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--- old/usr/src/uts/i86pc/os/intr.c
+++ new/usr/src/uts/i86pc/os/intr.c
1 1 /*
2 2 * CDDL HEADER START
3 3 *
4 4 * The contents of this file are subject to the terms of the
5 5 * Common Development and Distribution License (the "License").
6 6 * You may not use this file except in compliance with the License.
7 7 *
8 8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 9 * or http://www.opensolaris.org/os/licensing.
10 10 * See the License for the specific language governing permissions
11 11 * and limitations under the License.
12 12 *
13 13 * When distributing Covered Code, include this CDDL HEADER in each
14 14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 15 * If applicable, add the following below this CDDL HEADER, with the
16 16 * fields enclosed by brackets "[]" replaced with your own identifying
17 17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 18 *
19 19 * CDDL HEADER END
20 20 */
21 21
22 22 /*
23 23 * Copyright (c) 2004, 2010, Oracle and/or its affiliates. All rights reserved.
24 24 * Copyright (c) 2012, Joyent, Inc. All rights reserverd.
25 25 */
26 26
27 27 /*
28 28 * To understand the present state of interrupt handling on i86pc, we must
29 29 * first consider the history of interrupt controllers and our way of handling
30 30 * interrupts.
31 31 *
32 32 * History of Interrupt Controllers on i86pc
33 33 * -----------------------------------------
34 34 *
35 35 * Intel 8259 and 8259A
36 36 *
37 37 * The first interrupt controller that attained widespread use on i86pc was
38 38 * the Intel 8259(A) Programmable Interrupt Controller that first saw use with
39 39 * the 8086. It took up to 8 interrupt sources and combined them into one
40 40 * output wire. Up to 8 8259s could be slaved together providing up to 64 IRQs.
41 41 * With the switch to the 8259A, level mode interrupts became possible. For a
42 42 * long time on i86pc the 8259A was the only way to handle interrupts and it
43 43 * had its own set of quirks. The 8259A and its corresponding interval timer
44 44 * the 8254 are programmed using outb and inb instructions.
45 45 *
46 46 * Intel Advanced Programmable Interrupt Controller (APIC)
47 47 *
48 48 * Starting around the time of the introduction of the P6 family
49 49 * microarchitecture (i686) Intel introduced a new interrupt controller.
50 50 * Instead of having the series of slaved 8259A devices, Intel opted to outfit
51 51 * each processor with a Local APIC (lapic) and to outfit the system with at
52 52 * least one, but potentially more, I/O APICs (ioapic). The lapics and ioapics
53 53 * initially communicated over a dedicated bus, but this has since been
54 54 * replaced. Each physical core and even hyperthread currently contains its
55 55 * own local apic, which is not shared. There are a few exceptions for
56 56 * hyperthreads, but that does not usually concern us.
57 57 *
58 58 * Instead of talking directly to 8259 for status, sending End Of Interrupt
59 59 * (EOI), etc. a microprocessor now communicates directly to the lapic. This
60 60 * also allows for each microprocessor to be able to have independent controls.
61 61 * The programming method is different from the 8259. Consumers map the lapic
62 62 * registers into uncacheable memory to read and manipulate the state.
63 63 *
64 64 * The number of addressable interrupt vectors was increased to 256. However
65 65 * vectors 0-31 are reserved for the processor exception handling, leaving the
66 66 * remaining vectors for general use. In addition to hardware generated
67 67 * interrupts, the lapic provides a way for generating inter-processor
68 68 * interrupts (IPI) which are the basis for CPU cross calls and CPU pokes.
69 69 *
70 70 * AMD ended up implementing the Intel APIC architecture in lieu of their work
71 71 * with Cyrix.
72 72 *
73 73 * Intel x2apic
74 74 *
75 75 * The x2apic is an extension to the lapic which started showing up around the
76 76 * same time as the Sandy Bridge chipsets. It provides a new programming mode
77 77 * as well as new features. The goal of the x2apic is to solve a few problems
78 78 * with the previous generation of lapic and the x2apic is backwards compatible
79 79 * with the previous programming and model. The only downsides to using the
80 80 * backwards compatibility is that you are not able to take advantage of the new
81 81 * x2apic features.
82 82 *
83 83 * o The APIC ID is increased from an 8-bit value to a 32-bit value. This
84 84 * increases the maximum number of addressable physical processors beyond
85 85 * 256. This new ID is assembled in a similar manner as the information that
86 86 * is obtainable by the extended cpuid topology leaves.
87 87 *
88 88 * o A new means of generating IPIs was introduced.
89 89 *
90 90 * o Instead of memory mapping the registers, the x2apic only allows for
91 91 * programming it through a series of wrmsrs. This has important semantic
92 92 * side effects. Recall that the registers were previously all mapped to
93 93 * uncachable memory which meant that all operations to the local apic were
94 94 * serializing instructions. With the switch to using wrmsrs this has been
95 95 * relaxed and these operations can no longer be assumed to be serializing
96 96 * instructions.
97 97 *
98 98 * Note for the rest of this we are only going to concern ourselves with the
99 99 * apic and x2apic which practically all of i86pc has been using now for
100 100 * quite some time.
101 101 *
102 102 * Interrupt Priority Levels
103 103 * -------------------------
104 104 *
105 105 * On i86pc systems there are a total of fifteen interrupt priority levels
106 106 * (ipls) which range from 1-15. Level 0 is for normal processing and
107 107 * non-interrupt processing. To manipulate these values the family of spl
108 108 * functions (which date back to UNIX on the PDP-11) are used. Specifically,
109 109 * splr() to raise the priority level and splx() to lower it. One should not
110 110 * generally call setspl() directly.
111 111 *
112 112 * Both i86pc and the supported SPARC platforms honor the same conventions for
113 113 * the meaning behind these IPLs. The most important IPL is the platform's
114 114 * LOCK_LEVEL (0xa on i86pc). If a thread is above LOCK_LEVEL it _must_ not
115 115 * sleep on any synchronization object. The only allowed synchronization
116 116 * primitive is a mutex that has been specifically initialized to be a spin
117 117 * lock (see mutex_init(9F)). Another important level is DISP_LEVEL (0xb on
118 118 * i86pc). You must be at DISP_LEVEL if you want to control the dispatcher.
119 119 * The XC_HI_PIL is the highest level (0xf) and is used during cross-calls.
120 120 *
121 121 * Each interrupt that is registered in the system fires at a specific IPL.
122 122 * Generally most interrupts fire below LOCK_LEVEL.
123 123 *
124 124 * PSM Drivers
125 125 * -----------
126 126 *
127 127 * We currently have three sets of PSM (platform specific module) drivers
128 128 * available. uppc, pcplusmp, and apix. uppc (uni-processor PC) is the original
129 129 * driver that interacts with the 8259A and 8254. In general, it is not used
130 130 * anymore given the prevalence of the apic.
131 131 *
132 132 * The system prefers to use the apix driver over the pcplusmp driver. The apix
133 133 * driver requires HW support for an x2apic. If there is no x2apic HW, apix
134 134 * will not be used. In general we prefer using the apix driver over the
135 135 * pcplusmp driver because it gives us much more flexibility with respect to
136 136 * interrupts. In the apix driver each local apic has its own independent set
137 137 * of interrupts, whereas the pcplusmp driver only has a single global set of
138 138 * interrupts. This is why pcplusmp only supports a finite number of interrupts
139 139 * per IPL -- generally 16, often less. The apix driver supports using either
140 140 * the x2apic or the local apic programing modes. The programming mode does not
141 141 * change the number of interrupts available, just the number of processors
142 142 * that we can address. For the apix driver, the x2apic mode is enabled if the
143 143 * system supports interrupt re-mapping, otherwise the module manages the
144 144 * x2apic in local mode.
145 145 *
146 146 * When there is no x2apic present, we default back to the pcplusmp PSM driver.
147 147 * In general, this is not problematic unless you have more than 256
148 148 * processors in the machine or you do not have enough interrupts available.
149 149 *
150 150 * Controlling Interrupt Generation on i86pc
151 151 * -----------------------------------------
152 152 *
153 153 * There are two different ways to manipulate which interrupts will be
154 154 * generated on i86pc. Each offers different degrees of control.
155 155 *
156 156 * The first is through the flags register (eflags and rflags on i386 and amd64
157 157 * respectively). The IF bit determines whether or not interrupts are enabled
158 158 * or disabled. This is manipulated in one of several ways. The most common way
159 159 * is through the cli and sti instructions. These clear the IF flag and set it,
160 160 * respectively, for the current processor. The other common way is through the
161 161 * use of the intr_clear and intr_restore functions.
162 162 *
163 163 * Assuming interrupts are not blocked by the IF flag, then the second form is
164 164 * through the Processor-Priority Register (PPR). The PPR is used to determine
165 165 * whether or not a pending interrupt should be delivered. If the ipl of the
166 166 * new interrupt is higher than the current value in the PPR, then the lapic
167 167 * will either deliver it immediately (if interrupts are not in progress) or it
168 168 * will deliver it once the current interrupt processing has issued an EOI. The
169 169 * highest unmasked interrupt will be the one delivered.
170 170 *
171 171 * The PPR register is based upon the max of the following two registers in the
172 172 * lapic, the TPR register (also known as CR8 on amd64) that can be used to
173 173 * mask interrupt levels, and the current vector. Because the pcplusmp module
174 174 * always sets TPR appropriately early in the do_interrupt path, we can usually
175 175 * just think that the PPR is the TPR. The pcplusmp module also issues an EOI
176 176 * once it has set the TPR, so higher priority interrupts can come in while
177 177 * we're servicing a lower priority interrupt.
178 178 *
179 179 * Handling Interrupts
180 180 * -------------------
181 181 *
182 182 * Interrupts can be broken down into three categories based on priority and
183 183 * source:
184 184 *
185 185 * o High level interrupts
186 186 * o Low level hardware interrupts
187 187 * o Low level software interrupts
188 188 *
189 189 * High Level Interrupts
190 190 *
191 191 * High level interrupts encompasses both hardware-sourced and software-sourced
192 192 * interrupts. Examples of high level hardware interrupts include the serial
193 193 * console. High level software-sourced interrupts are still delivered through
194 194 * the local apic through IPIs. This is primarily cross calls.
195 195 *
196 196 * When a high level interrupt comes in, we will raise the SPL and then pin the
197 197 * current lwp to the processor. We will use its lwp, but our own interrupt
198 198 * stack and process the high level interrupt in-situ. These handlers are
199 199 * designed to be very short in nature and cannot go to sleep, only block on a
200 200 * spin lock. If the interrupt has a lot of work to do, it must generate a
201 201 * low-priority software interrupt that will be processed later.
202 202 *
203 203 * Low level hardware interrupts
204 204 *
205 205 * Low level hardware interrupts start off like their high-level cousins. The
206 206 * current CPU contains a number of kernel threads (kthread_t) that can be used
207 207 * to process low level interrupts. These are shared between both low level
208 208 * hardware and software interrupts. Note that while we run with our
209 209 * kthread_t, we borrow the pinned threads lwp_t until such a time as we hit a
210 210 * synchronization object. If we hit one and need to sleep, then the scheduler
211 211 * will instead create the rest of what we need.
212 212 *
213 213 * Low level software interrupts
214 214 *
215 215 * Low level software interrupts are handled in a similar way as hardware
216 216 * interrupts, but the notification vector is different. Each CPU has a bitmask
217 217 * of pending software interrupts. We can notify a CPU to process software
218 218 * interrupts through a specific trap vector as well as through several
219 219 * checks that are performed throughout the code. These checks will look at
220 220 * processing software interrupts as we lower our spl.
221 221 *
222 222 * We attempt to process the highest pending software interrupt that we can
223 223 * which is greater than our current IPL. If none currently exist, then we move
224 224 * on. We process a software interrupt in a similar fashion to a hardware
225 225 * interrupt.
226 226 *
227 227 * Traditional Interrupt Flow
228 228 * --------------------------
229 229 *
230 230 * The following diagram tracks the flow of the traditional uppc and pcplusmp
231 231 * interrupt handlers. The apix driver has its own version of do_interrupt().
232 232 * We come into the interrupt handler with all interrupts masked by the IF
233 233 * flag. This is because we set up the handler using an interrupt-gate, which
234 234 * is defined architecturally to have cleared the IF flag for us.
235 235 *
236 236 * +--------------+ +----------------+ +-----------+
237 237 * | _interrupt() |--->| do_interrupt() |--->| *setlvl() |
238 238 * +--------------+ +----------------+ +-----------+
239 239 * | | |
240 240 * | | |
241 241 * low-level| | | softint
242 242 * HW int | | +---------------------------------------+
243 243 * +--------------+ | | |
244 244 * | intr_thread_ |<-----+ | hi-level int |
245 245 * | prolog() | | +----------+ |
246 246 * +--------------+ +--->| hilevel_ | Not on intr stack |
247 247 * | | intr_ |-----------------+ |
248 248 * | | prolog() | | |
249 249 * +------------+ +----------+ | |
250 250 * | switch_sp_ | | On intr v |
251 251 * | and_call() | | Stack +------------+ |
252 252 * +------------+ | | switch_sp_ | |
253 253 * | v | and_call() | |
254 254 * v +-----------+ +------------+ |
255 255 * +-----------+ | dispatch_ | | |
256 256 * | dispatch_ | +-------------------| hilevel() |<------------+ |
257 257 * | hardint() | | +-----------+ |
258 258 * +-----------+ | |
259 259 * | v |
260 260 * | +-----+ +----------------------+ +-----+ hi-level |
261 261 * +---->| sti |->| av_dispatch_autovect |->| cli |---------+ |
262 262 * +-----+ +----------------------+ +-----+ | |
263 263 * | | | |
264 264 * v | | |
265 265 * +----------+ | | |
266 266 * | for each | | | |
267 267 * | handler | | | |
268 268 * | *intr() | | v |
269 269 * +--------------+ +----------+ | +----------------+ |
270 270 * | intr_thread_ | low-level | | hilevel_intr_ | |
271 271 * | epilog() |<-------------------------------+ | epilog() | |
272 272 * +--------------+ +----------------+ |
273 273 * | | | |
274 274 * | +----------------------v v---------------------+ |
275 275 * | +------------+ |
276 276 * | +---------------------->| *setlvlx() | |
277 277 * | | +------------+ |
278 278 * | | | |
279 279 * | | v |
280 280 * | | +--------+ +------------------+ +-------------+ |
281 281 * | | | return |<----| softint pending? |----->| dosoftint() |<-----+
282 282 * | | +--------+ no +------------------+ yes +-------------+
283 283 * | | ^ | |
284 284 * | | | softint pil too low | |
285 285 * | | +--------------------------------------+ |
286 286 * | | v
287 287 * | | +-----------+ +------------+ +-----------+
288 288 * | | | dispatch_ |<-----| switch_sp_ |<---------| *setspl() |
289 289 * | | | softint() | | and_call() | +-----------+
290 290 * | | +-----------+ +------------+
291 291 * | | |
292 292 * | | v
293 293 * | | +-----+ +----------------------+ +-----+ +------------+
294 294 * | | | sti |->| av_dispatch_autovect |->| cli |->| dosoftint_ |
295 295 * | | +-----+ +----------------------+ +-----+ | epilog() |
296 296 * | | +------------+
297 297 * | | | |
298 298 * | +----------------------------------------------------+ |
299 299 * v |
300 300 * +-----------+ |
301 301 * | interrupt | |
302 302 * | thread |<---------------------------------------------------+
303 303 * | blocked |
304 304 * +-----------+
305 305 * |
306 306 * v
307 307 * +----------------+ +------------+ +-----------+ +-------+ +---------+
308 308 * | set_base_spl() |->| *setlvlx() |->| splhigh() |->| sti() |->| swtch() |
309 309 * +----------------+ +------------+ +-----------+ +-------+ +---------+
310 310 *
311 311 * Calls made on Interrupt Stacks and Epilogue routines
312 312 *
313 313 * We use the switch_sp_and_call() assembly routine to switch our sp to the
314 314 * interrupt stacks and then call the appropriate dispatch function. In the
315 315 * case of interrupts which may block, softints and hardints, we always ensure
316 316 * that we are still on the interrupt thread when we call the epilog routine.
317 317 * This is not just important, it's necessary. If the interrupt thread blocked,
318 318 * we won't return from our switch_sp_and_call() function and instead we'll go
319 319 * through and set ourselves up to swtch() directly.
320 320 *
321 321 * New Interrupt Flow
322 322 * ------------------
323 323 *
324 324 * The apix module has its own interrupt path. This is done for various
325 325 * reasons. The first is that rather than having global interrupt vectors, we
326 326 * now have per-cpu vectors.
327 327 *
328 328 * The other substantial change is that the apix design does not use the TPR to
329 329 * mask interrupts below the current level. In fact, except for one special
330 330 * case, it does not use the TPR at all. Instead, it only uses the IF flag
331 331 * (cli/sti) to either block all interrupts or allow any interrupts to come in.
332 332 * The design is such that when interrupts are allowed to come in, if we are
333 333 * currently servicing a higher priority interupt, the new interrupt is treated
334 334 * as pending and serviced later. Specifically, in the pcplusmp module's
335 335 * apic_intr_enter() the code masks interrupts at or below the current
336 336 * IPL using the TPR before sending EOI, whereas the apix module's
337 337 * apix_intr_enter() simply sends EOI.
338 338 *
339 339 * The one special case where the apix code uses the TPR is when it calls
340 340 * through the apic_reg_ops function pointer apic_write_task_reg in
341 341 * apix_init_intr() to initially mask all levels and then finally to enable all
342 342 * levels.
343 343 *
344 344 * Recall that we come into the interrupt handler with all interrupts masked
345 345 * by the IF flag. This is because we set up the handler using an
346 346 * interrupt-gate which is defined architecturally to have cleared the IF flag
347 347 * for us.
348 348 *
349 349 * +--------------+ +---------------------+
350 350 * | _interrupt() |--->| apix_do_interrupt() |
351 351 * +--------------+ +---------------------+
352 352 * |
353 353 * hard int? +----+--------+ softint?
354 354 * | | (but no low-level looping)
355 355 * +-----------+ |
356 356 * | *setlvl() | |
357 357 * +---------+ +-----------+ +----------------------------------+
358 358 * |apix_add_| check IPL | |
359 359 * |pending_ |<-------------+------+----------------------+ |
360 360 * |hardint()| low-level int| hi-level int| |
361 361 * +---------+ v v |
362 362 * | check IPL +-----------------+ +---------------+ |
363 363 * +--+-----+ | apix_intr_ | | apix_hilevel_ | |
364 364 * | | | thread_prolog() | | intr_prolog() | |
365 365 * | return +-----------------+ +---------------+ |
366 366 * | | | On intr |
367 367 * | +------------+ | stack? +------------+ |
368 368 * | | switch_sp_ | +---------| switch_sp_ | |
369 369 * | | and_call() | | | and_call() | |
370 370 * | +------------+ | +------------+ |
371 371 * | | | | |
372 372 * | +----------------+ +----------------+ |
373 373 * | | apix_dispatch_ | | apix_dispatch_ | |
374 374 * | | lowlevel() | | hilevel() | |
375 375 * | +----------------+ +----------------+ |
376 376 * | | | |
377 377 * | v v |
378 378 * | +-------------------------+ |
379 379 * | |apix_dispatch_by_vector()|----+ |
380 380 * | +-------------------------+ | |
381 381 * | !XC_HI_PIL| | | | |
382 382 * | +---+ +-------+ +---+ | |
383 383 * | |sti| |*intr()| |cli| | |
384 384 * | +---+ +-------+ +---+ | hi-level? |
385 385 * | +---------------------------+----+ |
386 386 * | v low-level? v |
387 387 * | +----------------+ +----------------+ |
388 388 * | | apix_intr_ | | apix_hilevel_ | |
389 389 * | | thread_epilog()| | intr_epilog() | |
390 390 * | +----------------+ +----------------+ |
391 391 * | | | |
392 392 * | v-----------------+--------------------------------+ |
393 393 * | +------------+ |
394 394 * | | *setlvlx() | +----------------------------------------------------+
395 395 * | +------------+ |
396 396 * | | | +--------------------------------+ low
397 397 * v v v------+ v | level
398 398 * +------------------+ +------------------+ +-----------+ | pending?
399 399 * | apix_do_pending_ |----->| apix_do_pending_ |----->| apix_do_ |--+
400 400 * | hilevel() | | hardint() | | softint() | |
401 401 * +------------------+ +------------------+ +-----------+ return
402 402 * | | |
403 403 * | while pending | while pending | while pending
404 404 * | hi-level | low-level | softint
405 405 * | | |
406 406 * +---------------+ +-----------------+ +-----------------+
407 407 * | apix_hilevel_ | | apix_intr_ | | apix_do_ |
408 408 * | intr_prolog() | | thread_prolog() | | softint_prolog()|
409 409 * +---------------+ +-----------------+ +-----------------+
410 410 * | On intr | |
411 411 * | stack? +------------+ +------------+ +------------+
412 412 * +--------| switch_sp_ | | switch_sp_ | | switch_sp_ |
413 413 * | | and_call() | | and_call() | | and_call() |
414 414 * | +------------+ +------------+ +------------+
415 415 * | | | |
416 416 * +------------------+ +------------------+ +------------------------+
417 417 * | apix_dispatch_ | | apix_dispatch_ | | apix_dispatch_softint()|
418 418 * | pending_hilevel()| | pending_hardint()| +------------------------+
419 419 * +------------------+ +------------------+ | | | |
420 420 * | | | | | | | |
421 421 * | +----------------+ | +----------------+ | | | |
422 422 * | | apix_hilevel_ | | | apix_intr_ | | | | |
423 423 * | | intr_epilog() | | | thread_epilog()| | | | |
424 424 * | +----------------+ | +----------------+ | | | |
425 425 * | | | | | | | |
426 426 * | +------------+ | +----------+ +------+ | | |
427 427 * | | *setlvlx() | | |*setlvlx()| | | | |
428 428 * | +------------+ | +----------+ | +----------+ | +---------+
429 429 * | | +---+ |av_ | +---+ |apix_do_ |
430 430 * +---------------------------------+ |sti| |dispatch_ | |cli| |softint_ |
431 431 * | apix_dispatch_pending_autovect()| +---+ |softvect()| +---+ |epilog() |
432 432 * +---------------------------------+ +----------+ +---------+
433 433 * |!XC_HI_PIL | | | |
434 434 * +---+ +-------+ +---+ +----------+ +-------+
435 435 * |sti| |*intr()| |cli| |apix_post_| |*intr()|
436 436 * +---+ +-------+ +---+ |hardint() | +-------+
437 437 * +----------+
438 438 */
439 439
440 440 #include <sys/cpuvar.h>
441 441 #include <sys/cpu_event.h>
442 442 #include <sys/regset.h>
443 443 #include <sys/psw.h>
444 444 #include <sys/types.h>
445 445 #include <sys/thread.h>
446 446 #include <sys/systm.h>
447 447 #include <sys/segments.h>
448 448 #include <sys/pcb.h>
449 449 #include <sys/trap.h>
450 450 #include <sys/ftrace.h>
451 451 #include <sys/traptrace.h>
452 452 #include <sys/clock.h>
453 453 #include <sys/panic.h>
454 454 #include <sys/disp.h>
455 455 #include <vm/seg_kp.h>
456 456 #include <sys/stack.h>
457 457 #include <sys/sysmacros.h>
458 458 #include <sys/cmn_err.h>
459 459 #include <sys/kstat.h>
460 460 #include <sys/smp_impldefs.h>
461 461 #include <sys/pool_pset.h>
462 462 #include <sys/zone.h>
463 463 #include <sys/bitmap.h>
464 464 #include <sys/archsystm.h>
465 465 #include <sys/machsystm.h>
466 466 #include <sys/ontrap.h>
467 467 #include <sys/x86_archext.h>
468 468 #include <sys/promif.h>
469 469 #include <vm/hat_i86.h>
470 470 #if defined(__xpv)
471 471 #include <sys/hypervisor.h>
472 472 #endif
473 473
474 474
475 475 #if defined(__xpv) && defined(DEBUG)
476 476
477 477 /*
478 478 * This panic message is intended as an aid to interrupt debugging.
479 479 *
480 480 * The associated assertion tests the condition of enabling
481 481 * events when events are already enabled. The implication
482 482 * being that whatever code the programmer thought was
483 483 * protected by having events disabled until the second
484 484 * enable happened really wasn't protected at all ..
485 485 */
486 486
487 487 int stistipanic = 1; /* controls the debug panic check */
488 488 const char *stistimsg = "stisti";
489 489 ulong_t laststi[NCPU];
490 490
491 491 /*
492 492 * This variable tracks the last place events were disabled on each cpu
493 493 * it assists in debugging when asserts that interrupts are enabled trip.
494 494 */
495 495 ulong_t lastcli[NCPU];
496 496
497 497 #endif
498 498
499 499 void do_interrupt(struct regs *rp, trap_trace_rec_t *ttp);
500 500
501 501 void (*do_interrupt_common)(struct regs *, trap_trace_rec_t *) = do_interrupt;
502 502 uintptr_t (*get_intr_handler)(int, short) = NULL;
503 503
504 504 /*
505 505 * Set cpu's base SPL level to the highest active interrupt level
506 506 */
507 507 void
508 508 set_base_spl(void)
509 509 {
510 510 struct cpu *cpu = CPU;
511 511 uint16_t active = (uint16_t)cpu->cpu_intr_actv;
512 512
513 513 cpu->cpu_base_spl = active == 0 ? 0 : bsrw_insn(active);
514 514 }
515 515
516 516 /*
517 517 * Do all the work necessary to set up the cpu and thread structures
518 518 * to dispatch a high-level interrupt.
519 519 *
520 520 * Returns 0 if we're -not- already on the high-level interrupt stack,
521 521 * (and *must* switch to it), non-zero if we are already on that stack.
522 522 *
523 523 * Called with interrupts masked.
524 524 * The 'pil' is already set to the appropriate level for rp->r_trapno.
525 525 */
526 526 static int
527 527 hilevel_intr_prolog(struct cpu *cpu, uint_t pil, uint_t oldpil, struct regs *rp)
528 528 {
529 529 struct machcpu *mcpu = &cpu->cpu_m;
530 530 uint_t mask;
531 531 hrtime_t intrtime;
532 532 hrtime_t now = tsc_read();
533 533
534 534 ASSERT(pil > LOCK_LEVEL);
535 535
536 536 if (pil == CBE_HIGH_PIL) {
537 537 cpu->cpu_profile_pil = oldpil;
538 538 if (USERMODE(rp->r_cs)) {
539 539 cpu->cpu_profile_pc = 0;
540 540 cpu->cpu_profile_upc = rp->r_pc;
541 541 cpu->cpu_cpcprofile_pc = 0;
542 542 cpu->cpu_cpcprofile_upc = rp->r_pc;
543 543 } else {
544 544 cpu->cpu_profile_pc = rp->r_pc;
545 545 cpu->cpu_profile_upc = 0;
546 546 cpu->cpu_cpcprofile_pc = rp->r_pc;
547 547 cpu->cpu_cpcprofile_upc = 0;
548 548 }
549 549 }
550 550
551 551 mask = cpu->cpu_intr_actv & CPU_INTR_ACTV_HIGH_LEVEL_MASK;
552 552 if (mask != 0) {
553 553 int nestpil;
554 554
555 555 /*
556 556 * We have interrupted another high-level interrupt.
557 557 * Load starting timestamp, compute interval, update
558 558 * cumulative counter.
559 559 */
560 560 nestpil = bsrw_insn((uint16_t)mask);
561 561 ASSERT(nestpil < pil);
562 562 intrtime = now -
563 563 mcpu->pil_high_start[nestpil - (LOCK_LEVEL + 1)];
564 564 mcpu->intrstat[nestpil][0] += intrtime;
565 565 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
566 566 /*
567 567 * Another high-level interrupt is active below this one, so
568 568 * there is no need to check for an interrupt thread. That
569 569 * will be done by the lowest priority high-level interrupt
570 570 * active.
571 571 */
572 572 } else {
573 573 kthread_t *t = cpu->cpu_thread;
574 574
575 575 /*
576 576 * See if we are interrupting a low-level interrupt thread.
577 577 * If so, account for its time slice only if its time stamp
578 578 * is non-zero.
579 579 */
580 580 if ((t->t_flag & T_INTR_THREAD) != 0 && t->t_intr_start != 0) {
581 581 intrtime = now - t->t_intr_start;
582 582 mcpu->intrstat[t->t_pil][0] += intrtime;
583 583 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
584 584 t->t_intr_start = 0;
585 585 }
586 586 }
587 587
588 588 /*
589 589 * Store starting timestamp in CPU structure for this PIL.
590 590 */
591 591 mcpu->pil_high_start[pil - (LOCK_LEVEL + 1)] = now;
592 592
593 593 ASSERT((cpu->cpu_intr_actv & (1 << pil)) == 0);
594 594
595 595 if (pil == 15) {
596 596 /*
597 597 * To support reentrant level 15 interrupts, we maintain a
598 598 * recursion count in the top half of cpu_intr_actv. Only
599 599 * when this count hits zero do we clear the PIL 15 bit from
600 600 * the lower half of cpu_intr_actv.
601 601 */
602 602 uint16_t *refcntp = (uint16_t *)&cpu->cpu_intr_actv + 1;
603 603 (*refcntp)++;
604 604 }
605 605
606 606 mask = cpu->cpu_intr_actv;
607 607
608 608 cpu->cpu_intr_actv |= (1 << pil);
609 609
610 610 return (mask & CPU_INTR_ACTV_HIGH_LEVEL_MASK);
611 611 }
612 612
613 613 /*
614 614 * Does most of the work of returning from a high level interrupt.
615 615 *
616 616 * Returns 0 if there are no more high level interrupts (in which
617 617 * case we must switch back to the interrupted thread stack) or
618 618 * non-zero if there are more (in which case we should stay on it).
619 619 *
620 620 * Called with interrupts masked
621 621 */
622 622 static int
623 623 hilevel_intr_epilog(struct cpu *cpu, uint_t pil, uint_t oldpil, uint_t vecnum)
624 624 {
625 625 struct machcpu *mcpu = &cpu->cpu_m;
626 626 uint_t mask;
627 627 hrtime_t intrtime;
628 628 hrtime_t now = tsc_read();
629 629
630 630 ASSERT(mcpu->mcpu_pri == pil);
631 631
632 632 cpu->cpu_stats.sys.intr[pil - 1]++;
633 633
634 634 ASSERT(cpu->cpu_intr_actv & (1 << pil));
635 635
636 636 if (pil == 15) {
637 637 /*
638 638 * To support reentrant level 15 interrupts, we maintain a
639 639 * recursion count in the top half of cpu_intr_actv. Only
640 640 * when this count hits zero do we clear the PIL 15 bit from
641 641 * the lower half of cpu_intr_actv.
642 642 */
643 643 uint16_t *refcntp = (uint16_t *)&cpu->cpu_intr_actv + 1;
644 644
645 645 ASSERT(*refcntp > 0);
646 646
647 647 if (--(*refcntp) == 0)
648 648 cpu->cpu_intr_actv &= ~(1 << pil);
649 649 } else {
650 650 cpu->cpu_intr_actv &= ~(1 << pil);
651 651 }
652 652
653 653 ASSERT(mcpu->pil_high_start[pil - (LOCK_LEVEL + 1)] != 0);
654 654
655 655 intrtime = now - mcpu->pil_high_start[pil - (LOCK_LEVEL + 1)];
656 656 mcpu->intrstat[pil][0] += intrtime;
657 657 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
658 658
659 659 /*
660 660 * Check for lower-pil nested high-level interrupt beneath
661 661 * current one. If so, place a starting timestamp in its
662 662 * pil_high_start entry.
663 663 */
664 664 mask = cpu->cpu_intr_actv & CPU_INTR_ACTV_HIGH_LEVEL_MASK;
665 665 if (mask != 0) {
666 666 int nestpil;
667 667
668 668 /*
669 669 * find PIL of nested interrupt
670 670 */
671 671 nestpil = bsrw_insn((uint16_t)mask);
672 672 ASSERT(nestpil < pil);
673 673 mcpu->pil_high_start[nestpil - (LOCK_LEVEL + 1)] = now;
674 674 /*
675 675 * (Another high-level interrupt is active below this one,
676 676 * so there is no need to check for an interrupt
677 677 * thread. That will be done by the lowest priority
678 678 * high-level interrupt active.)
679 679 */
680 680 } else {
681 681 /*
682 682 * Check to see if there is a low-level interrupt active.
683 683 * If so, place a starting timestamp in the thread
684 684 * structure.
685 685 */
686 686 kthread_t *t = cpu->cpu_thread;
687 687
688 688 if (t->t_flag & T_INTR_THREAD)
689 689 t->t_intr_start = now;
690 690 }
691 691
692 692 mcpu->mcpu_pri = oldpil;
693 693 (void) (*setlvlx)(oldpil, vecnum);
694 694
695 695 return (cpu->cpu_intr_actv & CPU_INTR_ACTV_HIGH_LEVEL_MASK);
696 696 }
697 697
698 698 /*
699 699 * Set up the cpu, thread and interrupt thread structures for
700 700 * executing an interrupt thread. The new stack pointer of the
701 701 * interrupt thread (which *must* be switched to) is returned.
702 702 */
703 703 static caddr_t
704 704 intr_thread_prolog(struct cpu *cpu, caddr_t stackptr, uint_t pil)
705 705 {
706 706 struct machcpu *mcpu = &cpu->cpu_m;
707 707 kthread_t *t, *volatile it;
708 708 hrtime_t now = tsc_read();
709 709
710 710 ASSERT(pil > 0);
711 711 ASSERT((cpu->cpu_intr_actv & (1 << pil)) == 0);
712 712 cpu->cpu_intr_actv |= (1 << pil);
713 713
714 714 /*
715 715 * Get set to run an interrupt thread.
716 716 * There should always be an interrupt thread, since we
717 717 * allocate one for each level on each CPU.
718 718 *
719 719 * t_intr_start could be zero due to cpu_intr_swtch_enter.
720 720 */
721 721 t = cpu->cpu_thread;
722 722 if ((t->t_flag & T_INTR_THREAD) && t->t_intr_start != 0) {
723 723 hrtime_t intrtime = now - t->t_intr_start;
724 724 mcpu->intrstat[t->t_pil][0] += intrtime;
725 725 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
726 726 t->t_intr_start = 0;
727 727 }
728 728
729 729 ASSERT(SA((uintptr_t)stackptr) == (uintptr_t)stackptr);
730 730
731 731 t->t_sp = (uintptr_t)stackptr; /* mark stack in curthread for resume */
732 732
733 733 /*
734 734 * unlink the interrupt thread off the cpu
735 735 *
736 736 * Note that the code in kcpc_overflow_intr -relies- on the
737 737 * ordering of events here - in particular that t->t_lwp of
738 738 * the interrupt thread is set to the pinned thread *before*
739 739 * curthread is changed.
740 740 */
741 741 it = cpu->cpu_intr_thread;
742 742 cpu->cpu_intr_thread = it->t_link;
743 743 it->t_intr = t;
744 744 it->t_lwp = t->t_lwp;
745 745
746 746 /*
747 747 * (threads on the interrupt thread free list could have state
748 748 * preset to TS_ONPROC, but it helps in debugging if
749 749 * they're TS_FREE.)
750 750 */
751 751 it->t_state = TS_ONPROC;
752 752
753 753 cpu->cpu_thread = it; /* new curthread on this cpu */
754 754 it->t_pil = (uchar_t)pil;
755 755 it->t_pri = intr_pri + (pri_t)pil;
756 756 it->t_intr_start = now;
757 757
758 758 return (it->t_stk);
759 759 }
760 760
761 761
762 762 #ifdef DEBUG
763 763 int intr_thread_cnt;
764 764 #endif
765 765
766 766 /*
767 767 * Called with interrupts disabled
768 768 */
769 769 static void
770 770 intr_thread_epilog(struct cpu *cpu, uint_t vec, uint_t oldpil)
771 771 {
772 772 struct machcpu *mcpu = &cpu->cpu_m;
773 773 kthread_t *t;
774 774 kthread_t *it = cpu->cpu_thread; /* curthread */
775 775 uint_t pil, basespl;
776 776 hrtime_t intrtime;
777 777 hrtime_t now = tsc_read();
778 778
779 779 pil = it->t_pil;
780 780 cpu->cpu_stats.sys.intr[pil - 1]++;
781 781
782 782 ASSERT(it->t_intr_start != 0);
783 783 intrtime = now - it->t_intr_start;
784 784 mcpu->intrstat[pil][0] += intrtime;
785 785 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
786 786
787 787 ASSERT(cpu->cpu_intr_actv & (1 << pil));
788 788 cpu->cpu_intr_actv &= ~(1 << pil);
789 789
790 790 /*
791 791 * If there is still an interrupted thread underneath this one
792 792 * then the interrupt was never blocked and the return is
793 793 * fairly simple. Otherwise it isn't.
794 794 */
795 795 if ((t = it->t_intr) == NULL) {
796 796 /*
797 797 * The interrupted thread is no longer pinned underneath
798 798 * the interrupt thread. This means the interrupt must
799 799 * have blocked, and the interrupted thread has been
800 800 * unpinned, and has probably been running around the
801 801 * system for a while.
802 802 *
803 803 * Since there is no longer a thread under this one, put
804 804 * this interrupt thread back on the CPU's free list and
805 805 * resume the idle thread which will dispatch the next
806 806 * thread to run.
807 807 */
808 808 #ifdef DEBUG
809 809 intr_thread_cnt++;
810 810 #endif
811 811 cpu->cpu_stats.sys.intrblk++;
812 812 /*
813 813 * Set CPU's base SPL based on active interrupts bitmask
814 814 */
815 815 set_base_spl();
816 816 basespl = cpu->cpu_base_spl;
817 817 mcpu->mcpu_pri = basespl;
818 818 (*setlvlx)(basespl, vec);
819 819 (void) splhigh();
820 820 sti();
821 821 it->t_state = TS_FREE;
822 822 /*
823 823 * Return interrupt thread to pool
824 824 */
825 825 it->t_link = cpu->cpu_intr_thread;
826 826 cpu->cpu_intr_thread = it;
827 827 swtch();
828 828 panic("intr_thread_epilog: swtch returned");
829 829 /*NOTREACHED*/
830 830 }
831 831
832 832 /*
833 833 * Return interrupt thread to the pool
834 834 */
835 835 it->t_link = cpu->cpu_intr_thread;
836 836 cpu->cpu_intr_thread = it;
837 837 it->t_state = TS_FREE;
838 838
839 839 basespl = cpu->cpu_base_spl;
840 840 pil = MAX(oldpil, basespl);
841 841 mcpu->mcpu_pri = pil;
842 842 (*setlvlx)(pil, vec);
843 843 t->t_intr_start = now;
844 844 cpu->cpu_thread = t;
845 845 }
846 846
847 847 /*
848 848 * intr_get_time() is a resource for interrupt handlers to determine how
849 849 * much time has been spent handling the current interrupt. Such a function
850 850 * is needed because higher level interrupts can arrive during the
851 851 * processing of an interrupt. intr_get_time() only returns time spent in the
852 852 * current interrupt handler.
853 853 *
854 854 * The caller must be calling from an interrupt handler running at a pil
855 855 * below or at lock level. Timings are not provided for high-level
856 856 * interrupts.
857 857 *
858 858 * The first time intr_get_time() is called while handling an interrupt,
859 859 * it returns the time since the interrupt handler was invoked. Subsequent
860 860 * calls will return the time since the prior call to intr_get_time(). Time
861 861 * is returned as ticks. Use scalehrtimef() to convert ticks to nsec.
862 862 *
863 863 * Theory Of Intrstat[][]:
864 864 *
865 865 * uint64_t intrstat[pil][0..1] is an array indexed by pil level, with two
866 866 * uint64_ts per pil.
867 867 *
868 868 * intrstat[pil][0] is a cumulative count of the number of ticks spent
869 869 * handling all interrupts at the specified pil on this CPU. It is
870 870 * exported via kstats to the user.
871 871 *
872 872 * intrstat[pil][1] is always a count of ticks less than or equal to the
873 873 * value in [0]. The difference between [1] and [0] is the value returned
874 874 * by a call to intr_get_time(). At the start of interrupt processing,
875 875 * [0] and [1] will be equal (or nearly so). As the interrupt consumes
876 876 * time, [0] will increase, but [1] will remain the same. A call to
877 877 * intr_get_time() will return the difference, then update [1] to be the
878 878 * same as [0]. Future calls will return the time since the last call.
879 879 * Finally, when the interrupt completes, [1] is updated to the same as [0].
880 880 *
881 881 * Implementation:
882 882 *
883 883 * intr_get_time() works much like a higher level interrupt arriving. It
884 884 * "checkpoints" the timing information by incrementing intrstat[pil][0]
885 885 * to include elapsed running time, and by setting t_intr_start to rdtsc.
886 886 * It then sets the return value to intrstat[pil][0] - intrstat[pil][1],
887 887 * and updates intrstat[pil][1] to be the same as the new value of
888 888 * intrstat[pil][0].
889 889 *
890 890 * In the normal handling of interrupts, after an interrupt handler returns
891 891 * and the code in intr_thread() updates intrstat[pil][0], it then sets
892 892 * intrstat[pil][1] to the new value of intrstat[pil][0]. When [0] == [1],
893 893 * the timings are reset, i.e. intr_get_time() will return [0] - [1] which
894 894 * is 0.
895 895 *
896 896 * Whenever interrupts arrive on a CPU which is handling a lower pil
897 897 * interrupt, they update the lower pil's [0] to show time spent in the
898 898 * handler that they've interrupted. This results in a growing discrepancy
899 899 * between [0] and [1], which is returned the next time intr_get_time() is
900 900 * called. Time spent in the higher-pil interrupt will not be returned in
901 901 * the next intr_get_time() call from the original interrupt, because
902 902 * the higher-pil interrupt's time is accumulated in intrstat[higherpil][].
903 903 */
904 904 uint64_t
905 905 intr_get_time(void)
906 906 {
907 907 struct cpu *cpu;
908 908 struct machcpu *mcpu;
909 909 kthread_t *t;
910 910 uint64_t time, delta, ret;
911 911 uint_t pil;
912 912
913 913 cli();
914 914 cpu = CPU;
915 915 mcpu = &cpu->cpu_m;
916 916 t = cpu->cpu_thread;
917 917 pil = t->t_pil;
918 918 ASSERT((cpu->cpu_intr_actv & CPU_INTR_ACTV_HIGH_LEVEL_MASK) == 0);
919 919 ASSERT(t->t_flag & T_INTR_THREAD);
920 920 ASSERT(pil != 0);
921 921 ASSERT(t->t_intr_start != 0);
922 922
923 923 time = tsc_read();
924 924 delta = time - t->t_intr_start;
925 925 t->t_intr_start = time;
926 926
927 927 time = mcpu->intrstat[pil][0] + delta;
928 928 ret = time - mcpu->intrstat[pil][1];
929 929 mcpu->intrstat[pil][0] = time;
930 930 mcpu->intrstat[pil][1] = time;
931 931 cpu->cpu_intracct[cpu->cpu_mstate] += delta;
932 932
933 933 sti();
934 934 return (ret);
935 935 }
936 936
937 937 static caddr_t
938 938 dosoftint_prolog(
939 939 struct cpu *cpu,
940 940 caddr_t stackptr,
941 941 uint32_t st_pending,
942 942 uint_t oldpil)
943 943 {
944 944 kthread_t *t, *volatile it;
945 945 struct machcpu *mcpu = &cpu->cpu_m;
946 946 uint_t pil;
947 947 hrtime_t now;
948 948
949 949 top:
950 950 ASSERT(st_pending == mcpu->mcpu_softinfo.st_pending);
951 951
952 952 pil = bsrw_insn((uint16_t)st_pending);
953 953 if (pil <= oldpil || pil <= cpu->cpu_base_spl)
954 954 return (0);
955 955
956 956 /*
957 957 * XX64 Sigh.
958 958 *
959 959 * This is a transliteration of the i386 assembler code for
960 960 * soft interrupts. One question is "why does this need
961 961 * to be atomic?" One possible race is -other- processors
962 962 * posting soft interrupts to us in set_pending() i.e. the
963 963 * CPU might get preempted just after the address computation,
964 964 * but just before the atomic transaction, so another CPU would
965 965 * actually set the original CPU's st_pending bit. However,
966 966 * it looks like it would be simpler to disable preemption there.
967 967 * Are there other races for which preemption control doesn't work?
968 968 *
969 969 * The i386 assembler version -also- checks to see if the bit
970 970 * being cleared was actually set; if it wasn't, it rechecks
971 971 * for more. This seems a bit strange, as the only code that
972 972 * ever clears the bit is -this- code running with interrupts
973 973 * disabled on -this- CPU. This code would probably be cheaper:
974 974 *
975 975 * atomic_and_32((uint32_t *)&mcpu->mcpu_softinfo.st_pending,
976 976 * ~(1 << pil));
977 977 *
978 978 * and t->t_preempt--/++ around set_pending() even cheaper,
979 979 * but at this point, correctness is critical, so we slavishly
980 980 * emulate the i386 port.
981 981 */
982 982 if (atomic_btr32((uint32_t *)
983 983 &mcpu->mcpu_softinfo.st_pending, pil) == 0) {
984 984 st_pending = mcpu->mcpu_softinfo.st_pending;
985 985 goto top;
986 986 }
987 987
988 988 mcpu->mcpu_pri = pil;
989 989 (*setspl)(pil);
990 990
991 991 now = tsc_read();
992 992
993 993 /*
994 994 * Get set to run interrupt thread.
995 995 * There should always be an interrupt thread since we
996 996 * allocate one for each level on the CPU.
997 997 */
998 998 it = cpu->cpu_intr_thread;
999 999 cpu->cpu_intr_thread = it->t_link;
1000 1000
1001 1001 /* t_intr_start could be zero due to cpu_intr_swtch_enter. */
1002 1002 t = cpu->cpu_thread;
1003 1003 if ((t->t_flag & T_INTR_THREAD) && t->t_intr_start != 0) {
1004 1004 hrtime_t intrtime = now - t->t_intr_start;
1005 1005 mcpu->intrstat[pil][0] += intrtime;
1006 1006 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
1007 1007 t->t_intr_start = 0;
1008 1008 }
1009 1009
1010 1010 /*
1011 1011 * Note that the code in kcpc_overflow_intr -relies- on the
1012 1012 * ordering of events here - in particular that t->t_lwp of
1013 1013 * the interrupt thread is set to the pinned thread *before*
1014 1014 * curthread is changed.
1015 1015 */
1016 1016 it->t_lwp = t->t_lwp;
1017 1017 it->t_state = TS_ONPROC;
1018 1018
1019 1019 /*
1020 1020 * Push interrupted thread onto list from new thread.
1021 1021 * Set the new thread as the current one.
1022 1022 * Set interrupted thread's T_SP because if it is the idle thread,
1023 1023 * resume() may use that stack between threads.
1024 1024 */
1025 1025
1026 1026 ASSERT(SA((uintptr_t)stackptr) == (uintptr_t)stackptr);
1027 1027 t->t_sp = (uintptr_t)stackptr;
1028 1028
1029 1029 it->t_intr = t;
1030 1030 cpu->cpu_thread = it;
1031 1031
1032 1032 /*
1033 1033 * Set bit for this pil in CPU's interrupt active bitmask.
1034 1034 */
1035 1035 ASSERT((cpu->cpu_intr_actv & (1 << pil)) == 0);
1036 1036 cpu->cpu_intr_actv |= (1 << pil);
1037 1037
1038 1038 /*
1039 1039 * Initialize thread priority level from intr_pri
1040 1040 */
1041 1041 it->t_pil = (uchar_t)pil;
1042 1042 it->t_pri = (pri_t)pil + intr_pri;
1043 1043 it->t_intr_start = now;
1044 1044
1045 1045 return (it->t_stk);
1046 1046 }
1047 1047
1048 1048 static void
1049 1049 dosoftint_epilog(struct cpu *cpu, uint_t oldpil)
1050 1050 {
1051 1051 struct machcpu *mcpu = &cpu->cpu_m;
1052 1052 kthread_t *t, *it;
1053 1053 uint_t pil, basespl;
1054 1054 hrtime_t intrtime;
1055 1055 hrtime_t now = tsc_read();
1056 1056
1057 1057 it = cpu->cpu_thread;
1058 1058 pil = it->t_pil;
1059 1059
1060 1060 cpu->cpu_stats.sys.intr[pil - 1]++;
1061 1061
1062 1062 ASSERT(cpu->cpu_intr_actv & (1 << pil));
1063 1063 cpu->cpu_intr_actv &= ~(1 << pil);
1064 1064 intrtime = now - it->t_intr_start;
1065 1065 mcpu->intrstat[pil][0] += intrtime;
1066 1066 cpu->cpu_intracct[cpu->cpu_mstate] += intrtime;
1067 1067
1068 1068 /*
1069 1069 * If there is still an interrupted thread underneath this one
1070 1070 * then the interrupt was never blocked and the return is
1071 1071 * fairly simple. Otherwise it isn't.
1072 1072 */
1073 1073 if ((t = it->t_intr) == NULL) {
1074 1074 /*
1075 1075 * Put thread back on the interrupt thread list.
1076 1076 * This was an interrupt thread, so set CPU's base SPL.
1077 1077 */
1078 1078 set_base_spl();
1079 1079 it->t_state = TS_FREE;
1080 1080 it->t_link = cpu->cpu_intr_thread;
1081 1081 cpu->cpu_intr_thread = it;
1082 1082 (void) splhigh();
1083 1083 sti();
1084 1084 swtch();
1085 1085 /*NOTREACHED*/
1086 1086 panic("dosoftint_epilog: swtch returned");
1087 1087 }
1088 1088 it->t_link = cpu->cpu_intr_thread;
1089 1089 cpu->cpu_intr_thread = it;
1090 1090 it->t_state = TS_FREE;
1091 1091 cpu->cpu_thread = t;
1092 1092 if (t->t_flag & T_INTR_THREAD)
1093 1093 t->t_intr_start = now;
1094 1094 basespl = cpu->cpu_base_spl;
1095 1095 pil = MAX(oldpil, basespl);
1096 1096 mcpu->mcpu_pri = pil;
1097 1097 (*setspl)(pil);
1098 1098 }
1099 1099
1100 1100
1101 1101 /*
1102 1102 * Make the interrupted thread 'to' be runnable.
1103 1103 *
1104 1104 * Since t->t_sp has already been saved, t->t_pc is all
1105 1105 * that needs to be set in this function.
1106 1106 *
1107 1107 * Returns the interrupt level of the interrupt thread.
1108 1108 */
1109 1109 int
1110 1110 intr_passivate(
1111 1111 kthread_t *it, /* interrupt thread */
1112 1112 kthread_t *t) /* interrupted thread */
1113 1113 {
1114 1114 extern void _sys_rtt();
1115 1115
1116 1116 ASSERT(it->t_flag & T_INTR_THREAD);
1117 1117 ASSERT(SA(t->t_sp) == t->t_sp);
1118 1118
1119 1119 t->t_pc = (uintptr_t)_sys_rtt;
1120 1120 return (it->t_pil);
1121 1121 }
1122 1122
1123 1123 /*
1124 1124 * Create interrupt kstats for this CPU.
1125 1125 */
1126 1126 void
1127 1127 cpu_create_intrstat(cpu_t *cp)
1128 1128 {
1129 1129 int i;
1130 1130 kstat_t *intr_ksp;
1131 1131 kstat_named_t *knp;
1132 1132 char name[KSTAT_STRLEN];
1133 1133 zoneid_t zoneid;
1134 1134
1135 1135 ASSERT(MUTEX_HELD(&cpu_lock));
1136 1136
1137 1137 if (pool_pset_enabled())
1138 1138 zoneid = GLOBAL_ZONEID;
1139 1139 else
1140 1140 zoneid = ALL_ZONES;
1141 1141
1142 1142 intr_ksp = kstat_create_zone("cpu", cp->cpu_id, "intrstat", "misc",
1143 1143 KSTAT_TYPE_NAMED, PIL_MAX * 2, NULL, zoneid);
1144 1144
1145 1145 /*
1146 1146 * Initialize each PIL's named kstat
1147 1147 */
1148 1148 if (intr_ksp != NULL) {
1149 1149 intr_ksp->ks_update = cpu_kstat_intrstat_update;
1150 1150 knp = (kstat_named_t *)intr_ksp->ks_data;
1151 1151 intr_ksp->ks_private = cp;
1152 1152 for (i = 0; i < PIL_MAX; i++) {
1153 1153 (void) snprintf(name, KSTAT_STRLEN, "level-%d-time",
1154 1154 i + 1);
1155 1155 kstat_named_init(&knp[i * 2], name, KSTAT_DATA_UINT64);
1156 1156 (void) snprintf(name, KSTAT_STRLEN, "level-%d-count",
1157 1157 i + 1);
1158 1158 kstat_named_init(&knp[(i * 2) + 1], name,
1159 1159 KSTAT_DATA_UINT64);
1160 1160 }
1161 1161 kstat_install(intr_ksp);
1162 1162 }
1163 1163 }
1164 1164
1165 1165 /*
1166 1166 * Delete interrupt kstats for this CPU.
1167 1167 */
1168 1168 void
1169 1169 cpu_delete_intrstat(cpu_t *cp)
1170 1170 {
1171 1171 kstat_delete_byname_zone("cpu", cp->cpu_id, "intrstat", ALL_ZONES);
1172 1172 }
1173 1173
1174 1174 /*
1175 1175 * Convert interrupt statistics from CPU ticks to nanoseconds and
1176 1176 * update kstat.
1177 1177 */
1178 1178 int
1179 1179 cpu_kstat_intrstat_update(kstat_t *ksp, int rw)
1180 1180 {
1181 1181 kstat_named_t *knp = ksp->ks_data;
1182 1182 cpu_t *cpup = (cpu_t *)ksp->ks_private;
1183 1183 int i;
1184 1184 hrtime_t hrt;
1185 1185
1186 1186 if (rw == KSTAT_WRITE)
1187 1187 return (EACCES);
1188 1188
1189 1189 for (i = 0; i < PIL_MAX; i++) {
1190 1190 hrt = (hrtime_t)cpup->cpu_m.intrstat[i + 1][0];
1191 1191 scalehrtimef(&hrt);
1192 1192 knp[i * 2].value.ui64 = (uint64_t)hrt;
1193 1193 knp[(i * 2) + 1].value.ui64 = cpup->cpu_stats.sys.intr[i];
1194 1194 }
1195 1195
1196 1196 return (0);
1197 1197 }
1198 1198
1199 1199 /*
1200 1200 * An interrupt thread is ending a time slice, so compute the interval it
1201 1201 * ran for and update the statistic for its PIL.
1202 1202 */
1203 1203 void
1204 1204 cpu_intr_swtch_enter(kthread_id_t t)
1205 1205 {
1206 1206 uint64_t interval;
1207 1207 uint64_t start;
1208 1208 cpu_t *cpu;
1209 1209
1210 1210 ASSERT((t->t_flag & T_INTR_THREAD) != 0);
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1211 1211 ASSERT(t->t_pil > 0 && t->t_pil <= LOCK_LEVEL);
1212 1212
1213 1213 /*
1214 1214 * We could be here with a zero timestamp. This could happen if:
1215 1215 * an interrupt thread which no longer has a pinned thread underneath
1216 1216 * it (i.e. it blocked at some point in its past) has finished running
1217 1217 * its handler. intr_thread() updated the interrupt statistic for its
1218 1218 * PIL and zeroed its timestamp. Since there was no pinned thread to
1219 1219 * return to, swtch() gets called and we end up here.
1220 1220 *
1221 - * Note that we use atomic ops below (cas64 and atomic_add_64), which
1222 - * we don't use in the functions above, because we're not called
1223 - * with interrupts blocked, but the epilog/prolog functions are.
1221 + * Note that we use atomic ops below (atomic_cas_64 and
1222 + * atomic_add_64), which we don't use in the functions above,
1223 + * because we're not called with interrupts blocked, but the
1224 + * epilog/prolog functions are.
1224 1225 */
1225 1226 if (t->t_intr_start) {
1226 1227 do {
1227 1228 start = t->t_intr_start;
1228 1229 interval = tsc_read() - start;
1229 - } while (cas64(&t->t_intr_start, start, 0) != start);
1230 + } while (atomic_cas_64(&t->t_intr_start, start, 0) != start);
1230 1231 cpu = CPU;
1231 1232 cpu->cpu_m.intrstat[t->t_pil][0] += interval;
1232 1233
1233 1234 atomic_add_64((uint64_t *)&cpu->cpu_intracct[cpu->cpu_mstate],
1234 1235 interval);
1235 1236 } else
1236 1237 ASSERT(t->t_intr == NULL);
1237 1238 }
1238 1239
1239 1240 /*
1240 1241 * An interrupt thread is returning from swtch(). Place a starting timestamp
1241 1242 * in its thread structure.
1242 1243 */
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1243 1244 void
1244 1245 cpu_intr_swtch_exit(kthread_id_t t)
1245 1246 {
1246 1247 uint64_t ts;
1247 1248
1248 1249 ASSERT((t->t_flag & T_INTR_THREAD) != 0);
1249 1250 ASSERT(t->t_pil > 0 && t->t_pil <= LOCK_LEVEL);
1250 1251
1251 1252 do {
1252 1253 ts = t->t_intr_start;
1253 - } while (cas64(&t->t_intr_start, ts, tsc_read()) != ts);
1254 + } while (atomic_cas_64(&t->t_intr_start, ts, tsc_read()) != ts);
1254 1255 }
1255 1256
1256 1257 /*
1257 1258 * Dispatch a hilevel interrupt (one above LOCK_LEVEL)
1258 1259 */
1259 1260 /*ARGSUSED*/
1260 1261 static void
1261 1262 dispatch_hilevel(uint_t vector, uint_t arg2)
1262 1263 {
1263 1264 sti();
1264 1265 av_dispatch_autovect(vector);
1265 1266 cli();
1266 1267 }
1267 1268
1268 1269 /*
1269 1270 * Dispatch a soft interrupt
1270 1271 */
1271 1272 /*ARGSUSED*/
1272 1273 static void
1273 1274 dispatch_softint(uint_t oldpil, uint_t arg2)
1274 1275 {
1275 1276 struct cpu *cpu = CPU;
1276 1277
1277 1278 sti();
1278 1279 av_dispatch_softvect((int)cpu->cpu_thread->t_pil);
1279 1280 cli();
1280 1281
1281 1282 /*
1282 1283 * Must run softint_epilog() on the interrupt thread stack, since
1283 1284 * there may not be a return from it if the interrupt thread blocked.
1284 1285 */
1285 1286 dosoftint_epilog(cpu, oldpil);
1286 1287 }
1287 1288
1288 1289 /*
1289 1290 * Dispatch a normal interrupt
1290 1291 */
1291 1292 static void
1292 1293 dispatch_hardint(uint_t vector, uint_t oldipl)
1293 1294 {
1294 1295 struct cpu *cpu = CPU;
1295 1296
1296 1297 sti();
1297 1298 av_dispatch_autovect(vector);
1298 1299 cli();
1299 1300
1300 1301 /*
1301 1302 * Must run intr_thread_epilog() on the interrupt thread stack, since
1302 1303 * there may not be a return from it if the interrupt thread blocked.
1303 1304 */
1304 1305 intr_thread_epilog(cpu, vector, oldipl);
1305 1306 }
1306 1307
1307 1308 /*
1308 1309 * Deliver any softints the current interrupt priority allows.
1309 1310 * Called with interrupts disabled.
1310 1311 */
1311 1312 void
1312 1313 dosoftint(struct regs *regs)
1313 1314 {
1314 1315 struct cpu *cpu = CPU;
1315 1316 int oldipl;
1316 1317 caddr_t newsp;
1317 1318
1318 1319 while (cpu->cpu_softinfo.st_pending) {
1319 1320 oldipl = cpu->cpu_pri;
1320 1321 newsp = dosoftint_prolog(cpu, (caddr_t)regs,
1321 1322 cpu->cpu_softinfo.st_pending, oldipl);
1322 1323 /*
1323 1324 * If returned stack pointer is NULL, priority is too high
1324 1325 * to run any of the pending softints now.
1325 1326 * Break out and they will be run later.
1326 1327 */
1327 1328 if (newsp == NULL)
1328 1329 break;
1329 1330 switch_sp_and_call(newsp, dispatch_softint, oldipl, 0);
1330 1331 }
1331 1332 }
1332 1333
1333 1334 /*
1334 1335 * Interrupt service routine, called with interrupts disabled.
1335 1336 */
1336 1337 /*ARGSUSED*/
1337 1338 void
1338 1339 do_interrupt(struct regs *rp, trap_trace_rec_t *ttp)
1339 1340 {
1340 1341 struct cpu *cpu = CPU;
1341 1342 int newipl, oldipl = cpu->cpu_pri;
1342 1343 uint_t vector;
1343 1344 caddr_t newsp;
1344 1345
1345 1346 #ifdef TRAPTRACE
1346 1347 ttp->ttr_marker = TT_INTERRUPT;
1347 1348 ttp->ttr_ipl = 0xff;
1348 1349 ttp->ttr_pri = oldipl;
1349 1350 ttp->ttr_spl = cpu->cpu_base_spl;
1350 1351 ttp->ttr_vector = 0xff;
1351 1352 #endif /* TRAPTRACE */
1352 1353
1353 1354 cpu_idle_exit(CPU_IDLE_CB_FLAG_INTR);
1354 1355
1355 1356 ++*(uint16_t *)&cpu->cpu_m.mcpu_istamp;
1356 1357
1357 1358 /*
1358 1359 * If it's a softint go do it now.
1359 1360 */
1360 1361 if (rp->r_trapno == T_SOFTINT) {
1361 1362 dosoftint(rp);
1362 1363 ASSERT(!interrupts_enabled());
1363 1364 return;
1364 1365 }
1365 1366
1366 1367 /*
1367 1368 * Raise the interrupt priority.
1368 1369 */
1369 1370 newipl = (*setlvl)(oldipl, (int *)&rp->r_trapno);
1370 1371 #ifdef TRAPTRACE
1371 1372 ttp->ttr_ipl = newipl;
1372 1373 #endif /* TRAPTRACE */
1373 1374
1374 1375 /*
1375 1376 * Bail if it is a spurious interrupt
1376 1377 */
1377 1378 if (newipl == -1)
1378 1379 return;
1379 1380 cpu->cpu_pri = newipl;
1380 1381 vector = rp->r_trapno;
1381 1382 #ifdef TRAPTRACE
1382 1383 ttp->ttr_vector = vector;
1383 1384 #endif /* TRAPTRACE */
1384 1385 if (newipl > LOCK_LEVEL) {
1385 1386 /*
1386 1387 * High priority interrupts run on this cpu's interrupt stack.
1387 1388 */
1388 1389 if (hilevel_intr_prolog(cpu, newipl, oldipl, rp) == 0) {
1389 1390 newsp = cpu->cpu_intr_stack;
1390 1391 switch_sp_and_call(newsp, dispatch_hilevel, vector, 0);
1391 1392 } else { /* already on the interrupt stack */
1392 1393 dispatch_hilevel(vector, 0);
1393 1394 }
1394 1395 (void) hilevel_intr_epilog(cpu, newipl, oldipl, vector);
1395 1396 } else {
1396 1397 /*
1397 1398 * Run this interrupt in a separate thread.
1398 1399 */
1399 1400 newsp = intr_thread_prolog(cpu, (caddr_t)rp, newipl);
1400 1401 switch_sp_and_call(newsp, dispatch_hardint, vector, oldipl);
1401 1402 }
1402 1403
1403 1404 #if !defined(__xpv)
1404 1405 /*
1405 1406 * Deliver any pending soft interrupts.
1406 1407 */
1407 1408 if (cpu->cpu_softinfo.st_pending)
1408 1409 dosoftint(rp);
1409 1410 #endif /* !__xpv */
1410 1411 }
1411 1412
1412 1413
1413 1414 /*
1414 1415 * Common tasks always done by _sys_rtt, called with interrupts disabled.
1415 1416 * Returns 1 if returning to userland, 0 if returning to system mode.
1416 1417 */
1417 1418 int
1418 1419 sys_rtt_common(struct regs *rp)
1419 1420 {
1420 1421 kthread_t *tp;
1421 1422 extern void mutex_exit_critical_start();
1422 1423 extern long mutex_exit_critical_size;
1423 1424 extern void mutex_owner_running_critical_start();
1424 1425 extern long mutex_owner_running_critical_size;
1425 1426
1426 1427 loop:
1427 1428
1428 1429 /*
1429 1430 * Check if returning to user
1430 1431 */
1431 1432 tp = CPU->cpu_thread;
1432 1433 if (USERMODE(rp->r_cs)) {
1433 1434 /*
1434 1435 * Check if AST pending.
1435 1436 */
1436 1437 if (tp->t_astflag) {
1437 1438 /*
1438 1439 * Let trap() handle the AST
1439 1440 */
1440 1441 sti();
1441 1442 rp->r_trapno = T_AST;
1442 1443 trap(rp, (caddr_t)0, CPU->cpu_id);
1443 1444 cli();
1444 1445 goto loop;
1445 1446 }
1446 1447
1447 1448 #if defined(__amd64)
1448 1449 /*
1449 1450 * We are done if segment registers do not need updating.
1450 1451 */
1451 1452 if (tp->t_lwp->lwp_pcb.pcb_rupdate == 0)
1452 1453 return (1);
1453 1454
1454 1455 if (update_sregs(rp, tp->t_lwp)) {
1455 1456 /*
1456 1457 * 1 or more of the selectors is bad.
1457 1458 * Deliver a SIGSEGV.
1458 1459 */
1459 1460 proc_t *p = ttoproc(tp);
1460 1461
1461 1462 sti();
1462 1463 mutex_enter(&p->p_lock);
1463 1464 tp->t_lwp->lwp_cursig = SIGSEGV;
1464 1465 mutex_exit(&p->p_lock);
1465 1466 psig();
1466 1467 tp->t_sig_check = 1;
1467 1468 cli();
1468 1469 }
1469 1470 tp->t_lwp->lwp_pcb.pcb_rupdate = 0;
1470 1471
1471 1472 #endif /* __amd64 */
1472 1473 return (1);
1473 1474 }
1474 1475
1475 1476 /*
1476 1477 * Here if we are returning to supervisor mode.
1477 1478 * Check for a kernel preemption request.
1478 1479 */
1479 1480 if (CPU->cpu_kprunrun && (rp->r_ps & PS_IE)) {
1480 1481
1481 1482 /*
1482 1483 * Do nothing if already in kpreempt
1483 1484 */
1484 1485 if (!tp->t_preempt_lk) {
1485 1486 tp->t_preempt_lk = 1;
1486 1487 sti();
1487 1488 kpreempt(1); /* asynchronous kpreempt call */
1488 1489 cli();
1489 1490 tp->t_preempt_lk = 0;
1490 1491 }
1491 1492 }
1492 1493
1493 1494 /*
1494 1495 * If we interrupted the mutex_exit() critical region we must
1495 1496 * reset the PC back to the beginning to prevent missed wakeups
1496 1497 * See the comments in mutex_exit() for details.
1497 1498 */
1498 1499 if ((uintptr_t)rp->r_pc - (uintptr_t)mutex_exit_critical_start <
1499 1500 mutex_exit_critical_size) {
1500 1501 rp->r_pc = (greg_t)mutex_exit_critical_start;
1501 1502 }
1502 1503
1503 1504 /*
1504 1505 * If we interrupted the mutex_owner_running() critical region we
1505 1506 * must reset the PC back to the beginning to prevent dereferencing
1506 1507 * of a freed thread pointer. See the comments in mutex_owner_running
1507 1508 * for details.
1508 1509 */
1509 1510 if ((uintptr_t)rp->r_pc -
1510 1511 (uintptr_t)mutex_owner_running_critical_start <
1511 1512 mutex_owner_running_critical_size) {
1512 1513 rp->r_pc = (greg_t)mutex_owner_running_critical_start;
1513 1514 }
1514 1515
1515 1516 return (0);
1516 1517 }
1517 1518
1518 1519 void
1519 1520 send_dirint(int cpuid, int int_level)
1520 1521 {
1521 1522 (*send_dirintf)(cpuid, int_level);
1522 1523 }
1523 1524
1524 1525 #define IS_FAKE_SOFTINT(flag, newpri) \
1525 1526 (((flag) & PS_IE) && \
1526 1527 (((*get_pending_spl)() > (newpri)) || \
1527 1528 bsrw_insn((uint16_t)cpu->cpu_softinfo.st_pending) > (newpri)))
1528 1529
1529 1530 /*
1530 1531 * do_splx routine, takes new ipl to set
1531 1532 * returns the old ipl.
1532 1533 * We are careful not to set priority lower than CPU->cpu_base_pri,
1533 1534 * even though it seems we're raising the priority, it could be set
1534 1535 * higher at any time by an interrupt routine, so we must block interrupts
1535 1536 * and look at CPU->cpu_base_pri
1536 1537 */
1537 1538 int
1538 1539 do_splx(int newpri)
1539 1540 {
1540 1541 ulong_t flag;
1541 1542 cpu_t *cpu;
1542 1543 int curpri, basepri;
1543 1544
1544 1545 flag = intr_clear();
1545 1546 cpu = CPU; /* ints are disabled, now safe to cache cpu ptr */
1546 1547 curpri = cpu->cpu_m.mcpu_pri;
1547 1548 basepri = cpu->cpu_base_spl;
1548 1549 if (newpri < basepri)
1549 1550 newpri = basepri;
1550 1551 cpu->cpu_m.mcpu_pri = newpri;
1551 1552 (*setspl)(newpri);
1552 1553 /*
1553 1554 * If we are going to reenable interrupts see if new priority level
1554 1555 * allows pending softint delivery.
1555 1556 */
1556 1557 if (IS_FAKE_SOFTINT(flag, newpri))
1557 1558 fakesoftint();
1558 1559 ASSERT(!interrupts_enabled());
1559 1560 intr_restore(flag);
1560 1561 return (curpri);
1561 1562 }
1562 1563
1563 1564 /*
1564 1565 * Common spl raise routine, takes new ipl to set
1565 1566 * returns the old ipl, will not lower ipl.
1566 1567 */
1567 1568 int
1568 1569 splr(int newpri)
1569 1570 {
1570 1571 ulong_t flag;
1571 1572 cpu_t *cpu;
1572 1573 int curpri, basepri;
1573 1574
1574 1575 flag = intr_clear();
1575 1576 cpu = CPU; /* ints are disabled, now safe to cache cpu ptr */
1576 1577 curpri = cpu->cpu_m.mcpu_pri;
1577 1578 /*
1578 1579 * Only do something if new priority is larger
1579 1580 */
1580 1581 if (newpri > curpri) {
1581 1582 basepri = cpu->cpu_base_spl;
1582 1583 if (newpri < basepri)
1583 1584 newpri = basepri;
1584 1585 cpu->cpu_m.mcpu_pri = newpri;
1585 1586 (*setspl)(newpri);
1586 1587 /*
1587 1588 * See if new priority level allows pending softint delivery
1588 1589 */
1589 1590 if (IS_FAKE_SOFTINT(flag, newpri))
1590 1591 fakesoftint();
1591 1592 }
1592 1593 intr_restore(flag);
1593 1594 return (curpri);
1594 1595 }
1595 1596
1596 1597 int
1597 1598 getpil(void)
1598 1599 {
1599 1600 return (CPU->cpu_m.mcpu_pri);
1600 1601 }
1601 1602
1602 1603 int
1603 1604 spl_xcall(void)
1604 1605 {
1605 1606 return (splr(ipltospl(XCALL_PIL)));
1606 1607 }
1607 1608
1608 1609 int
1609 1610 interrupts_enabled(void)
1610 1611 {
1611 1612 ulong_t flag;
1612 1613
1613 1614 flag = getflags();
1614 1615 return ((flag & PS_IE) == PS_IE);
1615 1616 }
1616 1617
1617 1618 #ifdef DEBUG
1618 1619 void
1619 1620 assert_ints_enabled(void)
1620 1621 {
1621 1622 ASSERT(!interrupts_unleashed || interrupts_enabled());
1622 1623 }
1623 1624 #endif /* DEBUG */
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