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1 /*
2 * consumer.h -- SoC Regulator consumer support.
3 *
4 * Copyright (C) 2007, 2008 Wolfson Microelectronics PLC.
5 *
6 * Author: Liam Girdwood <lrg@slimlogic.co.uk>
7 *
8 * This program is free software; you can redistribute it and/or modify
9 * it under the terms of the GNU General Public License version 2 as
10 * published by the Free Software Foundation.
11 *
12 * Regulator Consumer Interface.
13 *
14 * A Power Management Regulator framework for SoC based devices.
15 * Features:-
16 * o Voltage and current level control.
17 * o Operating mode control.
18 * o Regulator status.
19 * o sysfs entries for showing client devices and status
20 *
21 * EXPERIMENTAL FEATURES:
22 * Dynamic Regulator operating Mode Switching (DRMS) - allows regulators
23 * to use most efficient operating mode depending upon voltage and load and
24 * is transparent to client drivers.
25 *
26 * e.g. Devices x,y,z share regulator r. Device x and y draw 20mA each during
27 * IO and 1mA at idle. Device z draws 100mA when under load and 5mA when
28 * idling. Regulator r has > 90% efficiency in NORMAL mode at loads > 100mA
29 * but this drops rapidly to 60% when below 100mA. Regulator r has > 90%
30 * efficiency in IDLE mode at loads < 10mA. Thus regulator r will operate
31 * in normal mode for loads > 10mA and in IDLE mode for load <= 10mA.
32 *
33 */
35 #ifndef __LINUX_REGULATOR_CONSUMER_H_
36 #define __LINUX_REGULATOR_CONSUMER_H_
38 #include <linux/device.h>
40 /*
41 * Regulator operating modes.
42 *
43 * Regulators can run in a variety of different operating modes depending on
44 * output load. This allows further system power savings by selecting the
45 * best (and most efficient) regulator mode for a desired load.
46 *
47 * Most drivers will only care about NORMAL. The modes below are generic and
48 * will probably not match the naming convention of your regulator data sheet
49 * but should match the use cases in the datasheet.
50 *
51 * In order of power efficiency (least efficient at top).
52 *
53 * Mode Description
54 * FAST Regulator can handle fast changes in it's load.
55 * e.g. useful in CPU voltage & frequency scaling where
56 * load can quickly increase with CPU frequency increases.
57 *
58 * NORMAL Normal regulator power supply mode. Most drivers will
59 * use this mode.
60 *
61 * IDLE Regulator runs in a more efficient mode for light
62 * loads. Can be used for devices that have a low power
63 * requirement during periods of inactivity. This mode
64 * may be more noisy than NORMAL and may not be able
65 * to handle fast load switching.
66 *
67 * STANDBY Regulator runs in the most efficient mode for very
68 * light loads. Can be used by devices when they are
69 * in a sleep/standby state. This mode is likely to be
70 * the most noisy and may not be able to handle fast load
71 * switching.
72 *
73 * NOTE: Most regulators will only support a subset of these modes. Some
74 * will only just support NORMAL.
75 *
76 * These modes can be OR'ed together to make up a mask of valid register modes.
77 */
79 #define REGULATOR_MODE_FAST 0x1
80 #define REGULATOR_MODE_NORMAL 0x2
81 #define REGULATOR_MODE_IDLE 0x4
82 #define REGULATOR_MODE_STANDBY 0x8
84 /*
85 * Regulator notifier events.
86 *
87 * UNDER_VOLTAGE Regulator output is under voltage.
88 * OVER_CURRENT Regulator output current is too high.
89 * REGULATION_OUT Regulator output is out of regulation.
90 * FAIL Regulator output has failed.
91 * OVER_TEMP Regulator over temp.
92 * FORCE_DISABLE Regulator forcibly shut down by software.
93 * VOLTAGE_CHANGE Regulator voltage changed.
94 * DISABLE Regulator was disabled.
95 *
96 * NOTE: These events can be OR'ed together when passed into handler.
97 */
99 #define REGULATOR_EVENT_UNDER_VOLTAGE 0x01
100 #define REGULATOR_EVENT_OVER_CURRENT 0x02
101 #define REGULATOR_EVENT_REGULATION_OUT 0x04
102 #define REGULATOR_EVENT_FAIL 0x08
103 #define REGULATOR_EVENT_OVER_TEMP 0x10
104 #define REGULATOR_EVENT_FORCE_DISABLE 0x20
105 #define REGULATOR_EVENT_VOLTAGE_CHANGE 0x40
106 #define REGULATOR_EVENT_DISABLE 0x80
110 /**
111 * struct regulator_bulk_data - Data used for bulk regulator operations.
112 *
113 * @supply: The name of the supply. Initialised by the user before
114 * using the bulk regulator APIs.
115 * @consumer: The regulator consumer for the supply. This will be managed
116 * by the bulk API.
117 *
118 * The regulator APIs provide a series of regulator_bulk_() API calls as
119 * a convenience to consumers which require multiple supplies. This
120 * structure is used to manage data for these calls.
121 */
125 };
127 #if defined(CONFIG_REGULATOR)
129 /* regulator get and put */
136 /* regulator output control and status */
168 /* regulator notifier block */
174 /* driver data - core doesn't touch */
178 #else
180 /*
181 * Make sure client drivers will still build on systems with no software
182 * controllable voltage or current regulators.
183 */
186 {
187 /* Nothing except the stubbed out regulator API should be
188 * looking at the value except to check if it is an error
189 * value. Drivers are free to handle NULL specifically by
190 * skipping all regulator API calls, but they don't have to.
191 * Drivers which don't, should make sure they properly handle
192 * corner cases of the API, such as regulator_get_voltage()
193 * returning 0.
194 */
196 }
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301 #endif
303 #endif