xref: /linux/Documentation/ABI/testing/sysfs-firmware-acpi (revision 6f52b16c5b29b89d92c0e7236f4655dc8491ad70)
1What:		/sys/firmware/acpi/bgrt/
2Date:		January 2012
3Contact:	Matthew Garrett <mjg@redhat.com>
4Description:
5		The BGRT is an ACPI 5.0 feature that allows the OS
6		to obtain a copy of the firmware boot splash and
7		some associated metadata. This is intended to be used
8		by boot splash applications in order to interact with
9		the firmware boot splash in order to avoid jarring
10		transitions.
11
12		image: The image bitmap. Currently a 32-bit BMP.
13		status: 1 if the image is valid, 0 if firmware invalidated it.
14		type: 0 indicates image is in BMP format.
15		version: The version of the BGRT. Currently 1.
16		xoffset: The number of pixels between the left of the screen
17			 and the left edge of the image.
18		yoffset: The number of pixels between the top of the screen
19			 and the top edge of the image.
20
21What:		/sys/firmware/acpi/hotplug/
22Date:		February 2013
23Contact:	Rafael J. Wysocki <rafael.j.wysocki@intel.com>
24Description:
25		There are separate hotplug profiles for different classes of
26		devices supported by ACPI, such as containers, memory modules,
27		processors, PCI root bridges etc.  A hotplug profile for a given
28		class of devices is a collection of settings defining the way
29		that class of devices will be handled by the ACPI core hotplug
30		code.  Those profiles are represented in sysfs as subdirectories
31		of /sys/firmware/acpi/hotplug/.
32
33		The following setting is available to user space for each
34		hotplug profile:
35
36		enabled: If set, the ACPI core will handle notifications of
37			hotplug events associated with the given class of
38			devices and will allow those devices to be ejected with
39			the help of the _EJ0 control method.  Unsetting it
40			effectively disables hotplug for the correspoinding
41			class of devices.
42
43		The value of the above attribute is an integer number: 1 (set)
44		or 0 (unset).  Attempts to write any other values to it will
45		cause -EINVAL to be returned.
46
47What:		/sys/firmware/acpi/interrupts/
48Date:		February 2008
49Contact:	Len Brown <lenb@kernel.org>
50Description:
51		All ACPI interrupts are handled via a single IRQ,
52		the System Control Interrupt (SCI), which appears
53		as "acpi" in /proc/interrupts.
54
55		However, one of the main functions of ACPI is to make
56		the platform understand random hardware without
57		special driver support.  So while the SCI handles a few
58		well known (fixed feature) interrupts sources, such
59		as the power button, it can also handle a variable
60		number of a "General Purpose Events" (GPE).
61
62		A GPE vectors to a specified handler in AML, which
63		can do a anything the BIOS writer wants from
64		OS context.  GPE 0x12, for example, would vector
65		to a level or edge handler called _L12 or _E12.
66		The handler may do its business and return.
67		Or the handler may send send a Notify event
68		to a Linux device driver registered on an ACPI device,
69		such as a battery, or a processor.
70
71		To figure out where all the SCI's are coming from,
72		/sys/firmware/acpi/interrupts contains a file listing
73		every possible source, and the count of how many
74		times it has triggered.
75
76		$ cd /sys/firmware/acpi/interrupts
77		$ grep . *
78		error:	     0
79		ff_gbl_lock:	   0   enable
80		ff_pmtimer:	  0  invalid
81		ff_pwr_btn:	  0   enable
82		ff_rt_clk:	 2  disable
83		ff_slp_btn:	  0  invalid
84		gpe00:	     0	invalid
85		gpe01:	     0	 enable
86		gpe02:	   108	 enable
87		gpe03:	     0	invalid
88		gpe04:	     0	invalid
89		gpe05:	     0	invalid
90		gpe06:	     0	 enable
91		gpe07:	     0	 enable
92		gpe08:	     0	invalid
93		gpe09:	     0	invalid
94		gpe0A:	     0	invalid
95		gpe0B:	     0	invalid
96		gpe0C:	     0	invalid
97		gpe0D:	     0	invalid
98		gpe0E:	     0	invalid
99		gpe0F:	     0	invalid
100		gpe10:	     0	invalid
101		gpe11:	     0	invalid
102		gpe12:	     0	invalid
103		gpe13:	     0	invalid
104		gpe14:	     0	invalid
105		gpe15:	     0	invalid
106		gpe16:	     0	invalid
107		gpe17:	  1084	 enable
108		gpe18:	     0	 enable
109		gpe19:	     0	invalid
110		gpe1A:	     0	invalid
111		gpe1B:	     0	invalid
112		gpe1C:	     0	invalid
113		gpe1D:	     0	invalid
114		gpe1E:	     0	invalid
115		gpe1F:	     0	invalid
116		gpe_all:    1192
117		sci:	1194
118		sci_not:     0
119
120		sci - The number of times the ACPI SCI
121		has been called and claimed an interrupt.
122
123		sci_not - The number of times the ACPI SCI
124		has been called and NOT claimed an interrupt.
125
126		gpe_all - count of SCI caused by GPEs.
127
128		gpeXX - count for individual GPE source
129
130		ff_gbl_lock - Global Lock
131
132		ff_pmtimer - PM Timer
133
134		ff_pwr_btn - Power Button
135
136		ff_rt_clk - Real Time Clock
137
138		ff_slp_btn - Sleep Button
139
140		error - an interrupt that can't be accounted for above.
141
142		invalid: it's either a GPE or a Fixed Event that
143			doesn't have an event handler.
144
145		disable: the GPE/Fixed Event is valid but disabled.
146
147		enable: the GPE/Fixed Event is valid and enabled.
148
149		Root has permission to clear any of these counters.  Eg.
150		# echo 0 > gpe11
151
152		All counters can be cleared by clearing the total "sci":
153		# echo 0 > sci
154
155		None of these counters has an effect on the function
156		of the system, they are simply statistics.
157
158		Besides this, user can also write specific strings to these files
159		to enable/disable/clear ACPI interrupts in user space, which can be
160		used to debug some ACPI interrupt storm issues.
161
162		Note that only writing to VALID GPE/Fixed Event is allowed,
163		i.e. user can only change the status of runtime GPE and
164		Fixed Event with event handler installed.
165
166		Let's take power button fixed event for example, please kill acpid
167		and other user space applications so that the machine won't shutdown
168		when pressing the power button.
169		# cat ff_pwr_btn
170		0	enabled
171		# press the power button for 3 times;
172		# cat ff_pwr_btn
173		3	enabled
174		# echo disable > ff_pwr_btn
175		# cat ff_pwr_btn
176		3	disabled
177		# press the power button for 3 times;
178		# cat ff_pwr_btn
179		3	disabled
180		# echo enable > ff_pwr_btn
181		# cat ff_pwr_btn
182		4	enabled
183		/*
184		 * this is because the status bit is set even if the enable bit is cleared,
185		 * and it triggers an ACPI fixed event when the enable bit is set again
186		 */
187		# press the power button for 3 times;
188		# cat ff_pwr_btn
189		7	enabled
190		# echo disable > ff_pwr_btn
191		# press the power button for 3 times;
192		# echo clear > ff_pwr_btn	/* clear the status bit */
193		# echo disable > ff_pwr_btn
194		# cat ff_pwr_btn
195		7	enabled
196
197