1/*-
2 * Copyright (c) 1996 Berkeley Software Design, Inc. All rights reserved.
3 *
4 * Redistribution and use in source and binary forms, with or without
5 * modification, are permitted provided that the following conditions
6 * are met:
7 * 1. Redistributions of source code must retain the above copyright
8 *    notice, this list of conditions and the following disclaimer.
9 * 2. Redistributions in binary form must reproduce the above copyright
10 *    notice, this list of conditions and the following disclaimer in the
11 *    documentation and/or other materials provided with the distribution.
12 * 3. Berkeley Software Design Inc's name may not be used to endorse or
13 *    promote products derived from this software without specific prior
14 *    written permission.
15 *
16 * THIS SOFTWARE IS PROVIDED BY BERKELEY SOFTWARE DESIGN INC ``AS IS'' AND
17 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
18 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
19 * ARE DISCLAIMED.  IN NO EVENT SHALL BERKELEY SOFTWARE DESIGN INC BE LIABLE
20 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
21 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
22 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
23 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
24 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
25 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
26 * SUCH DAMAGE.
27 *
28 *	from BSDI $Id: ktr.h,v 1.10.2.7 2000/03/16 21:44:42 cp Exp $
29 * $FreeBSD$
30 */
31
32/*
33 *	Wraparound kernel trace buffer support.
34 */
35
36#ifndef _SYS_KTR_H_
37#define _SYS_KTR_H_
38
39/*
40 * Trace classes
41 *
42 * Two of the trace classes (KTR_DEV and KTR_SUBSYS) are special in that
43 * they are really placeholders so that indvidual drivers and subsystems
44 * can map their internal tracing to the general class when they wish to
45 * have tracing enabled and map it to 0 when they don't.
46 */
47#define	KTR_GEN		0x00000001		/* General (TR) */
48#define	KTR_NET		0x00000002		/* Network */
49#define	KTR_DEV		0x00000004		/* Device driver */
50#define	KTR_LOCK	0x00000008		/* MP locking */
51#define	KTR_SMP		0x00000010		/* MP general */
52#define	KTR_SUBSYS	0x00000020		/* Subsystem. */
53#define	KTR_PMAP	0x00000040		/* Pmap tracing */
54#define	KTR_MALLOC	0x00000080		/* Malloc tracing */
55#define	KTR_TRAP	0x00000100		/* Trap processing */
56#define	KTR_INTR	0x00000200		/* Interrupt tracing */
57#define	KTR_SIG		0x00000400		/* Signal processing */
58#define	KTR_SPARE2	0x00000800		/* XXX Used by cxgb */
59#define	KTR_PROC	0x00001000		/* Process scheduling */
60#define	KTR_SYSC	0x00002000		/* System call */
61#define	KTR_INIT	0x00004000		/* System initialization */
62#define	KTR_SPARE3	0x00008000		/* XXX Used by cxgb */
63#define	KTR_SPARE4	0x00010000		/* XXX Used by cxgb */
64#define	KTR_EVH		0x00020000		/* Eventhandler */
65#define	KTR_VFS		0x00040000		/* VFS events */
66#define	KTR_VOP		0x00080000		/* Auto-generated vop events */
67#define	KTR_VM		0x00100000		/* The virtual memory system */
68#define	KTR_INET	0x00200000		/* IPv4 stack */
69#define	KTR_RUNQ	0x00400000		/* Run queue */
70#define	KTR_CONTENTION	0x00800000		/* Lock contention */
71#define	KTR_UMA		0x01000000		/* UMA slab allocator */
72#define	KTR_CALLOUT	0x02000000		/* Callouts and timeouts */
73#define	KTR_GEOM	0x04000000		/* GEOM I/O events */
74#define	KTR_BUSDMA	0x08000000		/* busdma(9) events */
75#define	KTR_INET6	0x10000000		/* IPv6 stack */
76#define	KTR_SCHED	0x20000000		/* Machine parsed sched info. */
77#define	KTR_BUF		0x40000000		/* Buffer cache */
78#define	KTR_ALL		0x7fffffff
79
80/* Trace classes to compile in */
81#ifdef KTR
82#ifndef KTR_COMPILE
83#define	KTR_COMPILE	(KTR_ALL)
84#endif
85#else	/* !KTR */
86#undef KTR_COMPILE
87#define KTR_COMPILE 0
88#endif	/* KTR */
89
90/*
91 * Version number for ktr_entry struct.  Increment this when you break binary
92 * compatibility.
93 */
94#define	KTR_VERSION	2
95
96#define	KTR_PARMS	6
97
98#ifndef LOCORE
99
100#include <sys/param.h>
101#include <sys/_cpuset.h>
102
103struct ktr_entry {
104	u_int64_t ktr_timestamp;
105	int	ktr_cpu;
106	int	ktr_line;
107	const	char *ktr_file;
108	const	char *ktr_desc;
109	struct	thread *ktr_thread;
110	u_long	ktr_parms[KTR_PARMS];
111};
112
113extern cpuset_t ktr_cpumask;
114extern int ktr_mask;
115extern int ktr_entries;
116extern int ktr_verbose;
117
118extern volatile int ktr_idx;
119extern struct ktr_entry *ktr_buf;
120
121#ifdef KTR
122
123void	ktr_tracepoint(u_int mask, const char *file, int line,
124	    const char *format, u_long arg1, u_long arg2, u_long arg3,
125	    u_long arg4, u_long arg5, u_long arg6);
126
127#define CTR6(m, format, p1, p2, p3, p4, p5, p6) do {			\
128	if (KTR_COMPILE & (m))						\
129		ktr_tracepoint((m), __FILE__, __LINE__, format,		\
130		    (u_long)(p1), (u_long)(p2), (u_long)(p3),		\
131		    (u_long)(p4), (u_long)(p5), (u_long)(p6));		\
132	} while(0)
133#define CTR0(m, format)			CTR6(m, format, 0, 0, 0, 0, 0, 0)
134#define CTR1(m, format, p1)		CTR6(m, format, p1, 0, 0, 0, 0, 0)
135#define	CTR2(m, format, p1, p2)		CTR6(m, format, p1, p2, 0, 0, 0, 0)
136#define	CTR3(m, format, p1, p2, p3)	CTR6(m, format, p1, p2, p3, 0, 0, 0)
137#define	CTR4(m, format, p1, p2, p3, p4)	CTR6(m, format, p1, p2, p3, p4, 0, 0)
138#define	CTR5(m, format, p1, p2, p3, p4, p5)	CTR6(m, format, p1, p2, p3, p4, p5, 0)
139#else	/* KTR */
140#define	CTR0(m, d)			(void)0
141#define	CTR1(m, d, p1)			(void)0
142#define	CTR2(m, d, p1, p2)		(void)0
143#define	CTR3(m, d, p1, p2, p3)		(void)0
144#define	CTR4(m, d, p1, p2, p3, p4)	(void)0
145#define	CTR5(m, d, p1, p2, p3, p4, p5)	(void)0
146#define	CTR6(m, d, p1, p2, p3, p4, p5, p6)	(void)0
147#endif	/* KTR */
148
149#define	TR0(d)				CTR0(KTR_GEN, d)
150#define	TR1(d, p1)			CTR1(KTR_GEN, d, p1)
151#define	TR2(d, p1, p2)			CTR2(KTR_GEN, d, p1, p2)
152#define	TR3(d, p1, p2, p3)		CTR3(KTR_GEN, d, p1, p2, p3)
153#define	TR4(d, p1, p2, p3, p4)		CTR4(KTR_GEN, d, p1, p2, p3, p4)
154#define	TR5(d, p1, p2, p3, p4, p5)	CTR5(KTR_GEN, d, p1, p2, p3, p4, p5)
155#define	TR6(d, p1, p2, p3, p4, p5, p6)	CTR6(KTR_GEN, d, p1, p2, p3, p4, p5, p6)
156
157/*
158 * The event macros implement KTR graphic plotting facilities provided
159 * by src/tools/sched/schedgraph.py.  Three generic types of events are
160 * supported: states, counters, and points.
161 *
162 * m is the ktr class for ktr_mask.
163 * ident is the string identifier that owns the event (ie: "thread 10001")
164 * etype is the type of event to plot (state, counter, point)
165 * edat is the event specific data (state name, counter value, point name)
166 * up to four attributes may be supplied as a name, value pair of arguments.
167 *
168 * etype and attribute names must be string constants.  This minimizes the
169 * number of ktr slots required by construction the final format strings
170 * at compile time.  Both must also include a colon and format specifier
171 * (ie. "prio:%d", prio).  It is recommended that string arguments be
172 * contained within escaped quotes if they may contain ',' or ':' characters.
173 *
174 * The special attribute (KTR_ATTR_LINKED, ident) creates a reference to another
175 * id on the graph for easy traversal of related graph elements.
176 */
177
178#define	KTR_ATTR_LINKED	"linkedto:\"%s\""
179#define	KTR_EFMT(egroup, ident, etype)					\
180	    "KTRGRAPH group:\"" egroup "\", id:\"%s\", " etype ", attributes: "
181
182#define	KTR_EVENT0(m, egroup, ident, etype, edat)			\
183	CTR2(m,	KTR_EFMT(egroup, ident, etype) "none", ident, edat)
184#define	KTR_EVENT1(m, egroup, ident, etype, edat, a0, v0)		\
185	CTR3(m, KTR_EFMT(egroup, ident, etype) a0, ident, edat, (v0))
186#define	KTR_EVENT2(m, egroup, ident, etype, edat, a0, v0, a1, v1)	\
187	CTR4(m, KTR_EFMT(egroup, ident, etype) a0 ", " a1,		\
188	    ident, edat, (v0), (v1))
189#define	KTR_EVENT3(m, egroup, ident, etype, edat, a0, v0, a1, v1, a2, v2)\
190	CTR5(m,KTR_EFMT(egroup, ident, etype) a0 ", " a1 ", " a2,	\
191	    ident, edat, (v0), (v1), (v2))
192#define	KTR_EVENT4(m, egroup, ident, etype, edat,			\
193	    a0, v0, a1, v1, a2, v2, a3, v3)				\
194	CTR6(m,KTR_EFMT(egroup, ident, etype) a0 ", " a1 ", " a2 ", " a3,\
195	     ident, edat, (v0), (v1), (v2), (v3))
196
197/*
198 * State functions graph state changes on an ident.
199 */
200#define KTR_STATE0(m, egroup, ident, state)				\
201	KTR_EVENT0(m, egroup, ident, "state:\"%s\"", state)
202#define KTR_STATE1(m, egroup, ident, state, a0, v0)			\
203	KTR_EVENT1(m, egroup, ident, "state:\"%s\"", state, a0, (v0))
204#define KTR_STATE2(m, egroup, ident, state, a0, v0, a1, v1)		\
205	KTR_EVENT2(m, egroup, ident, "state:\"%s\"", state, a0, (v0), a1, (v1))
206#define KTR_STATE3(m, egroup, ident, state, a0, v0, a1, v1, a2, v2)	\
207	KTR_EVENT3(m, egroup, ident, "state:\"%s\"",			\
208	    state, a0, (v0), a1, (v1), a2, (v2))
209#define KTR_STATE4(m, egroup, ident, state, a0, v0, a1, v1, a2, v2, a3, v3)\
210	KTR_EVENT4(m, egroup, ident, "state:\"%s\"",			\
211	    state, a0, (v0), a1, (v1), a2, (v2), a3, (v3))
212
213/*
214 * Counter functions graph counter values.  The counter id
215 * must not be intermixed with a state id.
216 */
217#define	KTR_COUNTER0(m, egroup, ident, counter)				\
218	KTR_EVENT0(m, egroup, ident, "counter:%d", counter)
219#define	KTR_COUNTER1(m, egroup, ident, edat, a0, v0)			\
220	KTR_EVENT1(m, egroup, ident, "counter:%d", counter, a0, (v0))
221#define	KTR_COUNTER2(m, egroup, ident, counter, a0, v0, a1, v1)		\
222	KTR_EVENT2(m, egroup, ident, "counter:%d", counter, a0, (v0), a1, (v1))
223#define	KTR_COUNTER3(m, egroup, ident, counter, a0, v0, a1, v1, a2, v2)	\
224	KTR_EVENT3(m, egroup, ident, "counter:%d",			\
225	    counter, a0, (v0), a1, (v1), a2, (v2))
226#define	KTR_COUNTER4(m, egroup, ident, counter, a0, v0, a1, v1, a2, v2, a3, v3)\
227	KTR_EVENT4(m, egroup, ident, "counter:%d",			\
228	    counter, a0, (v0), a1, (v1), a2, (v2), a3, (v3))
229
230/*
231 * Point functions plot points of interest on counter or state graphs.
232 */
233#define	KTR_POINT0(m, egroup, ident, point)				\
234	KTR_EVENT0(m, egroup, ident, "point:\"%s\"", point)
235#define	KTR_POINT1(m, egroup, ident, point, a0, v0)			\
236	KTR_EVENT1(m, egroup, ident, "point:\"%s\"", point, a0, (v0))
237#define	KTR_POINT2(m, egroup, ident, point, a0, v0, a1, v1)		\
238	KTR_EVENT2(m, egroup, ident, "point:\"%s\"", point, a0, (v0), a1, (v1))
239#define	KTR_POINT3(m, egroup, ident, point, a0, v0, a1, v1, a2, v2)	\
240	KTR_EVENT3(m, egroup, ident, "point:\"%s\"", point,		\
241	    a0, (v0), a1, (v1), a2, (v2))
242#define	KTR_POINT4(m, egroup, ident, point, a0, v0, a1, v1, a2, v2, a3, v3)\
243	KTR_EVENT4(m, egroup, ident, "point:\"%s\"",			\
244	    point, a0, (v0), a1, (v1), a2, (v2), a3, (v3))
245
246/*
247 * Start functions denote the start of a region of code or operation
248 * and should be paired with stop functions for timing of nested
249 * sequences.
250 *
251 * Specifying extra attributes with the name "key" will result in
252 * multi-part keys.  For example a block device and offset pair
253 * might be used to describe a buf undergoing I/O.
254 */
255#define	KTR_START0(m, egroup, ident, key)				\
256	KTR_EVENT0(m, egroup, ident, "start:0x%jX", (uintmax_t)key)
257#define	KTR_START1(m, egroup, ident, key, a0, v0)			\
258	KTR_EVENT1(m, egroup, ident, "start:0x%jX", (uintmax_t)key, a0, (v0))
259#define	KTR_START2(m, egroup, ident, key, a0, v0, a1, v1)		\
260	KTR_EVENT2(m, egroup, ident, "start:0x%jX", (uintmax_t)key,	\
261	    a0, (v0), a1, (v1))
262#define	KTR_START3(m, egroup, ident, key, a0, v0, a1, v1, a2, v2)\
263	KTR_EVENT3(m, egroup, ident, "start:0x%jX", (uintmax_t)key,	\
264	    a0, (v0), a1, (v1), a2, (v2))
265#define	KTR_START4(m, egroup, ident, key,				\
266	    a0, v0, a1, v1, a2, v2, a3, v3)				\
267	KTR_EVENT4(m, egroup, ident, "start:0x%jX", (uintmax_t)key,	\
268	    a0, (v0), a1, (v1), a2, (v2), a3, (v3))
269
270/*
271 * Stop functions denote the end of a region of code or operation
272 * and should be paired with start functions for timing of nested
273 * sequences.
274 */
275#define	KTR_STOP0(m, egroup, ident, key)				\
276	KTR_EVENT0(m, egroup, ident, "stop:0x%jX", (uintmax_t)key)
277#define	KTR_STOP1(m, egroup, ident, key, a0, v0)			\
278	KTR_EVENT1(m, egroup, ident, "stop:0x%jX", (uintmax_t)key, a0, (v0))
279#define	KTR_STOP2(m, egroup, ident, key, a0, v0, a1, v1)		\
280	KTR_EVENT2(m, egroup, ident, "stop:0x%jX", (uintmax_t)key,	\
281	    a0, (v0), a1, (v1))
282#define	KTR_STOP3(m, egroup, ident, key, a0, v0, a1, v1, a2, v2)\
283	KTR_EVENT3(m, egroup, ident, "stop:0x%jX", (uintmax_t)key,	\
284	    a0, (v0), a1, (v1), a2, (v2))
285#define	KTR_STOP4(m, egroup, ident, 					\
286	    key, a0, v0, a1, v1, a2, v2, a3, v3)			\
287	KTR_EVENT4(m, egroup, ident, "stop:0x%jX", (uintmax_t)key,	\
288	    a0, (v0), a1, (v1), a2, (v2), a3, (v3))
289
290/*
291 * Trace initialization events, similar to CTR with KTR_INIT, but
292 * completely ifdef'ed out if KTR_INIT isn't in KTR_COMPILE (to
293 * save string space, the compiler doesn't optimize out strings
294 * for the conditional ones above).
295 */
296#if (KTR_COMPILE & KTR_INIT) != 0
297#define	ITR0(d)				CTR0(KTR_INIT, d)
298#define	ITR1(d, p1)			CTR1(KTR_INIT, d, p1)
299#define	ITR2(d, p1, p2)			CTR2(KTR_INIT, d, p1, p2)
300#define	ITR3(d, p1, p2, p3)		CTR3(KTR_INIT, d, p1, p2, p3)
301#define	ITR4(d, p1, p2, p3, p4)		CTR4(KTR_INIT, d, p1, p2, p3, p4)
302#define	ITR5(d, p1, p2, p3, p4, p5)	CTR5(KTR_INIT, d, p1, p2, p3, p4, p5)
303#define	ITR6(d, p1, p2, p3, p4, p5, p6)	CTR6(KTR_INIT, d, p1, p2, p3, p4, p5, p6)
304#else
305#define	ITR0(d)
306#define	ITR1(d, p1)
307#define	ITR2(d, p1, p2)
308#define	ITR3(d, p1, p2, p3)
309#define	ITR4(d, p1, p2, p3, p4)
310#define	ITR5(d, p1, p2, p3, p4, p5)
311#define	ITR6(d, p1, p2, p3, p4, p5, p6)
312#endif
313
314#endif /* !LOCORE */
315
316#endif /* !_SYS_KTR_H_ */
317