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1 /*
2  * Copyright (C) 2017 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #ifndef INCLUDE_PERFETTO_TRACING_CORE_SHARED_MEMORY_ABI_H_
18 #define INCLUDE_PERFETTO_TRACING_CORE_SHARED_MEMORY_ABI_H_
19 
20 #include <stddef.h>
21 #include <stdint.h>
22 
23 #include <array>
24 #include <atomic>
25 #include <bitset>
26 #include <thread>
27 #include <type_traits>
28 #include <utility>
29 
30 #include "perfetto/base/logging.h"
31 
32 namespace perfetto {
33 
34 // This file defines the binary interface of the memory buffers shared between
35 // Producer and Service. This is a long-term stable ABI and has to be backwards
36 // compatible to deal with mismatching Producer and Service versions.
37 //
38 // Overview
39 // --------
40 // SMB := "Shared Memory Buffer".
41 // In the most typical case of a multi-process architecture (i.e. Producer and
42 // Service are hosted by different processes), a Producer means almost always
43 // a "client process producing data" (almost: in some cases a process might host
44 // > 1 Producer, if it links two libraries, independent of each other, that both
45 // use Perfetto tracing).
46 // The Service has one SMB for each Producer.
47 // A producer has one or (typically) more data sources. They all share the same
48 // SMB.
49 // The SMB is a staging area to decouple data sources living in the Producer
50 // and allow them to do non-blocking async writes.
51 // The SMB is *not* the ultimate logging buffer seen by the Consumer. That one
52 // is larger (~MBs) and not shared with Producers.
53 // Each SMB is small, typically few KB. Its size is configurable by the producer
54 // within a max limit of ~MB (see kMaxShmSize in tracing_service_impl.cc).
55 // The SMB is partitioned into fixed-size Page(s). The size of the Pages are
56 // determined by each Producer at connection time and cannot be changed.
57 // Hence, different producers can have SMB(s) that have a different Page size
58 // from each other, but the page size will be constant throughout all the
59 // lifetime of the SMB.
60 // Page(s) are partitioned by the Producer into variable size Chunk(s):
61 //
62 // +------------+      +--------------------------+
63 // | Producer 1 |  <-> |      SMB 1 [~32K - 1MB]  |
64 // +------------+      +--------+--------+--------+
65 //                     |  Page  |  Page  |  Page  |
66 //                     +--------+--------+--------+
67 //                     | Chunk  |        | Chunk  |
68 //                     +--------+  Chunk +--------+ <----+
69 //                     | Chunk  |        | Chunk  |      |
70 //                     +--------+--------+--------+      +---------------------+
71 //                                                       |       Service       |
72 // +------------+      +--------------------------+      +---------------------+
73 // | Producer 2 |  <-> |      SMB 2 [~32K - 1MB]  |     /| large ring buffers  |
74 // +------------+      +--------+--------+--------+ <--+ | (100K - several MB) |
75 //                     |  Page  |  Page  |  Page  |      +---------------------+
76 //                     +--------+--------+--------+
77 //                     | Chunk  |        | Chunk  |
78 //                     +--------+  Chunk +--------+
79 //                     | Chunk  |        | Chunk  |
80 //                     +--------+--------+--------+
81 //
82 // * Sizes of both SMB and ring buffers are purely indicative and decided at
83 // configuration time by the Producer (for SMB sizes) and the Consumer (for the
84 // final ring buffer size).
85 
86 // Page
87 // ----
88 // A page is a portion of the shared memory buffer and defines the granularity
89 // of the interaction between the Producer and tracing Service. When scanning
90 // the shared memory buffer to determine if something should be moved to the
91 // central logging buffers, the Service most of the times looks at and moves
92 // whole pages. Similarly, the Producer sends an IPC to invite the Service to
93 // drain the shared memory buffer only when a whole page is filled.
94 // Having fixed the total SMB size (hence the total memory overhead), the page
95 // size is a triangular tradeoff between:
96 // 1) IPC traffic: smaller pages -> more IPCs.
97 // 2) Producer lock freedom: larger pages -> larger chunks -> data sources can
98 //    write more data without needing to swap chunks and synchronize.
99 // 3) Risk of write-starving the SMB: larger pages -> higher chance that the
100 //    Service won't manage to drain them and the SMB remains full.
101 // The page size, on the other side, has no implications on wasted memory due to
102 // fragmentations (see Chunk below).
103 // The size of the page is chosen by the Service at connection time and stays
104 // fixed throughout all the lifetime of the Producer. Different producers (i.e.
105 // ~ different client processes) can use different page sizes.
106 // The page size must be an integer multiple of 4k (this is to allow VM page
107 // stealing optimizations) and obviously has to be an integer divisor of the
108 // total SMB size.
109 
110 // Chunk
111 // -----
112 // A chunk is a portion of a Page which is written and handled by a Producer.
113 // A chunk contains a linear sequence of TracePacket(s) (the root proto).
114 // A chunk cannot be written concurrently by two data sources. Protobufs must be
115 // encoded as contiguous byte streams and cannot be interleaved. Therefore, on
116 // the Producer side, a chunk is almost always owned exclusively by one thread
117 // (% extremely peculiar slow-path cases).
118 // Chunks are essentially single-writer single-thread lock-free arenas. Locking
119 // happens only when a Chunk is full and a new one needs to be acquired.
120 // Locking happens only within the scope of a Producer process. There is no
121 // inter-process locking. The Producer cannot lock the Service and viceversa.
122 // In the worst case, any of the two can starve the SMB, by marking all chunks
123 // as either being read or written. But that has the only side effect of
124 // losing the trace data.
125 // The Producer can decide to partition each page into a number of limited
126 // configurations (e.g., 1 page == 1 chunk, 1 page == 2 chunks and so on).
127 
128 // TracePacket
129 // -----------
130 // Is the atom of tracing. Putting aside pages and chunks a trace is merely a
131 // sequence of TracePacket(s). TracePacket is the root protobuf message.
132 // A TracePacket can span across several chunks (hence even across several
133 // pages). A TracePacket can therefore be >> chunk size, >> page size and even
134 // >> SMB size. The Chunk header carries metadata to deal with the TracePacket
135 // splitting case.
136 
137 // Use only explicitly-sized types below. DO NOT use size_t or any architecture
138 // dependent size (e.g. size_t) in the struct fields. This buffer will be read
139 // and written by processes that have a different bitness in the same OS.
140 // Instead it's fine to assume little-endianess. Big-endian is a dream we are
141 // not currently pursuing.
142 
143 class SharedMemoryABI {
144  public:
145   // This is due to Chunk::size being 16 bits.
146   static constexpr size_t kMaxPageSize = 64 * 1024;
147 
148   // "14" is the max number that can be encoded in a 32 bit atomic word using
149   // 2 state bits per Chunk and leaving 4 bits for the page layout.
150   // See PageLayout below.
151   static constexpr size_t kMaxChunksPerPage = 14;
152 
153   // Each TracePacket in the Chunk is prefixed by a 4 bytes redundant VarInt
154   // (see proto_utils.h) stating its size.
155   static constexpr size_t kPacketHeaderSize = 4;
156 
157   // Chunk states and transitions:
158   //    kChunkFree  <----------------+
159   //         |  (Producer)           |
160   //         V                       |
161   //  kChunkBeingWritten             |
162   //         |  (Producer)           |
163   //         V                       |
164   //  kChunkComplete                 |
165   //         |  (Service)            |
166   //         V                       |
167   //  kChunkBeingRead                |
168   //        |   (Service)            |
169   //        +------------------------+
170   enum ChunkState : uint32_t {
171     // The Chunk is free. The Service shall never touch it, the Producer can
172     // acquire it and transition it into kChunkBeingWritten.
173     kChunkFree = 0,
174 
175     // The Chunk is being used by the Producer and is not complete yet.
176     // The Service shall never touch kChunkBeingWritten pages.
177     kChunkBeingWritten = 1,
178 
179     // The Service is moving the page into its non-shared ring buffer. The
180     // Producer shall never touch kChunkBeingRead pages.
181     kChunkBeingRead = 2,
182 
183     // The Producer is done writing the page and won't touch it again. The
184     // Service can now move it to its non-shared ring buffer.
185     // kAllChunksComplete relies on this being == 3.
186     kChunkComplete = 3,
187   };
188   static constexpr const char* kChunkStateStr[] = {"Free", "BeingWritten",
189                                                    "BeingRead", "Complete"};
190 
191   enum PageLayout : uint32_t {
192     // The page is fully free and has not been partitioned yet.
193     kPageNotPartitioned = 0,
194 
195     // TODO(primiano): Aligning a chunk @ 16 bytes could allow to use faster
196     // intrinsics based on quad-word moves. Do the math and check what is the
197     // fragmentation loss.
198 
199     // align4(X) := the largest integer N s.t. (N % 4) == 0 && N <= X.
200     // 8 == sizeof(PageHeader).
201     kPageDiv1 = 1,   // Only one chunk of size: PAGE_SIZE - 8.
202     kPageDiv2 = 2,   // Two chunks of size: align4((PAGE_SIZE - 8) / 2).
203     kPageDiv4 = 3,   // Four chunks of size: align4((PAGE_SIZE - 8) / 4).
204     kPageDiv7 = 4,   // Seven chunks of size: align4((PAGE_SIZE - 8) / 7).
205     kPageDiv14 = 5,  // Fourteen chunks of size: align4((PAGE_SIZE - 8) / 14).
206 
207     // The rationale for 7 and 14 above is to maximize the page usage for the
208     // likely case of |page_size| == 4096:
209     // (((4096 - 8) / 14) % 4) == 0, while (((4096 - 8) / 16 % 4)) == 3. So
210     // Div16 would waste 3 * 16 = 48 bytes per page for chunk alignment gaps.
211 
212     kPageDivReserved1 = 6,
213     kPageDivReserved2 = 7,
214     kNumPageLayouts = 8,
215   };
216 
217   // Keep this consistent with the PageLayout enum above.
218   static constexpr uint32_t kNumChunksForLayout[] = {0, 1, 2, 4, 7, 14, 0, 0};
219 
220   // Layout of a Page.
221   // +===================================================+
222   // | Page header [8 bytes]                             |
223   // | Tells how many chunks there are, how big they are |
224   // | and their state (free, read, write, complete).    |
225   // +===================================================+
226   // +***************************************************+
227   // | Chunk #0 header [8 bytes]                         |
228   // | Tells how many packets there are and whether the  |
229   // | whether the 1st and last ones are fragmented.     |
230   // | Also has a chunk id to reassemble fragments.    |
231   // +***************************************************+
232   // +---------------------------------------------------+
233   // | Packet #0 size [varint, up to 4 bytes]            |
234   // + - - - - - - - - - - - - - - - - - - - - - - - - - +
235   // | Packet #0 payload                                 |
236   // | A TracePacket protobuf message                    |
237   // +---------------------------------------------------+
238   //                         ...
239   // + . . . . . . . . . . . . . . . . . . . . . . . . . +
240   // |      Optional padding to maintain aligment        |
241   // + . . . . . . . . . . . . . . . . . . . . . . . . . +
242   // +---------------------------------------------------+
243   // | Packet #N size [varint, up to 4 bytes]            |
244   // + - - - - - - - - - - - - - - - - - - - - - - - - - +
245   // | Packet #N payload                                 |
246   // | A TracePacket protobuf message                    |
247   // +---------------------------------------------------+
248   //                         ...
249   // +***************************************************+
250   // | Chunk #M header [8 bytes]                         |
251   //                         ...
252 
253   // Alignment applies to start offset only. The Chunk size is *not* aligned.
254   static constexpr uint32_t kChunkAlignment = 4;
255   static constexpr uint32_t kChunkShift = 2;
256   static constexpr uint32_t kChunkMask = 0x3;
257   static constexpr uint32_t kLayoutMask = 0x70000000;
258   static constexpr uint32_t kLayoutShift = 28;
259   static constexpr uint32_t kAllChunksMask = 0x0FFFFFFF;
260 
261   // This assumes that kChunkComplete == 3.
262   static constexpr uint32_t kAllChunksComplete = 0x0FFFFFFF;
263   static constexpr uint32_t kAllChunksFree = 0;
264   static constexpr size_t kInvalidPageIdx = static_cast<size_t>(-1);
265 
266   // There is one page header per page, at the beginning of the page.
267   struct PageHeader {
268     // |layout| bits:
269     // [31] [30:28] [27:26] ... [1:0]
270     //  |      |       |     |    |
271     //  |      |       |     |    +---------- ChunkState[0]
272     //  |      |       |     +--------------- ChunkState[12..1]
273     //  |      |       +--------------------- ChunkState[13]
274     //  |      +----------------------------- PageLayout (0 == page fully free)
275     //  +------------------------------------ Reserved for future use
276     std::atomic<uint32_t> layout;
277 
278     // If we'll ever going to use this in the future it might come handy
279     // reviving the kPageBeingPartitioned logic (look in git log, it was there
280     // at some point in the past).
281     uint32_t reserved;
282   };
283 
284   // There is one Chunk header per chunk (hence PageLayout per page) at the
285   // beginning of each chunk.
286   struct ChunkHeader {
287     enum Flags : uint8_t {
288       // If set, the first TracePacket in the chunk is partial and continues
289       // from |chunk_id| - 1 (within the same |writer_id|).
290       kFirstPacketContinuesFromPrevChunk = 1 << 0,
291 
292       // If set, the last TracePacket in the chunk is partial and continues on
293       // |chunk_id| + 1 (within the same |writer_id|).
294       kLastPacketContinuesOnNextChunk = 1 << 1,
295 
296       // If set, the last (fragmented) TracePacket in the chunk has holes (even
297       // if the chunk is marked as kChunkComplete) that need to be patched
298       // out-of-band before the chunk can be read.
299       kChunkNeedsPatching = 1 << 2,
300     };
301 
302     struct Packets {
303       // Number of valid TracePacket protobuf messages contained in the chunk.
304       // Each TracePacket is prefixed by its own size. This field is
305       // monotonically updated by the Producer with release store semantic when
306       // the packet at position |count| is started. This last packet may not be
307       // considered complete until |count| is incremented for the subsequent
308       // packet or the chunk is completed.
309       uint16_t count : 10;
310       static constexpr size_t kMaxCount = (1 << 10) - 1;
311 
312       // See Flags above.
313       uint16_t flags : 6;
314     };
315 
316     // A monotonic counter of the chunk within the scoped of a |writer_id|.
317     // The tuple (ProducerID, WriterID, ChunkID) allows to figure out if two
318     // chunks are contiguous (and hence a trace packets spanning across them can
319     // be glued) or we had some holes due to the ring buffer wrapping.
320     // This is set only when transitioning from kChunkFree to kChunkBeingWritten
321     // and remains unchanged throughout the remaining lifetime of the chunk.
322     std::atomic<uint32_t> chunk_id;
323 
324     // ID of the writer, unique within the producer.
325     // Like |chunk_id|, this is set only when transitioning from kChunkFree to
326     // kChunkBeingWritten.
327     std::atomic<uint16_t> writer_id;
328 
329     // There is no ProducerID here. The service figures that out from the IPC
330     // channel, which is unspoofable.
331 
332     // Updated with release-store semantics.
333     std::atomic<Packets> packets;
334   };
335 
336   class Chunk {
337    public:
338     Chunk();  // Constructs an invalid chunk.
339 
340     // Chunk is move-only, to document the scope of the Acquire/Release
341     // TryLock operations below.
342     Chunk(const Chunk&) = delete;
343     Chunk operator=(const Chunk&) = delete;
344     Chunk(Chunk&&) noexcept;
345     Chunk& operator=(Chunk&&);
346 
begin()347     uint8_t* begin() const { return begin_; }
end()348     uint8_t* end() const { return begin_ + size_; }
349 
350     // Size, including Chunk header.
size()351     size_t size() const { return size_; }
352 
353     // Begin of the first packet (or packet fragment).
payload_begin()354     uint8_t* payload_begin() const { return begin_ + sizeof(ChunkHeader); }
payload_size()355     size_t payload_size() const {
356       PERFETTO_DCHECK(size_ >= sizeof(ChunkHeader));
357       return size_ - sizeof(ChunkHeader);
358     }
359 
is_valid()360     bool is_valid() const { return begin_ && size_; }
361 
362     // Index of the chunk within the page [0..13] (13 comes from kPageDiv14).
chunk_idx()363     uint8_t chunk_idx() const { return chunk_idx_; }
364 
header()365     ChunkHeader* header() { return reinterpret_cast<ChunkHeader*>(begin_); }
366 
writer_id()367     uint16_t writer_id() {
368       return header()->writer_id.load(std::memory_order_relaxed);
369     }
370 
371     // Returns the count of packets and the flags with acquire-load semantics.
GetPacketCountAndFlags()372     std::pair<uint16_t, uint8_t> GetPacketCountAndFlags() {
373       auto packets = header()->packets.load(std::memory_order_acquire);
374       const uint16_t packets_count = packets.count;
375       const uint8_t packets_flags = packets.flags;
376       return std::make_pair(packets_count, packets_flags);
377     }
378 
379     // Increases |packets.count| with release semantics (note, however, that the
380     // packet count is incremented *before* starting writing a packet). Returns
381     // the new packet count. The increment is atomic but NOT race-free (i.e. no
382     // CAS). Only the Producer is supposed to perform this increment, and it's
383     // supposed to do that in a thread-safe way (holding a lock). A Chunk cannot
384     // be shared by multiple Producer threads without locking. The packet count
385     // is cleared by TryAcquireChunk(), when passing the new header for the
386     // chunk.
IncrementPacketCount()387     uint16_t IncrementPacketCount() {
388       ChunkHeader* chunk_header = header();
389       auto packets = chunk_header->packets.load(std::memory_order_relaxed);
390       packets.count++;
391       chunk_header->packets.store(packets, std::memory_order_release);
392       return packets.count;
393     }
394 
395     // Increases |packets.count| to the given |packet_count|, but only if
396     // |packet_count| is larger than the current value of |packets.count|.
397     // Returns the new packet count. Same atomicity guarantees as
398     // IncrementPacketCount().
IncreasePacketCountTo(uint16_t packet_count)399     uint16_t IncreasePacketCountTo(uint16_t packet_count) {
400       ChunkHeader* chunk_header = header();
401       auto packets = chunk_header->packets.load(std::memory_order_relaxed);
402       if (packets.count < packet_count)
403         packets.count = packet_count;
404       chunk_header->packets.store(packets, std::memory_order_release);
405       return packets.count;
406     }
407 
408     // Flags are cleared by TryAcquireChunk(), by passing the new header for
409     // the chunk.
SetFlag(ChunkHeader::Flags flag)410     void SetFlag(ChunkHeader::Flags flag) {
411       ChunkHeader* chunk_header = header();
412       auto packets = chunk_header->packets.load(std::memory_order_relaxed);
413       packets.flags |= flag;
414       chunk_header->packets.store(packets, std::memory_order_release);
415     }
416 
417    private:
418     friend class SharedMemoryABI;
419     Chunk(uint8_t* begin, uint16_t size, uint8_t chunk_idx);
420 
421     // Don't add extra fields, keep the move operator fast.
422     uint8_t* begin_ = nullptr;
423     uint16_t size_ = 0;
424     uint8_t chunk_idx_ = 0;
425   };
426 
427   // Construct an instance from an existing shared memory buffer.
428   SharedMemoryABI(uint8_t* start, size_t size, size_t page_size);
429   SharedMemoryABI();
430 
431   void Initialize(uint8_t* start, size_t size, size_t page_size);
432 
start()433   uint8_t* start() const { return start_; }
end()434   uint8_t* end() const { return start_ + size_; }
size()435   size_t size() const { return size_; }
page_size()436   size_t page_size() const { return page_size_; }
num_pages()437   size_t num_pages() const { return num_pages_; }
is_valid()438   bool is_valid() { return num_pages() > 0; }
439 
page_start(size_t page_idx)440   uint8_t* page_start(size_t page_idx) {
441     PERFETTO_DCHECK(page_idx < num_pages_);
442     return start_ + page_size_ * page_idx;
443   }
444 
page_header(size_t page_idx)445   PageHeader* page_header(size_t page_idx) {
446     return reinterpret_cast<PageHeader*>(page_start(page_idx));
447   }
448 
449   // Returns true if the page is fully clear and has not been partitioned yet.
450   // The state of the page can change at any point after this returns (or even
451   // before). The Producer should use this only as a hint to decide out whether
452   // it should TryPartitionPage() or acquire an individual chunk.
is_page_free(size_t page_idx)453   bool is_page_free(size_t page_idx) {
454     return page_header(page_idx)->layout.load(std::memory_order_relaxed) == 0;
455   }
456 
457   // Returns true if all chunks in the page are kChunkComplete. As above, this
458   // is advisory only. The Service is supposed to use this only to decide
459   // whether to TryAcquireAllChunksForReading() or not.
is_page_complete(size_t page_idx)460   bool is_page_complete(size_t page_idx) {
461     auto layout = page_header(page_idx)->layout.load(std::memory_order_relaxed);
462     const uint32_t num_chunks = GetNumChunksForLayout(layout);
463     if (num_chunks == 0)
464       return false;  // Non partitioned pages cannot be complete.
465     return (layout & kAllChunksMask) ==
466            (kAllChunksComplete & ((1 << (num_chunks * kChunkShift)) - 1));
467   }
468 
469   // For testing / debugging only.
page_header_dbg(size_t page_idx)470   std::string page_header_dbg(size_t page_idx) {
471     uint32_t x = page_header(page_idx)->layout.load(std::memory_order_relaxed);
472     return std::bitset<32>(x).to_string();
473   }
474 
475   // Returns the page layout, which is a bitmap that specifies the chunking
476   // layout of the page and each chunk's current state. Reads with an
477   // acquire-load semantic to ensure a producer's writes corresponding to an
478   // update of the layout (e.g. clearing a chunk's header) are observed
479   // consistently.
GetPageLayout(size_t page_idx)480   uint32_t GetPageLayout(size_t page_idx) {
481     return page_header(page_idx)->layout.load(std::memory_order_acquire);
482   }
483 
484   // Returns a bitmap in which each bit is set if the corresponding Chunk exists
485   // in the page (according to the page layout) and is free. If the page is not
486   // partitioned it returns 0 (as if the page had no free chunks).
487   uint32_t GetFreeChunks(size_t page_idx);
488 
489   // Tries to atomically partition a page with the given |layout|. Returns true
490   // if the page was free and has been partitioned with the given |layout|,
491   // false if the page wasn't free anymore by the time we got there.
492   // If succeeds all the chunks are atomically set in the kChunkFree state.
493   bool TryPartitionPage(size_t page_idx, PageLayout layout);
494 
495   // Tries to atomically mark a single chunk within the page as
496   // kChunkBeingWritten. Returns an invalid chunk if the page is not partitioned
497   // or the chunk is not in the kChunkFree state. If succeeds sets the chunk
498   // header to |header|.
TryAcquireChunkForWriting(size_t page_idx,size_t chunk_idx,const ChunkHeader * header)499   Chunk TryAcquireChunkForWriting(size_t page_idx,
500                                   size_t chunk_idx,
501                                   const ChunkHeader* header) {
502     return TryAcquireChunk(page_idx, chunk_idx, kChunkBeingWritten, header);
503   }
504 
505   // Similar to TryAcquireChunkForWriting. Fails if the chunk isn't in the
506   // kChunkComplete state.
TryAcquireChunkForReading(size_t page_idx,size_t chunk_idx)507   Chunk TryAcquireChunkForReading(size_t page_idx, size_t chunk_idx) {
508     return TryAcquireChunk(page_idx, chunk_idx, kChunkBeingRead, nullptr);
509   }
510 
511   // The caller must have successfully TryAcquireAllChunksForReading().
512   Chunk GetChunkUnchecked(size_t page_idx,
513                           uint32_t page_layout,
514                           size_t chunk_idx);
515 
516   // Puts a chunk into the kChunkComplete state. Returns the page index.
ReleaseChunkAsComplete(Chunk chunk)517   size_t ReleaseChunkAsComplete(Chunk chunk) {
518     return ReleaseChunk(std::move(chunk), kChunkComplete);
519   }
520 
521   // Puts a chunk into the kChunkFree state. Returns the page index.
ReleaseChunkAsFree(Chunk chunk)522   size_t ReleaseChunkAsFree(Chunk chunk) {
523     return ReleaseChunk(std::move(chunk), kChunkFree);
524   }
525 
GetChunkState(size_t page_idx,size_t chunk_idx)526   ChunkState GetChunkState(size_t page_idx, size_t chunk_idx) {
527     PageHeader* phdr = page_header(page_idx);
528     uint32_t layout = phdr->layout.load(std::memory_order_relaxed);
529     return GetChunkStateFromLayout(layout, chunk_idx);
530   }
531 
532   std::pair<size_t, size_t> GetPageAndChunkIndex(const Chunk& chunk);
533 
GetChunkSizeForLayout(uint32_t page_layout)534   uint16_t GetChunkSizeForLayout(uint32_t page_layout) const {
535     return chunk_sizes_[(page_layout & kLayoutMask) >> kLayoutShift];
536   }
537 
GetChunkStateFromLayout(uint32_t page_layout,size_t chunk_idx)538   static ChunkState GetChunkStateFromLayout(uint32_t page_layout,
539                                             size_t chunk_idx) {
540     return static_cast<ChunkState>((page_layout >> (chunk_idx * kChunkShift)) &
541                                    kChunkMask);
542   }
543 
GetNumChunksForLayout(uint32_t page_layout)544   static constexpr uint32_t GetNumChunksForLayout(uint32_t page_layout) {
545     return kNumChunksForLayout[(page_layout & kLayoutMask) >> kLayoutShift];
546   }
547 
548   // Returns a bitmap in which each bit is set if the corresponding Chunk exists
549   // in the page (according to the page layout) and is not free. If the page is
550   // not partitioned it returns 0 (as if the page had no used chunks). Bit N
551   // corresponds to Chunk N.
GetUsedChunks(uint32_t page_layout)552   static uint32_t GetUsedChunks(uint32_t page_layout) {
553     const uint32_t num_chunks = GetNumChunksForLayout(page_layout);
554     uint32_t res = 0;
555     for (uint32_t i = 0; i < num_chunks; i++) {
556       res |= ((page_layout & kChunkMask) != kChunkFree) ? (1 << i) : 0;
557       page_layout >>= kChunkShift;
558     }
559     return res;
560   }
561 
562  private:
563   SharedMemoryABI(const SharedMemoryABI&) = delete;
564   SharedMemoryABI& operator=(const SharedMemoryABI&) = delete;
565 
566   Chunk TryAcquireChunk(size_t page_idx,
567                         size_t chunk_idx,
568                         ChunkState,
569                         const ChunkHeader*);
570   size_t ReleaseChunk(Chunk chunk, ChunkState);
571 
572   uint8_t* start_ = nullptr;
573   size_t size_ = 0;
574   size_t page_size_ = 0;
575   size_t num_pages_ = 0;
576   std::array<uint16_t, kNumPageLayouts> chunk_sizes_;
577 };
578 
579 }  // namespace perfetto
580 
581 #endif  // INCLUDE_PERFETTO_TRACING_CORE_SHARED_MEMORY_ABI_H_
582