xref: /freebsd/sys/contrib/device-tree/Bindings/opp/opp.txt (revision 5ca8e32633c4ffbbcd6762e5888b6a4ba0708c6c)
1Generic OPP (Operating Performance Points) Bindings
2----------------------------------------------------
3
4Devices work at voltage-current-frequency combinations and some implementations
5have the liberty of choosing these. These combinations are called Operating
6Performance Points aka OPPs. This document defines bindings for these OPPs
7applicable across wide range of devices. For illustration purpose, this document
8uses CPU as a device.
9
10This document contain multiple versions of OPP binding and only one of them
11should be used per device.
12
13Binding 1: operating-points
14============================
15
16This binding only supports voltage-frequency pairs.
17
18Properties:
19- operating-points: An array of 2-tuples items, and each item consists
20  of frequency and voltage like <freq-kHz vol-uV>.
21	freq: clock frequency in kHz
22	vol: voltage in microvolt
23
24Examples:
25
26cpu@0 {
27	compatible = "arm,cortex-a9";
28	reg = <0>;
29	next-level-cache = <&L2>;
30	operating-points = <
31		/* kHz    uV */
32		792000  1100000
33		396000  950000
34		198000  850000
35	>;
36};
37
38
39Binding 2: operating-points-v2
40============================
41
42* Property: operating-points-v2
43
44Devices supporting OPPs must set their "operating-points-v2" property with
45phandle to a OPP table in their DT node. The OPP core will use this phandle to
46find the operating points for the device.
47
48This can contain more than one phandle for power domain providers that provide
49multiple power domains. That is, one phandle for each power domain. If only one
50phandle is available, then the same OPP table will be used for all power domains
51provided by the power domain provider.
52
53If required, this can be extended for SoC vendor specific bindings. Such bindings
54should be documented as Documentation/devicetree/bindings/power/<vendor>-opp.txt
55and should have a compatible description like: "operating-points-v2-<vendor>".
56
57* OPP Table Node
58
59This describes the OPPs belonging to a device. This node can have following
60properties:
61
62Required properties:
63- compatible: Allow OPPs to express their compatibility. It should be:
64  "operating-points-v2".
65
66- OPP nodes: One or more OPP nodes describing voltage-current-frequency
67  combinations. Their name isn't significant but their phandle can be used to
68  reference an OPP. These are mandatory except for the case where the OPP table
69  is present only to indicate dependency between devices using the opp-shared
70  property.
71
72Optional properties:
73- opp-shared: Indicates that device nodes using this OPP Table Node's phandle
74  switch their DVFS state together, i.e. they share clock/voltage/current lines.
75  Missing property means devices have independent clock/voltage/current lines,
76  but they share OPP tables.
77
78- status: Marks the OPP table enabled/disabled.
79
80
81* OPP Node
82
83This defines voltage-current-frequency combinations along with other related
84properties.
85
86Required properties:
87- opp-hz: Frequency in Hz, expressed as a 64-bit big-endian integer. This is a
88  required property for all device nodes, unless another "required" property to
89  uniquely identify the OPP nodes exists. Devices like power domains must have
90  another (implementation dependent) property.
91
92- opp-peak-kBps: Peak bandwidth in kilobytes per second, expressed as an array
93  of 32-bit big-endian integers. Each element of the array represents the
94  peak bandwidth value of each interconnect path. The number of elements should
95  match the number of interconnect paths.
96
97Optional properties:
98- opp-microvolt: voltage in micro Volts.
99
100  A single regulator's voltage is specified with an array of size one or three.
101  Single entry is for target voltage and three entries are for <target min max>
102  voltages.
103
104  Entries for multiple regulators shall be provided in the same field separated
105  by angular brackets <>. The OPP binding doesn't provide any provisions to
106  relate the values to their power supplies or the order in which the supplies
107  need to be configured and that is left for the implementation specific
108  binding.
109
110  Entries for all regulators shall be of the same size, i.e. either all use a
111  single value or triplets.
112
113- opp-microvolt-<name>: Named opp-microvolt property. This is exactly similar to
114  the above opp-microvolt property, but allows multiple voltage ranges to be
115  provided for the same OPP. At runtime, the platform can pick a <name> and
116  matching opp-microvolt-<name> property will be enabled for all OPPs. If the
117  platform doesn't pick a specific <name> or the <name> doesn't match with any
118  opp-microvolt-<name> properties, then opp-microvolt property shall be used, if
119  present.
120
121- opp-microamp: The maximum current drawn by the device in microamperes
122  considering system specific parameters (such as transients, process, aging,
123  maximum operating temperature range etc.) as necessary. This may be used to
124  set the most efficient regulator operating mode.
125
126  Should only be set if opp-microvolt is set for the OPP.
127
128  Entries for multiple regulators shall be provided in the same field separated
129  by angular brackets <>. If current values aren't required for a regulator,
130  then it shall be filled with 0. If current values aren't required for any of
131  the regulators, then this field is not required. The OPP binding doesn't
132  provide any provisions to relate the values to their power supplies or the
133  order in which the supplies need to be configured and that is left for the
134  implementation specific binding.
135
136- opp-microamp-<name>: Named opp-microamp property. Similar to
137  opp-microvolt-<name> property, but for microamp instead.
138
139- opp-level: A value representing the performance level of the device,
140  expressed as a 32-bit integer.
141
142- opp-avg-kBps: Average bandwidth in kilobytes per second, expressed as an array
143  of 32-bit big-endian integers. Each element of the array represents the
144  average bandwidth value of each interconnect path. The number of elements
145  should match the number of interconnect paths. This property is only
146  meaningful in OPP tables where opp-peak-kBps is present.
147
148- clock-latency-ns: Specifies the maximum possible transition latency (in
149  nanoseconds) for switching to this OPP from any other OPP.
150
151- turbo-mode: Marks the OPP to be used only for turbo modes. Turbo mode is
152  available on some platforms, where the device can run over its operating
153  frequency for a short duration of time limited by the device's power, current
154  and thermal limits.
155
156- opp-suspend: Marks the OPP to be used during device suspend. If multiple OPPs
157  in the table have this, the OPP with highest opp-hz will be used.
158
159- opp-supported-hw: This property allows a platform to enable only a subset of
160  the OPPs from the larger set present in the OPP table, based on the current
161  version of the hardware (already known to the operating system).
162
163  Each block present in the array of blocks in this property, represents a
164  sub-group of hardware versions supported by the OPP. i.e. <sub-group A>,
165  <sub-group B>, etc. The OPP will be enabled if _any_ of these sub-groups match
166  the hardware's version.
167
168  Each sub-group is a platform defined array representing the hierarchy of
169  hardware versions supported by the platform. For a platform with three
170  hierarchical levels of version (X.Y.Z), this field shall look like
171
172  opp-supported-hw = <X1 Y1 Z1>, <X2 Y2 Z2>, <X3 Y3 Z3>.
173
174  Each level (eg. X1) in version hierarchy is represented by a 32 bit value, one
175  bit per version and so there can be maximum 32 versions per level. Logical AND
176  (&) operation is performed for each level with the hardware's level version
177  and a non-zero output for _all_ the levels in a sub-group means the OPP is
178  supported by hardware. A value of 0xFFFFFFFF for each level in the sub-group
179  will enable the OPP for all versions for the hardware.
180
181- status: Marks the node enabled/disabled.
182
183- required-opps: This contains phandle to an OPP node in another device's OPP
184  table. It may contain an array of phandles, where each phandle points to an
185  OPP of a different device. It should not contain multiple phandles to the OPP
186  nodes in the same OPP table. This specifies the minimum required OPP of the
187  device(s), whose OPP's phandle is present in this property, for the
188  functioning of the current device at the current OPP (where this property is
189  present).
190
191Example 1: Single cluster Dual-core ARM cortex A9, switch DVFS states together.
192
193/ {
194	cpus {
195		#address-cells = <1>;
196		#size-cells = <0>;
197
198		cpu@0 {
199			compatible = "arm,cortex-a9";
200			reg = <0>;
201			next-level-cache = <&L2>;
202			clocks = <&clk_controller 0>;
203			clock-names = "cpu";
204			cpu-supply = <&cpu_supply0>;
205			operating-points-v2 = <&cpu0_opp_table>;
206		};
207
208		cpu@1 {
209			compatible = "arm,cortex-a9";
210			reg = <1>;
211			next-level-cache = <&L2>;
212			clocks = <&clk_controller 0>;
213			clock-names = "cpu";
214			cpu-supply = <&cpu_supply0>;
215			operating-points-v2 = <&cpu0_opp_table>;
216		};
217	};
218
219	cpu0_opp_table: opp_table0 {
220		compatible = "operating-points-v2";
221		opp-shared;
222
223		opp-1000000000 {
224			opp-hz = /bits/ 64 <1000000000>;
225			opp-microvolt = <975000 970000 985000>;
226			opp-microamp = <70000>;
227			clock-latency-ns = <300000>;
228			opp-suspend;
229		};
230		opp-1100000000 {
231			opp-hz = /bits/ 64 <1100000000>;
232			opp-microvolt = <1000000 980000 1010000>;
233			opp-microamp = <80000>;
234			clock-latency-ns = <310000>;
235		};
236		opp-1200000000 {
237			opp-hz = /bits/ 64 <1200000000>;
238			opp-microvolt = <1025000>;
239			clock-latency-ns = <290000>;
240			turbo-mode;
241		};
242	};
243};
244
245Example 2: Single cluster, Quad-core Qualcom-krait, switches DVFS states
246independently.
247
248/ {
249	cpus {
250		#address-cells = <1>;
251		#size-cells = <0>;
252
253		cpu@0 {
254			compatible = "qcom,krait";
255			reg = <0>;
256			next-level-cache = <&L2>;
257			clocks = <&clk_controller 0>;
258			clock-names = "cpu";
259			cpu-supply = <&cpu_supply0>;
260			operating-points-v2 = <&cpu_opp_table>;
261		};
262
263		cpu@1 {
264			compatible = "qcom,krait";
265			reg = <1>;
266			next-level-cache = <&L2>;
267			clocks = <&clk_controller 1>;
268			clock-names = "cpu";
269			cpu-supply = <&cpu_supply1>;
270			operating-points-v2 = <&cpu_opp_table>;
271		};
272
273		cpu@2 {
274			compatible = "qcom,krait";
275			reg = <2>;
276			next-level-cache = <&L2>;
277			clocks = <&clk_controller 2>;
278			clock-names = "cpu";
279			cpu-supply = <&cpu_supply2>;
280			operating-points-v2 = <&cpu_opp_table>;
281		};
282
283		cpu@3 {
284			compatible = "qcom,krait";
285			reg = <3>;
286			next-level-cache = <&L2>;
287			clocks = <&clk_controller 3>;
288			clock-names = "cpu";
289			cpu-supply = <&cpu_supply3>;
290			operating-points-v2 = <&cpu_opp_table>;
291		};
292	};
293
294	cpu_opp_table: opp_table {
295		compatible = "operating-points-v2";
296
297		/*
298		 * Missing opp-shared property means CPUs switch DVFS states
299		 * independently.
300		 */
301
302		opp-1000000000 {
303			opp-hz = /bits/ 64 <1000000000>;
304			opp-microvolt = <975000 970000 985000>;
305			opp-microamp = <70000>;
306			clock-latency-ns = <300000>;
307			opp-suspend;
308		};
309		opp-1100000000 {
310			opp-hz = /bits/ 64 <1100000000>;
311			opp-microvolt = <1000000 980000 1010000>;
312			opp-microamp = <80000>;
313			clock-latency-ns = <310000>;
314		};
315		opp-1200000000 {
316			opp-hz = /bits/ 64 <1200000000>;
317			opp-microvolt = <1025000>;
318			opp-microamp = <90000;
319			lock-latency-ns = <290000>;
320			turbo-mode;
321		};
322	};
323};
324
325Example 3: Dual-cluster, Dual-core per cluster. CPUs within a cluster switch
326DVFS state together.
327
328/ {
329	cpus {
330		#address-cells = <1>;
331		#size-cells = <0>;
332
333		cpu@0 {
334			compatible = "arm,cortex-a7";
335			reg = <0>;
336			next-level-cache = <&L2>;
337			clocks = <&clk_controller 0>;
338			clock-names = "cpu";
339			cpu-supply = <&cpu_supply0>;
340			operating-points-v2 = <&cluster0_opp>;
341		};
342
343		cpu@1 {
344			compatible = "arm,cortex-a7";
345			reg = <1>;
346			next-level-cache = <&L2>;
347			clocks = <&clk_controller 0>;
348			clock-names = "cpu";
349			cpu-supply = <&cpu_supply0>;
350			operating-points-v2 = <&cluster0_opp>;
351		};
352
353		cpu@100 {
354			compatible = "arm,cortex-a15";
355			reg = <100>;
356			next-level-cache = <&L2>;
357			clocks = <&clk_controller 1>;
358			clock-names = "cpu";
359			cpu-supply = <&cpu_supply1>;
360			operating-points-v2 = <&cluster1_opp>;
361		};
362
363		cpu@101 {
364			compatible = "arm,cortex-a15";
365			reg = <101>;
366			next-level-cache = <&L2>;
367			clocks = <&clk_controller 1>;
368			clock-names = "cpu";
369			cpu-supply = <&cpu_supply1>;
370			operating-points-v2 = <&cluster1_opp>;
371		};
372	};
373
374	cluster0_opp: opp_table0 {
375		compatible = "operating-points-v2";
376		opp-shared;
377
378		opp-1000000000 {
379			opp-hz = /bits/ 64 <1000000000>;
380			opp-microvolt = <975000 970000 985000>;
381			opp-microamp = <70000>;
382			clock-latency-ns = <300000>;
383			opp-suspend;
384		};
385		opp-1100000000 {
386			opp-hz = /bits/ 64 <1100000000>;
387			opp-microvolt = <1000000 980000 1010000>;
388			opp-microamp = <80000>;
389			clock-latency-ns = <310000>;
390		};
391		opp-1200000000 {
392			opp-hz = /bits/ 64 <1200000000>;
393			opp-microvolt = <1025000>;
394			opp-microamp = <90000>;
395			clock-latency-ns = <290000>;
396			turbo-mode;
397		};
398	};
399
400	cluster1_opp: opp_table1 {
401		compatible = "operating-points-v2";
402		opp-shared;
403
404		opp-1300000000 {
405			opp-hz = /bits/ 64 <1300000000>;
406			opp-microvolt = <1050000 1045000 1055000>;
407			opp-microamp = <95000>;
408			clock-latency-ns = <400000>;
409			opp-suspend;
410		};
411		opp-1400000000 {
412			opp-hz = /bits/ 64 <1400000000>;
413			opp-microvolt = <1075000>;
414			opp-microamp = <100000>;
415			clock-latency-ns = <400000>;
416		};
417		opp-1500000000 {
418			opp-hz = /bits/ 64 <1500000000>;
419			opp-microvolt = <1100000 1010000 1110000>;
420			opp-microamp = <95000>;
421			clock-latency-ns = <400000>;
422			turbo-mode;
423		};
424	};
425};
426
427Example 4: Handling multiple regulators
428
429/ {
430	cpus {
431		cpu@0 {
432			compatible = "vendor,cpu-type";
433			...
434
435			vcc0-supply = <&cpu_supply0>;
436			vcc1-supply = <&cpu_supply1>;
437			vcc2-supply = <&cpu_supply2>;
438			operating-points-v2 = <&cpu0_opp_table>;
439		};
440	};
441
442	cpu0_opp_table: opp_table0 {
443		compatible = "operating-points-v2";
444		opp-shared;
445
446		opp-1000000000 {
447			opp-hz = /bits/ 64 <1000000000>;
448			opp-microvolt = <970000>, /* Supply 0 */
449					<960000>, /* Supply 1 */
450					<960000>; /* Supply 2 */
451			opp-microamp =  <70000>,  /* Supply 0 */
452					<70000>,  /* Supply 1 */
453					<70000>;  /* Supply 2 */
454			clock-latency-ns = <300000>;
455		};
456
457		/* OR */
458
459		opp-1000000000 {
460			opp-hz = /bits/ 64 <1000000000>;
461			opp-microvolt = <975000 970000 985000>, /* Supply 0 */
462					<965000 960000 975000>, /* Supply 1 */
463					<965000 960000 975000>; /* Supply 2 */
464			opp-microamp =  <70000>,		/* Supply 0 */
465					<70000>,		/* Supply 1 */
466					<70000>;		/* Supply 2 */
467			clock-latency-ns = <300000>;
468		};
469
470		/* OR */
471
472		opp-1000000000 {
473			opp-hz = /bits/ 64 <1000000000>;
474			opp-microvolt = <975000 970000 985000>, /* Supply 0 */
475					<965000 960000 975000>, /* Supply 1 */
476					<965000 960000 975000>; /* Supply 2 */
477			opp-microamp =  <70000>,		/* Supply 0 */
478					<0>,			/* Supply 1 doesn't need this */
479					<70000>;		/* Supply 2 */
480			clock-latency-ns = <300000>;
481		};
482	};
483};
484
485Example 5: opp-supported-hw
486(example: three level hierarchy of versions: cuts, substrate and process)
487
488/ {
489	cpus {
490		cpu@0 {
491			compatible = "arm,cortex-a7";
492			...
493
494			cpu-supply = <&cpu_supply>
495			operating-points-v2 = <&cpu0_opp_table_slow>;
496		};
497	};
498
499	opp_table {
500		compatible = "operating-points-v2";
501		opp-shared;
502
503		opp-600000000 {
504			/*
505			 * Supports all substrate and process versions for 0xF
506			 * cuts, i.e. only first four cuts.
507			 */
508			opp-supported-hw = <0xF 0xFFFFFFFF 0xFFFFFFFF>
509			opp-hz = /bits/ 64 <600000000>;
510			...
511		};
512
513		opp-800000000 {
514			/*
515			 * Supports:
516			 * - cuts: only one, 6th cut (represented by 6th bit).
517			 * - substrate: supports 16 different substrate versions
518			 * - process: supports 9 different process versions
519			 */
520			opp-supported-hw = <0x20 0xff0000ff 0x0000f4f0>
521			opp-hz = /bits/ 64 <800000000>;
522			...
523		};
524
525		opp-900000000 {
526			/*
527			 * Supports:
528			 * - All cuts and substrate where process version is 0x2.
529			 * - All cuts and process where substrate version is 0x2.
530			 */
531			opp-supported-hw = <0xFFFFFFFF 0xFFFFFFFF 0x02>, <0xFFFFFFFF 0x01 0xFFFFFFFF>
532			opp-hz = /bits/ 64 <900000000>;
533			...
534		};
535	};
536};
537
538Example 6: opp-microvolt-<name>, opp-microamp-<name>:
539(example: device with two possible microvolt ranges: slow and fast)
540
541/ {
542	cpus {
543		cpu@0 {
544			compatible = "arm,cortex-a7";
545			...
546
547			operating-points-v2 = <&cpu0_opp_table>;
548		};
549	};
550
551	cpu0_opp_table: opp_table0 {
552		compatible = "operating-points-v2";
553		opp-shared;
554
555		opp-1000000000 {
556			opp-hz = /bits/ 64 <1000000000>;
557			opp-microvolt-slow = <915000 900000 925000>;
558			opp-microvolt-fast = <975000 970000 985000>;
559			opp-microamp-slow =  <70000>;
560			opp-microamp-fast =  <71000>;
561		};
562
563		opp-1200000000 {
564			opp-hz = /bits/ 64 <1200000000>;
565			opp-microvolt-slow = <915000 900000 925000>, /* Supply vcc0 */
566					      <925000 910000 935000>; /* Supply vcc1 */
567			opp-microvolt-fast = <975000 970000 985000>, /* Supply vcc0 */
568					     <965000 960000 975000>; /* Supply vcc1 */
569			opp-microamp =  <70000>; /* Will be used for both slow/fast */
570		};
571	};
572};
573
574Example 7: Single cluster Quad-core ARM cortex A53, OPP points from firmware,
575distinct clock controls but two sets of clock/voltage/current lines.
576
577/ {
578	cpus {
579		#address-cells = <2>;
580		#size-cells = <0>;
581
582		cpu@0 {
583			compatible = "arm,cortex-a53";
584			reg = <0x0 0x100>;
585			next-level-cache = <&A53_L2>;
586			clocks = <&dvfs_controller 0>;
587			operating-points-v2 = <&cpu_opp0_table>;
588		};
589		cpu@1 {
590			compatible = "arm,cortex-a53";
591			reg = <0x0 0x101>;
592			next-level-cache = <&A53_L2>;
593			clocks = <&dvfs_controller 1>;
594			operating-points-v2 = <&cpu_opp0_table>;
595		};
596		cpu@2 {
597			compatible = "arm,cortex-a53";
598			reg = <0x0 0x102>;
599			next-level-cache = <&A53_L2>;
600			clocks = <&dvfs_controller 2>;
601			operating-points-v2 = <&cpu_opp1_table>;
602		};
603		cpu@3 {
604			compatible = "arm,cortex-a53";
605			reg = <0x0 0x103>;
606			next-level-cache = <&A53_L2>;
607			clocks = <&dvfs_controller 3>;
608			operating-points-v2 = <&cpu_opp1_table>;
609		};
610
611	};
612
613	cpu_opp0_table: opp0_table {
614		compatible = "operating-points-v2";
615		opp-shared;
616	};
617
618	cpu_opp1_table: opp1_table {
619		compatible = "operating-points-v2";
620		opp-shared;
621	};
622};
623