0x00500019`);
424	check_warn_return(status, "error writing 0x0014");
425
426	status = ufx_reg_write(dev, index: `0x0018`, data: `0x020D0F15`);
427	check_warn_return(status, "error writing 0x0018");
428
429	status = ufx_reg_write(dev, index: `0x001C`, data: `0x02532305`);
430	check_warn_return(status, "error writing 0x001C");
431
432	status = ufx_reg_write(dev, index: `0x0020`, data: `0x0B030905`);
433	check_warn_return(status, "error writing 0x0020");
434
435	status = ufx_reg_write(dev, index: `0x0024`, data: `0x00000827`);
436	check_warn_return(status, "error writing 0x0024");
437
438	status = ufx_reg_write(dev, index: `0x0028`, data: `0x00000000`);
439	check_warn_return(status, "error writing 0x0028");
440
441	status = ufx_reg_write(dev, index: `0x002C`, data: `0x00000042`);
442	check_warn_return(status, "error writing 0x002C");
443
444	status = ufx_reg_write(dev, index: `0x0030`, data: `0x09520000`);
445	check_warn_return(status, "error writing 0x0030");
446
447	status = ufx_reg_write(dev, index: `0x0034`, data: `0x02223314`);
448	check_warn_return(status, "error writing 0x0034");
449
450	status = ufx_reg_write(dev, index: `0x0038`, data: `0x00430043`);
451	check_warn_return(status, "error writing 0x0038");
452
453	status = ufx_reg_write(dev, index: `0x003C`, data: `0xF00F000F`);
454	check_warn_return(status, "error writing 0x003C");
455
456	status = ufx_reg_write(dev, index: `0x0040`, data: `0xF380F00F`);
457	check_warn_return(status, "error writing 0x0040");
458
459	status = ufx_reg_write(dev, index: `0x0044`, data: `0xF00F0496`);
460	check_warn_return(status, "error writing 0x0044");
461
462	status = ufx_reg_write(dev, index: `0x0048`, data: `0x03080406`);
463	check_warn_return(status, "error writing 0x0048");
464
465	status = ufx_reg_write(dev, index: `0x004C`, data: `0x00001000`);
466	check_warn_return(status, "error writing 0x004C");
467
468	status = ufx_reg_write(dev, index: `0x005C`, data: `0x00000007`);
469	check_warn_return(status, "error writing 0x005C");
470
471	status = ufx_reg_write(dev, index: `0x0100`, data: `0x54F00012`);
472	check_warn_return(status, "error writing 0x0100");
473
474	status = ufx_reg_write(dev, index: `0x0104`, data: `0x00004012`);
475	check_warn_return(status, "error writing 0x0104");
476
477	status = ufx_reg_write(dev, index: `0x0118`, data: `0x40404040`);
478	check_warn_return(status, "error writing 0x0118");
479
480	status = ufx_reg_write(dev, index: `0x0000`, data: `0x00000001`);
481	check_warn_return(status, "error writing 0x0000");
482
483	while (i++ < `500`) {
484	status = ufx_reg_read(dev, index: `0x0000`, data: &tmp);
485	check_warn_return(status, "error reading 0x0000");
486
487	if (all_bits_set(tmp, `0xC0000000`))
488	return `0`;
489	}
490
491	pr_err("DDR2 initialisation timed out, reg 0x0000=0x%08x", tmp);
492	return -ETIMEDOUT;
493	}
494
495	struct pll_values {
496	u32 div_r0;
497	u32 div_f0;
498	u32 div_q0;
499	u32 range0;
500	u32 div_r1;
501	u32 div_f1;
502	u32 div_q1;
503	u32 range1;
504	};
505
506	static u32 ufx_calc_range(u32 ref_freq)
507	{
508	if (ref_freq >= `88000000`)
509	return `7`;
510
511	if (ref_freq >= `54000000`)
512	return `6`;
513
514	if (ref_freq >= `34000000`)
515	return `5`;
516
517	if (ref_freq >= `21000000`)
518	return `4`;
519
520	if (ref_freq >= `13000000`)
521	return `3`;
522
523	if (ref_freq >= `8000000`)
524	return `2`;
525
526	return `1`;
527	}
528
529	/ calculates PLL divider settings for a desired target frequency /
530	static void ufx_calc_pll_values(const u32 clk_pixel_pll, struct pll_values *asic_pll)
531	{
532	const u32 ref_clk = `25000000`;
533	u32 div_r0, div_f0, div_q0, div_r1, div_f1, div_q1;
534	u32 min_error = clk_pixel_pll;
535
536	for (div_r0 = `1`; div_r0 <= `32`; div_r0++) {
537	u32 ref_freq0 = ref_clk / div_r0;
538	if (ref_freq0 < `5000000`)
539	break;
540
541	if (ref_freq0 > `200000000`)
542	continue;
543
544	for (div_f0 = `1`; div_f0 <= `256`; div_f0++) {
545	u32 vco_freq0 = ref_freq0 * div_f0;
546
547	if (vco_freq0 < `350000000`)
548	continue;
549
550	if (vco_freq0 > `700000000`)
551	break;
552
553	for (div_q0 = `0`; div_q0 < `7`; div_q0++) {
554	u32 pllout_freq0 = vco_freq0 / (`1` << div_q0);
555
556	if (pllout_freq0 < `5000000`)
557	break;
558
559	if (pllout_freq0 > `200000000`)
560	continue;
561
562	for (div_r1 = `1`; div_r1 <= `32`; div_r1++) {
563	u32 ref_freq1 = pllout_freq0 / div_r1;
564
565	if (ref_freq1 < `5000000`)
566	break;
567
568	for (div_f1 = `1`; div_f1 <= `256`; div_f1++) {
569	u32 vco_freq1 = ref_freq1 * div_f1;
570
571	if (vco_freq1 < `350000000`)
572	continue;
573
574	if (vco_freq1 > `700000000`)
575	break;
576
577	for (div_q1 = `0`; div_q1 < `7`; div_q1++) {
578	u32 pllout_freq1 = vco_freq1 / (`1` << div_q1);
579	int error = abs(pllout_freq1 - clk_pixel_pll);
580
581	if (pllout_freq1 < `5000000`)
582	break;
583
584	if (pllout_freq1 > `700000000`)
585	continue;
586
587	if (error < min_error) {
588	min_error = error;
589
590	/ final returned value is equal to calculated value - 1*
591	* because a value of 0 = divide by 1 */
592	asic_pll->div_r0 = div_r0 - `1`;
593	asic_pll->div_f0 = div_f0 - `1`;
594	asic_pll->div_q0 = div_q0;
595	asic_pll->div_r1 = div_r1 - `1`;
596	asic_pll->div_f1 = div_f1 - `1`;
597	asic_pll->div_q1 = div_q1;
598
599	asic_pll->range0 = ufx_calc_range(ref_freq: ref_freq0);
600	asic_pll->range1 = ufx_calc_range(ref_freq: ref_freq1);
601
602	if (min_error == `0`)
603	return;
604	}
605	}
606	}
607	}
608	}
609	}
610	}
611	}
612
613	/ sets analog bit PLL configuration values /
614	static int ufx_config_pix_clk(struct ufx_data *dev, u32 pixclock)
615	{
616	struct pll_values asic_pll = {`0`};
617	u32 value, clk_pixel, clk_pixel_pll;
618	int status;
619
620	/ convert pixclock (in ps) to frequency (in Hz) /
621	clk_pixel = PICOS2KHZ(pixclock) * `1000`;
622	pr_debug("pixclock %d ps = clk_pixel %d Hz", pixclock, clk_pixel);
623
624	/ clk_pixel = 1/2 clk_pixel_pll /
625	clk_pixel_pll = clk_pixel * `2`;
626
627	ufx_calc_pll_values(clk_pixel_pll, asic_pll: &asic_pll);
628
629	/ Keep BYPASS and RESET signals asserted until configured /
630	status = ufx_reg_write(dev, index: `0x7000`, data: `0x8000000F`);
631	check_warn_return(status, "error writing 0x7000");
632
633	value = (asic_pll.div_f1 \| (asic_pll.div_r1 << `8`) \|
634	(asic_pll.div_q1 << `16`) \| (asic_pll.range1 << `20`));
635	status = ufx_reg_write(dev, index: `0x7008`, data: value);
636	check_warn_return(status, "error writing 0x7008");
637
638	value = (asic_pll.div_f0 \| (asic_pll.div_r0 << `8`) \|
639	(asic_pll.div_q0 << `16`) \| (asic_pll.range0 << `20`));
640	status = ufx_reg_write(dev, index: `0x7004`, data: value);
641	check_warn_return(status, "error writing 0x7004");
642
643	status = ufx_reg_clear_bits(dev, index: `0x7000`, bits: `0x00000005`);
644	check_warn_return(status,
645	"error clearing PLL0 bypass bits in 0x7000");
646	msleep(msecs: `1`);
647
648	status = ufx_reg_clear_bits(dev, index: `0x7000`, bits: `0x0000000A`);
649	check_warn_return(status,
650	"error clearing PLL1 bypass bits in 0x7000");
651	msleep(msecs: `1`);
652
653	status = ufx_reg_clear_bits(dev, index: `0x7000`, bits: `0x80000000`);
654	check_warn_return(status, "error clearing gate bits in 0x7000");
655
656	return `0`;
657	}
658
659	static int ufx_set_vid_mode(struct ufx_data dev, struct* fb_var_screeninfo *var)
660	{
661	u32 temp;
662	u16 h_total, h_active, h_blank_start, h_blank_end, h_sync_start, h_sync_end;
663	u16 v_total, v_active, v_blank_start, v_blank_end, v_sync_start, v_sync_end;
664
665	int status = ufx_reg_write(dev, index: `0x8028`, data: `0`);
666	check_warn_return(status, "ufx_set_vid_mode error disabling RGB pad");
667
668	status = ufx_reg_write(dev, index: `0x8024`, data: `0`);
669	check_warn_return(status, "ufx_set_vid_mode error disabling VDAC");
670
671	/ shut everything down before changing timing /
672	status = ufx_blank(dev, wait: true);
673	check_warn_return(status, "ufx_set_vid_mode error blanking display");
674
675	status = ufx_disable(dev, wait: true);
676	check_warn_return(status, "ufx_set_vid_mode error disabling display");
677
678	status = ufx_config_pix_clk(dev, pixclock: var->pixclock);
679	check_warn_return(status, "ufx_set_vid_mode error configuring pixclock");
680
681	status = ufx_reg_write(dev, index: `0x2000`, data: `0x00000104`);
682	check_warn_return(status, "ufx_set_vid_mode error writing 0x2000");
683
684	/ set horizontal timings /
685	h_total = var->xres + var->right_margin + var->hsync_len + var->left_margin;
686	h_active = var->xres;
687	h_blank_start = var->xres + var->right_margin;
688	h_blank_end = var->xres + var->right_margin + var->hsync_len;
689	h_sync_start = var->xres + var->right_margin;
690	h_sync_end = var->xres + var->right_margin + var->hsync_len;
691
692	temp = ((h_total - `1`) << `16`) \| (h_active - `1`);
693	status = ufx_reg_write(dev, index: `0x2008`, data: temp);
694	check_warn_return(status, "ufx_set_vid_mode error writing 0x2008");
695
696	temp = ((h_blank_start - `1`) << `16`) \| (h_blank_end - `1`);
697	status = ufx_reg_write(dev, index: `0x200C`, data: temp);
698	check_warn_return(status, "ufx_set_vid_mode error writing 0x200C");
699
700	temp = ((h_sync_start - `1`) << `16`) \| (h_sync_end - `1`);
701	status = ufx_reg_write(dev, index: `0x2010`, data: temp);
702	check_warn_return(status, "ufx_set_vid_mode error writing 0x2010");
703
704	/ set vertical timings /
705	v_total = var->upper_margin + var->yres + var->lower_margin + var->vsync_len;
706	v_active = var->yres;
707	v_blank_start = var->yres + var->lower_margin;
708	v_blank_end = var->yres + var->lower_margin + var->vsync_len;
709	v_sync_start = var->yres + var->lower_margin;
710	v_sync_end = var->yres + var->lower_margin + var->vsync_len;
711
712	temp = ((v_total - `1`) << `16`) \| (v_active - `1`);
713	status = ufx_reg_write(dev, index: `0x2014`, data: temp);
714	check_warn_return(status, "ufx_set_vid_mode error writing 0x2014");
715
716	temp = ((v_blank_start - `1`) << `16`) \| (v_blank_end - `1`);
717	status = ufx_reg_write(dev, index: `0x2018`, data: temp);
718	check_warn_return(status, "ufx_set_vid_mode error writing 0x2018");
719
720	temp = ((v_sync_start - `1`) << `16`) \| (v_sync_end - `1`);
721	status = ufx_reg_write(dev, index: `0x201C`, data: temp);
722	check_warn_return(status, "ufx_set_vid_mode error writing 0x201C");
723
724	status = ufx_reg_write(dev, index: `0x2020`, data: `0x00000000`);
725	check_warn_return(status, "ufx_set_vid_mode error writing 0x2020");
726
727	status = ufx_reg_write(dev, index: `0x2024`, data: `0x00000000`);
728	check_warn_return(status, "ufx_set_vid_mode error writing 0x2024");
729
730	/ Set the frame length register (#pix * 2 bytes/pixel) /
731	temp = var->xres * var->yres * `2`;
732	temp = (temp + `7`) & (~`0x7`);
733	status = ufx_reg_write(dev, index: `0x2028`, data: temp);
734	check_warn_return(status, "ufx_set_vid_mode error writing 0x2028");
735
736	/ enable desired output interface & disable others /
737	status = ufx_reg_write(dev, index: `0x2040`, data: `0`);
738	check_warn_return(status, "ufx_set_vid_mode error writing 0x2040");
739
740	status = ufx_reg_write(dev, index: `0x2044`, data: `0`);
741	check_warn_return(status, "ufx_set_vid_mode error writing 0x2044");
742
743	status = ufx_reg_write(dev, index: `0x2048`, data: `0`);
744	check_warn_return(status, "ufx_set_vid_mode error writing 0x2048");
745
746	/ set the sync polarities & enable bit /
747	temp = `0x00000001`;
748	if (var->sync & FB_SYNC_HOR_HIGH_ACT)
749	temp \|= `0x00000010`;
750
751	if (var->sync & FB_SYNC_VERT_HIGH_ACT)
752	temp \|= `0x00000008`;
753
754	status = ufx_reg_write(dev, index: `0x2040`, data: temp);
755	check_warn_return(status, "ufx_set_vid_mode error writing 0x2040");
756
757	/ start everything back up /
758	status = ufx_enable(dev, wait: true);
759	check_warn_return(status, "ufx_set_vid_mode error enabling display");
760
761	/ Unblank the display /
762	status = ufx_unblank(dev, wait: true);
763	check_warn_return(status, "ufx_set_vid_mode error unblanking display");
764
765	/ enable RGB pad /
766	status = ufx_reg_write(dev, index: `0x8028`, data: `0x00000003`);
767	check_warn_return(status, "ufx_set_vid_mode error enabling RGB pad");
768
769	/ enable VDAC /
770	status = ufx_reg_write(dev, index: `0x8024`, data: `0x00000007`);
771	check_warn_return(status, "ufx_set_vid_mode error enabling VDAC");
772
773	return `0`;
774	}
775
776	static int ufx_ops_mmap(struct fb_info info, struct* vm_area_struct *vma)
777	{
778	unsigned long start = vma->vm_start;
779	unsigned long size = vma->vm_end - vma->vm_start;
780	unsigned long offset = vma->vm_pgoff << PAGE_SHIFT;
781	unsigned long page, pos;
782
783	if (info->fbdefio)
784	return fb_deferred_io_mmap(info, vma);
785
786	vma->vm_page_prot = pgprot_decrypted(vma->vm_page_prot);
787
788	if (vma->vm_pgoff > (~`0UL` >> PAGE_SHIFT))
789	return -EINVAL;
790	if (size > info->fix.smem_len)
791	return -EINVAL;
792	if (offset > info->fix.smem_len - size)
793	return -EINVAL;
794
795	pos = (unsigned long)info->fix.smem_start + offset;
796
797	pr_debug("mmap() framebuffer addr:%lu size:%lu\n",
798	pos, size);
799
800	while (size > `0`) {
801	page = vmalloc_to_pfn(addr: (void *)pos);
802	if (remap_pfn_range(vma, addr: start, pfn: page, PAGE_SIZE, PAGE_SHARED))
803	return -EAGAIN;
804
805	start += PAGE_SIZE;
806	pos += PAGE_SIZE;
807	if (size > PAGE_SIZE)
808	size -= PAGE_SIZE;
809	else
810	size = `0`;
811	}
812
813	return `0`;
814	}
815
816	static void ufx_raw_rect(struct ufx_data dev, u16 cmd, int x, int y,
817	int width, int height)
818	{
819	size_t packed_line_len = ALIGN((width * `2`), `4`);
820	size_t packed_rect_len = packed_line_len * height;
821	int line;
822
823	BUG_ON(!dev);
824	BUG_ON(!dev->info);
825
826	/ command word /
827	((u32 )&cmd[`0`]) = cpu_to_le32(`0x01`);
828
829	/ length word /
830	((u32 )&cmd[`2`]) = cpu_to_le32(packed_rect_len + `16`);
831
832	cmd[`4`] = cpu_to_le16(x);
833	cmd[`5`] = cpu_to_le16(y);
834	cmd[`6`] = cpu_to_le16(width);
835	cmd[`7`] = cpu_to_le16(height);
836
837	/ frame base address /
838	((u32 )&cmd[`8`]) = cpu_to_le32(`0`);
839
840	/ color mode and horizontal resolution /
841	cmd[`10`] = cpu_to_le16(`0x4000` \| dev->info->var.xres);
842
843	/ vertical resolution /
844	cmd[`11`] = cpu_to_le16(dev->info->var.yres);
845
846	/ packed data /
847	for (line = `0`; line < height; line++) {
848	const int line_offset = dev->info->fix.line_length * (y + line);
849	const int byte_offset = line_offset + (x * BPP);
850	memcpy(&cmd[(`24` + (packed_line_len * line)) / `2`],
851	(char )dev->info->fix.smem_start + byte_offset, width BPP);
852	}
853	}
854
855	static int ufx_handle_damage(struct ufx_data dev, int* x, int y,
856	int width, int height)
857	{
858	size_t packed_line_len = ALIGN((width * `2`), `4`);
859	int len, status, urb_lines, start_line = `0`;
860
861	if ((width <= `0`) \|\| (height <= `0`) \|\|
862	(x + width > dev->info->var.xres) \|\|
863	(y + height > dev->info->var.yres))
864	return -EINVAL;
865
866	if (!atomic_read(v: &dev->usb_active))
867	return `0`;
868
869	while (start_line < height) {
870	struct urb *urb = ufx_get_urb(dev);
871	if (!urb) {
872	pr_warn("ufx_handle_damage unable to get urb");
873	return `0`;
874	}
875
876	/ assume we have enough space to transfer at least one line /
877	BUG_ON(urb->transfer_buffer_length < (`24` + (width * `2`)));
878
879	/ calculate the maximum number of lines we could fit in /
880	urb_lines = (urb->transfer_buffer_length - `24`) / packed_line_len;
881
882	/ but we might not need this many /
883	urb_lines = min(urb_lines, (height - start_line));
884
885	memset(urb->transfer_buffer, `0`, urb->transfer_buffer_length);
886
887	ufx_raw_rect(dev, cmd: urb->transfer_buffer, x, y: (y + start_line), width, height: urb_lines);
888	len = `24` + (packed_line_len * urb_lines);
889
890	status = ufx_submit_urb(dev, urb, len);
891	check_warn_return(status, "Error submitting URB");
892
893	start_line += urb_lines;
894	}
895
896	return `0`;
897	}
898
899	/ NOTE: fb_defio.c is holding info->fbdefio.mutex*
900	* Touching ANY framebuffer memory that triggers a page fault
901	* in fb_defio will cause a deadlock, when it also tries to
902	* grab the same mutex. */
903	static void ufx_dpy_deferred_io(struct fb_info info, struct* list_head *pagereflist)
904	{
905	struct ufx_data *dev = info->par;
906	struct fb_deferred_io_pageref *pageref;
907
908	if (!fb_defio)
909	return;
910
911	if (!atomic_read(v: &dev->usb_active))
912	return;
913
914	/ walk the written page list and render each to device /
915	list_for_each_entry(pageref, pagereflist, list) {
916	/ create a rectangle of full screen width that encloses the*
917	* entire dirty framebuffer page */
918	const int x = `0`;
919	const int width = dev->info->var.xres;
920	const int y = pageref->offset / (width * `2`);
921	int height = (PAGE_SIZE / (width * `2`)) + `1`;
922	height = min(height, (int)(dev->info->var.yres - y));
923
924	BUG_ON(y >= dev->info->var.yres);
925	BUG_ON((y + height) > dev->info->var.yres);
926
927	ufx_handle_damage(dev, x, y, width, height);
928	}
929	}
930
931	static int ufx_ops_ioctl(struct fb_info info, unsigned* int cmd,
932	unsigned long arg)
933	{
934	struct ufx_data *dev = info->par;
935	struct dloarea *area = NULL;
936
937	if (!atomic_read(v: &dev->usb_active))
938	return `0`;
939
940	/ TODO: Update X server to get this from sysfs instead /
941	if (cmd == UFX_IOCTL_RETURN_EDID) {
942	u8 __user edid = (u8 __user )arg;
943	if (copy_to_user(to: edid, from: dev->edid, n: dev->edid_size))
944	return -EFAULT;
945	return `0`;
946	}
947
948	/ TODO: Help propose a standard fb.h ioctl to report mmap damage /
949	if (cmd == UFX_IOCTL_REPORT_DAMAGE) {
950	/ If we have a damage-aware client, turn fb_defio "off"*
951	* To avoid perf imact of unnecessary page fault handling.
952	* Done by resetting the delay for this fb_info to a very
953	* long period. Pages will become writable and stay that way.
954	* Reset to normal value when all clients have closed this fb.
955	*/
956	if (info->fbdefio)
957	info->fbdefio->delay = UFX_DEFIO_WRITE_DISABLE;
958
959	area = (struct dloarea *)arg;
960
961	if (area->x < `0`)
962	area->x = `0`;
963
964	if (area->x > info->var.xres)
965	area->x = info->var.xres;
966
967	if (area->y < `0`)
968	area->y = `0`;
969
970	if (area->y > info->var.yres)
971	area->y = info->var.yres;
972
973	ufx_handle_damage(dev, x: area->x, y: area->y, width: area->w, height: area->h);
974	}
975
976	return `0`;
977	}
978
979	/ taken from vesafb /
980	static int
981	ufx_ops_setcolreg(unsigned regno, unsigned red, unsigned green,
982	unsigned blue, unsigned transp, struct fb_info *info)
983	{
984	int err = `0`;
985
986	if (regno >= info->cmap.len)
987	return `1`;
988
989	if (regno < `16`) {
990	if (info->var.red.offset == `10`) {
991	/ 1:5:5:5 /
992	((u32 *) (info->pseudo_palette))[regno] =
993	((red & `0xf800`) >> `1`) \|
994	((green & `0xf800`) >> `6`) \| ((blue & `0xf800`) >> `11`);
995	} else {
996	/ 0:5:6:5 /
997	((u32 *) (info->pseudo_palette))[regno] =
998	((red & `0xf800`)) \|
999	((green & `0xfc00`) >> `5`) \| ((blue & `0xf800`) >> `11`);
1000	}
1001	}
1002
1003	return err;
1004	}
1005
1006	/ It's common for several clients to have framebuffer open simultaneously.*
1007	* e.g. both fbcon and X. Makes things interesting.
1008	* Assumes caller is holding info->lock (for open and release at least) */
1009	static int ufx_ops_open(struct fb_info info, int* user)
1010	{
1011	struct ufx_data *dev = info->par;
1012
1013	/ fbcon aggressively connects to first framebuffer it finds,*
1014	* preventing other clients (X) from working properly. Usually
1015	* not what the user wants. Fail by default with option to enable. */
1016	if (user == `0` && !console)
1017	return -EBUSY;
1018
1019	mutex_lock(&disconnect_mutex);
1020
1021	/ If the USB device is gone, we don't accept new opens /
1022	if (dev->virtualized) {
1023	mutex_unlock(lock: &disconnect_mutex);
1024	return -ENODEV;
1025	}
1026
1027	dev->fb_count++;
1028
1029	kref_get(kref: &dev->kref);
1030
1031	if (fb_defio && (info->fbdefio == NULL)) {
1032	/ enable defio at last moment if not disabled by client /
1033
1034	struct fb_deferred_io *fbdefio;
1035
1036	fbdefio = kzalloc(size: sizeof(*fbdefio), GFP_KERNEL);
1037	if (fbdefio) {
1038	fbdefio->delay = UFX_DEFIO_WRITE_DELAY;
1039	fbdefio->deferred_io = ufx_dpy_deferred_io;
1040	}
1041
1042	info->fbdefio = fbdefio;
1043	fb_deferred_io_init(info);
1044	}
1045
1046	pr_debug("open /dev/fb%d user=%d fb_info=%p count=%d",
1047	info->node, user, info, dev->fb_count);
1048
1049	mutex_unlock(lock: &disconnect_mutex);
1050
1051	return `0`;
1052	}
1053
1054	/*
1055	* Called when all client interfaces to start transactions have been disabled,
1056	* and all references to our device instance (ufx_data) are released.
1057	* Every transaction must have a reference, so we know are fully spun down
1058	*/
1059	static void ufx_free(struct kref *kref)
1060	{
1061	struct ufx_data dev = container_of(kref, struct* ufx_data, kref);
1062
1063	kfree(objp: dev);
1064	}
1065
1066	static void ufx_ops_destory(struct fb_info *info)
1067	{
1068	struct ufx_data *dev = info->par;
1069	int node = info->node;
1070
1071	/ Assume info structure is freed after this point /
1072	framebuffer_release(info);
1073
1074	pr_debug("fb_info for /dev/fb%d has been freed", node);
1075
1076	/ release reference taken by kref_init in probe() /
1077	kref_put(kref: &dev->kref, release: ufx_free);
1078	}
1079
1080
1081	static void ufx_release_urb_work(struct work_struct *work)
1082	{
1083	struct urb_node unode = container_of(work, struct* urb_node,
1084	release_urb_work.work);
1085
1086	up(sem: &unode->dev->urbs.limit_sem);
1087	}
1088
1089	static void ufx_free_framebuffer(struct ufx_data *dev)
1090	{
1091	struct fb_info *info = dev->info;
1092
1093	if (info->cmap.len != `0`)
1094	fb_dealloc_cmap(cmap: &info->cmap);
1095	if (info->monspecs.modedb)
1096	fb_destroy_modedb(modedb: info->monspecs.modedb);
1097	vfree(addr: info->screen_buffer);
1098
1099	fb_destroy_modelist(head: &info->modelist);
1100
1101	dev->info = NULL;
1102
1103	/ ref taken in probe() as part of registering framebfufer /
1104	kref_put(kref: &dev->kref, release: ufx_free);
1105	}
1106
1107	/*
1108	* Assumes caller is holding info->lock mutex (for open and release at least)
1109	*/
1110	static int ufx_ops_release(struct fb_info info, int* user)
1111	{
1112	struct ufx_data *dev = info->par;
1113
1114	mutex_lock(&disconnect_mutex);
1115
1116	dev->fb_count--;
1117
1118	/ We can't free fb_info here - fbmem will touch it when we return /
1119	if (dev->virtualized && (dev->fb_count == `0`))
1120	ufx_free_framebuffer(dev);
1121
1122	if ((dev->fb_count == `0`) && (info->fbdefio)) {
1123	fb_deferred_io_cleanup(info);
1124	kfree(objp: info->fbdefio);
1125	info->fbdefio = NULL;
1126	}
1127
1128	pr_debug("released /dev/fb%d user=%d count=%d",
1129	info->node, user, dev->fb_count);
1130
1131	kref_put(kref: &dev->kref, release: ufx_free);
1132
1133	mutex_unlock(lock: &disconnect_mutex);
1134
1135	return `0`;
1136	}
1137
1138	/ Check whether a video mode is supported by the chip*
1139	* We start from monitor's modes, so don't need to filter that here */
1140	static int ufx_is_valid_mode(struct fb_videomode *mode,
1141	struct fb_info *info)
1142	{
1143	if ((mode->xres * mode->yres) > (`2048` * `1152`)) {
1144	pr_debug("%dx%d too many pixels",
1145	mode->xres, mode->yres);
1146	return `0`;
1147	}
1148
1149	if (mode->pixclock < `5000`) {
1150	pr_debug("%dx%d %dps pixel clock too fast",
1151	mode->xres, mode->yres, mode->pixclock);
1152	return `0`;
1153	}
1154
1155	pr_debug("%dx%d (pixclk %dps %dMHz) valid mode", mode->xres, mode->yres,
1156	mode->pixclock, (`1000000` / mode->pixclock));
1157	return `1`;
1158	}
1159
1160	static void ufx_var_color_format(struct fb_var_screeninfo *var)
1161	{
1162	const struct fb_bitfield red = { `11`, `5`, `0` };
1163	const struct fb_bitfield green = { `5`, `6`, `0` };
1164	const struct fb_bitfield blue = { `0`, `5`, `0` };
1165
1166	var->bits_per_pixel = `16`;
1167	var->red = red;
1168	var->green = green;
1169	var->blue = blue;
1170	}
1171
1172	static int ufx_ops_check_var(struct fb_var_screeninfo *var,
1173	struct fb_info *info)
1174	{
1175	struct fb_videomode mode;
1176
1177	/ TODO: support dynamically changing framebuffer size /
1178	if ((var->xres * var->yres * `2`) > info->fix.smem_len)
1179	return -EINVAL;
1180
1181	/ set device-specific elements of var unrelated to mode /
1182	ufx_var_color_format(var);
1183
1184	fb_var_to_videomode(mode: &mode, var);
1185
1186	if (!ufx_is_valid_mode(mode: &mode, info))
1187	return -EINVAL;
1188
1189	return `0`;
1190	}
1191
1192	static int ufx_ops_set_par(struct fb_info *info)
1193	{
1194	struct ufx_data *dev = info->par;
1195	int result;
1196	u16 *pix_framebuffer;
1197	int i;
1198
1199	pr_debug("set_par mode %dx%d", info->var.xres, info->var.yres);
1200	result = ufx_set_vid_mode(dev, var: &info->var);
1201
1202	if ((result == `0`) && (dev->fb_count == `0`)) {
1203	/ paint greenscreen /
1204	pix_framebuffer = (u16 *)info->screen_buffer;
1205	for (i = `0`; i < info->fix.smem_len / `2`; i++)
1206	pix_framebuffer[i] = `0x37e6`;
1207
1208	ufx_handle_damage(dev, x: `0`, y: `0`, width: info->var.xres, height: info->var.yres);
1209	}
1210
1211	/ re-enable defio if previously disabled by damage tracking /
1212	if (info->fbdefio)
1213	info->fbdefio->delay = UFX_DEFIO_WRITE_DELAY;
1214
1215	return result;
1216	}
1217
1218	/ In order to come back from full DPMS off, we need to set the mode again /
1219	static int ufx_ops_blank(int blank_mode, struct fb_info *info)
1220	{
1221	struct ufx_data *dev = info->par;
1222	ufx_set_vid_mode(dev, var: &info->var);
1223	return `0`;
1224	}
1225
1226	static void ufx_ops_damage_range(struct fb_info *info, off_t off, size_t len)
1227	{
1228	struct ufx_data *dev = info->par;
1229	int start = max((int)(off / info->fix.line_length), `0`);
1230	int lines = min((u32)((len / info->fix.line_length) + `1`), (u32)info->var.yres);
1231
1232	ufx_handle_damage(dev, x: `0`, y: start, width: info->var.xres, height: lines);
1233	}
1234
1235	static void ufx_ops_damage_area(struct fb_info *info, u32 x, u32 y, u32 width, u32 height)
1236	{
1237	struct ufx_data *dev = info->par;
1238
1239	ufx_handle_damage(dev, x, y, width, height);
1240	}
1241
1242	FB_GEN_DEFAULT_DEFERRED_SYSMEM_OPS(ufx_ops,
1243	ufx_ops_damage_range,
1244	ufx_ops_damage_area)
1245
1246	static const struct fb_ops ufx_ops = {
1247	.owner = THIS_MODULE,
1248	__FB_DEFAULT_DEFERRED_OPS_RDWR(ufx_ops),
1249	.fb_setcolreg = ufx_ops_setcolreg,
1250	__FB_DEFAULT_DEFERRED_OPS_DRAW(ufx_ops),
1251	.fb_mmap = ufx_ops_mmap,
1252	.fb_ioctl = ufx_ops_ioctl,
1253	.fb_open = ufx_ops_open,
1254	.fb_release = ufx_ops_release,
1255	.fb_blank = ufx_ops_blank,
1256	.fb_check_var = ufx_ops_check_var,
1257	.fb_set_par = ufx_ops_set_par,
1258	.fb_destroy = ufx_ops_destory,
1259	};
1260
1261	/ Assumes &info->lock held by caller*
1262	* Assumes no active clients have framebuffer open */
1263	static int ufx_realloc_framebuffer(struct ufx_data dev, struct* fb_info *info)
1264	{
1265	int old_len = info->fix.smem_len;
1266	int new_len;
1267	unsigned char *old_fb = info->screen_buffer;
1268	unsigned char *new_fb;
1269
1270	pr_debug("Reallocating framebuffer. Addresses will change!");
1271
1272	new_len = info->fix.line_length * info->var.yres;
1273
1274	if (PAGE_ALIGN(new_len) > old_len) {
1275	/*
1276	* Alloc system memory for virtual framebuffer
1277	*/
1278	new_fb = vmalloc(size: new_len);
1279	if (!new_fb)
1280	return -ENOMEM;
1281
1282	if (info->screen_buffer) {
1283	memcpy(new_fb, old_fb, old_len);
1284	vfree(addr: info->screen_buffer);
1285	}
1286
1287	info->screen_buffer = new_fb;
1288	info->fix.smem_len = PAGE_ALIGN(new_len);
1289	info->fix.smem_start = (unsigned long) new_fb;
1290	info->flags = smscufx_info_flags;
1291	}
1292	return `0`;
1293	}
1294
1295	/ sets up I2C Controller for 100 Kbps, std. speed, 7-bit addr, master,*
1296	* restart enabled, but no start byte, enable controller */
1297	static int ufx_i2c_init(struct ufx_data *dev)
1298	{
1299	u32 tmp;
1300
1301	/ disable the controller before it can be reprogrammed /
1302	int status = ufx_reg_write(dev, index: `0x106C`, data: `0x00`);
1303	check_warn_return(status, "failed to disable I2C");
1304
1305	/ Setup the clock count registers*
1306	* (12+1) = 13 clks @ 2.5 MHz = 5.2 uS */
1307	status = ufx_reg_write(dev, index: `0x1018`, data: `12`);
1308	check_warn_return(status, "error writing 0x1018");
1309
1310	/ (6+8) = 14 clks @ 2.5 MHz = 5.6 uS /
1311	status = ufx_reg_write(dev, index: `0x1014`, data: `6`);
1312	check_warn_return(status, "error writing 0x1014");
1313
1314	status = ufx_reg_read(dev, index: `0x1000`, data: &tmp);
1315	check_warn_return(status, "error reading 0x1000");
1316
1317	/ set speed to std mode /
1318	tmp &= ~(`0x06`);
1319	tmp \|= `0x02`;
1320
1321	/ 7-bit (not 10-bit) addressing /
1322	tmp &= ~(`0x10`);
1323
1324	/ enable restart conditions and master mode /
1325	tmp \|= `0x21`;
1326
1327	status = ufx_reg_write(dev, index: `0x1000`, data: tmp);
1328	check_warn_return(status, "error writing 0x1000");
1329
1330	/ Set normal tx using target address 0 /
1331	status = ufx_reg_clear_and_set_bits(dev, index: `0x1004`, bits_to_clear: `0xC00`, bits_to_set: `0x000`);
1332	check_warn_return(status, "error setting TX mode bits in 0x1004");
1333
1334	/ Enable the controller /
1335	status = ufx_reg_write(dev, index: `0x106C`, data: `0x01`);
1336	check_warn_return(status, "failed to enable I2C");
1337
1338	return `0`;
1339	}
1340
1341	/ sets the I2C port mux and target address /
1342	static int ufx_i2c_configure(struct ufx_data *dev)
1343	{
1344	int status = ufx_reg_write(dev, index: `0x106C`, data: `0x00`);
1345	check_warn_return(status, "failed to disable I2C");
1346
1347	status = ufx_reg_write(dev, index: `0x3010`, data: `0x00000000`);
1348	check_warn_return(status, "failed to write 0x3010");
1349
1350	/ A0h is std for any EDID, right shifted by one /
1351	status = ufx_reg_clear_and_set_bits(dev, index: `0x1004`, bits_to_clear: `0x3FF`, bits_to_set: (`0xA0` >> `1`));
1352	check_warn_return(status, "failed to set TAR bits in 0x1004");
1353
1354	status = ufx_reg_write(dev, index: `0x106C`, data: `0x01`);
1355	check_warn_return(status, "failed to enable I2C");
1356
1357	return `0`;
1358	}
1359
1360	/ wait for BUSY to clear, with a timeout of 50ms with 10ms sleeps. if no*
1361	* monitor is connected, there is no error except for timeout */
1362	static int ufx_i2c_wait_busy(struct ufx_data *dev)
1363	{
1364	u32 tmp;
1365	int i, status;
1366
1367	for (i = `0`; i < `15`; i++) {
1368	status = ufx_reg_read(dev, index: `0x1100`, data: &tmp);
1369	check_warn_return(status, "0x1100 read failed");
1370
1371	/ if BUSY is clear, check for error /
1372	if ((tmp & `0x80000000`) == `0`) {
1373	if (tmp & `0x20000000`) {
1374	pr_warn("I2C read failed, 0x1100=0x%08x", tmp);
1375	return -EIO;
1376	}
1377
1378	return `0`;
1379	}
1380
1381	/ perform the first 10 retries without delay /
1382	if (i >= `10`)
1383	msleep(msecs: `10`);
1384	}
1385
1386	pr_warn("I2C access timed out, resetting I2C hardware");
1387	status = ufx_reg_write(dev, index: `0x1100`, data: `0x40000000`);
1388	check_warn_return(status, "0x1100 write failed");
1389
1390	return -ETIMEDOUT;
1391	}
1392
1393	/ reads a 128-byte EDID block from the currently selected port and TAR /
1394	static int ufx_read_edid(struct ufx_data dev, u8 edid, int edid_len)
1395	{
1396	int i, j, status;
1397	u32 edid_u32 = (u32 )edid;
1398
1399	BUG_ON(edid_len != EDID_LENGTH);
1400
1401	status = ufx_i2c_configure(dev);
1402	if (status < `0`) {
1403	pr_err("ufx_i2c_configure failed");
1404	return status;
1405	}
1406
1407	memset(edid, `0xff`, EDID_LENGTH);
1408
1409	/ Read the 128-byte EDID as 2 bursts of 64 bytes /
1410	for (i = `0`; i < `2`; i++) {
1411	u32 temp = `0x28070000` \| (`63` << `20`) \| (((u32)(i * `64`)) << `8`);
1412	status = ufx_reg_write(dev, index: `0x1100`, data: temp);
1413	check_warn_return(status, "Failed to write 0x1100");
1414
1415	temp \|= `0x80000000`;
1416	status = ufx_reg_write(dev, index: `0x1100`, data: temp);
1417	check_warn_return(status, "Failed to write 0x1100");
1418
1419	status = ufx_i2c_wait_busy(dev);
1420	check_warn_return(status, "Timeout waiting for I2C BUSY to clear");
1421
1422	for (j = `0`; j < `16`; j++) {
1423	u32 data_reg_addr = `0x1110` + (j * `4`);
1424	status = ufx_reg_read(dev, index: data_reg_addr, data: edid_u32++);
1425	check_warn_return(status, "Error reading i2c data");
1426	}
1427	}
1428
1429	/ all FF's in the first 16 bytes indicates nothing is connected /
1430	for (i = `0`; i < `16`; i++) {
1431	if (edid[i] != `0xFF`) {
1432	pr_debug("edid data read successfully");
1433	return EDID_LENGTH;
1434	}
1435	}
1436
1437	pr_warn("edid data contains all 0xff");
1438	return -ETIMEDOUT;
1439	}
1440
1441	/ 1) use sw default*
1442	* 2) Parse into various fb_info structs
1443	* 3) Allocate virtual framebuffer memory to back highest res mode
1444	*
1445	* Parses EDID into three places used by various parts of fbdev:
1446	* fb_var_screeninfo contains the timing of the monitor's preferred mode
1447	* fb_info.monspecs is full parsed EDID info, including monspecs.modedb
1448	* fb_info.modelist is a linked list of all monitor & VESA modes which work
1449	*
1450	* If EDID is not readable/valid, then modelist is all VESA modes,
1451	* monspecs is NULL, and fb_var_screeninfo is set to safe VESA mode
1452	* Returns 0 if successful */
1453	static int ufx_setup_modes(struct ufx_data dev, struct* fb_info *info,
1454	char *default_edid, size_t default_edid_size)
1455	{
1456	const struct fb_videomode *default_vmode = NULL;
1457	u8 *edid;
1458	int i, result = `0`, tries = `3`;
1459
1460	if (refcount_read(r: &info->count)) / only use mutex if info has been registered /
1461	mutex_lock(&info->lock);
1462
1463	edid = kmalloc(EDID_LENGTH, GFP_KERNEL);
1464	if (!edid) {
1465	result = -ENOMEM;
1466	goto error;
1467	}
1468
1469	fb_destroy_modelist(head: &info->modelist);
1470	memset(&info->monspecs, `0`, sizeof(info->monspecs));
1471
1472	/ Try to (re)read EDID from hardware first*
1473	* EDID data may return, but not parse as valid
1474	* Try again a few times, in case of e.g. analog cable noise */
1475	while (tries--) {
1476	i = ufx_read_edid(dev, edid, EDID_LENGTH);
1477
1478	if (i >= EDID_LENGTH)
1479	fb_edid_to_monspecs(edid, specs: &info->monspecs);
1480
1481	if (info->monspecs.modedb_len > `0`) {
1482	dev->edid = edid;
1483	dev->edid_size = i;
1484	break;
1485	}
1486	}
1487
1488	/ If that fails, use a previously returned EDID if available /
1489	if (info->monspecs.modedb_len == `0`) {
1490	pr_err("Unable to get valid EDID from device/display\n");
1491
1492	if (dev->edid) {
1493	fb_edid_to_monspecs(edid: dev->edid, specs: &info->monspecs);
1494	if (info->monspecs.modedb_len > `0`)
1495	pr_err("Using previously queried EDID\n");
1496	}
1497	}
1498
1499	/ If that fails, use the default EDID we were handed /
1500	if (info->monspecs.modedb_len == `0`) {
1501	if (default_edid_size >= EDID_LENGTH) {
1502	fb_edid_to_monspecs(edid: default_edid, specs: &info->monspecs);
1503	if (info->monspecs.modedb_len > `0`) {
1504	memcpy(edid, default_edid, default_edid_size);
1505	dev->edid = edid;
1506	dev->edid_size = default_edid_size;
1507	pr_err("Using default/backup EDID\n");
1508	}
1509	}
1510	}
1511
1512	/ If we've got modes, let's pick a best default mode /
1513	if (info->monspecs.modedb_len > `0`) {
1514
1515	for (i = `0`; i < info->monspecs.modedb_len; i++) {
1516	if (ufx_is_valid_mode(mode: &info->monspecs.modedb[i], info))
1517	fb_add_videomode(mode: &info->monspecs.modedb[i],
1518	head: &info->modelist);
1519	else / if we've removed top/best mode /
1520	info->monspecs.misc &= ~FB_MISC_1ST_DETAIL;
1521	}
1522
1523	default_vmode = fb_find_best_display(specs: &info->monspecs,
1524	head: &info->modelist);
1525	}
1526
1527	/ If everything else has failed, fall back to safe default mode /
1528	if (default_vmode == NULL) {
1529
1530	struct fb_videomode fb_vmode = {`0`};
1531
1532	/ Add the standard VESA modes to our modelist*
1533	* Since we don't have EDID, there may be modes that
1534	* overspec monitor and/or are incorrect aspect ratio, etc.
1535	* But at least the user has a chance to choose
1536	*/
1537	for (i = `0`; i < VESA_MODEDB_SIZE; i++) {
1538	if (ufx_is_valid_mode(mode: (struct fb_videomode *)
1539	&vesa_modes[i], info))
1540	fb_add_videomode(mode: &vesa_modes[i],
1541	head: &info->modelist);
1542	}
1543
1544	/ default to resolution safe for projectors*
1545	* (since they are most common case without EDID)
1546	*/
1547	fb_vmode.xres = `800`;
1548	fb_vmode.yres = `600`;
1549	fb_vmode.refresh = `60`;
1550	default_vmode = fb_find_nearest_mode(mode: &fb_vmode,
1551	head: &info->modelist);
1552	}
1553
1554	/ If we have good mode and no active clients /
1555	if ((default_vmode != NULL) && (dev->fb_count == `0`)) {
1556
1557	fb_videomode_to_var(var: &info->var, mode: default_vmode);
1558	ufx_var_color_format(var: &info->var);
1559
1560	/ with mode size info, we can now alloc our framebuffer /
1561	memcpy(&info->fix, &ufx_fix, sizeof(ufx_fix));
1562	info->fix.line_length = info->var.xres *
1563	(info->var.bits_per_pixel / `8`);
1564
1565	result = ufx_realloc_framebuffer(dev, info);
1566
1567	} else
1568	result = -EINVAL;
1569
1570	error:
1571	if (edid && (dev->edid != edid))
1572	kfree(objp: edid);
1573
1574	if (refcount_read(r: &info->count))
1575	mutex_unlock(lock: &info->lock);
1576
1577	return result;
1578	}
1579
1580	static int ufx_usb_probe(struct usb_interface *interface,
1581	const struct usb_device_id *id)
1582	{
1583	struct usb_device *usbdev;
1584	struct ufx_data *dev;
1585	struct fb_info *info;
1586	int retval = -ENOMEM;
1587	u32 id_rev, fpga_rev;
1588
1589	/ usb initialization /
1590	usbdev = interface_to_usbdev(interface);
1591	BUG_ON(!usbdev);
1592
1593	dev = kzalloc(size: sizeof(*dev), GFP_KERNEL);
1594	if (dev == NULL) {
1595	dev_err(&usbdev->dev, "ufx_usb_probe: failed alloc of dev struct\n");
1596	return -ENOMEM;
1597	}
1598
1599	/ we need to wait for both usb and fbdev to spin down on disconnect /
1600	kref_init(kref: &dev->kref); / matching kref_put in usb .disconnect fn /
1601	kref_get(kref: &dev->kref); / matching kref_put in free_framebuffer_work /
1602
1603	dev->udev = usbdev;
1604	dev->gdev = &usbdev->dev; / our generic struct device * /
1605	usb_set_intfdata(intf: interface, data: dev);
1606
1607	dev_dbg(dev->gdev, "%s %s - serial #%s\n",
1608	usbdev->manufacturer, usbdev->product, usbdev->serial);
1609	dev_dbg(dev->gdev, "vid_%04x&pid_%04x&rev_%04x driver's ufx_data struct at %p\n",
1610	le16_to_cpu(usbdev->descriptor.idVendor),
1611	le16_to_cpu(usbdev->descriptor.idProduct),
1612	le16_to_cpu(usbdev->descriptor.bcdDevice), dev);
1613	dev_dbg(dev->gdev, "console enable=%d\n", console);
1614	dev_dbg(dev->gdev, "fb_defio enable=%d\n", fb_defio);
1615
1616	if (!ufx_alloc_urb_list(dev, WRITES_IN_FLIGHT, MAX_TRANSFER)) {
1617	dev_err(dev->gdev, "ufx_alloc_urb_list failed\n");
1618	goto put_ref;
1619	}
1620
1621	/ We don't register a new USB class. Our client interface is fbdev /
1622
1623	/ allocates framebuffer driver structure, not framebuffer memory /
1624	info = framebuffer_alloc(size: `0`, dev: &usbdev->dev);
1625	if (!info) {
1626	dev_err(dev->gdev, "framebuffer_alloc failed\n");
1627	goto free_urb_list;
1628	}
1629
1630	dev->info = info;
1631	info->par = dev;
1632	info->pseudo_palette = dev->pseudo_palette;
1633	info->fbops = &ufx_ops;
1634	INIT_LIST_HEAD(list: &info->modelist);
1635
1636	retval = fb_alloc_cmap(cmap: &info->cmap, len: `256`, transp: `0`);
1637	if (retval < `0`) {
1638	dev_err(dev->gdev, "fb_alloc_cmap failed %x\n", retval);
1639	goto destroy_modedb;
1640	}
1641
1642	retval = ufx_reg_read(dev, index: `0x3000`, data: &id_rev);
1643	check_warn_goto_error(retval, "error %d reading 0x3000 register from device", retval);
1644	dev_dbg(dev->gdev, "ID_REV register value 0x%08x", id_rev);
1645
1646	retval = ufx_reg_read(dev, index: `0x3004`, data: &fpga_rev);
1647	check_warn_goto_error(retval, "error %d reading 0x3004 register from device", retval);
1648	dev_dbg(dev->gdev, "FPGA_REV register value 0x%08x", fpga_rev);
1649
1650	dev_dbg(dev->gdev, "resetting device");
1651	retval = ufx_lite_reset(dev);
1652	check_warn_goto_error(retval, "error %d resetting device", retval);
1653
1654	dev_dbg(dev->gdev, "configuring system clock");
1655	retval = ufx_config_sys_clk(dev);
1656	check_warn_goto_error(retval, "error %d configuring system clock", retval);
1657
1658	dev_dbg(dev->gdev, "configuring DDR2 controller");
1659	retval = ufx_config_ddr2(dev);
1660	check_warn_goto_error(retval, "error %d initialising DDR2 controller", retval);
1661
1662	dev_dbg(dev->gdev, "configuring I2C controller");
1663	retval = ufx_i2c_init(dev);
1664	check_warn_goto_error(retval, "error %d initialising I2C controller", retval);
1665
1666	dev_dbg(dev->gdev, "selecting display mode");
1667	retval = ufx_setup_modes(dev, info, NULL, default_edid_size: `0`);
1668	check_warn_goto_error(retval, "unable to find common mode for display and adapter");
1669
1670	retval = ufx_reg_set_bits(dev, index: `0x4000`, bits: `0x00000001`);
1671	if (retval < `0`) {
1672	dev_err(dev->gdev, "error %d enabling graphics engine", retval);
1673	goto setup_modes;
1674	}
1675
1676	/ ready to begin using device /
1677	atomic_set(v: &dev->usb_active, i: `1`);
1678
1679	dev_dbg(dev->gdev, "checking var");
1680	retval = ufx_ops_check_var(var: &info->var, info);
1681	if (retval < `0`) {
1682	dev_err(dev->gdev, "error %d ufx_ops_check_var", retval);
1683	goto reset_active;
1684	}
1685
1686	dev_dbg(dev->gdev, "setting par");
1687	retval = ufx_ops_set_par(info);
1688	if (retval < `0`) {
1689	dev_err(dev->gdev, "error %d ufx_ops_set_par", retval);
1690	goto reset_active;
1691	}
1692
1693	dev_dbg(dev->gdev, "registering framebuffer");
1694	retval = register_framebuffer(fb_info: info);
1695	if (retval < `0`) {
1696	dev_err(dev->gdev, "error %d register_framebuffer", retval);
1697	goto reset_active;
1698	}
1699
1700	dev_info(dev->gdev, "SMSC UDX USB device /dev/fb%d attached. %dx%d resolution."
1701	" Using %dK framebuffer memory\n", info->node,
1702	info->var.xres, info->var.yres, info->fix.smem_len >> `10`);
1703
1704	return `0`;
1705
1706	reset_active:
1707	atomic_set(v: &dev->usb_active, i: `0`);
1708	setup_modes:
1709	fb_destroy_modedb(modedb: info->monspecs.modedb);
1710	vfree(addr: info->screen_buffer);
1711	fb_destroy_modelist(head: &info->modelist);
1712	error:
1713	fb_dealloc_cmap(cmap: &info->cmap);
1714	destroy_modedb:
1715	framebuffer_release(info);
1716	free_urb_list:
1717	if (dev->urbs.count > `0`)
1718	ufx_free_urb_list(dev);
1719	put_ref:
1720	kref_put(kref: &dev->kref, release: ufx_free); / ref for framebuffer /
1721	kref_put(kref: &dev->kref, release: ufx_free); / last ref from kref_init /
1722	return retval;
1723	}
1724
1725	static void ufx_usb_disconnect(struct usb_interface *interface)
1726	{
1727	struct ufx_data *dev;
1728	struct fb_info *info;
1729
1730	mutex_lock(&disconnect_mutex);
1731
1732	dev = usb_get_intfdata(intf: interface);
1733	info = dev->info;
1734
1735	pr_debug("USB disconnect starting\n");
1736
1737	/ we virtualize until all fb clients release. Then we free /
1738	dev->virtualized = true;
1739
1740	/ When non-active we'll update virtual framebuffer, but no new urbs /
1741	atomic_set(v: &dev->usb_active, i: `0`);
1742
1743	usb_set_intfdata(intf: interface, NULL);
1744
1745	/ if clients still have us open, will be freed on last close /
1746	if (dev->fb_count == `0`)
1747	ufx_free_framebuffer(dev);
1748
1749	/ this function will wait for all in-flight urbs to complete /
1750	if (dev->urbs.count > `0`)
1751	ufx_free_urb_list(dev);
1752
1753	pr_debug("freeing ufx_data %p", dev);
1754
1755	unregister_framebuffer(fb_info: info);
1756
1757	mutex_unlock(lock: &disconnect_mutex);
1758	}
1759
1760	static struct usb_driver ufx_driver = {
1761	.name = "smscufx",
1762	.probe = ufx_usb_probe,
1763	.disconnect = ufx_usb_disconnect,
1764	.id_table = id_table,
1765	};
1766
1767	module_usb_driver(ufx_driver);
1768
1769	static void ufx_urb_completion(struct urb *urb)
1770	{
1771	struct urb_node *unode = urb->context;
1772	struct ufx_data *dev = unode->dev;
1773	unsigned long flags;
1774
1775	/ sync/async unlink faults aren't errors /
1776	if (urb->status) {
1777	if (!(urb->status == -ENOENT \|\|
1778	urb->status == -ECONNRESET \|\|
1779	urb->status == -ESHUTDOWN)) {
1780	pr_err("%s - nonzero write bulk status received: %d\n",
1781	__func__, urb->status);
1782	atomic_set(v: &dev->lost_pixels, i: `1`);
1783	}
1784	}
1785
1786	urb->transfer_buffer_length = dev->urbs.size; / reset to actual /
1787
1788	spin_lock_irqsave(&dev->urbs.lock, flags);
1789	list_add_tail(new: &unode->entry, head: &dev->urbs.list);
1790	dev->urbs.available++;
1791	spin_unlock_irqrestore(lock: &dev->urbs.lock, flags);
1792
1793	/ When using fb_defio, we deadlock if up() is called*
1794	* while another is waiting. So queue to another process */
1795	if (fb_defio)
1796	schedule_delayed_work(dwork: &unode->release_urb_work, delay: `0`);
1797	else
1798	up(sem: &dev->urbs.limit_sem);
1799	}
1800
1801	static void ufx_free_urb_list(struct ufx_data *dev)
1802	{
1803	int count = dev->urbs.count;
1804	struct list_head *node;
1805	struct urb_node *unode;
1806	struct urb *urb;
1807	int ret;
1808	unsigned long flags;
1809
1810	pr_debug("Waiting for completes and freeing all render urbs\n");
1811
1812	/ keep waiting and freeing, until we've got 'em all /
1813	while (count--) {
1814	/ Getting interrupted means a leak, but ok at shutdown/
1815	ret = down_interruptible(sem: &dev->urbs.limit_sem);
1816	if (ret)
1817	break;
1818
1819	spin_lock_irqsave(&dev->urbs.lock, flags);
1820
1821	node = dev->urbs.list.next; / have reserved one with sem /
1822	list_del_init(entry: node);
1823
1824	spin_unlock_irqrestore(lock: &dev->urbs.lock, flags);
1825
1826	unode = list_entry(node, struct urb_node, entry);
1827	urb = unode->urb;
1828
1829	/ Free each separately allocated piece /
1830	usb_free_coherent(dev: urb->dev, size: dev->urbs.size,
1831	addr: urb->transfer_buffer, dma: urb->transfer_dma);
1832	usb_free_urb(urb);
1833	kfree(objp: node);
1834	}
1835	}
1836
1837	static int ufx_alloc_urb_list(struct ufx_data dev, int* count, size_t size)
1838	{
1839	int i = `0`;
1840	struct urb *urb;
1841	struct urb_node *unode;
1842	char *buf;
1843
1844	spin_lock_init(&dev->urbs.lock);
1845
1846	dev->urbs.size = size;
1847	INIT_LIST_HEAD(list: &dev->urbs.list);
1848
1849	while (i < count) {
1850	unode = kzalloc(size: sizeof(*unode), GFP_KERNEL);
1851	if (!unode)
1852	break;
1853	unode->dev = dev;
1854
1855	INIT_DELAYED_WORK(&unode->release_urb_work,
1856	ufx_release_urb_work);
1857
1858	urb = usb_alloc_urb(iso_packets: `0`, GFP_KERNEL);
1859	if (!urb) {
1860	kfree(objp: unode);
1861	break;
1862	}
1863	unode->urb = urb;
1864
1865	buf = usb_alloc_coherent(dev: dev->udev, size, GFP_KERNEL,
1866	dma: &urb->transfer_dma);
1867	if (!buf) {
1868	kfree(objp: unode);
1869	usb_free_urb(urb);
1870	break;
1871	}
1872
1873	/ urb->transfer_buffer_length set to actual before submit /
1874	usb_fill_bulk_urb(urb, dev: dev->udev, usb_sndbulkpipe(dev->udev, `1`),
1875	transfer_buffer: buf, buffer_length: size, complete_fn: ufx_urb_completion, context: unode);
1876	urb->transfer_flags \|= URB_NO_TRANSFER_DMA_MAP;
1877
1878	list_add_tail(new: &unode->entry, head: &dev->urbs.list);
1879
1880	i++;
1881	}
1882
1883	sema_init(sem: &dev->urbs.limit_sem, val: i);
1884	dev->urbs.count = i;
1885	dev->urbs.available = i;
1886
1887	pr_debug("allocated %d %d byte urbs\n", i, (int) size);
1888
1889	return i;
1890	}
1891
1892	static struct urb ufx_get_urb(struct* ufx_data *dev)
1893	{
1894	int ret = `0`;
1895	struct list_head *entry;
1896	struct urb_node *unode;
1897	struct urb *urb = NULL;
1898	unsigned long flags;
1899
1900	/ Wait for an in-flight buffer to complete and get re-queued /
1901	ret = down_timeout(sem: &dev->urbs.limit_sem, GET_URB_TIMEOUT);
1902	if (ret) {
1903	atomic_set(v: &dev->lost_pixels, i: `1`);
1904	pr_warn("wait for urb interrupted: %x available: %d\n",
1905	ret, dev->urbs.available);
1906	goto error;
1907	}
1908
1909	spin_lock_irqsave(&dev->urbs.lock, flags);
1910
1911	BUG_ON(list_empty(&dev->urbs.list)); / reserved one with limit_sem /
1912	entry = dev->urbs.list.next;
1913	list_del_init(entry);
1914	dev->urbs.available--;
1915
1916	spin_unlock_irqrestore(lock: &dev->urbs.lock, flags);
1917
1918	unode = list_entry(entry, struct urb_node, entry);
1919	urb = unode->urb;
1920
1921	error:
1922	return urb;
1923	}
1924
1925	static int ufx_submit_urb(struct ufx_data dev, struct* urb *urb, size_t len)
1926	{
1927	int ret;
1928
1929	BUG_ON(len > dev->urbs.size);
1930
1931	urb->transfer_buffer_length = len; / set to actual payload len /
1932	ret = usb_submit_urb(urb, GFP_KERNEL);
1933	if (ret) {
1934	ufx_urb_completion(urb); / because no one else will /
1935	atomic_set(v: &dev->lost_pixels, i: `1`);
1936	pr_err("usb_submit_urb error %x\n", ret);
1937	}
1938	return ret;
1939	}
1940
1941	module_param(console, bool, S_IWUSR \| S_IRUSR \| S_IWGRP \| S_IRGRP);
1942	MODULE_PARM_DESC(console, "Allow fbcon to be used on this display");
1943
1944	module_param(fb_defio, bool, S_IWUSR \| S_IRUSR \| S_IWGRP \| S_IRGRP);
1945	MODULE_PARM_DESC(fb_defio, "Enable fb_defio mmap support");
1946
1947	MODULE_AUTHOR("Steve Glendinning <steve.glendinning@shawell.net>");
1948	MODULE_DESCRIPTION("SMSC UFX kernel framebuffer driver");
1949	MODULE_LICENSE("GPL");
1950

source code of linux/drivers/video/fbdev/smscufx.c