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1/*
2 * Copyright © 2017 Intel Corporation
3 *
4 * Permission is hereby granted, free of charge, to any person obtaining a
5 * copy of this software and associated documentation files (the "Software"),
6 * to deal in the Software without restriction, including without limitation
7 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
8 * and/or sell copies of the Software, and to permit persons to whom the
9 * Software is furnished to do so, subject to the following conditions:
10 *
11 * The above copyright notice and this permission notice (including the next
12 * paragraph) shall be included in all copies or substantial portions of the
13 * Software.
14 *
15 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
16 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
17 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
18 * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
19 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
20 * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS
21 * IN THE SOFTWARE.
22 *
23 */
24
25#include <linux/slab.h>
26
27#include "i915_syncmap.h"
28
29#include "i915_gem.h" /* GEM_BUG_ON() */
30#include "i915_selftest.h"
31
32#define SHIFT ilog2(KSYNCMAP)
33#define MASK (KSYNCMAP - 1)
34
35/*
36 * struct i915_syncmap is a layer of a radixtree that maps a u64 fence
37 * context id to the last u32 fence seqno waited upon from that context.
38 * Unlike lib/radixtree it uses a parent pointer that allows traversal back to
39 * the root. This allows us to access the whole tree via a single pointer
40 * to the most recently used layer. We expect fence contexts to be dense
41 * and most reuse to be on the same i915_gem_context but on neighbouring
42 * engines (i.e. on adjacent contexts) and reuse the same leaf, a very
43 * effective lookup cache. If the new lookup is not on the same leaf, we
44 * expect it to be on the neighbouring branch.
45 *
46 * A leaf holds an array of u32 seqno, and has height 0. The bitmap field
47 * allows us to store whether a particular seqno is valid (i.e. allows us
48 * to distinguish unset from 0).
49 *
50 * A branch holds an array of layer pointers, and has height > 0, and always
51 * has at least 2 layers (either branches or leaves) below it.
52 *
53 * For example,
54 * for x in
55 * 0 1 2 0x10 0x11 0x200 0x201
56 * 0x500000 0x500001 0x503000 0x503001
57 * 0xE<<60:
58 * i915_syncmap_set(&sync, x, lower_32_bits(x));
59 * will build a tree like:
60 * 0xXXXXXXXXXXXXXXXX
61 * 0-> 0x0000000000XXXXXX
62 * | 0-> 0x0000000000000XXX
63 * | | 0-> 0x00000000000000XX
64 * | | | 0-> 0x000000000000000X 0:0, 1:1, 2:2
65 * | | | 1-> 0x000000000000001X 0:10, 1:11
66 * | | 2-> 0x000000000000020X 0:200, 1:201
67 * | 5-> 0x000000000050XXXX
68 * | 0-> 0x000000000050000X 0:500000, 1:500001
69 * | 3-> 0x000000000050300X 0:503000, 1:503001
70 * e-> 0xe00000000000000X e:e
71 */
72
73struct i915_syncmap {
74 u64 prefix;
75 unsigned int height;
76 unsigned int bitmap;
77 struct i915_syncmap *parent;
78 union {
79 DECLARE_FLEX_ARRAY(u32, seqno);
80 DECLARE_FLEX_ARRAY(struct i915_syncmap *, child);
81 };
82};
83
84/**
85 * i915_syncmap_init -- initialise the #i915_syncmap
86 * @root: pointer to the #i915_syncmap
87 */
88void i915_syncmap_init(struct i915_syncmap **root)
89{
90 BUILD_BUG_ON_NOT_POWER_OF_2(KSYNCMAP);
91 BUILD_BUG_ON_NOT_POWER_OF_2(SHIFT);
92 BUILD_BUG_ON(KSYNCMAP > BITS_PER_TYPE((*root)->bitmap));
93 *root = NULL;
94}
95
96static inline u32 *__sync_seqno(struct i915_syncmap *p)
97{
98 GEM_BUG_ON(p->height);
99 return p->seqno;
100}
101
102static inline struct i915_syncmap **__sync_child(struct i915_syncmap *p)
103{
104 GEM_BUG_ON(!p->height);
105 return p->child;
106}
107
108static inline unsigned int
109__sync_branch_idx(const struct i915_syncmap *p, u64 id)
110{
111 return (id >> p->height) & MASK;
112}
113
114static inline unsigned int
115__sync_leaf_idx(const struct i915_syncmap *p, u64 id)
116{
117 GEM_BUG_ON(p->height);
118 return id & MASK;
119}
120
121static inline u64 __sync_branch_prefix(const struct i915_syncmap *p, u64 id)
122{
123 return id >> p->height >> SHIFT;
124}
125
126static inline u64 __sync_leaf_prefix(const struct i915_syncmap *p, u64 id)
127{
128 GEM_BUG_ON(p->height);
129 return id >> SHIFT;
130}
131
132static inline bool seqno_later(u32 a, u32 b)
133{
134 return (s32)(a - b) >= 0;
135}
136
137/**
138 * i915_syncmap_is_later -- compare against the last know sync point
139 * @root: pointer to the #i915_syncmap
140 * @id: the context id (other timeline) we are synchronising to
141 * @seqno: the sequence number along the other timeline
142 *
143 * If we have already synchronised this @root timeline with another (@id) then
144 * we can omit any repeated or earlier synchronisation requests. If the two
145 * timelines are already coupled, we can also omit the dependency between the
146 * two as that is already known via the timeline.
147 *
148 * Returns true if the two timelines are already synchronised wrt to @seqno,
149 * false if not and the synchronisation must be emitted.
150 */
151bool i915_syncmap_is_later(struct i915_syncmap **root, u64 id, u32 seqno)
152{
153 struct i915_syncmap *p;
154 unsigned int idx;
155
156 p = *root;
157 if (!p)
158 return false;
159
160 if (likely(__sync_leaf_prefix(p, id) == p->prefix))
161 goto found;
162
163 /* First climb the tree back to a parent branch */
164 do {
165 p = p->parent;
166 if (!p)
167 return false;
168
169 if (__sync_branch_prefix(p, id) == p->prefix)
170 break;
171 } while (1);
172
173 /* And then descend again until we find our leaf */
174 do {
175 if (!p->height)
176 break;
177
178 p = __sync_child(p)[__sync_branch_idx(p, id)];
179 if (!p)
180 return false;
181
182 if (__sync_branch_prefix(p, id) != p->prefix)
183 return false;
184 } while (1);
185
186 *root = p;
187found:
188 idx = __sync_leaf_idx(p, id);
189 if (!(p->bitmap & BIT(idx)))
190 return false;
191
192 return seqno_later(__sync_seqno(p)[idx], seqno);
193}
194
195static struct i915_syncmap *
196__sync_alloc_leaf(struct i915_syncmap *parent, u64 id)
197{
198 struct i915_syncmap *p;
199
200 p = kmalloc(struct_size(p, seqno, KSYNCMAP), GFP_KERNEL);
201 if (unlikely(!p))
202 return NULL;
203
204 p->parent = parent;
205 p->height = 0;
206 p->bitmap = 0;
207 p->prefix = __sync_leaf_prefix(p, id);
208 return p;
209}
210
211static inline void __sync_set_seqno(struct i915_syncmap *p, u64 id, u32 seqno)
212{
213 unsigned int idx = __sync_leaf_idx(p, id);
214
215 p->bitmap |= BIT(idx);
216 __sync_seqno(p)[idx] = seqno;
217}
218
219static inline void __sync_set_child(struct i915_syncmap *p,
220 unsigned int idx,
221 struct i915_syncmap *child)
222{
223 p->bitmap |= BIT(idx);
224 __sync_child(p)[idx] = child;
225}
226
227static noinline int __sync_set(struct i915_syncmap **root, u64 id, u32 seqno)
228{
229 struct i915_syncmap *p = *root;
230 unsigned int idx;
231
232 if (!p) {
233 p = __sync_alloc_leaf(NULL, id);
234 if (unlikely(!p))
235 return -ENOMEM;
236
237 goto found;
238 }
239
240 /* Caller handled the likely cached case */
241 GEM_BUG_ON(__sync_leaf_prefix(p, id) == p->prefix);
242
243 /* Climb back up the tree until we find a common prefix */
244 do {
245 if (!p->parent)
246 break;
247
248 p = p->parent;
249
250 if (__sync_branch_prefix(p, id) == p->prefix)
251 break;
252 } while (1);
253
254 /*
255 * No shortcut, we have to descend the tree to find the right layer
256 * containing this fence.
257 *
258 * Each layer in the tree holds 16 (KSYNCMAP) pointers, either fences
259 * or lower layers. Leaf nodes (height = 0) contain the fences, all
260 * other nodes (height > 0) are internal layers that point to a lower
261 * node. Each internal layer has at least 2 descendents.
262 *
263 * Starting at the top, we check whether the current prefix matches. If
264 * it doesn't, we have gone past our target and need to insert a join
265 * into the tree, and a new leaf node for the target as a descendent
266 * of the join, as well as the original layer.
267 *
268 * The matching prefix means we are still following the right branch
269 * of the tree. If it has height 0, we have found our leaf and just
270 * need to replace the fence slot with ourselves. If the height is
271 * not zero, our slot contains the next layer in the tree (unless
272 * it is empty, in which case we can add ourselves as a new leaf).
273 * As descend the tree the prefix grows (and height decreases).
274 */
275 do {
276 struct i915_syncmap *next;
277
278 if (__sync_branch_prefix(p, id) != p->prefix) {
279 unsigned int above;
280
281 /* Insert a join above the current layer */
282 next = kzalloc(struct_size(next, child, KSYNCMAP),
283 GFP_KERNEL);
284 if (unlikely(!next))
285 return -ENOMEM;
286
287 /* Compute the height at which these two diverge */
288 above = fls64(__sync_branch_prefix(p, id) ^ p->prefix);
289 above = round_up(above, SHIFT);
290 next->height = above + p->height;
291 next->prefix = __sync_branch_prefix(next, id);
292
293 /* Insert the join into the parent */
294 if (p->parent) {
295 idx = __sync_branch_idx(p->parent, id);
296 __sync_child(p->parent)[idx] = next;
297 GEM_BUG_ON(!(p->parent->bitmap & BIT(idx)));
298 }
299 next->parent = p->parent;
300
301 /* Compute the idx of the other branch, not our id! */
302 idx = p->prefix >> (above - SHIFT) & MASK;
303 __sync_set_child(next, idx, p);
304 p->parent = next;
305
306 /* Ascend to the join */
307 p = next;
308 } else {
309 if (!p->height)
310 break;
311 }
312
313 /* Descend into the next layer */
314 GEM_BUG_ON(!p->height);
315 idx = __sync_branch_idx(p, id);
316 next = __sync_child(p)[idx];
317 if (!next) {
318 next = __sync_alloc_leaf(p, id);
319 if (unlikely(!next))
320 return -ENOMEM;
321
322 __sync_set_child(p, idx, next);
323 p = next;
324 break;
325 }
326
327 p = next;
328 } while (1);
329
330found:
331 GEM_BUG_ON(p->prefix != __sync_leaf_prefix(p, id));
332 __sync_set_seqno(p, id, seqno);
333 *root = p;
334 return 0;
335}
336
337/**
338 * i915_syncmap_set -- mark the most recent syncpoint between contexts
339 * @root: pointer to the #i915_syncmap
340 * @id: the context id (other timeline) we have synchronised to
341 * @seqno: the sequence number along the other timeline
342 *
343 * When we synchronise this @root timeline with another (@id), we also know
344 * that we have synchronized with all previous seqno along that timeline. If
345 * we then have a request to synchronise with the same seqno or older, we can
346 * omit it, see i915_syncmap_is_later()
347 *
348 * Returns 0 on success, or a negative error code.
349 */
350int i915_syncmap_set(struct i915_syncmap **root, u64 id, u32 seqno)
351{
352 struct i915_syncmap *p = *root;
353
354 /*
355 * We expect to be called in sequence following is_later(id), which
356 * should have preloaded the root for us.
357 */
358 if (likely(p && __sync_leaf_prefix(p, id) == p->prefix)) {
359 __sync_set_seqno(p, id, seqno);
360 return 0;
361 }
362
363 return __sync_set(root, id, seqno);
364}
365
366static void __sync_free(struct i915_syncmap *p)
367{
368 if (p->height) {
369 unsigned int i;
370
371 while ((i = ffs(p->bitmap))) {
372 p->bitmap &= ~0u << i;
373 __sync_free(__sync_child(p)[i - 1]);
374 }
375 }
376
377 kfree(p);
378}
379
380/**
381 * i915_syncmap_free -- free all memory associated with the syncmap
382 * @root: pointer to the #i915_syncmap
383 *
384 * Either when the timeline is to be freed and we no longer need the sync
385 * point tracking, or when the fences are all known to be signaled and the
386 * sync point tracking is redundant, we can free the #i915_syncmap to recover
387 * its allocations.
388 *
389 * Will reinitialise the @root pointer so that the #i915_syncmap is ready for
390 * reuse.
391 */
392void i915_syncmap_free(struct i915_syncmap **root)
393{
394 struct i915_syncmap *p;
395
396 p = *root;
397 if (!p)
398 return;
399
400 while (p->parent)
401 p = p->parent;
402
403 __sync_free(p);
404 *root = NULL;
405}
406
407#if IS_ENABLED(CONFIG_DRM_I915_SELFTEST)
408#include "selftests/i915_syncmap.c"
409#endif