Blame - marvell/linux/drivers/input/misc/bma150.c - T108

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b.liu	e958203	2025-04-17 19:18:16 +0800	[diff] [blame^]	1	// SPDX-License-Identifier: GPL-2.0-or-later
				2	/*
				3	* Copyright (c) 2011 Bosch Sensortec GmbH
				4	* Copyright (c) 2011 Unixphere
				5	*
				6	* This driver adds support for Bosch Sensortec's digital acceleration
				7	* sensors BMA150 and SMB380.
				8	* The SMB380 is fully compatible with BMA150 and only differs in packaging.
				9	*
				10	* The datasheet for the BMA150 chip can be found here:
				11	* http://www.bosch-sensortec.com/content/language1/downloads/BST-BMA150-DS000-07.pdf
				12	*/
				13	#include <linux/kernel.h>
				14	#include <linux/module.h>
				15	#include <linux/i2c.h>
				16	#include <linux/input.h>
				17	#include <linux/input-polldev.h>
				18	#include <linux/interrupt.h>
				19	#include <linux/delay.h>
				20	#include <linux/slab.h>
				21	#include <linux/pm.h>
				22	#include <linux/pm_runtime.h>
				23	#include <linux/bma150.h>
				24
				25	#define ABSMAX_ACC_VAL 0x01FF
				26	#define ABSMIN_ACC_VAL -(ABSMAX_ACC_VAL)
				27
				28	/* Each axis is represented by a 2-byte data word */
				29	#define BMA150_XYZ_DATA_SIZE 6
				30
				31	/* Input poll interval in milliseconds */
				32	#define BMA150_POLL_INTERVAL 10
				33	#define BMA150_POLL_MAX 200
				34	#define BMA150_POLL_MIN 0
				35
				36	#define BMA150_MODE_NORMAL 0
				37	#define BMA150_MODE_SLEEP 2
				38	#define BMA150_MODE_WAKE_UP 3
				39
				40	/* Data register addresses */
				41	#define BMA150_DATA_0_REG 0x00
				42	#define BMA150_DATA_1_REG 0x01
				43	#define BMA150_DATA_2_REG 0x02
				44
				45	/* Control register addresses */
				46	#define BMA150_CTRL_0_REG 0x0A
				47	#define BMA150_CTRL_1_REG 0x0B
				48	#define BMA150_CTRL_2_REG 0x14
				49	#define BMA150_CTRL_3_REG 0x15
				50
				51	/* Configuration/Setting register addresses */
				52	#define BMA150_CFG_0_REG 0x0C
				53	#define BMA150_CFG_1_REG 0x0D
				54	#define BMA150_CFG_2_REG 0x0E
				55	#define BMA150_CFG_3_REG 0x0F
				56	#define BMA150_CFG_4_REG 0x10
				57	#define BMA150_CFG_5_REG 0x11
				58
				59	#define BMA150_CHIP_ID 2
				60	#define BMA150_CHIP_ID_REG BMA150_DATA_0_REG
				61
				62	#define BMA150_ACC_X_LSB_REG BMA150_DATA_2_REG
				63
				64	#define BMA150_SLEEP_POS 0
				65	#define BMA150_SLEEP_MSK 0x01
				66	#define BMA150_SLEEP_REG BMA150_CTRL_0_REG
				67
				68	#define BMA150_BANDWIDTH_POS 0
				69	#define BMA150_BANDWIDTH_MSK 0x07
				70	#define BMA150_BANDWIDTH_REG BMA150_CTRL_2_REG
				71
				72	#define BMA150_RANGE_POS 3
				73	#define BMA150_RANGE_MSK 0x18
				74	#define BMA150_RANGE_REG BMA150_CTRL_2_REG
				75
				76	#define BMA150_WAKE_UP_POS 0
				77	#define BMA150_WAKE_UP_MSK 0x01
				78	#define BMA150_WAKE_UP_REG BMA150_CTRL_3_REG
				79
				80	#define BMA150_SW_RES_POS 1
				81	#define BMA150_SW_RES_MSK 0x02
				82	#define BMA150_SW_RES_REG BMA150_CTRL_0_REG
				83
				84	/* Any-motion interrupt register fields */
				85	#define BMA150_ANY_MOTION_EN_POS 6
				86	#define BMA150_ANY_MOTION_EN_MSK 0x40
				87	#define BMA150_ANY_MOTION_EN_REG BMA150_CTRL_1_REG
				88
				89	#define BMA150_ANY_MOTION_DUR_POS 6
				90	#define BMA150_ANY_MOTION_DUR_MSK 0xC0
				91	#define BMA150_ANY_MOTION_DUR_REG BMA150_CFG_5_REG
				92
				93	#define BMA150_ANY_MOTION_THRES_REG BMA150_CFG_4_REG
				94
				95	/* Advanced interrupt register fields */
				96	#define BMA150_ADV_INT_EN_POS 6
				97	#define BMA150_ADV_INT_EN_MSK 0x40
				98	#define BMA150_ADV_INT_EN_REG BMA150_CTRL_3_REG
				99
				100	/* High-G interrupt register fields */
				101	#define BMA150_HIGH_G_EN_POS 1
				102	#define BMA150_HIGH_G_EN_MSK 0x02
				103	#define BMA150_HIGH_G_EN_REG BMA150_CTRL_1_REG
				104
				105	#define BMA150_HIGH_G_HYST_POS 3
				106	#define BMA150_HIGH_G_HYST_MSK 0x38
				107	#define BMA150_HIGH_G_HYST_REG BMA150_CFG_5_REG
				108
				109	#define BMA150_HIGH_G_DUR_REG BMA150_CFG_3_REG
				110	#define BMA150_HIGH_G_THRES_REG BMA150_CFG_2_REG
				111
				112	/* Low-G interrupt register fields */
				113	#define BMA150_LOW_G_EN_POS 0
				114	#define BMA150_LOW_G_EN_MSK 0x01
				115	#define BMA150_LOW_G_EN_REG BMA150_CTRL_1_REG
				116
				117	#define BMA150_LOW_G_HYST_POS 0
				118	#define BMA150_LOW_G_HYST_MSK 0x07
				119	#define BMA150_LOW_G_HYST_REG BMA150_CFG_5_REG
				120
				121	#define BMA150_LOW_G_DUR_REG BMA150_CFG_1_REG
				122	#define BMA150_LOW_G_THRES_REG BMA150_CFG_0_REG
				123
				124	struct bma150_data {
				125	struct i2c_client *client;
				126	struct input_polled_dev *input_polled;
				127	struct input_dev *input;
				128	u8 mode;
				129	};
				130
				131	/*
				132	* The settings for the given range, bandwidth and interrupt features
				133	* are stated and verified by Bosch Sensortec where they are configured
				134	* to provide a generic sensitivity performance.
				135	*/
				136	static const struct bma150_cfg default_cfg = {
				137	.any_motion_int = 1,
				138	.hg_int = 1,
				139	.lg_int = 1,
				140	.any_motion_dur = 0,
				141	.any_motion_thres = 0,
				142	.hg_hyst = 0,
				143	.hg_dur = 150,
				144	.hg_thres = 160,
				145	.lg_hyst = 0,
				146	.lg_dur = 150,
				147	.lg_thres = 20,
				148	.range = BMA150_RANGE_2G,
				149	.bandwidth = BMA150_BW_50HZ
				150	};
				151
				152	static int bma150_write_byte(struct i2c_client *client, u8 reg, u8 val)
				153	{
				154	s32 ret;
				155
				156	/* As per specification, disable irq in between register writes */
				157	if (client->irq)
				158	disable_irq_nosync(client->irq);
				159
				160	ret = i2c_smbus_write_byte_data(client, reg, val);
				161
				162	if (client->irq)
				163	enable_irq(client->irq);
				164
				165	return ret;
				166	}
				167
				168	static int bma150_set_reg_bits(struct i2c_client *client,
				169	int val, int shift, u8 mask, u8 reg)
				170	{
				171	int data;
				172
				173	data = i2c_smbus_read_byte_data(client, reg);
				174	if (data < 0)
				175	return data;
				176
				177	data = (data & ~mask) \| ((val << shift) & mask);
				178	return bma150_write_byte(client, reg, data);
				179	}
				180
				181	static int bma150_set_mode(struct bma150_data *bma150, u8 mode)
				182	{
				183	int error;
				184
				185	error = bma150_set_reg_bits(bma150->client, mode, BMA150_WAKE_UP_POS,
				186	BMA150_WAKE_UP_MSK, BMA150_WAKE_UP_REG);
				187	if (error)
				188	return error;
				189
				190	error = bma150_set_reg_bits(bma150->client, mode, BMA150_SLEEP_POS,
				191	BMA150_SLEEP_MSK, BMA150_SLEEP_REG);
				192	if (error)
				193	return error;
				194
				195	if (mode == BMA150_MODE_NORMAL)
				196	usleep_range(2000, 2100);
				197
				198	bma150->mode = mode;
				199	return 0;
				200	}
				201
				202	static int bma150_soft_reset(struct bma150_data *bma150)
				203	{
				204	int error;
				205
				206	error = bma150_set_reg_bits(bma150->client, 1, BMA150_SW_RES_POS,
				207	BMA150_SW_RES_MSK, BMA150_SW_RES_REG);
				208	if (error)
				209	return error;
				210
				211	usleep_range(2000, 2100);
				212	return 0;
				213	}
				214
				215	static int bma150_set_range(struct bma150_data *bma150, u8 range)
				216	{
				217	return bma150_set_reg_bits(bma150->client, range, BMA150_RANGE_POS,
				218	BMA150_RANGE_MSK, BMA150_RANGE_REG);
				219	}
				220
				221	static int bma150_set_bandwidth(struct bma150_data *bma150, u8 bw)
				222	{
				223	return bma150_set_reg_bits(bma150->client, bw, BMA150_BANDWIDTH_POS,
				224	BMA150_BANDWIDTH_MSK, BMA150_BANDWIDTH_REG);
				225	}
				226
				227	static int bma150_set_low_g_interrupt(struct bma150_data *bma150,
				228	u8 enable, u8 hyst, u8 dur, u8 thres)
				229	{
				230	int error;
				231
				232	error = bma150_set_reg_bits(bma150->client, hyst,
				233	BMA150_LOW_G_HYST_POS, BMA150_LOW_G_HYST_MSK,
				234	BMA150_LOW_G_HYST_REG);
				235	if (error)
				236	return error;
				237
				238	error = bma150_write_byte(bma150->client, BMA150_LOW_G_DUR_REG, dur);
				239	if (error)
				240	return error;
				241
				242	error = bma150_write_byte(bma150->client, BMA150_LOW_G_THRES_REG, thres);
				243	if (error)
				244	return error;
				245
				246	return bma150_set_reg_bits(bma150->client, !!enable,
				247	BMA150_LOW_G_EN_POS, BMA150_LOW_G_EN_MSK,
				248	BMA150_LOW_G_EN_REG);
				249	}
				250
				251	static int bma150_set_high_g_interrupt(struct bma150_data *bma150,
				252	u8 enable, u8 hyst, u8 dur, u8 thres)
				253	{
				254	int error;
				255
				256	error = bma150_set_reg_bits(bma150->client, hyst,
				257	BMA150_HIGH_G_HYST_POS, BMA150_HIGH_G_HYST_MSK,
				258	BMA150_HIGH_G_HYST_REG);
				259	if (error)
				260	return error;
				261
				262	error = bma150_write_byte(bma150->client,
				263	BMA150_HIGH_G_DUR_REG, dur);
				264	if (error)
				265	return error;
				266
				267	error = bma150_write_byte(bma150->client,
				268	BMA150_HIGH_G_THRES_REG, thres);
				269	if (error)
				270	return error;
				271
				272	return bma150_set_reg_bits(bma150->client, !!enable,
				273	BMA150_HIGH_G_EN_POS, BMA150_HIGH_G_EN_MSK,
				274	BMA150_HIGH_G_EN_REG);
				275	}
				276
				277
				278	static int bma150_set_any_motion_interrupt(struct bma150_data *bma150,
				279	u8 enable, u8 dur, u8 thres)
				280	{
				281	int error;
				282
				283	error = bma150_set_reg_bits(bma150->client, dur,
				284	BMA150_ANY_MOTION_DUR_POS,
				285	BMA150_ANY_MOTION_DUR_MSK,
				286	BMA150_ANY_MOTION_DUR_REG);
				287	if (error)
				288	return error;
				289
				290	error = bma150_write_byte(bma150->client,
				291	BMA150_ANY_MOTION_THRES_REG, thres);
				292	if (error)
				293	return error;
				294
				295	error = bma150_set_reg_bits(bma150->client, !!enable,
				296	BMA150_ADV_INT_EN_POS, BMA150_ADV_INT_EN_MSK,
				297	BMA150_ADV_INT_EN_REG);
				298	if (error)
				299	return error;
				300
				301	return bma150_set_reg_bits(bma150->client, !!enable,
				302	BMA150_ANY_MOTION_EN_POS,
				303	BMA150_ANY_MOTION_EN_MSK,
				304	BMA150_ANY_MOTION_EN_REG);
				305	}
				306
				307	static void bma150_report_xyz(struct bma150_data *bma150)
				308	{
				309	u8 data[BMA150_XYZ_DATA_SIZE];
				310	s16 x, y, z;
				311	s32 ret;
				312
				313	ret = i2c_smbus_read_i2c_block_data(bma150->client,
				314	BMA150_ACC_X_LSB_REG, BMA150_XYZ_DATA_SIZE, data);
				315	if (ret != BMA150_XYZ_DATA_SIZE)
				316	return;
				317
				318	x = ((0xc0 & data[0]) >> 6) \| (data[1] << 2);
				319	y = ((0xc0 & data[2]) >> 6) \| (data[3] << 2);
				320	z = ((0xc0 & data[4]) >> 6) \| (data[5] << 2);
				321
				322	x = sign_extend32(x, 9);
				323	y = sign_extend32(y, 9);
				324	z = sign_extend32(z, 9);
				325
				326	input_report_abs(bma150->input, ABS_X, x);
				327	input_report_abs(bma150->input, ABS_Y, y);
				328	input_report_abs(bma150->input, ABS_Z, z);
				329	input_sync(bma150->input);
				330	}
				331
				332	static irqreturn_t bma150_irq_thread(int irq, void *dev)
				333	{
				334	bma150_report_xyz(dev);
				335
				336	return IRQ_HANDLED;
				337	}
				338
				339	static void bma150_poll(struct input_polled_dev *dev)
				340	{
				341	bma150_report_xyz(dev->private);
				342	}
				343
				344	static int bma150_open(struct bma150_data *bma150)
				345	{
				346	int error;
				347
				348	error = pm_runtime_get_sync(&bma150->client->dev);
				349	if (error < 0 && error != -ENOSYS)
				350	return error;
				351
				352	/*
				353	* See if runtime PM woke up the device. If runtime PM
				354	* is disabled we need to do it ourselves.
				355	*/
				356	if (bma150->mode != BMA150_MODE_NORMAL) {
				357	error = bma150_set_mode(bma150, BMA150_MODE_NORMAL);
				358	if (error)
				359	return error;
				360	}
				361
				362	return 0;
				363	}
				364
				365	static void bma150_close(struct bma150_data *bma150)
				366	{
				367	pm_runtime_put_sync(&bma150->client->dev);
				368
				369	if (bma150->mode != BMA150_MODE_SLEEP)
				370	bma150_set_mode(bma150, BMA150_MODE_SLEEP);
				371	}
				372
				373	static int bma150_irq_open(struct input_dev *input)
				374	{
				375	struct bma150_data *bma150 = input_get_drvdata(input);
				376
				377	return bma150_open(bma150);
				378	}
				379
				380	static void bma150_irq_close(struct input_dev *input)
				381	{
				382	struct bma150_data *bma150 = input_get_drvdata(input);
				383
				384	bma150_close(bma150);
				385	}
				386
				387	static void bma150_poll_open(struct input_polled_dev *ipoll_dev)
				388	{
				389	struct bma150_data *bma150 = ipoll_dev->private;
				390
				391	bma150_open(bma150);
				392	}
				393
				394	static void bma150_poll_close(struct input_polled_dev *ipoll_dev)
				395	{
				396	struct bma150_data *bma150 = ipoll_dev->private;
				397
				398	bma150_close(bma150);
				399	}
				400
				401	static int bma150_initialize(struct bma150_data *bma150,
				402	const struct bma150_cfg *cfg)
				403	{
				404	int error;
				405
				406	error = bma150_soft_reset(bma150);
				407	if (error)
				408	return error;
				409
				410	error = bma150_set_bandwidth(bma150, cfg->bandwidth);
				411	if (error)
				412	return error;
				413
				414	error = bma150_set_range(bma150, cfg->range);
				415	if (error)
				416	return error;
				417
				418	if (bma150->client->irq) {
				419	error = bma150_set_any_motion_interrupt(bma150,
				420	cfg->any_motion_int,
				421	cfg->any_motion_dur,
				422	cfg->any_motion_thres);
				423	if (error)
				424	return error;
				425
				426	error = bma150_set_high_g_interrupt(bma150,
				427	cfg->hg_int, cfg->hg_hyst,
				428	cfg->hg_dur, cfg->hg_thres);
				429	if (error)
				430	return error;
				431
				432	error = bma150_set_low_g_interrupt(bma150,
				433	cfg->lg_int, cfg->lg_hyst,
				434	cfg->lg_dur, cfg->lg_thres);
				435	if (error)
				436	return error;
				437	}
				438
				439	return bma150_set_mode(bma150, BMA150_MODE_SLEEP);
				440	}
				441
				442	static void bma150_init_input_device(struct bma150_data *bma150,
				443	struct input_dev *idev)
				444	{
				445	idev->name = BMA150_DRIVER;
				446	idev->phys = BMA150_DRIVER "/input0";
				447	idev->id.bustype = BUS_I2C;
				448	idev->dev.parent = &bma150->client->dev;
				449
				450	idev->evbit[0] = BIT_MASK(EV_ABS);
				451	input_set_abs_params(idev, ABS_X, ABSMIN_ACC_VAL, ABSMAX_ACC_VAL, 0, 0);
				452	input_set_abs_params(idev, ABS_Y, ABSMIN_ACC_VAL, ABSMAX_ACC_VAL, 0, 0);
				453	input_set_abs_params(idev, ABS_Z, ABSMIN_ACC_VAL, ABSMAX_ACC_VAL, 0, 0);
				454	}
				455
				456	static int bma150_register_input_device(struct bma150_data *bma150)
				457	{
				458	struct input_dev *idev;
				459	int error;
				460
				461	idev = input_allocate_device();
				462	if (!idev)
				463	return -ENOMEM;
				464
				465	bma150_init_input_device(bma150, idev);
				466
				467	idev->open = bma150_irq_open;
				468	idev->close = bma150_irq_close;
				469	input_set_drvdata(idev, bma150);
				470
				471	bma150->input = idev;
				472
				473	error = input_register_device(idev);
				474	if (error) {
				475	input_free_device(idev);
				476	return error;
				477	}
				478
				479	return 0;
				480	}
				481
				482	static int bma150_register_polled_device(struct bma150_data *bma150)
				483	{
				484	struct input_polled_dev *ipoll_dev;
				485	int error;
				486
				487	ipoll_dev = input_allocate_polled_device();
				488	if (!ipoll_dev)
				489	return -ENOMEM;
				490
				491	ipoll_dev->private = bma150;
				492	ipoll_dev->open = bma150_poll_open;
				493	ipoll_dev->close = bma150_poll_close;
				494	ipoll_dev->poll = bma150_poll;
				495	ipoll_dev->poll_interval = BMA150_POLL_INTERVAL;
				496	ipoll_dev->poll_interval_min = BMA150_POLL_MIN;
				497	ipoll_dev->poll_interval_max = BMA150_POLL_MAX;
				498
				499	bma150_init_input_device(bma150, ipoll_dev->input);
				500
				501	bma150->input_polled = ipoll_dev;
				502	bma150->input = ipoll_dev->input;
				503
				504	error = input_register_polled_device(ipoll_dev);
				505	if (error) {
				506	input_free_polled_device(ipoll_dev);
				507	return error;
				508	}
				509
				510	return 0;
				511	}
				512
				513	static int bma150_probe(struct i2c_client *client,
				514	const struct i2c_device_id *id)
				515	{
				516	const struct bma150_platform_data *pdata =
				517	dev_get_platdata(&client->dev);
				518	const struct bma150_cfg *cfg;
				519	struct bma150_data *bma150;
				520	int chip_id;
				521	int error;
				522
				523	if (!i2c_check_functionality(client->adapter, I2C_FUNC_I2C)) {
				524	dev_err(&client->dev, "i2c_check_functionality error\n");
				525	return -EIO;
				526	}
				527
				528	chip_id = i2c_smbus_read_byte_data(client, BMA150_CHIP_ID_REG);
				529	if (chip_id != BMA150_CHIP_ID) {
				530	dev_err(&client->dev, "BMA150 chip id error: %d\n", chip_id);
				531	return -EINVAL;
				532	}
				533
				534	bma150 = kzalloc(sizeof(struct bma150_data), GFP_KERNEL);
				535	if (!bma150)
				536	return -ENOMEM;
				537
				538	bma150->client = client;
				539
				540	if (pdata) {
				541	if (pdata->irq_gpio_cfg) {
				542	error = pdata->irq_gpio_cfg();
				543	if (error) {
				544	dev_err(&client->dev,
				545	"IRQ GPIO conf. error %d, error %d\n",
				546	client->irq, error);
				547	goto err_free_mem;
				548	}
				549	}
				550	cfg = &pdata->cfg;
				551	} else {
				552	cfg = &default_cfg;
				553	}
				554
				555	error = bma150_initialize(bma150, cfg);
				556	if (error)
				557	goto err_free_mem;
				558
				559	if (client->irq > 0) {
				560	error = bma150_register_input_device(bma150);
				561	if (error)
				562	goto err_free_mem;
				563
				564	error = request_threaded_irq(client->irq,
				565	NULL, bma150_irq_thread,
				566	IRQF_TRIGGER_RISING \| IRQF_ONESHOT,
				567	BMA150_DRIVER, bma150);
				568	if (error) {
				569	dev_err(&client->dev,
				570	"irq request failed %d, error %d\n",
				571	client->irq, error);
				572	input_unregister_device(bma150->input);
				573	goto err_free_mem;
				574	}
				575	} else {
				576	error = bma150_register_polled_device(bma150);
				577	if (error)
				578	goto err_free_mem;
				579	}
				580
				581	i2c_set_clientdata(client, bma150);
				582
				583	pm_runtime_enable(&client->dev);
				584
				585	return 0;
				586
				587	err_free_mem:
				588	kfree(bma150);
				589	return error;
				590	}
				591
				592	static int bma150_remove(struct i2c_client *client)
				593	{
				594	struct bma150_data *bma150 = i2c_get_clientdata(client);
				595
				596	pm_runtime_disable(&client->dev);
				597
				598	if (client->irq > 0) {
				599	free_irq(client->irq, bma150);
				600	input_unregister_device(bma150->input);
				601	} else {
				602	input_unregister_polled_device(bma150->input_polled);
				603	input_free_polled_device(bma150->input_polled);
				604	}
				605
				606	kfree(bma150);
				607
				608	return 0;
				609	}
				610
				611	#ifdef CONFIG_PM
				612	static int bma150_suspend(struct device *dev)
				613	{
				614	struct i2c_client *client = to_i2c_client(dev);
				615	struct bma150_data *bma150 = i2c_get_clientdata(client);
				616
				617	return bma150_set_mode(bma150, BMA150_MODE_SLEEP);
				618	}
				619
				620	static int bma150_resume(struct device *dev)
				621	{
				622	struct i2c_client *client = to_i2c_client(dev);
				623	struct bma150_data *bma150 = i2c_get_clientdata(client);
				624
				625	return bma150_set_mode(bma150, BMA150_MODE_NORMAL);
				626	}
				627	#endif
				628
				629	static UNIVERSAL_DEV_PM_OPS(bma150_pm, bma150_suspend, bma150_resume, NULL);
				630
				631	static const struct i2c_device_id bma150_id[] = {
				632	{ "bma150", 0 },
				633	{ "smb380", 0 },
				634	{ "bma023", 0 },
				635	{ }
				636	};
				637
				638	MODULE_DEVICE_TABLE(i2c, bma150_id);
				639
				640	static struct i2c_driver bma150_driver = {
				641	.driver = {
				642	.name = BMA150_DRIVER,
				643	.pm = &bma150_pm,
				644	},
				645	.class = I2C_CLASS_HWMON,
				646	.id_table = bma150_id,
				647	.probe = bma150_probe,
				648	.remove = bma150_remove,
				649	};
				650
				651	module_i2c_driver(bma150_driver);
				652
				653	MODULE_AUTHOR("Albert Zhang <xu.zhang@bosch-sensortec.com>");
				654	MODULE_DESCRIPTION("BMA150 driver");
				655	MODULE_LICENSE("GPL");