xref: /openbmc/qemu/hw/core/resettable.c (revision 990d2c18)
1 /*
2  * Resettable interface.
3  *
4  * Copyright (c) 2019 GreenSocs SAS
5  *
6  * Authors:
7  *   Damien Hedde
8  *
9  * This work is licensed under the terms of the GNU GPL, version 2 or later.
10  * See the COPYING file in the top-level directory.
11  */
12 
13 #include "qemu/osdep.h"
14 #include "qemu/module.h"
15 #include "hw/resettable.h"
16 #include "trace.h"
17 
18 /**
19  * resettable_phase_enter/hold/exit:
20  * Function executing a phase recursively in a resettable object and its
21  * children.
22  */
23 static void resettable_phase_enter(Object *obj, void *opaque, ResetType type);
24 static void resettable_phase_hold(Object *obj, void *opaque, ResetType type);
25 static void resettable_phase_exit(Object *obj, void *opaque, ResetType type);
26 
27 /**
28  * enter_phase_in_progress:
29  * True if we are currently in reset enter phase.
30  *
31  * exit_phase_in_progress:
32  * count the number of exit phase we are in.
33  *
34  * Note: These flags are only used to guarantee (using asserts) that the reset
35  * API is used correctly. We can use global variables because we rely on the
36  * iothread mutex to ensure only one reset operation is in a progress at a
37  * given time.
38  */
39 static bool enter_phase_in_progress;
40 static unsigned exit_phase_in_progress;
41 
42 void resettable_reset(Object *obj, ResetType type)
43 {
44     trace_resettable_reset(obj, type);
45     resettable_assert_reset(obj, type);
46     resettable_release_reset(obj, type);
47 }
48 
49 void resettable_assert_reset(Object *obj, ResetType type)
50 {
51     trace_resettable_reset_assert_begin(obj, type);
52     assert(!enter_phase_in_progress);
53 
54     enter_phase_in_progress = true;
55     resettable_phase_enter(obj, NULL, type);
56     enter_phase_in_progress = false;
57 
58     resettable_phase_hold(obj, NULL, type);
59 
60     trace_resettable_reset_assert_end(obj);
61 }
62 
63 void resettable_release_reset(Object *obj, ResetType type)
64 {
65     trace_resettable_reset_release_begin(obj, type);
66     assert(!enter_phase_in_progress);
67 
68     exit_phase_in_progress += 1;
69     resettable_phase_exit(obj, NULL, type);
70     exit_phase_in_progress -= 1;
71 
72     trace_resettable_reset_release_end(obj);
73 }
74 
75 bool resettable_is_in_reset(Object *obj)
76 {
77     ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
78     ResettableState *s = rc->get_state(obj);
79 
80     return s->count > 0;
81 }
82 
83 /**
84  * resettable_child_foreach:
85  * helper to avoid checking the existence of the method.
86  */
87 static void resettable_child_foreach(ResettableClass *rc, Object *obj,
88                                      ResettableChildCallback cb,
89                                      void *opaque, ResetType type)
90 {
91     if (rc->child_foreach) {
92         rc->child_foreach(obj, cb, opaque, type);
93     }
94 }
95 
96 static void resettable_phase_enter(Object *obj, void *opaque, ResetType type)
97 {
98     ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
99     ResettableState *s = rc->get_state(obj);
100     const char *obj_typename = object_get_typename(obj);
101     bool action_needed = false;
102 
103     /* exit phase has to finish properly before entering back in reset */
104     assert(!s->exit_phase_in_progress);
105 
106     trace_resettable_phase_enter_begin(obj, obj_typename, s->count, type);
107 
108     /* Only take action if we really enter reset for the 1st time. */
109     /*
110      * TODO: if adding more ResetType support, some additional checks
111      * are probably needed here.
112      */
113     if (s->count++ == 0) {
114         action_needed = true;
115     }
116     /*
117      * We limit the count to an arbitrary "big" value. The value is big
118      * enough not to be triggered normally.
119      * The assert will stop an infinite loop if there is a cycle in the
120      * reset tree. The loop goes through resettable_foreach_child below
121      * which at some point will call us again.
122      */
123     assert(s->count <= 50);
124 
125     /*
126      * handle the children even if action_needed is at false so that
127      * child counts are incremented too
128      */
129     resettable_child_foreach(rc, obj, resettable_phase_enter, NULL, type);
130 
131     /* execute enter phase for the object if needed */
132     if (action_needed) {
133         trace_resettable_phase_enter_exec(obj, obj_typename, type,
134                                           !!rc->phases.enter);
135         if (rc->phases.enter) {
136             rc->phases.enter(obj, type);
137         }
138         s->hold_phase_pending = true;
139     }
140     trace_resettable_phase_enter_end(obj, obj_typename, s->count);
141 }
142 
143 static void resettable_phase_hold(Object *obj, void *opaque, ResetType type)
144 {
145     ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
146     ResettableState *s = rc->get_state(obj);
147     const char *obj_typename = object_get_typename(obj);
148 
149     /* exit phase has to finish properly before entering back in reset */
150     assert(!s->exit_phase_in_progress);
151 
152     trace_resettable_phase_hold_begin(obj, obj_typename, s->count, type);
153 
154     /* handle children first */
155     resettable_child_foreach(rc, obj, resettable_phase_hold, NULL, type);
156 
157     /* exec hold phase */
158     if (s->hold_phase_pending) {
159         s->hold_phase_pending = false;
160         trace_resettable_phase_hold_exec(obj, obj_typename, !!rc->phases.hold);
161         if (rc->phases.hold) {
162             rc->phases.hold(obj, type);
163         }
164     }
165     trace_resettable_phase_hold_end(obj, obj_typename, s->count);
166 }
167 
168 static void resettable_phase_exit(Object *obj, void *opaque, ResetType type)
169 {
170     ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
171     ResettableState *s = rc->get_state(obj);
172     const char *obj_typename = object_get_typename(obj);
173 
174     assert(!s->exit_phase_in_progress);
175     trace_resettable_phase_exit_begin(obj, obj_typename, s->count, type);
176 
177     /* exit_phase_in_progress ensures this phase is 'atomic' */
178     s->exit_phase_in_progress = true;
179     resettable_child_foreach(rc, obj, resettable_phase_exit, NULL, type);
180 
181     assert(s->count > 0);
182     if (--s->count == 0) {
183         trace_resettable_phase_exit_exec(obj, obj_typename, !!rc->phases.exit);
184         if (rc->phases.exit) {
185             rc->phases.exit(obj, type);
186         }
187     }
188     s->exit_phase_in_progress = false;
189     trace_resettable_phase_exit_end(obj, obj_typename, s->count);
190 }
191 
192 /*
193  * resettable_get_count:
194  * Get the count of the Resettable object @obj. Return 0 if @obj is NULL.
195  */
196 static unsigned resettable_get_count(Object *obj)
197 {
198     if (obj) {
199         ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
200         return rc->get_state(obj)->count;
201     }
202     return 0;
203 }
204 
205 void resettable_change_parent(Object *obj, Object *newp, Object *oldp)
206 {
207     ResettableClass *rc = RESETTABLE_GET_CLASS(obj);
208     ResettableState *s = rc->get_state(obj);
209     unsigned newp_count = resettable_get_count(newp);
210     unsigned oldp_count = resettable_get_count(oldp);
211 
212     /*
213      * Ensure we do not change parent when in enter or exit phase.
214      * During these phases, the reset subtree being updated is partly in reset
215      * and partly not in reset (it depends on the actual position in
216      * resettable_child_foreach()s). We are not able to tell in which part is a
217      * leaving or arriving device. Thus we cannot set the reset count of the
218      * moving device to the proper value.
219      */
220     assert(!enter_phase_in_progress && !exit_phase_in_progress);
221     trace_resettable_change_parent(obj, oldp, oldp_count, newp, newp_count);
222 
223     /*
224      * At most one of the two 'for' loops will be executed below
225      * in order to cope with the difference between the two counts.
226      */
227     /* if newp is more reset than oldp */
228     for (unsigned i = oldp_count; i < newp_count; i++) {
229         resettable_assert_reset(obj, RESET_TYPE_COLD);
230     }
231     /*
232      * if obj is leaving a bus under reset, we need to ensure
233      * hold phase is not pending.
234      */
235     if (oldp_count && s->hold_phase_pending) {
236         resettable_phase_hold(obj, NULL, RESET_TYPE_COLD);
237     }
238     /* if oldp is more reset than newp */
239     for (unsigned i = newp_count; i < oldp_count; i++) {
240         resettable_release_reset(obj, RESET_TYPE_COLD);
241     }
242 }
243 
244 void resettable_cold_reset_fn(void *opaque)
245 {
246     resettable_reset((Object *) opaque, RESET_TYPE_COLD);
247 }
248 
249 void resettable_class_set_parent_phases(ResettableClass *rc,
250                                         ResettableEnterPhase enter,
251                                         ResettableHoldPhase hold,
252                                         ResettableExitPhase exit,
253                                         ResettablePhases *parent_phases)
254 {
255     *parent_phases = rc->phases;
256     if (enter) {
257         rc->phases.enter = enter;
258     }
259     if (hold) {
260         rc->phases.hold = hold;
261     }
262     if (exit) {
263         rc->phases.exit = exit;
264     }
265 }
266 
267 static const TypeInfo resettable_interface_info = {
268     .name       = TYPE_RESETTABLE_INTERFACE,
269     .parent     = TYPE_INTERFACE,
270     .class_size = sizeof(ResettableClass),
271 };
272 
273 static void reset_register_types(void)
274 {
275     type_register_static(&resettable_interface_info);
276 }
277 
278 type_init(reset_register_types)
279