1 /***************************************************************************
2 * API for image sensors connected to the SN9C10x PC Camera Controllers *
4 * Copyright (C) 2004-2005 by Luca Risolia <luca.risolia@studio.unibo.it> *
6 * This program is free software; you can redistribute it and/or modify *
7 * it under the terms of the GNU General Public License as published by *
8 * the Free Software Foundation; either version 2 of the License, or *
9 * (at your option) any later version. *
11 * This program is distributed in the hope that it will be useful, *
12 * but WITHOUT ANY WARRANTY; without even the implied warranty of *
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the *
14 * GNU General Public License for more details. *
16 * You should have received a copy of the GNU General Public License *
17 * along with this program; if not, write to the Free Software *
18 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. *
19 ***************************************************************************/
21 #ifndef _SN9C102_SENSOR_H_
22 #define _SN9C102_SENSOR_H_
24 #include <linux/usb.h>
25 #include <linux/videodev.h>
26 #include <linux/device.h>
27 #include <linux/stddef.h>
28 #include <linux/errno.h>
29 #include <asm/types.h>
31 struct sn9c102_device;
32 struct sn9c102_sensor;
34 /*****************************************************************************/
38 This is a small interface that allows you to add support for any CCD/CMOS
39 image sensors connected to the SN9C10X bridges. The entire API is documented
40 below. In the most general case, to support a sensor there are three steps
42 1) define the main "sn9c102_sensor" structure by setting the basic fields;
43 2) write a probing function to be called by the core module when the USB
44 camera is recognized, then add both the USB ids and the name of that
45 function to the two corresponding tables SENSOR_TABLE and ID_TABLE (see
47 3) implement the methods that you want/need (and fill the rest of the main
48 structure accordingly).
49 "sn9c102_pas106b.c" is an example of all this stuff. Remember that you do
50 NOT need to touch the source code of the core module for the things to work
51 properly, unless you find bugs or flaws in it. Finally, do not forget to
52 read the V4L2 API for completeness.
55 /*****************************************************************************/
58 Probing functions: on success, you must attach the sensor to the camera
59 by calling sn9c102_attach_sensor() provided below.
60 To enable the I2C communication, you might need to perform a really basic
61 initialization of the SN9C10X chip by using the write function declared
63 Functions must return 0 on success, the appropriate error otherwise.
65 extern int sn9c102_probe_hv7131d(struct sn9c102_device* cam);
66 extern int sn9c102_probe_mi0343(struct sn9c102_device* cam);
67 extern int sn9c102_probe_pas106b(struct sn9c102_device* cam);
68 extern int sn9c102_probe_pas202bcb(struct sn9c102_device* cam);
69 extern int sn9c102_probe_tas5110c1b(struct sn9c102_device* cam);
70 extern int sn9c102_probe_tas5130d1b(struct sn9c102_device* cam);
73 Add the above entries to this table. Be sure to add the entry in the right
74 place, since, on failure, the next probing routine is called according to
75 the order of the list below, from top to bottom.
77 #define SN9C102_SENSOR_TABLE \
78 static int (*sn9c102_sensor_table[])(struct sn9c102_device*) = { \
79 &sn9c102_probe_mi0343, /* strong detection based on SENSOR ids */ \
80 &sn9c102_probe_pas106b, /* strong detection based on SENSOR ids */ \
81 &sn9c102_probe_pas202bcb, /* strong detection based on SENSOR ids */ \
82 &sn9c102_probe_hv7131d, /* strong detection based on SENSOR ids */ \
83 &sn9c102_probe_tas5110c1b, /* detection based on USB pid/vid */ \
84 &sn9c102_probe_tas5130d1b, /* detection based on USB pid/vid */ \
88 /* Attach a probed sensor to the camera. */
90 sn9c102_attach_sensor(struct sn9c102_device* cam,
91 struct sn9c102_sensor* sensor);
93 /* Each SN9C10X camera has proper PID/VID identifiers. Add them here in case.*/
94 #define SN9C102_ID_TABLE \
95 static const struct usb_device_id sn9c102_id_table[] = { \
96 { USB_DEVICE(0x0c45, 0x6001), }, /* TAS5110C1B */ \
97 { USB_DEVICE(0x0c45, 0x6005), }, /* TAS5110C1B */ \
98 { USB_DEVICE(0x0c45, 0x6009), }, /* PAS106B */ \
99 { USB_DEVICE(0x0c45, 0x600d), }, /* PAS106B */ \
100 { USB_DEVICE(0x0c45, 0x6024), }, \
101 { USB_DEVICE(0x0c45, 0x6025), }, /* TAS5130D1B and TAS5110C1B */ \
102 { USB_DEVICE(0x0c45, 0x6028), }, /* PAS202BCB */ \
103 { USB_DEVICE(0x0c45, 0x6029), }, /* PAS106B */ \
104 { USB_DEVICE(0x0c45, 0x602a), }, /* HV7131D */ \
105 { USB_DEVICE(0x0c45, 0x602b), }, /* MI-0343 */ \
106 { USB_DEVICE(0x0c45, 0x602c), }, /* OV7620 */ \
107 { USB_DEVICE(0x0c45, 0x6030), }, /* MI03x */ \
108 { USB_DEVICE(0x0c45, 0x6080), }, \
109 { USB_DEVICE(0x0c45, 0x6082), }, /* MI0343 and MI0360 */ \
110 { USB_DEVICE(0x0c45, 0x6083), }, /* HV7131[D|E1] */ \
111 { USB_DEVICE(0x0c45, 0x6088), }, \
112 { USB_DEVICE(0x0c45, 0x608a), }, \
113 { USB_DEVICE(0x0c45, 0x608b), }, \
114 { USB_DEVICE(0x0c45, 0x608c), }, /* HV7131x */ \
115 { USB_DEVICE(0x0c45, 0x608e), }, /* CIS-VF10 */ \
116 { USB_DEVICE(0x0c45, 0x608f), }, /* OV7630 */ \
117 { USB_DEVICE(0x0c45, 0x60a0), }, \
118 { USB_DEVICE(0x0c45, 0x60a2), }, \
119 { USB_DEVICE(0x0c45, 0x60a3), }, \
120 { USB_DEVICE(0x0c45, 0x60a8), }, /* PAS106B */ \
121 { USB_DEVICE(0x0c45, 0x60aa), }, /* TAS5130D1B */ \
122 { USB_DEVICE(0x0c45, 0x60ab), }, /* TAS5110C1B */ \
123 { USB_DEVICE(0x0c45, 0x60ac), }, \
124 { USB_DEVICE(0x0c45, 0x60ae), }, \
125 { USB_DEVICE(0x0c45, 0x60af), }, /* PAS202BCB */ \
126 { USB_DEVICE(0x0c45, 0x60b0), }, \
127 { USB_DEVICE(0x0c45, 0x60b2), }, \
128 { USB_DEVICE(0x0c45, 0x60b3), }, \
129 { USB_DEVICE(0x0c45, 0x60b8), }, \
130 { USB_DEVICE(0x0c45, 0x60ba), }, \
131 { USB_DEVICE(0x0c45, 0x60bb), }, \
132 { USB_DEVICE(0x0c45, 0x60bc), }, \
133 { USB_DEVICE(0x0c45, 0x60be), }, \
137 /*****************************************************************************/
140 Read/write routines: they always return -1 on error, 0 or the read value
141 otherwise. NOTE that a real read operation is not supported by the SN9C10X
142 chip for some of its registers. To work around this problem, a pseudo-read
143 call is provided instead: it returns the last successfully written value
144 on the register (0 if it has never been written), the usual -1 on error.
147 /* The "try" I2C I/O versions are used when probing the sensor */
148 extern int sn9c102_i2c_try_read(struct sn9c102_device*,struct sn9c102_sensor*,
152 These must be used if and only if the sensor doesn't implement the standard
153 I2C protocol. There are a number of good reasons why you must use the
154 single-byte versions of these functions: do not abuse. The first function
155 writes n bytes, from data0 to datan, to registers 0x09 - 0x09+n of SN9C10X
156 chip. The second one programs the registers 0x09 and 0x10 with data0 and
157 data1, and places the n bytes read from the sensor register table in the
158 buffer pointed by 'buffer'. Both the functions return -1 on error; the write
159 version returns 0 on success, while the read version returns the first read
162 extern int sn9c102_i2c_try_raw_write(struct sn9c102_device* cam,
163 struct sn9c102_sensor* sensor, u8 n,
164 u8 data0, u8 data1, u8 data2, u8 data3,
166 extern int sn9c102_i2c_try_raw_read(struct sn9c102_device* cam,
167 struct sn9c102_sensor* sensor, u8 data0,
168 u8 data1, u8 n, u8 buffer[]);
170 /* To be used after the sensor struct has been attached to the camera struct */
171 extern int sn9c102_i2c_write(struct sn9c102_device*, u8 address, u8 value);
172 extern int sn9c102_i2c_read(struct sn9c102_device*, u8 address);
174 /* I/O on registers in the bridge. Could be used by the sensor methods too */
175 extern int sn9c102_write_reg(struct sn9c102_device*, u8 value, u16 index);
176 extern int sn9c102_pread_reg(struct sn9c102_device*, u16 index);
179 NOTE: there are no exported debugging functions. To uniform the output you
180 must use the dev_info()/dev_warn()/dev_err() macros defined in device.h,
181 already included here, the argument being the struct device 'dev' of the
182 sensor structure. Do NOT use these macros before the sensor is attached or
183 the kernel will crash! However, you should not need to notify the user about
184 common errors or other messages, since this is done by the master module.
187 /*****************************************************************************/
189 enum sn9c102_i2c_sysfs_ops {
190 SN9C102_I2C_READ = 0x01,
191 SN9C102_I2C_WRITE = 0x02,
194 enum sn9c102_i2c_frequency { /* sensors may support both the frequencies */
195 SN9C102_I2C_100KHZ = 0x01,
196 SN9C102_I2C_400KHZ = 0x02,
199 enum sn9c102_i2c_interface {
204 struct sn9c102_sensor {
205 char name[32], /* sensor name */
206 maintainer[64]; /* name of the mantainer <email> */
208 /* Supported operations through the 'sysfs' interface */
209 enum sn9c102_i2c_sysfs_ops sysfs_ops;
212 These sensor capabilities must be provided if the SN9C10X controller
213 needs to communicate through the sensor serial interface by using
214 at least one of the i2c functions available.
216 enum sn9c102_i2c_frequency frequency;
217 enum sn9c102_i2c_interface interface;
220 This identifier must be provided if the image sensor implements
221 the standard I2C protocol.
223 u8 i2c_slave_id; /* reg. 0x09 */
226 NOTE: Where not noted,most of the functions below are not mandatory.
227 Set to null if you do not implement them. If implemented,
228 they must return 0 on success, the proper error otherwise.
231 int (*init)(struct sn9c102_device* cam);
233 This function will be called after the sensor has been attached.
234 It should be used to initialize the sensor only, but may also
235 configure part of the SN9C10X chip if necessary. You don't need to
236 setup picture settings like brightness, contrast, etc.. here, if
237 the corrisponding controls are implemented (see below), since
238 they are adjusted in the core driver by calling the set_ctrl()
239 method after init(), where the arguments are the default values
240 specified in the v4l2_queryctrl list of supported controls;
241 Same suggestions apply for other settings, _if_ the corresponding
242 methods are present; if not, the initialization must configure the
243 sensor according to the default configuration structures below.
246 struct v4l2_queryctrl qctrl[V4L2_CID_LASTP1-V4L2_CID_BASE];
248 Optional list of default controls, defined as indicated in the
249 V4L2 API. Menu type controls are not handled by this interface.
252 int (*get_ctrl)(struct sn9c102_device* cam, struct v4l2_control* ctrl);
253 int (*set_ctrl)(struct sn9c102_device* cam,
254 const struct v4l2_control* ctrl);
256 You must implement at least the set_ctrl method if you have defined
257 the list above. The returned value must follow the V4L2
258 specifications for the VIDIOC_G|C_CTRL ioctls. V4L2_CID_H|VCENTER
259 are not supported by this driver, so do not implement them. Also,
260 you don't have to check whether the passed values are out of bounds,
261 given that this is done by the core module.
264 struct v4l2_cropcap cropcap;
266 Think the image sensor as a grid of R,G,B monochromatic pixels
267 disposed according to a particular Bayer pattern, which describes
268 the complete array of pixels, from (0,0) to (xmax, ymax). We will
269 use this coordinate system from now on. It is assumed the sensor
270 chip can be programmed to capture/transmit a subsection of that
271 array of pixels: we will call this subsection "active window".
272 It is not always true that the largest achievable active window can
273 cover the whole array of pixels. The V4L2 API defines another
274 area called "source rectangle", which, in turn, is a subrectangle of
275 the active window. The SN9C10X chip is always programmed to read the
277 The bounds of both the active window and the source rectangle are
278 specified in the cropcap substructures 'bounds' and 'defrect'.
279 By default, the source rectangle should cover the largest possible
280 area. Again, it is not always true that the largest source rectangle
281 can cover the entire active window, although it is a rare case for
282 the hardware we have. The bounds of the source rectangle _must_ be
283 multiple of 16 and must use the same coordinate system as indicated
284 before; their centers shall align initially.
285 If necessary, the sensor chip must be initialized during init() to
286 set the bounds of the active sensor window; however, by default, it
287 usually covers the largest achievable area (maxwidth x maxheight)
288 of pixels, so no particular initialization is needed, if you have
289 defined the correct default bounds in the structures.
290 See the V4L2 API for further details.
291 NOTE: once you have defined the bounds of the active window
292 (struct cropcap.bounds) you must not change them.anymore.
293 Only 'bounds' and 'defrect' fields are mandatory, other fields
297 int (*set_crop)(struct sn9c102_device* cam,
298 const struct v4l2_rect* rect);
300 To be called on VIDIOC_C_SETCROP. The core module always calls a
301 default routine which configures the appropriate SN9C10X regs (also
302 scaling), but you may need to override/adjust specific stuff.
303 'rect' contains width and height values that are multiple of 16: in
304 case you override the default function, you always have to program
305 the chip to match those values; on error return the corresponding
306 error code without rolling back.
307 NOTE: in case, you must program the SN9C10X chip to get rid of
308 blank pixels or blank lines at the _start_ of each line or
309 frame after each HSYNC or VSYNC, so that the image starts with
310 real RGB data (see regs 0x12, 0x13) (having set H_SIZE and,
311 V_SIZE you don't have to care about blank pixels or blank
312 lines at the end of each line or frame).
315 struct v4l2_pix_format pix_format;
317 What you have to define here are: 1) initial 'width' and 'height' of
318 the target rectangle 2) the initial 'pixelformat', which can be
319 either V4L2_PIX_FMT_SN9C10X (for compressed video) or
320 V4L2_PIX_FMT_SBGGR8 3) 'priv', which we'll be used to indicate the
321 number of bits per pixel for uncompressed video, 8 or 9 (despite the
322 current value of 'pixelformat').
323 NOTE 1: both 'width' and 'height' _must_ be either 1/1 or 1/2 or 1/4
324 of cropcap.defrect.width and cropcap.defrect.height. I
326 NOTE 2: The initial compression quality is defined by the first bit
327 of reg 0x17 during the initialization of the image sensor.
328 NOTE 3: as said above, you have to program the SN9C10X chip to get
329 rid of any blank pixels, so that the output of the sensor
330 matches the RGB bayer sequence (i.e. BGBGBG...GRGRGR).
333 int (*set_pix_format)(struct sn9c102_device* cam,
334 const struct v4l2_pix_format* pix);
336 To be called on VIDIOC_S_FMT, when switching from the SBGGR8 to
337 SN9C10X pixel format or viceversa. On error return the corresponding
338 error code without rolling back.
341 const struct device* dev;
343 This is the argument for dev_err(), dev_info() and dev_warn(). It
344 is used for debugging purposes. You must not access the struct
345 before the sensor is attached.
348 const struct usb_device* usbdev;
350 Points to the usb_device struct after the sensor is attached.
351 Do not touch unless you know what you are doing.
355 Do NOT write to the data below, it's READ ONLY. It is used by the
356 core module to store successfully updated values of the above
357 settings, for rollbacks..etc..in case of errors during atomic I/O
359 struct v4l2_queryctrl _qctrl[V4L2_CID_LASTP1-V4L2_CID_BASE];
360 struct v4l2_rect _rect;
363 /*****************************************************************************/
365 /* Private ioctl's for control settings supported by some image sensors */
366 #define SN9C102_V4L2_CID_DAC_MAGNITUDE V4L2_CID_PRIVATE_BASE
367 #define SN9C102_V4L2_CID_GREEN_BALANCE V4L2_CID_PRIVATE_BASE + 1
368 #define SN9C102_V4L2_CID_RESET_LEVEL V4L2_CID_PRIVATE_BASE + 2
369 #define SN9C102_V4L2_CID_PIXEL_BIAS_VOLTAGE V4L2_CID_PRIVATE_BASE + 3
371 #endif /* _SN9C102_SENSOR_H_ */