kmp_itt.h source code [openmp/runtime/src/kmp_itt.h]

1	#if USE_ITT_BUILD
2	/*
3	* kmp_itt.h -- ITT Notify interface.
4	*/
5
6	//===----------------------------------------------------------------------===//
7	//
8	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
9	// See https://llvm.org/LICENSE.txt for license information.
10	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
11	//
12	//===----------------------------------------------------------------------===//
13
14	#ifndef KMP_ITT_H
15	#define KMP_ITT_H
16
17	#include "kmp_lock.h"
18
19	#define INTEL_ITTNOTIFY_API_PRIVATE
20	#include "ittnotify.h"
21	#include "legacy/ittnotify.h"
22
23	#if KMP_DEBUG
24	#define __kmp_inline // Turn off inlining in debug mode.
25	#else
26	#define __kmp_inline static inline
27	#endif
28
29	#if USE_ITT_NOTIFY
30	extern kmp_int32 __kmp_itt_prepare_delay;
31	#ifdef __cplusplus
32	extern "C" void __kmp_itt_fini_ittlib(void);
33	#else
34	extern void __kmp_itt_fini_ittlib(void);
35	#endif
36	#endif
37
38	// Simplify the handling of an argument that is only required when USE_ITT_BUILD
39	// is enabled.
40	#define USE_ITT_BUILD_ARG(x) , x
41
42	void __kmp_itt_initialize();
43	void __kmp_itt_destroy();
44	void __kmp_itt_reset();
45
46	// -----------------------------------------------------------------------------
47	// New stuff for reporting high-level constructs.
48
49	// Note the naming convention:
50	// __kmp_itt_xxxing() function should be called before action, while
51	// __kmp_itt_xxxed() function should be called after action.
52
53	// --- Parallel region reporting ---
54	__kmp_inline void
55	__kmp_itt_region_forking(int gtid, int team_size,
56	int barriers); // Primary only, before forking threads.
57	__kmp_inline void
58	__kmp_itt_region_joined(int gtid); // Primary only, after joining threads.
59	// () Note: A thread may execute tasks after this point, though.*
60
61	// --- Frame reporting ---
62	// region=0: no regions, region=1: parallel, region=2: serialized parallel
63	__kmp_inline void __kmp_itt_frame_submit(int gtid, __itt_timestamp begin,
64	__itt_timestamp end, int imbalance,
65	ident_t loc, int* team_size,
66	int region = `0`);
67
68	// --- Metadata reporting ---
69	// begin/end - begin/end timestamps of a barrier frame, imbalance - aggregated
70	// wait time value, reduction -if this is a reduction barrier
71	__kmp_inline void __kmp_itt_metadata_imbalance(int gtid, kmp_uint64 begin,
72	kmp_uint64 end,
73	kmp_uint64 imbalance,
74	kmp_uint64 reduction);
75	// sched_type: 0 - static, 1 - dynamic, 2 - guided, 3 - custom (all others);
76	// iterations - loop trip count, chunk - chunk size
77	__kmp_inline void __kmp_itt_metadata_loop(ident_t *loc, kmp_uint64 sched_type,
78	kmp_uint64 iterations,
79	kmp_uint64 chunk);
80	__kmp_inline void __kmp_itt_metadata_single(ident_t *loc);
81
82	// --- Barrier reporting ---
83	__kmp_inline void __kmp_itt_barrier_object(int* gtid, int bt, int set_name = `0`,
84	int delta = `0`);
85	__kmp_inline void __kmp_itt_barrier_starting(int gtid, void *object);
86	__kmp_inline void __kmp_itt_barrier_middle(int gtid, void *object);
87	__kmp_inline void __kmp_itt_barrier_finished(int gtid, void *object);
88
89	// --- Taskwait reporting ---
90	__kmp_inline void __kmp_itt_taskwait_object(int* gtid);
91	__kmp_inline void __kmp_itt_taskwait_starting(int gtid, void *object);
92	__kmp_inline void __kmp_itt_taskwait_finished(int gtid, void *object);
93	#define KMP_ITT_TASKWAIT_STARTING(obj) \
94	if (UNLIKELY(__itt_sync_create_ptr)) { \
95	obj = __kmp_itt_taskwait_object(gtid); \
96	if (obj != NULL) { \
97	__kmp_itt_taskwait_starting(gtid, obj); \
98	} \
99	}
100	#define KMP_ITT_TASKWAIT_FINISHED(obj) \
101	if (UNLIKELY(obj != NULL)) \
102	__kmp_itt_taskwait_finished(gtid, obj);
103
104	// --- Task reporting ---
105	__kmp_inline void __kmp_itt_task_starting(void *object);
106	__kmp_inline void __kmp_itt_task_finished(void *object);
107
108	// --- Lock reporting ---
109	#if KMP_USE_DYNAMIC_LOCK
110	__kmp_inline void __kmp_itt_lock_creating(kmp_user_lock_p lock,
111	const ident_t *);
112	#else
113	__kmp_inline void __kmp_itt_lock_creating(kmp_user_lock_p lock);
114	#endif
115	__kmp_inline void __kmp_itt_lock_acquiring(kmp_user_lock_p lock);
116	__kmp_inline void __kmp_itt_lock_acquired(kmp_user_lock_p lock);
117	__kmp_inline void __kmp_itt_lock_releasing(kmp_user_lock_p lock);
118	__kmp_inline void __kmp_itt_lock_cancelled(kmp_user_lock_p lock);
119	__kmp_inline void __kmp_itt_lock_destroyed(kmp_user_lock_p lock);
120
121	// --- Critical reporting ---
122	#if KMP_USE_DYNAMIC_LOCK
123	__kmp_inline void __kmp_itt_critical_creating(kmp_user_lock_p lock,
124	const ident_t *);
125	#else
126	__kmp_inline void __kmp_itt_critical_creating(kmp_user_lock_p lock);
127	#endif
128	__kmp_inline void __kmp_itt_critical_acquiring(kmp_user_lock_p lock);
129	__kmp_inline void __kmp_itt_critical_acquired(kmp_user_lock_p lock);
130	__kmp_inline void __kmp_itt_critical_releasing(kmp_user_lock_p lock);
131	__kmp_inline void __kmp_itt_critical_destroyed(kmp_user_lock_p lock);
132
133	// --- Single reporting ---
134	__kmp_inline void __kmp_itt_single_start(int gtid);
135	__kmp_inline void __kmp_itt_single_end(int gtid);
136
137	// --- Ordered reporting ---
138	__kmp_inline void __kmp_itt_ordered_init(int gtid);
139	__kmp_inline void __kmp_itt_ordered_prep(int gtid);
140	__kmp_inline void __kmp_itt_ordered_start(int gtid);
141	__kmp_inline void __kmp_itt_ordered_end(int gtid);
142
143	// --- Threads reporting ---
144	__kmp_inline void __kmp_itt_thread_ignore();
145	__kmp_inline void __kmp_itt_thread_name(int gtid);
146
147	// --- System objects ---
148	__kmp_inline void __kmp_itt_system_object_created(void *object,
149	char const *name);
150
151	// --- Stack stitching ---
152	__kmp_inline __itt_caller __kmp_itt_stack_caller_create(void);
153	__kmp_inline void __kmp_itt_stack_caller_destroy(__itt_caller);
154	__kmp_inline void __kmp_itt_stack_callee_enter(__itt_caller);
155	__kmp_inline void __kmp_itt_stack_callee_leave(__itt_caller);
156
157	// -----------------------------------------------------------------------------
158	// Old stuff for reporting low-level internal synchronization.
159
160	#if USE_ITT_NOTIFY
161
162	/ Support for SSC marks, which are used by SDE*
163	http://software.intel.com/en-us/articles/intel-software-development-emulator
164	to mark points in instruction traces that represent spin-loops and are
165	therefore uninteresting when collecting traces for architecture simulation.
166	*/
167	#ifndef INCLUDE_SSC_MARKS
168	#define INCLUDE_SSC_MARKS (KMP_OS_LINUX && KMP_ARCH_X86_64)
169	#endif
170
171	/ Linux 64 only for now /
172	#if (INCLUDE_SSC_MARKS && KMP_OS_LINUX && KMP_ARCH_X86_64)
173	// Portable (at least for gcc and icc) code to insert the necessary instructions
174	// to set %ebx and execute the unlikely no-op.
175	#if defined(__INTEL_COMPILER)
176	#define INSERT_SSC_MARK(tag) __SSC_MARK(tag)
177	#else
178	#define INSERT_SSC_MARK(tag) \
179	__asm__ __volatile__("movl %0, %%ebx; .byte 0x64, 0x67, 0x90 " ::"i"(tag) \
180	: "%ebx")
181	#endif
182	#else
183	#define INSERT_SSC_MARK(tag) ((void)0)
184	#endif
185
186	/ Markers for the start and end of regions that represent polling and are*
187	therefore uninteresting to architectural simulations 0x4376 and 0x4377 are
188	arbitrary numbers that should be unique in the space of SSC tags, but there
189	is no central issuing authority rather randomness is expected to work. /*
190	#define SSC_MARK_SPIN_START() INSERT_SSC_MARK(0x4376)
191	#define SSC_MARK_SPIN_END() INSERT_SSC_MARK(0x4377)
192
193	// Markers for architecture simulation.
194	// FORKING : Before the primary thread forks.
195	// JOINING : At the start of the join.
196	// INVOKING : Before the threads invoke microtasks.
197	// DISPATCH_INIT: At the start of dynamically scheduled loop.
198	// DISPATCH_NEXT: After claming next iteration of dynamically scheduled loop.
199	#define SSC_MARK_FORKING() INSERT_SSC_MARK(0xd693)
200	#define SSC_MARK_JOINING() INSERT_SSC_MARK(0xd694)
201	#define SSC_MARK_INVOKING() INSERT_SSC_MARK(0xd695)
202	#define SSC_MARK_DISPATCH_INIT() INSERT_SSC_MARK(0xd696)
203	#define SSC_MARK_DISPATCH_NEXT() INSERT_SSC_MARK(0xd697)
204
205	// The object is an address that associates a specific set of the prepare,
206	// acquire, release, and cancel operations.
207
208	/ Sync prepare indicates a thread is going to start waiting for another thread*
209	to send a release event. This operation should be done just before the
210	thread begins checking for the existence of the release event /*
211
212	/ Sync cancel indicates a thread is cancelling a wait on another thread and*
213	continuing execution without waiting for the other thread to release it /*
214
215	/ Sync acquired indicates a thread has received a release event from another*
216	thread and has stopped waiting. This operation must occur only after the
217	release event is received. /*
218
219	/ Sync release indicates a thread is going to send a release event to another*
220	thread so it will stop waiting and continue execution. This operation must
221	just happen before the release event. /*
222
223	#define KMP_FSYNC_PREPARE(obj) __itt_fsync_prepare((void *)(obj))
224	#define KMP_FSYNC_CANCEL(obj) __itt_fsync_cancel((void *)(obj))
225	#define KMP_FSYNC_ACQUIRED(obj) __itt_fsync_acquired((void *)(obj))
226	#define KMP_FSYNC_RELEASING(obj) __itt_fsync_releasing((void *)(obj))
227
228	/ In case of waiting in a spin loop, ITT wants KMP_FSYNC_PREPARE() to be called*
229	with a delay (and not called at all if waiting time is small). So, in spin
230	loops, do not use KMP_FSYNC_PREPARE(), but use KMP_FSYNC_SPIN_INIT() (before
231	spin loop), KMP_FSYNC_SPIN_PREPARE() (whithin the spin loop), and
232	KMP_FSYNC_SPIN_ACQUIRED(). See KMP_WAIT() for example. /*
233
234	#undef KMP_FSYNC_SPIN_INIT
235	#define KMP_FSYNC_SPIN_INIT(obj, spin) \
236	int sync_iters = 0; \
237	if (__itt_fsync_prepare_ptr) { \
238	if (obj == NULL) { \
239	obj = spin; \
240	} /* if */ \
241	} /* if */ \
242	SSC_MARK_SPIN_START()
243
244	#undef KMP_FSYNC_SPIN_PREPARE
245	#define KMP_FSYNC_SPIN_PREPARE(obj) \
246	do { \
247	if (__itt_fsync_prepare_ptr && sync_iters < __kmp_itt_prepare_delay) { \
248	++sync_iters; \
249	if (sync_iters >= __kmp_itt_prepare_delay) { \
250	KMP_FSYNC_PREPARE((void *)obj); \
251	} /* if */ \
252	} /* if */ \
253	} while (0)
254	#undef KMP_FSYNC_SPIN_ACQUIRED
255	#define KMP_FSYNC_SPIN_ACQUIRED(obj) \
256	do { \
257	SSC_MARK_SPIN_END(); \
258	if (sync_iters >= __kmp_itt_prepare_delay) { \
259	KMP_FSYNC_ACQUIRED((void *)obj); \
260	} /* if */ \
261	} while (0)
262
263	/ ITT will not report objects created within KMP_ITT_IGNORE(), e. g.:*
264	KMP_ITT_IGNORE(
265	ptr = malloc( size );
266	);
267	*/
268	#define KMP_ITT_IGNORE(statement) \
269	do { \
270	__itt_state_t __itt_state_; \
271	if (__itt_state_get_ptr) { \
272	__itt_state_ = __itt_state_get(); \
273	__itt_obj_mode_set(__itt_obj_prop_ignore, __itt_obj_state_set); \
274	} /* if */ \
275	{ statement } \
276	if (__itt_state_get_ptr) { \
277	__itt_state_set(__itt_state_); \
278	} /* if */ \
279	} while (0)
280
281	// Maximum number of frame domains to use (maps to
282	// different OpenMP regions in the user source code).
283	const int KMP_MAX_FRAME_DOMAINS = `997`;
284	typedef struct kmp_itthash_entry {
285	ident_t *loc;
286	int team_size;
287	__itt_domain *d;
288	struct kmp_itthash_entry *next_in_bucket;
289	} kmp_itthash_entry_t;
290	typedef struct kmp_itthash {
291	kmp_itthash_entry_t *buckets[KMP_MAX_FRAME_DOMAINS];
292	int count; // just a heuristic to limit number of entries
293	} kmp_itthash_t;
294	extern kmp_itthash_t __kmp_itt_region_domains;
295	extern kmp_itthash_t __kmp_itt_barrier_domains;
296	extern __itt_domain *metadata_domain;
297	extern __itt_string_handle *string_handle_imbl;
298	extern __itt_string_handle *string_handle_loop;
299	extern __itt_string_handle *string_handle_sngl;
300
301	#else
302
303	// Null definitions of the synchronization tracing functions.
304	#define KMP_FSYNC_PREPARE(obj) ((void)0)
305	#define KMP_FSYNC_CANCEL(obj) ((void)0)
306	#define KMP_FSYNC_ACQUIRED(obj) ((void)0)
307	#define KMP_FSYNC_RELEASING(obj) ((void)0)
308
309	#define KMP_FSYNC_SPIN_INIT(obj, spin) ((void)0)
310	#define KMP_FSYNC_SPIN_PREPARE(obj) ((void)0)
311	#define KMP_FSYNC_SPIN_ACQUIRED(obj) ((void)0)
312
313	#define KMP_ITT_IGNORE(stmt) \
314	do { \
315	stmt \
316	} while (0)
317
318	#endif // USE_ITT_NOTIFY
319
320	#if !KMP_DEBUG
321	// In release mode include definitions of inline functions.
322	#include "kmp_itt.inl"
323	#endif
324
325	#endif // KMP_ITT_H
326
327	#else /* USE_ITT_BUILD */
328
329	// Null definitions of the synchronization tracing functions.
330	// If USE_ITT_BULID is not enabled, USE_ITT_NOTIFY cannot be either.
331	// By defining these we avoid unpleasant ifdef tests in many places.
332	#define KMP_FSYNC_PREPARE(obj) ((void)0)
333	#define KMP_FSYNC_CANCEL(obj) ((void)0)
334	#define KMP_FSYNC_ACQUIRED(obj) ((void)0)
335	#define KMP_FSYNC_RELEASING(obj) ((void)0)
336
337	#define KMP_FSYNC_SPIN_INIT(obj, spin) ((void)0)
338	#define KMP_FSYNC_SPIN_PREPARE(obj) ((void)0)
339	#define KMP_FSYNC_SPIN_ACQUIRED(obj) ((void)0)
340
341	#define KMP_ITT_IGNORE(stmt) \
342	do { \
343	stmt \
344	} while (0)
345
346	#define USE_ITT_BUILD_ARG(x)
347
348	#endif /* USE_ITT_BUILD */
349

source code of openmp/runtime/src/kmp_itt.h