1 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #include "base/metrics/stats_table.h"
7 #include "base/logging.h"
8 #include "base/memory/scoped_ptr.h"
9 #include "base/memory/shared_memory.h"
10 #include "base/process/process_handle.h"
11 #include "base/strings/string_piece.h"
12 #include "base/strings/string_util.h"
13 #include "base/strings/utf_string_conversions.h"
14 #include "base/threading/platform_thread.h"
15 #include "base/threading/thread_local_storage.h"
19 // The StatsTable uses a shared memory segment that is laid out as follows
21 // +-------------------------------------------+
22 // | Version | Size | MaxCounters | MaxThreads |
23 // +-------------------------------------------+
24 // | Thread names table |
25 // +-------------------------------------------+
26 // | Thread TID table |
27 // +-------------------------------------------+
28 // | Thread PID table |
29 // +-------------------------------------------+
30 // | Counter names table |
31 // +-------------------------------------------+
33 // +-------------------------------------------+
35 // The data layout is a grid, where the columns are the thread_ids and the
36 // rows are the counter_ids.
38 // If the first character of the thread_name is '\0', then that column is
40 // If the first character of the counter_name is '\0', then that row is
44 // This class is designed to be both multi-thread and multi-process safe.
45 // Aside from initialization, this is done by partitioning the data which
46 // each thread uses so that no locking is required. However, to allocate
47 // the rows and columns of the table to particular threads, locking is
50 // At the shared-memory level, we have a lock. This lock protects the
51 // shared-memory table only, and is used when we create new counters (e.g.
52 // use rows) or when we register new threads (e.g. use columns). Reading
53 // data from the table does not require any locking at the shared memory
56 // Each process which accesses the table will create a StatsTable object.
57 // The StatsTable maintains a hash table of the existing counters in the
58 // table for faster lookup. Since the hash table is process specific,
59 // each process maintains its own cache. We avoid complexity here by never
60 // de-allocating from the hash table. (Counters are dynamically added,
61 // but not dynamically removed).
63 // In order for external viewers to be able to read our shared memory,
64 // we all need to use the same size ints.
65 COMPILE_ASSERT(sizeof(int)==4, expect_4_byte_ints
);
69 // An internal version in case we ever change the format of this
70 // file, and so that we can identify our table.
71 const int kTableVersion
= 0x13131313;
73 // The name for un-named counters and threads in the table.
74 const char kUnknownName
[] = "<unknown>";
76 // Calculates delta to align an offset to the size of an int
77 inline int AlignOffset(int offset
) {
78 return (sizeof(int) - (offset
% sizeof(int))) % sizeof(int);
81 inline int AlignedSize(int size
) {
82 return size
+ AlignOffset(size
);
87 // The StatsTable::Internal maintains convenience pointers into the
88 // shared memory segment. Use this class to keep the data structure
89 // clean and accessible.
90 class StatsTable::Internal
{
92 // Various header information contained in the memory mapped segment.
100 // Construct a new Internal based on expected size parameters, or
101 // return NULL on failure.
102 static Internal
* New(const StatsTable::TableIdentifier
& table
,
107 SharedMemory
* shared_memory() { return shared_memory_
.get(); }
109 // Accessors for our header pointers
110 TableHeader
* table_header() const { return table_header_
; }
111 int version() const { return table_header_
->version
; }
112 int size() const { return table_header_
->size
; }
113 int max_counters() const { return table_header_
->max_counters
; }
114 int max_threads() const { return table_header_
->max_threads
; }
116 // Accessors for our tables
117 char* thread_name(int slot_id
) const {
118 return &thread_names_table_
[
119 (slot_id
-1) * (StatsTable::kMaxThreadNameLength
)];
121 PlatformThreadId
* thread_tid(int slot_id
) const {
122 return &(thread_tid_table_
[slot_id
-1]);
124 int* thread_pid(int slot_id
) const {
125 return &(thread_pid_table_
[slot_id
-1]);
127 char* counter_name(int counter_id
) const {
128 return &counter_names_table_
[
129 (counter_id
-1) * (StatsTable::kMaxCounterNameLength
)];
131 int* row(int counter_id
) const {
132 return &data_table_
[(counter_id
-1) * max_threads()];
136 // Constructor is private because you should use New() instead.
137 explicit Internal(SharedMemory
* shared_memory
)
138 : shared_memory_(shared_memory
),
140 thread_names_table_(NULL
),
141 thread_tid_table_(NULL
),
142 thread_pid_table_(NULL
),
143 counter_names_table_(NULL
),
147 // Create or open the SharedMemory used by the stats table.
148 static SharedMemory
* CreateSharedMemory(
149 const StatsTable::TableIdentifier
& table
,
152 // Initializes the table on first access. Sets header values
153 // appropriately and zeroes all counters.
154 void InitializeTable(void* memory
, int size
, int max_counters
,
157 // Initializes our in-memory pointers into a pre-created StatsTable.
158 void ComputeMappedPointers(void* memory
);
160 scoped_ptr
<SharedMemory
> shared_memory_
;
161 TableHeader
* table_header_
;
162 char* thread_names_table_
;
163 PlatformThreadId
* thread_tid_table_
;
164 int* thread_pid_table_
;
165 char* counter_names_table_
;
168 DISALLOW_COPY_AND_ASSIGN(Internal
);
172 StatsTable::Internal
* StatsTable::Internal::New(
173 const StatsTable::TableIdentifier
& table
,
177 scoped_ptr
<SharedMemory
> shared_memory(CreateSharedMemory(table
, size
));
178 if (!shared_memory
.get())
180 if (!shared_memory
->Map(size
))
182 void* memory
= shared_memory
->memory();
184 scoped_ptr
<Internal
> internal(new Internal(shared_memory
.release()));
185 TableHeader
* header
= static_cast<TableHeader
*>(memory
);
187 // If the version does not match, then assume the table needs
188 // to be initialized.
189 if (header
->version
!= kTableVersion
)
190 internal
->InitializeTable(memory
, size
, max_counters
, max_threads
);
192 // We have a valid table, so compute our pointers.
193 internal
->ComputeMappedPointers(memory
);
195 return internal
.release();
199 SharedMemory
* StatsTable::Internal::CreateSharedMemory(
200 const StatsTable::TableIdentifier
& table
,
202 #if defined(OS_POSIX)
203 // Check for existing table.
205 return new SharedMemory(table
, false);
207 // Otherwise we need to create it.
208 scoped_ptr
<SharedMemory
> shared_memory(new SharedMemory());
209 if (!shared_memory
->CreateAnonymous(size
))
211 return shared_memory
.release();
212 #elif defined(OS_WIN)
213 scoped_ptr
<SharedMemory
> shared_memory(new SharedMemory());
215 // Create an anonymous table.
216 if (!shared_memory
->CreateAnonymous(size
))
219 // Create a named table for sharing between processes.
220 if (!shared_memory
->CreateNamedDeprecated(table
, true, size
))
223 return shared_memory
.release();
227 void StatsTable::Internal::InitializeTable(void* memory
, int size
,
231 memset(memory
, 0, size
);
233 // Initialize the header.
234 TableHeader
* header
= static_cast<TableHeader
*>(memory
);
235 header
->version
= kTableVersion
;
237 header
->max_counters
= max_counters
;
238 header
->max_threads
= max_threads
;
241 void StatsTable::Internal::ComputeMappedPointers(void* memory
) {
242 char* data
= static_cast<char*>(memory
);
245 table_header_
= reinterpret_cast<TableHeader
*>(data
);
246 offset
+= sizeof(*table_header_
);
247 offset
+= AlignOffset(offset
);
249 // Verify we're looking at a valid StatsTable.
250 DCHECK_EQ(table_header_
->version
, kTableVersion
);
252 thread_names_table_
= reinterpret_cast<char*>(data
+ offset
);
253 offset
+= sizeof(char) *
254 max_threads() * StatsTable::kMaxThreadNameLength
;
255 offset
+= AlignOffset(offset
);
257 thread_tid_table_
= reinterpret_cast<PlatformThreadId
*>(data
+ offset
);
258 offset
+= sizeof(int) * max_threads();
259 offset
+= AlignOffset(offset
);
261 thread_pid_table_
= reinterpret_cast<int*>(data
+ offset
);
262 offset
+= sizeof(int) * max_threads();
263 offset
+= AlignOffset(offset
);
265 counter_names_table_
= reinterpret_cast<char*>(data
+ offset
);
266 offset
+= sizeof(char) *
267 max_counters() * StatsTable::kMaxCounterNameLength
;
268 offset
+= AlignOffset(offset
);
270 data_table_
= reinterpret_cast<int*>(data
+ offset
);
271 offset
+= sizeof(int) * max_threads() * max_counters();
273 DCHECK_EQ(offset
, size());
276 // TLSData carries the data stored in the TLS slots for the
277 // StatsTable. This is used so that we can properly cleanup when the
278 // thread exits and return the table slot.
280 // Each thread that calls RegisterThread in the StatsTable will have
281 // a TLSData stored in its TLS.
282 struct StatsTable::TLSData
{
287 // We keep a singleton table which can be easily accessed.
288 StatsTable
* global_table
= NULL
;
290 StatsTable::StatsTable(const TableIdentifier
& table
,
294 tls_index_(SlotReturnFunction
) {
296 AlignedSize(sizeof(Internal::TableHeader
)) +
297 AlignedSize((max_counters
* sizeof(char) * kMaxCounterNameLength
)) +
298 AlignedSize((max_threads
* sizeof(char) * kMaxThreadNameLength
)) +
299 AlignedSize(max_threads
* sizeof(int)) +
300 AlignedSize(max_threads
* sizeof(int)) +
301 AlignedSize((sizeof(int) * (max_counters
* max_threads
)));
303 internal_
= Internal::New(table
, table_size
, max_threads
, max_counters
);
306 DPLOG(ERROR
) << "StatsTable did not initialize";
309 StatsTable::~StatsTable() {
310 // Before we tear down our copy of the table, be sure to
311 // unregister our thread.
314 // Return ThreadLocalStorage. At this point, if any registered threads
315 // still exist, they cannot Unregister.
318 // Cleanup our shared memory.
321 // If we are the global table, unregister ourselves.
322 if (global_table
== this)
326 StatsTable
* StatsTable::current() {
330 void StatsTable::set_current(StatsTable
* value
) {
331 global_table
= value
;
334 int StatsTable::GetSlot() const {
335 TLSData
* data
= GetTLSData();
341 int StatsTable::RegisterThread(const std::string
& name
) {
346 // Registering a thread requires that we lock the shared memory
347 // so that two threads don't grab the same slot. Fortunately,
348 // thread creation shouldn't happen in inner loops.
349 // TODO(viettrungluu): crbug.com/345734: Use a different locking mechanism.
351 SharedMemoryAutoLockDeprecated
lock(internal_
->shared_memory());
352 slot
= FindEmptyThread();
357 // We have space, so consume a column in the table.
358 std::string thread_name
= name
;
360 thread_name
= kUnknownName
;
361 strlcpy(internal_
->thread_name(slot
), thread_name
.c_str(),
362 kMaxThreadNameLength
);
363 *(internal_
->thread_tid(slot
)) = PlatformThread::CurrentId();
364 *(internal_
->thread_pid(slot
)) = GetCurrentProcId();
367 // Set our thread local storage.
368 TLSData
* data
= new TLSData
;
371 tls_index_
.Set(data
);
375 int StatsTable::CountThreadsRegistered() const {
379 // Loop through the shared memory and count the threads that are active.
380 // We intentionally do not lock the table during the operation.
382 for (int index
= 1; index
<= internal_
->max_threads(); index
++) {
383 char* name
= internal_
->thread_name(index
);
390 int StatsTable::FindCounter(const std::string
& name
) {
391 // Note: the API returns counters numbered from 1..N, although
392 // internally, the array is 0..N-1. This is so that we can return
393 // zero as "not found".
397 // Create a scope for our auto-lock.
399 AutoLock
scoped_lock(counters_lock_
);
401 // Attempt to find the counter.
402 CountersMap::const_iterator iter
;
403 iter
= counters_
.find(name
);
404 if (iter
!= counters_
.end())
408 // Counter does not exist, so add it.
409 return AddCounter(name
);
412 int* StatsTable::GetLocation(int counter_id
, int slot_id
) const {
415 if (slot_id
> internal_
->max_threads())
418 int* row
= internal_
->row(counter_id
);
419 return &(row
[slot_id
-1]);
422 const char* StatsTable::GetRowName(int index
) const {
426 return internal_
->counter_name(index
);
429 int StatsTable::GetRowValue(int index
) const {
430 return GetRowValue(index
, 0);
433 int StatsTable::GetRowValue(int index
, int pid
) const {
438 int* row
= internal_
->row(index
);
439 for (int slot_id
= 1; slot_id
<= internal_
->max_threads(); slot_id
++) {
440 if (pid
== 0 || *internal_
->thread_pid(slot_id
) == pid
)
441 rv
+= row
[slot_id
-1];
446 int StatsTable::GetCounterValue(const std::string
& name
) {
447 return GetCounterValue(name
, 0);
450 int StatsTable::GetCounterValue(const std::string
& name
, int pid
) {
454 int row
= FindCounter(name
);
457 return GetRowValue(row
, pid
);
460 int StatsTable::GetMaxCounters() const {
463 return internal_
->max_counters();
466 int StatsTable::GetMaxThreads() const {
469 return internal_
->max_threads();
472 int* StatsTable::FindLocation(const char* name
) {
473 // Get the static StatsTable
474 StatsTable
*table
= StatsTable::current();
478 // Get the slot for this thread. Try to register
479 // it if none exists.
480 int slot
= table
->GetSlot();
482 slot
= table
->RegisterThread(std::string());
486 // Find the counter id for the counter.
487 std::string
str_name(name
);
488 int counter
= table
->FindCounter(str_name
);
490 // Now we can find the location in the table.
491 return table
->GetLocation(counter
, slot
);
494 void StatsTable::UnregisterThread() {
495 UnregisterThread(GetTLSData());
498 void StatsTable::UnregisterThread(TLSData
* data
) {
503 // Mark the slot free by zeroing out the thread name.
504 char* name
= internal_
->thread_name(data
->slot
);
507 // Remove the calling thread's TLS so that it cannot use the slot.
508 tls_index_
.Set(NULL
);
512 void StatsTable::SlotReturnFunction(void* data
) {
513 // This is called by the TLS destructor, which on some platforms has
514 // already cleared the TLS info, so use the tls_data argument
515 // rather than trying to fetch it ourselves.
516 TLSData
* tls_data
= static_cast<TLSData
*>(data
);
518 DCHECK(tls_data
->table
);
519 tls_data
->table
->UnregisterThread(tls_data
);
523 int StatsTable::FindEmptyThread() const {
524 // Note: the API returns slots numbered from 1..N, although
525 // internally, the array is 0..N-1. This is so that we can return
526 // zero as "not found".
528 // The reason for doing this is because the thread 'slot' is stored
529 // in TLS, which is always initialized to zero, not -1. If 0 were
530 // returned as a valid slot number, it would be confused with the
531 // uninitialized state.
536 for (; index
<= internal_
->max_threads(); index
++) {
537 char* name
= internal_
->thread_name(index
);
541 if (index
> internal_
->max_threads())
542 return 0; // The table is full.
546 int StatsTable::FindCounterOrEmptyRow(const std::string
& name
) const {
547 // Note: the API returns slots numbered from 1..N, although
548 // internally, the array is 0..N-1. This is so that we can return
549 // zero as "not found".
551 // There isn't much reason for this other than to be consistent
552 // with the way we track columns for thread slots. (See comments
553 // in FindEmptyThread for why it is done this way).
558 for (int index
= 1; index
<= internal_
->max_counters(); index
++) {
559 char* row_name
= internal_
->counter_name(index
);
560 if (!*row_name
&& !free_slot
)
561 free_slot
= index
; // save that we found a free slot
562 else if (!strncmp(row_name
, name
.c_str(), kMaxCounterNameLength
))
568 int StatsTable::AddCounter(const std::string
& name
) {
574 // To add a counter to the shared memory, we need the
575 // shared memory lock.
576 SharedMemoryAutoLockDeprecated
lock(internal_
->shared_memory());
578 // We have space, so create a new counter.
579 counter_id
= FindCounterOrEmptyRow(name
);
583 std::string counter_name
= name
;
585 counter_name
= kUnknownName
;
586 strlcpy(internal_
->counter_name(counter_id
), counter_name
.c_str(),
587 kMaxCounterNameLength
);
590 // now add to our in-memory cache
592 AutoLock
lock(counters_lock_
);
593 counters_
[name
] = counter_id
;
598 StatsTable::TLSData
* StatsTable::GetTLSData() const {
600 static_cast<TLSData
*>(tls_index_
.Get());
605 DCHECK_EQ(data
->table
, this);
609 #if defined(OS_POSIX)
610 SharedMemoryHandle
StatsTable::GetSharedMemoryHandle() const {
612 return SharedMemory::NULLHandle();
613 return internal_
->shared_memory()->handle();