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55e303ae | 1 | /* |
39236c6e | 2 | * Copyright (c) 2000-2012 Apple Inc. All rights reserved. |
55e303ae | 3 | * |
2d21ac55 | 4 | * @APPLE_OSREFERENCE_LICENSE_HEADER_START@ |
55e303ae | 5 | * |
2d21ac55 A |
6 | * This file contains Original Code and/or Modifications of Original Code |
7 | * as defined in and that are subject to the Apple Public Source License | |
8 | * Version 2.0 (the 'License'). You may not use this file except in | |
9 | * compliance with the License. The rights granted to you under the License | |
10 | * may not be used to create, or enable the creation or redistribution of, | |
11 | * unlawful or unlicensed copies of an Apple operating system, or to | |
12 | * circumvent, violate, or enable the circumvention or violation of, any | |
13 | * terms of an Apple operating system software license agreement. | |
8f6c56a5 | 14 | * |
2d21ac55 A |
15 | * Please obtain a copy of the License at |
16 | * http://www.opensource.apple.com/apsl/ and read it before using this file. | |
17 | * | |
18 | * The Original Code and all software distributed under the License are | |
19 | * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER | |
8f6c56a5 A |
20 | * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, |
21 | * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, | |
2d21ac55 A |
22 | * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. |
23 | * Please see the License for the specific language governing rights and | |
24 | * limitations under the License. | |
8f6c56a5 | 25 | * |
2d21ac55 | 26 | * @APPLE_OSREFERENCE_LICENSE_HEADER_END@ |
55e303ae A |
27 | */ |
28 | /* | |
29 | * @OSF_COPYRIGHT@ | |
30 | */ | |
31 | ||
55e303ae | 32 | #include <mach_rt.h> |
55e303ae A |
33 | #include <mach_kdp.h> |
34 | #include <mach_ldebug.h> | |
91447636 A |
35 | #include <gprof.h> |
36 | ||
37 | #include <mach/mach_types.h> | |
38 | #include <mach/kern_return.h> | |
39 | ||
40 | #include <kern/kern_types.h> | |
41 | #include <kern/startup.h> | |
c910b4d9 | 42 | #include <kern/timer_queue.h> |
91447636 A |
43 | #include <kern/processor.h> |
44 | #include <kern/cpu_number.h> | |
45 | #include <kern/cpu_data.h> | |
46 | #include <kern/assert.h> | |
47 | #include <kern/machine.h> | |
0c530ab8 | 48 | #include <kern/pms.h> |
593a1d5f | 49 | #include <kern/misc_protos.h> |
39236c6e | 50 | #include <kern/timer_call.h> |
6d2010ae A |
51 | #include <kern/kalloc.h> |
52 | #include <kern/queue.h> | |
fe8ab488 | 53 | #include <prng/random.h> |
91447636 A |
54 | |
55 | #include <vm/vm_map.h> | |
56 | #include <vm/vm_kern.h> | |
57 | ||
58 | #include <profiling/profile-mk.h> | |
55e303ae | 59 | |
fe8ab488 | 60 | #include <i386/bit_routines.h> |
b0d623f7 A |
61 | #include <i386/proc_reg.h> |
62 | #include <i386/cpu_threads.h> | |
63 | #include <i386/mp_desc.h> | |
64 | #include <i386/misc_protos.h> | |
65 | #include <i386/trap.h> | |
66 | #include <i386/postcode.h> | |
67 | #include <i386/machine_routines.h> | |
55e303ae A |
68 | #include <i386/mp.h> |
69 | #include <i386/mp_events.h> | |
593a1d5f | 70 | #include <i386/lapic.h> |
55e303ae | 71 | #include <i386/cpuid.h> |
b0d623f7 | 72 | #include <i386/fpu.h> |
55e303ae | 73 | #include <i386/machine_cpu.h> |
0c530ab8 | 74 | #include <i386/pmCPU.h> |
b0d623f7 | 75 | #if CONFIG_MCA |
2d21ac55 | 76 | #include <i386/machine_check.h> |
b0d623f7 A |
77 | #endif |
78 | #include <i386/acpi.h> | |
0c530ab8 A |
79 | |
80 | #include <chud/chud_xnu.h> | |
81 | #include <chud/chud_xnu_private.h> | |
82 | ||
83 | #include <sys/kdebug.h> | |
55e303ae | 84 | |
39236c6e A |
85 | #include <console/serial_protos.h> |
86 | ||
55e303ae A |
87 | #if MP_DEBUG |
88 | #define PAUSE delay(1000000) | |
89 | #define DBG(x...) kprintf(x) | |
90 | #else | |
91 | #define DBG(x...) | |
92 | #define PAUSE | |
93 | #endif /* MP_DEBUG */ | |
94 | ||
6d2010ae A |
95 | /* Debugging/test trace events: */ |
96 | #define TRACE_MP_TLB_FLUSH MACHDBG_CODE(DBG_MACH_MP, 0) | |
97 | #define TRACE_MP_CPUS_CALL MACHDBG_CODE(DBG_MACH_MP, 1) | |
98 | #define TRACE_MP_CPUS_CALL_LOCAL MACHDBG_CODE(DBG_MACH_MP, 2) | |
99 | #define TRACE_MP_CPUS_CALL_ACTION MACHDBG_CODE(DBG_MACH_MP, 3) | |
100 | #define TRACE_MP_CPUS_CALL_NOBUF MACHDBG_CODE(DBG_MACH_MP, 4) | |
bd504ef0 A |
101 | #define TRACE_MP_CPU_FAST_START MACHDBG_CODE(DBG_MACH_MP, 5) |
102 | #define TRACE_MP_CPU_START MACHDBG_CODE(DBG_MACH_MP, 6) | |
103 | #define TRACE_MP_CPU_DEACTIVATE MACHDBG_CODE(DBG_MACH_MP, 7) | |
55e303ae | 104 | |
7e4a7d39 A |
105 | #define ABS(v) (((v) > 0)?(v):-(v)) |
106 | ||
55e303ae | 107 | void slave_boot_init(void); |
6d2010ae | 108 | void i386_cpu_IPI(int cpu); |
55e303ae | 109 | |
39236c6e | 110 | #if MACH_KDP |
b0d623f7 | 111 | static void mp_kdp_wait(boolean_t flush, boolean_t isNMI); |
39236c6e | 112 | #endif /* MACH_KDP */ |
55e303ae | 113 | static void mp_rendezvous_action(void); |
2d21ac55 | 114 | static void mp_broadcast_action(void); |
55e303ae | 115 | |
39236c6e | 116 | #if MACH_KDP |
0c530ab8 | 117 | static boolean_t cpu_signal_pending(int cpu, mp_event_t event); |
39236c6e | 118 | #endif /* MACH_KDP */ |
593a1d5f | 119 | static int NMIInterruptHandler(x86_saved_state_t *regs); |
0c530ab8 | 120 | |
b0d623f7 | 121 | boolean_t smp_initialized = FALSE; |
7e4a7d39 | 122 | uint32_t TSC_sync_margin = 0xFFF; |
935ed37a A |
123 | volatile boolean_t force_immediate_debugger_NMI = FALSE; |
124 | volatile boolean_t pmap_tlb_flush_timeout = FALSE; | |
55e303ae | 125 | decl_simple_lock_data(,mp_kdp_lock); |
91447636 | 126 | |
b0d623f7 A |
127 | decl_lck_mtx_data(static, mp_cpu_boot_lock); |
128 | lck_mtx_ext_t mp_cpu_boot_lock_ext; | |
55e303ae A |
129 | |
130 | /* Variables needed for MP rendezvous. */ | |
0c530ab8 | 131 | decl_simple_lock_data(,mp_rv_lock); |
b0d623f7 A |
132 | static void (*mp_rv_setup_func)(void *arg); |
133 | static void (*mp_rv_action_func)(void *arg); | |
134 | static void (*mp_rv_teardown_func)(void *arg); | |
135 | static void *mp_rv_func_arg; | |
136 | static volatile int mp_rv_ncpus; | |
0c530ab8 A |
137 | /* Cache-aligned barriers: */ |
138 | static volatile long mp_rv_entry __attribute__((aligned(64))); | |
139 | static volatile long mp_rv_exit __attribute__((aligned(64))); | |
140 | static volatile long mp_rv_complete __attribute__((aligned(64))); | |
55e303ae | 141 | |
b0d623f7 A |
142 | volatile uint64_t debugger_entry_time; |
143 | volatile uint64_t debugger_exit_time; | |
144 | #if MACH_KDP | |
7ddcb079 | 145 | #include <kdp/kdp.h> |
d41d1dae | 146 | extern int kdp_snapshot; |
b0d623f7 A |
147 | static struct _kdp_xcpu_call_func { |
148 | kdp_x86_xcpu_func_t func; | |
149 | void *arg0, *arg1; | |
150 | volatile long ret; | |
151 | volatile uint16_t cpu; | |
152 | } kdp_xcpu_call_func = { | |
153 | .cpu = KDP_XCPU_NONE | |
154 | }; | |
155 | ||
156 | #endif | |
157 | ||
2d21ac55 A |
158 | /* Variables needed for MP broadcast. */ |
159 | static void (*mp_bc_action_func)(void *arg); | |
160 | static void *mp_bc_func_arg; | |
593a1d5f | 161 | static int mp_bc_ncpus; |
2d21ac55 | 162 | static volatile long mp_bc_count; |
b0d623f7 A |
163 | decl_lck_mtx_data(static, mp_bc_lock); |
164 | lck_mtx_ext_t mp_bc_lock_ext; | |
593a1d5f | 165 | static volatile int debugger_cpu = -1; |
39236c6e A |
166 | volatile long NMIPI_acks = 0; |
167 | volatile long NMI_count = 0; | |
168 | ||
169 | extern void NMI_cpus(void); | |
2d21ac55 | 170 | |
6d2010ae | 171 | static void mp_cpus_call_init(void); |
2d21ac55 | 172 | static void mp_cpus_call_action(void); |
c910b4d9 | 173 | static void mp_call_PM(void); |
2d21ac55 | 174 | |
fe8ab488 A |
175 | static boolean_t mp_cpus_call_wait_timeout = FALSE; |
176 | ||
b0d623f7 A |
177 | char mp_slave_stack[PAGE_SIZE] __attribute__((aligned(PAGE_SIZE))); // Temp stack for slave init |
178 | ||
6d2010ae A |
179 | /* PAL-related routines */ |
180 | boolean_t i386_smp_init(int nmi_vector, i386_intr_func_t nmi_handler, | |
181 | int ipi_vector, i386_intr_func_t ipi_handler); | |
182 | void i386_start_cpu(int lapic_id, int cpu_num); | |
183 | void i386_send_NMI(int cpu); | |
b0d623f7 | 184 | |
91447636 A |
185 | #if GPROF |
186 | /* | |
187 | * Initialize dummy structs for profiling. These aren't used but | |
188 | * allows hertz_tick() to be built with GPROF defined. | |
189 | */ | |
190 | struct profile_vars _profile_vars; | |
191 | struct profile_vars *_profile_vars_cpus[MAX_CPUS] = { &_profile_vars }; | |
192 | #define GPROF_INIT() \ | |
193 | { \ | |
194 | int i; \ | |
195 | \ | |
196 | /* Hack to initialize pointers to unused profiling structs */ \ | |
197 | for (i = 1; i < MAX_CPUS; i++) \ | |
198 | _profile_vars_cpus[i] = &_profile_vars; \ | |
199 | } | |
200 | #else | |
201 | #define GPROF_INIT() | |
202 | #endif /* GPROF */ | |
203 | ||
b0d623f7 A |
204 | static lck_grp_t smp_lck_grp; |
205 | static lck_grp_attr_t smp_lck_grp_attr; | |
206 | ||
6d2010ae A |
207 | #define NUM_CPU_WARM_CALLS 20 |
208 | struct timer_call cpu_warm_call_arr[NUM_CPU_WARM_CALLS]; | |
209 | queue_head_t cpu_warm_call_list; | |
210 | decl_simple_lock_data(static, cpu_warm_lock); | |
211 | ||
212 | typedef struct cpu_warm_data { | |
213 | timer_call_t cwd_call; | |
214 | uint64_t cwd_deadline; | |
215 | int cwd_result; | |
216 | } *cpu_warm_data_t; | |
217 | ||
218 | static void cpu_prewarm_init(void); | |
219 | static void cpu_warm_timer_call_func(call_entry_param_t p0, call_entry_param_t p1); | |
220 | static void _cpu_warm_setup(void *arg); | |
221 | static timer_call_t grab_warm_timer_call(void); | |
222 | static void free_warm_timer_call(timer_call_t call); | |
b0d623f7 | 223 | |
55e303ae A |
224 | void |
225 | smp_init(void) | |
55e303ae | 226 | { |
91447636 A |
227 | simple_lock_init(&mp_kdp_lock, 0); |
228 | simple_lock_init(&mp_rv_lock, 0); | |
b0d623f7 A |
229 | lck_grp_attr_setdefault(&smp_lck_grp_attr); |
230 | lck_grp_init(&smp_lck_grp, "i386_smp", &smp_lck_grp_attr); | |
231 | lck_mtx_init_ext(&mp_cpu_boot_lock, &mp_cpu_boot_lock_ext, &smp_lck_grp, LCK_ATTR_NULL); | |
232 | lck_mtx_init_ext(&mp_bc_lock, &mp_bc_lock_ext, &smp_lck_grp, LCK_ATTR_NULL); | |
91447636 | 233 | console_init(); |
55e303ae | 234 | |
6d2010ae A |
235 | if(!i386_smp_init(LAPIC_NMI_INTERRUPT, NMIInterruptHandler, |
236 | LAPIC_VECTOR(INTERPROCESSOR), cpu_signal_handler)) | |
55e303ae A |
237 | return; |
238 | ||
91447636 A |
239 | cpu_thread_init(); |
240 | ||
91447636 A |
241 | GPROF_INIT(); |
242 | DBGLOG_CPU_INIT(master_cpu); | |
243 | ||
6d2010ae | 244 | mp_cpus_call_init(); |
fe8ab488 | 245 | mp_cpus_call_cpu_init(master_cpu); |
55e303ae | 246 | |
7e4a7d39 | 247 | if (PE_parse_boot_argn("TSC_sync_margin", |
316670eb | 248 | &TSC_sync_margin, sizeof(TSC_sync_margin))) { |
7e4a7d39 | 249 | kprintf("TSC sync Margin 0x%x\n", TSC_sync_margin); |
316670eb A |
250 | } else if (cpuid_vmm_present()) { |
251 | kprintf("TSC sync margin disabled\n"); | |
252 | TSC_sync_margin = 0; | |
253 | } | |
55e303ae A |
254 | smp_initialized = TRUE; |
255 | ||
6d2010ae A |
256 | cpu_prewarm_init(); |
257 | ||
55e303ae A |
258 | return; |
259 | } | |
260 | ||
7e4a7d39 A |
261 | typedef struct { |
262 | int target_cpu; | |
263 | int target_lapic; | |
264 | int starter_cpu; | |
265 | } processor_start_info_t; | |
266 | static processor_start_info_t start_info __attribute__((aligned(64))); | |
267 | ||
268 | /* | |
269 | * Cache-alignment is to avoid cross-cpu false-sharing interference. | |
270 | */ | |
271 | static volatile long tsc_entry_barrier __attribute__((aligned(64))); | |
272 | static volatile long tsc_exit_barrier __attribute__((aligned(64))); | |
273 | static volatile uint64_t tsc_target __attribute__((aligned(64))); | |
274 | ||
0c530ab8 | 275 | /* |
593a1d5f | 276 | * Poll a CPU to see when it has marked itself as running. |
0c530ab8 | 277 | */ |
593a1d5f A |
278 | static void |
279 | mp_wait_for_cpu_up(int slot_num, unsigned int iters, unsigned int usecdelay) | |
91447636 | 280 | { |
7e4a7d39 | 281 | while (iters-- > 0) { |
593a1d5f | 282 | if (cpu_datap(slot_num)->cpu_running) |
7e4a7d39 | 283 | break; |
593a1d5f | 284 | delay(usecdelay); |
91447636 | 285 | } |
55e303ae A |
286 | } |
287 | ||
b0d623f7 A |
288 | /* |
289 | * Quickly bring a CPU back online which has been halted. | |
290 | */ | |
291 | kern_return_t | |
292 | intel_startCPU_fast(int slot_num) | |
293 | { | |
7e4a7d39 | 294 | kern_return_t rc; |
b0d623f7 A |
295 | |
296 | /* | |
297 | * Try to perform a fast restart | |
298 | */ | |
299 | rc = pmCPUExitHalt(slot_num); | |
300 | if (rc != KERN_SUCCESS) | |
301 | /* | |
302 | * The CPU was not eligible for a fast restart. | |
303 | */ | |
304 | return(rc); | |
305 | ||
bd504ef0 A |
306 | KERNEL_DEBUG_CONSTANT( |
307 | TRACE_MP_CPU_FAST_START | DBG_FUNC_START, | |
308 | slot_num, 0, 0, 0, 0); | |
309 | ||
b0d623f7 A |
310 | /* |
311 | * Wait until the CPU is back online. | |
312 | */ | |
313 | mp_disable_preemption(); | |
314 | ||
315 | /* | |
316 | * We use short pauses (1us) for low latency. 30,000 iterations is | |
317 | * longer than a full restart would require so it should be more | |
318 | * than long enough. | |
319 | */ | |
6d2010ae | 320 | |
b0d623f7 A |
321 | mp_wait_for_cpu_up(slot_num, 30000, 1); |
322 | mp_enable_preemption(); | |
323 | ||
bd504ef0 A |
324 | KERNEL_DEBUG_CONSTANT( |
325 | TRACE_MP_CPU_FAST_START | DBG_FUNC_END, | |
326 | slot_num, cpu_datap(slot_num)->cpu_running, 0, 0, 0); | |
327 | ||
b0d623f7 A |
328 | /* |
329 | * Check to make sure that the CPU is really running. If not, | |
330 | * go through the slow path. | |
331 | */ | |
332 | if (cpu_datap(slot_num)->cpu_running) | |
333 | return(KERN_SUCCESS); | |
7e4a7d39 | 334 | else |
b0d623f7 A |
335 | return(KERN_FAILURE); |
336 | } | |
337 | ||
7e4a7d39 A |
338 | static void |
339 | started_cpu(void) | |
340 | { | |
341 | /* Here on the started cpu with cpu_running set TRUE */ | |
c910b4d9 | 342 | |
7e4a7d39 A |
343 | if (TSC_sync_margin && |
344 | start_info.target_cpu == cpu_number()) { | |
345 | /* | |
346 | * I've just started-up, synchronize again with the starter cpu | |
347 | * and then snap my TSC. | |
348 | */ | |
349 | tsc_target = 0; | |
350 | atomic_decl(&tsc_entry_barrier, 1); | |
351 | while (tsc_entry_barrier != 0) | |
352 | ; /* spin for starter and target at barrier */ | |
353 | tsc_target = rdtsc64(); | |
354 | atomic_decl(&tsc_exit_barrier, 1); | |
355 | } | |
356 | } | |
c910b4d9 A |
357 | |
358 | static void | |
359 | start_cpu(void *arg) | |
360 | { | |
361 | int i = 1000; | |
362 | processor_start_info_t *psip = (processor_start_info_t *) arg; | |
363 | ||
364 | /* Ignore this if the current processor is not the starter */ | |
365 | if (cpu_number() != psip->starter_cpu) | |
366 | return; | |
367 | ||
bd504ef0 A |
368 | DBG("start_cpu(%p) about to start cpu %d, lapic %d\n", |
369 | arg, psip->target_cpu, psip->target_lapic); | |
370 | ||
371 | KERNEL_DEBUG_CONSTANT( | |
372 | TRACE_MP_CPU_START | DBG_FUNC_START, | |
373 | psip->target_cpu, | |
374 | psip->target_lapic, 0, 0, 0); | |
375 | ||
6d2010ae | 376 | i386_start_cpu(psip->target_lapic, psip->target_cpu); |
c910b4d9 A |
377 | |
378 | #ifdef POSTCODE_DELAY | |
379 | /* Wait much longer if postcodes are displayed for a delay period. */ | |
380 | i *= 10000; | |
381 | #endif | |
bd504ef0 A |
382 | DBG("start_cpu(%p) about to wait for cpu %d\n", |
383 | arg, psip->target_cpu); | |
384 | ||
c910b4d9 | 385 | mp_wait_for_cpu_up(psip->target_cpu, i*100, 100); |
bd504ef0 A |
386 | |
387 | KERNEL_DEBUG_CONSTANT( | |
388 | TRACE_MP_CPU_START | DBG_FUNC_END, | |
389 | psip->target_cpu, | |
390 | cpu_datap(psip->target_cpu)->cpu_running, 0, 0, 0); | |
391 | ||
7e4a7d39 A |
392 | if (TSC_sync_margin && |
393 | cpu_datap(psip->target_cpu)->cpu_running) { | |
394 | /* | |
395 | * Compare the TSC from the started processor with ours. | |
396 | * Report and log/panic if it diverges by more than | |
397 | * TSC_sync_margin (TSC_SYNC_MARGIN) ticks. This margin | |
398 | * can be overriden by boot-arg (with 0 meaning no checking). | |
399 | */ | |
400 | uint64_t tsc_starter; | |
401 | int64_t tsc_delta; | |
402 | atomic_decl(&tsc_entry_barrier, 1); | |
403 | while (tsc_entry_barrier != 0) | |
404 | ; /* spin for both processors at barrier */ | |
405 | tsc_starter = rdtsc64(); | |
406 | atomic_decl(&tsc_exit_barrier, 1); | |
407 | while (tsc_exit_barrier != 0) | |
408 | ; /* spin for target to store its TSC */ | |
409 | tsc_delta = tsc_target - tsc_starter; | |
410 | kprintf("TSC sync for cpu %d: 0x%016llx delta 0x%llx (%lld)\n", | |
411 | psip->target_cpu, tsc_target, tsc_delta, tsc_delta); | |
412 | if (ABS(tsc_delta) > (int64_t) TSC_sync_margin) { | |
413 | #if DEBUG | |
414 | panic( | |
415 | #else | |
416 | printf( | |
417 | #endif | |
418 | "Unsynchronized TSC for cpu %d: " | |
419 | "0x%016llx, delta 0x%llx\n", | |
420 | psip->target_cpu, tsc_target, tsc_delta); | |
421 | } | |
422 | } | |
c910b4d9 A |
423 | } |
424 | ||
55e303ae A |
425 | kern_return_t |
426 | intel_startCPU( | |
427 | int slot_num) | |
428 | { | |
c910b4d9 A |
429 | int lapic = cpu_to_lapic[slot_num]; |
430 | boolean_t istate; | |
55e303ae | 431 | |
91447636 A |
432 | assert(lapic != -1); |
433 | ||
434 | DBGLOG_CPU_INIT(slot_num); | |
55e303ae | 435 | |
91447636 | 436 | DBG("intel_startCPU(%d) lapic_id=%d\n", slot_num, lapic); |
6d2010ae | 437 | DBG("IdlePTD(%p): 0x%x\n", &IdlePTD, (int) (uintptr_t)IdlePTD); |
55e303ae | 438 | |
0c530ab8 A |
439 | /* |
440 | * Initialize (or re-initialize) the descriptor tables for this cpu. | |
441 | * Propagate processor mode to slave. | |
442 | */ | |
39236c6e | 443 | cpu_desc_init64(cpu_datap(slot_num)); |
91447636 | 444 | |
c910b4d9 | 445 | /* Serialize use of the slave boot stack, etc. */ |
b0d623f7 | 446 | lck_mtx_lock(&mp_cpu_boot_lock); |
55e303ae | 447 | |
c910b4d9 | 448 | istate = ml_set_interrupts_enabled(FALSE); |
91447636 | 449 | if (slot_num == get_cpu_number()) { |
c910b4d9 | 450 | ml_set_interrupts_enabled(istate); |
b0d623f7 | 451 | lck_mtx_unlock(&mp_cpu_boot_lock); |
91447636 A |
452 | return KERN_SUCCESS; |
453 | } | |
55e303ae | 454 | |
b0d623f7 A |
455 | start_info.starter_cpu = cpu_number(); |
456 | start_info.target_cpu = slot_num; | |
c910b4d9 | 457 | start_info.target_lapic = lapic; |
7e4a7d39 A |
458 | tsc_entry_barrier = 2; |
459 | tsc_exit_barrier = 2; | |
55e303ae | 460 | |
c910b4d9 | 461 | /* |
b0d623f7 | 462 | * Perform the processor startup sequence with all running |
c910b4d9 A |
463 | * processors rendezvous'ed. This is required during periods when |
464 | * the cache-disable bit is set for MTRR/PAT initialization. | |
465 | */ | |
b0d623f7 | 466 | mp_rendezvous_no_intrs(start_cpu, (void *) &start_info); |
55e303ae | 467 | |
7e4a7d39 A |
468 | start_info.target_cpu = 0; |
469 | ||
c910b4d9 | 470 | ml_set_interrupts_enabled(istate); |
b0d623f7 | 471 | lck_mtx_unlock(&mp_cpu_boot_lock); |
55e303ae | 472 | |
91447636 | 473 | if (!cpu_datap(slot_num)->cpu_running) { |
0c530ab8 | 474 | kprintf("Failed to start CPU %02d\n", slot_num); |
91447636 A |
475 | printf("Failed to start CPU %02d, rebooting...\n", slot_num); |
476 | delay(1000000); | |
b0d623f7 | 477 | halt_cpu(); |
55e303ae A |
478 | return KERN_SUCCESS; |
479 | } else { | |
2d21ac55 | 480 | kprintf("Started cpu %d (lapic id %08x)\n", slot_num, lapic); |
55e303ae A |
481 | return KERN_SUCCESS; |
482 | } | |
483 | } | |
484 | ||
55e303ae | 485 | #if MP_DEBUG |
91447636 A |
486 | cpu_signal_event_log_t *cpu_signal[MAX_CPUS]; |
487 | cpu_signal_event_log_t *cpu_handle[MAX_CPUS]; | |
55e303ae A |
488 | |
489 | MP_EVENT_NAME_DECL(); | |
490 | ||
55e303ae A |
491 | #endif /* MP_DEBUG */ |
492 | ||
fe8ab488 A |
493 | /* |
494 | * Note: called with NULL state when polling for TLB flush and cross-calls. | |
495 | */ | |
593a1d5f | 496 | int |
0c530ab8 | 497 | cpu_signal_handler(x86_saved_state_t *regs) |
55e303ae | 498 | { |
39236c6e A |
499 | #if !MACH_KDP |
500 | #pragma unused (regs) | |
501 | #endif /* !MACH_KDP */ | |
91447636 | 502 | int my_cpu; |
55e303ae | 503 | volatile int *my_word; |
55e303ae | 504 | |
6d2010ae | 505 | SCHED_STATS_IPI(current_processor()); |
55e303ae A |
506 | |
507 | my_cpu = cpu_number(); | |
060df5ea A |
508 | my_word = &cpu_data_ptr[my_cpu]->cpu_signals; |
509 | /* Store the initial set of signals for diagnostics. New | |
510 | * signals could arrive while these are being processed | |
511 | * so it's no more than a hint. | |
512 | */ | |
6d2010ae | 513 | |
060df5ea | 514 | cpu_data_ptr[my_cpu]->cpu_prior_signals = *my_word; |
55e303ae A |
515 | |
516 | do { | |
55e303ae | 517 | #if MACH_KDP |
fe8ab488 | 518 | if (i_bit(MP_KDP, my_word)) { |
55e303ae A |
519 | DBGLOG(cpu_handle,my_cpu,MP_KDP); |
520 | i_bit_clear(MP_KDP, my_word); | |
0c530ab8 A |
521 | /* Ensure that the i386_kernel_state at the base of the |
522 | * current thread's stack (if any) is synchronized with the | |
523 | * context at the moment of the interrupt, to facilitate | |
524 | * access through the debugger. | |
0c530ab8 | 525 | */ |
b0d623f7 | 526 | sync_iss_to_iks(regs); |
d41d1dae A |
527 | if (pmsafe_debug && !kdp_snapshot) |
528 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_SAFE); | |
b0d623f7 | 529 | mp_kdp_wait(TRUE, FALSE); |
d41d1dae A |
530 | if (pmsafe_debug && !kdp_snapshot) |
531 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_NORMAL); | |
55e303ae A |
532 | } else |
533 | #endif /* MACH_KDP */ | |
91447636 | 534 | if (i_bit(MP_TLB_FLUSH, my_word)) { |
55e303ae A |
535 | DBGLOG(cpu_handle,my_cpu,MP_TLB_FLUSH); |
536 | i_bit_clear(MP_TLB_FLUSH, my_word); | |
537 | pmap_update_interrupt(); | |
55e303ae A |
538 | } else if (i_bit(MP_RENDEZVOUS, my_word)) { |
539 | DBGLOG(cpu_handle,my_cpu,MP_RENDEZVOUS); | |
540 | i_bit_clear(MP_RENDEZVOUS, my_word); | |
541 | mp_rendezvous_action(); | |
2d21ac55 A |
542 | } else if (i_bit(MP_BROADCAST, my_word)) { |
543 | DBGLOG(cpu_handle,my_cpu,MP_BROADCAST); | |
544 | i_bit_clear(MP_BROADCAST, my_word); | |
545 | mp_broadcast_action(); | |
0c530ab8 A |
546 | } else if (i_bit(MP_CHUD, my_word)) { |
547 | DBGLOG(cpu_handle,my_cpu,MP_CHUD); | |
548 | i_bit_clear(MP_CHUD, my_word); | |
549 | chudxnu_cpu_signal_handler(); | |
2d21ac55 A |
550 | } else if (i_bit(MP_CALL, my_word)) { |
551 | DBGLOG(cpu_handle,my_cpu,MP_CALL); | |
552 | i_bit_clear(MP_CALL, my_word); | |
553 | mp_cpus_call_action(); | |
c910b4d9 A |
554 | } else if (i_bit(MP_CALL_PM, my_word)) { |
555 | DBGLOG(cpu_handle,my_cpu,MP_CALL_PM); | |
556 | i_bit_clear(MP_CALL_PM, my_word); | |
557 | mp_call_PM(); | |
55e303ae | 558 | } |
fe8ab488 A |
559 | if (regs == NULL) { |
560 | /* Called to poll only for cross-calls and TLB flush */ | |
561 | break; | |
562 | } else if (i_bit(MP_AST, my_word)) { | |
563 | DBGLOG(cpu_handle,my_cpu,MP_AST); | |
564 | i_bit_clear(MP_AST, my_word); | |
565 | ast_check(cpu_to_processor(my_cpu)); | |
566 | } | |
55e303ae A |
567 | } while (*my_word); |
568 | ||
593a1d5f | 569 | return 0; |
55e303ae A |
570 | } |
571 | ||
fe8ab488 | 572 | extern void kprintf_break_lock(void); |
593a1d5f | 573 | static int |
2d21ac55 | 574 | NMIInterruptHandler(x86_saved_state_t *regs) |
0c530ab8 | 575 | { |
fe8ab488 | 576 | void *stackptr; |
060df5ea | 577 | |
6d2010ae A |
578 | if (panic_active() && !panicDebugging) { |
579 | if (pmsafe_debug) | |
580 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_SAFE); | |
581 | for(;;) | |
582 | cpu_pause(); | |
583 | } | |
584 | ||
060df5ea | 585 | atomic_incl(&NMIPI_acks, 1); |
39236c6e | 586 | atomic_incl(&NMI_count, 1); |
0c530ab8 | 587 | sync_iss_to_iks_unconditionally(regs); |
b0d623f7 | 588 | __asm__ volatile("movq %%rbp, %0" : "=m" (stackptr)); |
935ed37a | 589 | |
593a1d5f | 590 | if (cpu_number() == debugger_cpu) |
fe8ab488 | 591 | goto NMExit; |
593a1d5f | 592 | |
060df5ea | 593 | if (spinlock_timed_out) { |
7ddcb079 | 594 | char pstr[192]; |
060df5ea A |
595 | snprintf(&pstr[0], sizeof(pstr), "Panic(CPU %d): NMIPI for spinlock acquisition timeout, spinlock: %p, spinlock owner: %p, current_thread: %p, spinlock_owner_cpu: 0x%x\n", cpu_number(), spinlock_timed_out, (void *) spinlock_timed_out->interlock.lock_data, current_thread(), spinlock_owner_cpu); |
596 | panic_i386_backtrace(stackptr, 64, &pstr[0], TRUE, regs); | |
fe8ab488 A |
597 | } else if (mp_cpus_call_wait_timeout) { |
598 | char pstr[192]; | |
599 | snprintf(&pstr[0], sizeof(pstr), "Panic(CPU %d): Unresponsive processor, this CPU timed-out during cross-call\n", cpu_number()); | |
600 | panic_i386_backtrace(stackptr, 64, &pstr[0], TRUE, regs); | |
060df5ea | 601 | } else if (pmap_tlb_flush_timeout == TRUE) { |
593a1d5f | 602 | char pstr[128]; |
7ddcb079 | 603 | snprintf(&pstr[0], sizeof(pstr), "Panic(CPU %d): Unresponsive processor (this CPU did not acknowledge interrupts) TLB state:0x%x\n", cpu_number(), current_cpu_datap()->cpu_tlb_invalid); |
6d2010ae | 604 | panic_i386_backtrace(stackptr, 48, &pstr[0], TRUE, regs); |
fe8ab488 | 605 | } |
b0d623f7 A |
606 | |
607 | #if MACH_KDP | |
d41d1dae A |
608 | if (pmsafe_debug && !kdp_snapshot) |
609 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_SAFE); | |
060df5ea | 610 | current_cpu_datap()->cpu_NMI_acknowledged = TRUE; |
15129b1c | 611 | i_bit_clear(MP_KDP, ¤t_cpu_datap()->cpu_signals); |
fe8ab488 A |
612 | if (pmap_tlb_flush_timeout || |
613 | spinlock_timed_out || | |
614 | mp_cpus_call_wait_timeout || | |
615 | panic_active()) { | |
616 | mp_kdp_wait(FALSE, TRUE); | |
617 | } else if (virtualized && (debug_boot_arg & DB_NMI)) { | |
618 | /* | |
619 | * Under a VMM with the debug boot-arg set, drop into kdp. | |
620 | * Since an NMI is involved, there's a risk of contending with | |
621 | * a panic. And side-effects of NMIs may result in entry into, | |
622 | * and continuing from, the debugger being unreliable. | |
623 | */ | |
624 | kprintf_break_lock(); | |
625 | kprintf("Debugger entry requested by NMI\n"); | |
626 | kdp_i386_trap(T_DEBUG, saved_state64(regs), 0, 0); | |
627 | printf("Debugger entry requested by NMI\n"); | |
628 | } else { | |
629 | mp_kdp_wait(FALSE, FALSE); | |
630 | } | |
d41d1dae A |
631 | if (pmsafe_debug && !kdp_snapshot) |
632 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_NORMAL); | |
b0d623f7 | 633 | #endif |
593a1d5f | 634 | NMExit: |
0c530ab8 A |
635 | return 1; |
636 | } | |
637 | ||
2d21ac55 A |
638 | |
639 | /* | |
640 | * cpu_interrupt is really just to be used by the scheduler to | |
641 | * get a CPU's attention it may not always issue an IPI. If an | |
642 | * IPI is always needed then use i386_cpu_IPI. | |
643 | */ | |
644 | void | |
645 | cpu_interrupt(int cpu) | |
646 | { | |
6d2010ae A |
647 | boolean_t did_IPI = FALSE; |
648 | ||
2d21ac55 A |
649 | if (smp_initialized |
650 | && pmCPUExitIdle(cpu_datap(cpu))) { | |
651 | i386_cpu_IPI(cpu); | |
6d2010ae | 652 | did_IPI = TRUE; |
2d21ac55 | 653 | } |
6d2010ae A |
654 | |
655 | KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SCHED, MACH_REMOTE_AST), cpu, did_IPI, 0, 0, 0); | |
55e303ae A |
656 | } |
657 | ||
0c530ab8 A |
658 | /* |
659 | * Send a true NMI via the local APIC to the specified CPU. | |
660 | */ | |
935ed37a | 661 | void |
0c530ab8 A |
662 | cpu_NMI_interrupt(int cpu) |
663 | { | |
0c530ab8 | 664 | if (smp_initialized) { |
6d2010ae | 665 | i386_send_NMI(cpu); |
0c530ab8 | 666 | } |
0c530ab8 A |
667 | } |
668 | ||
39236c6e A |
669 | void |
670 | NMI_cpus(void) | |
671 | { | |
672 | unsigned int cpu; | |
673 | boolean_t intrs_enabled; | |
674 | uint64_t tsc_timeout; | |
675 | ||
676 | intrs_enabled = ml_set_interrupts_enabled(FALSE); | |
677 | ||
678 | for (cpu = 0; cpu < real_ncpus; cpu++) { | |
679 | if (!cpu_datap(cpu)->cpu_running) | |
680 | continue; | |
681 | cpu_datap(cpu)->cpu_NMI_acknowledged = FALSE; | |
682 | cpu_NMI_interrupt(cpu); | |
683 | tsc_timeout = !machine_timeout_suspended() ? | |
684 | rdtsc64() + (1000 * 1000 * 1000 * 10ULL) : | |
685 | ~0ULL; | |
686 | while (!cpu_datap(cpu)->cpu_NMI_acknowledged) { | |
687 | handle_pending_TLB_flushes(); | |
688 | cpu_pause(); | |
689 | if (rdtsc64() > tsc_timeout) | |
690 | panic("NMI_cpus() timeout cpu %d", cpu); | |
691 | } | |
692 | cpu_datap(cpu)->cpu_NMI_acknowledged = FALSE; | |
693 | } | |
694 | ||
695 | ml_set_interrupts_enabled(intrs_enabled); | |
696 | } | |
697 | ||
b0d623f7 | 698 | static void (* volatile mp_PM_func)(void) = NULL; |
c910b4d9 A |
699 | |
700 | static void | |
701 | mp_call_PM(void) | |
702 | { | |
703 | assert(!ml_get_interrupts_enabled()); | |
704 | ||
705 | if (mp_PM_func != NULL) | |
706 | mp_PM_func(); | |
707 | } | |
708 | ||
709 | void | |
710 | cpu_PM_interrupt(int cpu) | |
711 | { | |
712 | assert(!ml_get_interrupts_enabled()); | |
713 | ||
714 | if (mp_PM_func != NULL) { | |
715 | if (cpu == cpu_number()) | |
716 | mp_PM_func(); | |
717 | else | |
718 | i386_signal_cpu(cpu, MP_CALL_PM, ASYNC); | |
719 | } | |
720 | } | |
721 | ||
722 | void | |
723 | PM_interrupt_register(void (*fn)(void)) | |
724 | { | |
725 | mp_PM_func = fn; | |
726 | } | |
727 | ||
55e303ae A |
728 | void |
729 | i386_signal_cpu(int cpu, mp_event_t event, mp_sync_t mode) | |
730 | { | |
91447636 A |
731 | volatile int *signals = &cpu_datap(cpu)->cpu_signals; |
732 | uint64_t tsc_timeout; | |
6601e61a | 733 | |
0c530ab8 | 734 | |
91447636 | 735 | if (!cpu_datap(cpu)->cpu_running) |
55e303ae A |
736 | return; |
737 | ||
0c530ab8 | 738 | if (event == MP_TLB_FLUSH) |
6d2010ae | 739 | KERNEL_DEBUG(TRACE_MP_TLB_FLUSH | DBG_FUNC_START, cpu, 0, 0, 0, 0); |
6601e61a | 740 | |
0c530ab8 A |
741 | DBGLOG(cpu_signal, cpu, event); |
742 | ||
55e303ae | 743 | i_bit_set(event, signals); |
2d21ac55 | 744 | i386_cpu_IPI(cpu); |
55e303ae A |
745 | if (mode == SYNC) { |
746 | again: | |
39236c6e A |
747 | tsc_timeout = !machine_timeout_suspended() ? |
748 | rdtsc64() + (1000*1000*1000) : | |
749 | ~0ULL; | |
91447636 | 750 | while (i_bit(event, signals) && rdtsc64() < tsc_timeout) { |
55e303ae A |
751 | cpu_pause(); |
752 | } | |
753 | if (i_bit(event, signals)) { | |
754 | DBG("i386_signal_cpu(%d, 0x%x, SYNC) timed out\n", | |
755 | cpu, event); | |
756 | goto again; | |
757 | } | |
758 | } | |
0c530ab8 | 759 | if (event == MP_TLB_FLUSH) |
6d2010ae | 760 | KERNEL_DEBUG(TRACE_MP_TLB_FLUSH | DBG_FUNC_END, cpu, 0, 0, 0, 0); |
55e303ae A |
761 | } |
762 | ||
2d21ac55 A |
763 | /* |
764 | * Send event to all running cpus. | |
765 | * Called with the topology locked. | |
766 | */ | |
55e303ae A |
767 | void |
768 | i386_signal_cpus(mp_event_t event, mp_sync_t mode) | |
769 | { | |
91447636 A |
770 | unsigned int cpu; |
771 | unsigned int my_cpu = cpu_number(); | |
55e303ae | 772 | |
b0d623f7 | 773 | assert(hw_lock_held((hw_lock_t)&x86_topo_lock)); |
2d21ac55 | 774 | |
91447636 A |
775 | for (cpu = 0; cpu < real_ncpus; cpu++) { |
776 | if (cpu == my_cpu || !cpu_datap(cpu)->cpu_running) | |
55e303ae A |
777 | continue; |
778 | i386_signal_cpu(cpu, event, mode); | |
779 | } | |
780 | } | |
781 | ||
2d21ac55 A |
782 | /* |
783 | * Return the number of running cpus. | |
784 | * Called with the topology locked. | |
785 | */ | |
55e303ae A |
786 | int |
787 | i386_active_cpus(void) | |
788 | { | |
91447636 A |
789 | unsigned int cpu; |
790 | unsigned int ncpus = 0; | |
55e303ae | 791 | |
b0d623f7 | 792 | assert(hw_lock_held((hw_lock_t)&x86_topo_lock)); |
2d21ac55 | 793 | |
91447636 A |
794 | for (cpu = 0; cpu < real_ncpus; cpu++) { |
795 | if (cpu_datap(cpu)->cpu_running) | |
55e303ae A |
796 | ncpus++; |
797 | } | |
798 | return(ncpus); | |
799 | } | |
800 | ||
39236c6e A |
801 | /* |
802 | * Helper function called when busy-waiting: panic if too long | |
803 | * a TSC-based time has elapsed since the start of the spin. | |
804 | */ | |
fe8ab488 A |
805 | static boolean_t |
806 | mp_spin_timeout(uint64_t tsc_start) | |
39236c6e A |
807 | { |
808 | uint64_t tsc_timeout; | |
809 | ||
810 | cpu_pause(); | |
811 | if (machine_timeout_suspended()) | |
fe8ab488 | 812 | return FALSE; |
39236c6e A |
813 | |
814 | /* | |
815 | * The timeout is 4 * the spinlock timeout period | |
816 | * unless we have serial console printing (kprintf) enabled | |
817 | * in which case we allow an even greater margin. | |
818 | */ | |
819 | tsc_timeout = disable_serial_output ? (uint64_t) LockTimeOutTSC << 2 | |
820 | : (uint64_t) LockTimeOutTSC << 4; | |
fe8ab488 A |
821 | return (rdtsc64() > tsc_start + tsc_timeout); |
822 | } | |
823 | ||
824 | /* | |
825 | * Helper function to take a spinlock while ensuring that incoming IPIs | |
826 | * are still serviced if interrupts are masked while we spin. | |
827 | */ | |
828 | static boolean_t | |
829 | mp_safe_spin_lock(usimple_lock_t lock) | |
830 | { | |
831 | if (ml_get_interrupts_enabled()) { | |
832 | simple_lock(lock); | |
833 | return TRUE; | |
834 | } else { | |
835 | uint64_t tsc_spin_start = rdtsc64(); | |
836 | while (!simple_lock_try(lock)) { | |
837 | cpu_signal_handler(NULL); | |
838 | if (mp_spin_timeout(tsc_spin_start)) { | |
839 | uint32_t lock_cpu; | |
840 | uintptr_t lowner = (uintptr_t) | |
841 | lock->interlock.lock_data; | |
842 | spinlock_timed_out = lock; | |
843 | lock_cpu = spinlock_timeout_NMI(lowner); | |
844 | panic("mp_safe_spin_lock() timed out," | |
845 | " lock: %p, owner thread: 0x%lx," | |
846 | " current_thread: %p, owner on CPU 0x%x", | |
847 | lock, lowner, | |
848 | current_thread(), lock_cpu); | |
849 | } | |
850 | } | |
851 | return FALSE; | |
852 | } | |
39236c6e A |
853 | } |
854 | ||
55e303ae A |
855 | /* |
856 | * All-CPU rendezvous: | |
857 | * - CPUs are signalled, | |
858 | * - all execute the setup function (if specified), | |
859 | * - rendezvous (i.e. all cpus reach a barrier), | |
860 | * - all execute the action function (if specified), | |
861 | * - rendezvous again, | |
862 | * - execute the teardown function (if specified), and then | |
863 | * - resume. | |
864 | * | |
865 | * Note that the supplied external functions _must_ be reentrant and aware | |
866 | * that they are running in parallel and in an unknown lock context. | |
867 | */ | |
868 | ||
869 | static void | |
870 | mp_rendezvous_action(void) | |
871 | { | |
39236c6e A |
872 | boolean_t intrs_enabled; |
873 | uint64_t tsc_spin_start; | |
55e303ae A |
874 | |
875 | /* setup function */ | |
876 | if (mp_rv_setup_func != NULL) | |
877 | mp_rv_setup_func(mp_rv_func_arg); | |
2d21ac55 A |
878 | |
879 | intrs_enabled = ml_get_interrupts_enabled(); | |
880 | ||
55e303ae | 881 | /* spin on entry rendezvous */ |
0c530ab8 | 882 | atomic_incl(&mp_rv_entry, 1); |
39236c6e | 883 | tsc_spin_start = rdtsc64(); |
0c530ab8 | 884 | while (mp_rv_entry < mp_rv_ncpus) { |
2d21ac55 A |
885 | /* poll for pesky tlb flushes if interrupts disabled */ |
886 | if (!intrs_enabled) | |
887 | handle_pending_TLB_flushes(); | |
fe8ab488 A |
888 | if (mp_spin_timeout(tsc_spin_start)) |
889 | panic("mp_rendezvous_action() entry"); | |
0c530ab8 | 890 | } |
6d2010ae | 891 | |
55e303ae A |
892 | /* action function */ |
893 | if (mp_rv_action_func != NULL) | |
894 | mp_rv_action_func(mp_rv_func_arg); | |
6d2010ae | 895 | |
55e303ae | 896 | /* spin on exit rendezvous */ |
0c530ab8 | 897 | atomic_incl(&mp_rv_exit, 1); |
39236c6e | 898 | tsc_spin_start = rdtsc64(); |
2d21ac55 A |
899 | while (mp_rv_exit < mp_rv_ncpus) { |
900 | if (!intrs_enabled) | |
901 | handle_pending_TLB_flushes(); | |
fe8ab488 A |
902 | if (mp_spin_timeout(tsc_spin_start)) |
903 | panic("mp_rendezvous_action() exit"); | |
2d21ac55 | 904 | } |
6d2010ae | 905 | |
55e303ae A |
906 | /* teardown function */ |
907 | if (mp_rv_teardown_func != NULL) | |
908 | mp_rv_teardown_func(mp_rv_func_arg); | |
0c530ab8 A |
909 | |
910 | /* Bump completion count */ | |
911 | atomic_incl(&mp_rv_complete, 1); | |
55e303ae A |
912 | } |
913 | ||
914 | void | |
915 | mp_rendezvous(void (*setup_func)(void *), | |
916 | void (*action_func)(void *), | |
917 | void (*teardown_func)(void *), | |
918 | void *arg) | |
919 | { | |
39236c6e | 920 | uint64_t tsc_spin_start; |
55e303ae A |
921 | |
922 | if (!smp_initialized) { | |
923 | if (setup_func != NULL) | |
924 | setup_func(arg); | |
925 | if (action_func != NULL) | |
926 | action_func(arg); | |
927 | if (teardown_func != NULL) | |
928 | teardown_func(arg); | |
929 | return; | |
930 | } | |
931 | ||
932 | /* obtain rendezvous lock */ | |
fe8ab488 | 933 | (void) mp_safe_spin_lock(&mp_rv_lock); |
55e303ae A |
934 | |
935 | /* set static function pointers */ | |
936 | mp_rv_setup_func = setup_func; | |
937 | mp_rv_action_func = action_func; | |
938 | mp_rv_teardown_func = teardown_func; | |
939 | mp_rv_func_arg = arg; | |
940 | ||
0c530ab8 A |
941 | mp_rv_entry = 0; |
942 | mp_rv_exit = 0; | |
943 | mp_rv_complete = 0; | |
55e303ae A |
944 | |
945 | /* | |
946 | * signal other processors, which will call mp_rendezvous_action() | |
2d21ac55 | 947 | * with interrupts disabled |
55e303ae | 948 | */ |
fe8ab488 | 949 | (void) mp_safe_spin_lock(&x86_topo_lock); |
0c530ab8 | 950 | mp_rv_ncpus = i386_active_cpus(); |
55e303ae | 951 | i386_signal_cpus(MP_RENDEZVOUS, ASYNC); |
2d21ac55 | 952 | simple_unlock(&x86_topo_lock); |
55e303ae A |
953 | |
954 | /* call executor function on this cpu */ | |
955 | mp_rendezvous_action(); | |
956 | ||
0c530ab8 A |
957 | /* |
958 | * Spin for everyone to complete. | |
959 | * This is necessary to ensure that all processors have proceeded | |
960 | * from the exit barrier before we release the rendezvous structure. | |
961 | */ | |
39236c6e | 962 | tsc_spin_start = rdtsc64(); |
0c530ab8 | 963 | while (mp_rv_complete < mp_rv_ncpus) { |
fe8ab488 A |
964 | if (mp_spin_timeout(tsc_spin_start)) |
965 | panic("mp_rendezvous() timeout"); | |
0c530ab8 A |
966 | } |
967 | ||
2d21ac55 A |
968 | /* Tidy up */ |
969 | mp_rv_setup_func = NULL; | |
970 | mp_rv_action_func = NULL; | |
971 | mp_rv_teardown_func = NULL; | |
972 | mp_rv_func_arg = NULL; | |
973 | ||
55e303ae A |
974 | /* release lock */ |
975 | simple_unlock(&mp_rv_lock); | |
976 | } | |
977 | ||
0c530ab8 A |
978 | void |
979 | mp_rendezvous_break_lock(void) | |
980 | { | |
981 | simple_lock_init(&mp_rv_lock, 0); | |
982 | } | |
983 | ||
984 | static void | |
985 | setup_disable_intrs(__unused void * param_not_used) | |
986 | { | |
987 | /* disable interrupts before the first barrier */ | |
988 | boolean_t intr = ml_set_interrupts_enabled(FALSE); | |
989 | ||
990 | current_cpu_datap()->cpu_iflag = intr; | |
991 | DBG("CPU%d: %s\n", get_cpu_number(), __FUNCTION__); | |
992 | } | |
993 | ||
994 | static void | |
995 | teardown_restore_intrs(__unused void * param_not_used) | |
996 | { | |
997 | /* restore interrupt flag following MTRR changes */ | |
998 | ml_set_interrupts_enabled(current_cpu_datap()->cpu_iflag); | |
999 | DBG("CPU%d: %s\n", get_cpu_number(), __FUNCTION__); | |
1000 | } | |
1001 | ||
1002 | /* | |
1003 | * A wrapper to mp_rendezvous() to call action_func() with interrupts disabled. | |
1004 | * This is exported for use by kexts. | |
1005 | */ | |
1006 | void | |
1007 | mp_rendezvous_no_intrs( | |
1008 | void (*action_func)(void *), | |
1009 | void *arg) | |
1010 | { | |
1011 | mp_rendezvous(setup_disable_intrs, | |
1012 | action_func, | |
1013 | teardown_restore_intrs, | |
1014 | arg); | |
1015 | } | |
1016 | ||
6d2010ae A |
1017 | |
1018 | typedef struct { | |
1019 | queue_chain_t link; /* queue linkage */ | |
1020 | void (*func)(void *,void *); /* routine to call */ | |
1021 | void *arg0; /* routine's 1st arg */ | |
1022 | void *arg1; /* routine's 2nd arg */ | |
fe8ab488 | 1023 | cpumask_t *maskp; /* completion response mask */ |
6d2010ae | 1024 | } mp_call_t; |
316670eb A |
1025 | |
1026 | ||
1027 | typedef struct { | |
1028 | queue_head_t queue; | |
1029 | decl_simple_lock_data(, lock); | |
1030 | } mp_call_queue_t; | |
6d2010ae | 1031 | #define MP_CPUS_CALL_BUFS_PER_CPU MAX_CPUS |
316670eb A |
1032 | static mp_call_queue_t mp_cpus_call_freelist; |
1033 | static mp_call_queue_t mp_cpus_call_head[MAX_CPUS]; | |
6d2010ae A |
1034 | |
1035 | static inline boolean_t | |
316670eb | 1036 | mp_call_head_lock(mp_call_queue_t *cqp) |
6d2010ae A |
1037 | { |
1038 | boolean_t intrs_enabled; | |
1039 | ||
1040 | intrs_enabled = ml_set_interrupts_enabled(FALSE); | |
316670eb | 1041 | simple_lock(&cqp->lock); |
6d2010ae A |
1042 | |
1043 | return intrs_enabled; | |
1044 | } | |
1045 | ||
fe8ab488 A |
1046 | void |
1047 | mp_cpus_NMIPI(cpumask_t cpu_mask) { | |
1048 | unsigned int cpu, cpu_bit; | |
1049 | uint64_t deadline; | |
1050 | ||
1051 | for (cpu = 0, cpu_bit = 1; cpu < real_ncpus; cpu++, cpu_bit <<= 1) { | |
1052 | if (cpu_mask & cpu_bit) | |
1053 | cpu_NMI_interrupt(cpu); | |
1054 | } | |
1055 | deadline = mach_absolute_time() + (LockTimeOut); | |
1056 | while (mach_absolute_time() < deadline) | |
1057 | cpu_pause(); | |
1058 | } | |
1059 | ||
1060 | #if MACH_ASSERT | |
6d2010ae | 1061 | static inline boolean_t |
316670eb | 1062 | mp_call_head_is_locked(mp_call_queue_t *cqp) |
6d2010ae A |
1063 | { |
1064 | return !ml_get_interrupts_enabled() && | |
316670eb | 1065 | hw_lock_held((hw_lock_t)&cqp->lock); |
6d2010ae | 1066 | } |
fe8ab488 | 1067 | #endif |
6d2010ae A |
1068 | |
1069 | static inline void | |
316670eb | 1070 | mp_call_head_unlock(mp_call_queue_t *cqp, boolean_t intrs_enabled) |
6d2010ae | 1071 | { |
316670eb | 1072 | simple_unlock(&cqp->lock); |
6d2010ae A |
1073 | ml_set_interrupts_enabled(intrs_enabled); |
1074 | } | |
1075 | ||
1076 | static inline mp_call_t * | |
1077 | mp_call_alloc(void) | |
1078 | { | |
316670eb A |
1079 | mp_call_t *callp = NULL; |
1080 | boolean_t intrs_enabled; | |
1081 | mp_call_queue_t *cqp = &mp_cpus_call_freelist; | |
1082 | ||
1083 | intrs_enabled = mp_call_head_lock(cqp); | |
1084 | if (!queue_empty(&cqp->queue)) | |
1085 | queue_remove_first(&cqp->queue, callp, typeof(callp), link); | |
1086 | mp_call_head_unlock(cqp, intrs_enabled); | |
6d2010ae | 1087 | |
6d2010ae A |
1088 | return callp; |
1089 | } | |
1090 | ||
1091 | static inline void | |
1092 | mp_call_free(mp_call_t *callp) | |
0c530ab8 | 1093 | { |
316670eb A |
1094 | boolean_t intrs_enabled; |
1095 | mp_call_queue_t *cqp = &mp_cpus_call_freelist; | |
1096 | ||
1097 | intrs_enabled = mp_call_head_lock(cqp); | |
1098 | queue_enter_first(&cqp->queue, callp, typeof(callp), link); | |
1099 | mp_call_head_unlock(cqp, intrs_enabled); | |
6d2010ae A |
1100 | } |
1101 | ||
1102 | static inline mp_call_t * | |
316670eb | 1103 | mp_call_dequeue_locked(mp_call_queue_t *cqp) |
6d2010ae | 1104 | { |
316670eb | 1105 | mp_call_t *callp = NULL; |
0c530ab8 | 1106 | |
316670eb A |
1107 | assert(mp_call_head_is_locked(cqp)); |
1108 | if (!queue_empty(&cqp->queue)) | |
1109 | queue_remove_first(&cqp->queue, callp, typeof(callp), link); | |
6d2010ae A |
1110 | return callp; |
1111 | } | |
1112 | ||
316670eb A |
1113 | static inline void |
1114 | mp_call_enqueue_locked( | |
1115 | mp_call_queue_t *cqp, | |
1116 | mp_call_t *callp) | |
1117 | { | |
1118 | queue_enter(&cqp->queue, callp, typeof(callp), link); | |
1119 | } | |
1120 | ||
6d2010ae A |
1121 | /* Called on the boot processor to initialize global structures */ |
1122 | static void | |
1123 | mp_cpus_call_init(void) | |
1124 | { | |
316670eb A |
1125 | mp_call_queue_t *cqp = &mp_cpus_call_freelist; |
1126 | ||
6d2010ae | 1127 | DBG("mp_cpus_call_init()\n"); |
316670eb A |
1128 | simple_lock_init(&cqp->lock, 0); |
1129 | queue_init(&cqp->queue); | |
6d2010ae A |
1130 | } |
1131 | ||
1132 | /* | |
fe8ab488 | 1133 | * Called at processor registration to add call buffers to the free list |
6d2010ae | 1134 | * and to initialize the per-cpu call queue. |
6d2010ae | 1135 | */ |
fe8ab488 A |
1136 | void |
1137 | mp_cpus_call_cpu_init(int cpu) | |
6d2010ae | 1138 | { |
6d2010ae | 1139 | int i; |
fe8ab488 | 1140 | mp_call_queue_t *cqp = &mp_cpus_call_head[cpu]; |
6d2010ae A |
1141 | mp_call_t *callp; |
1142 | ||
316670eb A |
1143 | simple_lock_init(&cqp->lock, 0); |
1144 | queue_init(&cqp->queue); | |
6d2010ae A |
1145 | for (i = 0; i < MP_CPUS_CALL_BUFS_PER_CPU; i++) { |
1146 | callp = (mp_call_t *) kalloc(sizeof(mp_call_t)); | |
6d2010ae | 1147 | mp_call_free(callp); |
0c530ab8 | 1148 | } |
6d2010ae | 1149 | |
fe8ab488 | 1150 | DBG("mp_cpus_call_init(%d) done\n", cpu); |
0c530ab8 A |
1151 | } |
1152 | ||
2d21ac55 A |
1153 | /* |
1154 | * This is called from cpu_signal_handler() to process an MP_CALL signal. | |
6d2010ae | 1155 | * And also from i386_deactivate_cpu() when a cpu is being taken offline. |
2d21ac55 A |
1156 | */ |
1157 | static void | |
1158 | mp_cpus_call_action(void) | |
1159 | { | |
316670eb | 1160 | mp_call_queue_t *cqp; |
6d2010ae A |
1161 | boolean_t intrs_enabled; |
1162 | mp_call_t *callp; | |
1163 | mp_call_t call; | |
1164 | ||
1165 | assert(!ml_get_interrupts_enabled()); | |
316670eb A |
1166 | cqp = &mp_cpus_call_head[cpu_number()]; |
1167 | intrs_enabled = mp_call_head_lock(cqp); | |
1168 | while ((callp = mp_call_dequeue_locked(cqp)) != NULL) { | |
6d2010ae A |
1169 | /* Copy call request to the stack to free buffer */ |
1170 | call = *callp; | |
1171 | mp_call_free(callp); | |
1172 | if (call.func != NULL) { | |
316670eb | 1173 | mp_call_head_unlock(cqp, intrs_enabled); |
6d2010ae A |
1174 | KERNEL_DEBUG_CONSTANT( |
1175 | TRACE_MP_CPUS_CALL_ACTION, | |
fe8ab488 | 1176 | call.func, call.arg0, call.arg1, call.maskp, 0); |
6d2010ae | 1177 | call.func(call.arg0, call.arg1); |
316670eb | 1178 | (void) mp_call_head_lock(cqp); |
6d2010ae | 1179 | } |
fe8ab488 A |
1180 | if (call.maskp != NULL) |
1181 | i_bit_set(cpu_number(), call.maskp); | |
6d2010ae | 1182 | } |
316670eb | 1183 | mp_call_head_unlock(cqp, intrs_enabled); |
2d21ac55 A |
1184 | } |
1185 | ||
1186 | /* | |
1187 | * mp_cpus_call() runs a given function on cpus specified in a given cpu mask. | |
6d2010ae A |
1188 | * Possible modes are: |
1189 | * SYNC: function is called serially on target cpus in logical cpu order | |
1190 | * waiting for each call to be acknowledged before proceeding | |
1191 | * ASYNC: function call is queued to the specified cpus | |
1192 | * waiting for all calls to complete in parallel before returning | |
1193 | * NOSYNC: function calls are queued | |
1194 | * but we return before confirmation of calls completing. | |
2d21ac55 A |
1195 | * The action function may be NULL. |
1196 | * The cpu mask may include the local cpu. Offline cpus are ignored. | |
6d2010ae | 1197 | * The return value is the number of cpus on which the call was made or queued. |
2d21ac55 A |
1198 | */ |
1199 | cpu_t | |
1200 | mp_cpus_call( | |
1201 | cpumask_t cpus, | |
1202 | mp_sync_t mode, | |
1203 | void (*action_func)(void *), | |
1204 | void *arg) | |
6d2010ae A |
1205 | { |
1206 | return mp_cpus_call1( | |
1207 | cpus, | |
1208 | mode, | |
1209 | (void (*)(void *,void *))action_func, | |
1210 | arg, | |
1211 | NULL, | |
1212 | NULL, | |
1213 | NULL); | |
1214 | } | |
1215 | ||
1216 | static void | |
316670eb | 1217 | mp_cpus_call_wait(boolean_t intrs_enabled, |
fe8ab488 A |
1218 | cpumask_t cpus_called, |
1219 | cpumask_t *cpus_responded) | |
6d2010ae | 1220 | { |
316670eb | 1221 | mp_call_queue_t *cqp; |
39236c6e | 1222 | uint64_t tsc_spin_start; |
6d2010ae | 1223 | |
316670eb | 1224 | cqp = &mp_cpus_call_head[cpu_number()]; |
6d2010ae | 1225 | |
39236c6e | 1226 | tsc_spin_start = rdtsc64(); |
fe8ab488 | 1227 | while (*cpus_responded != cpus_called) { |
6d2010ae | 1228 | if (!intrs_enabled) { |
316670eb A |
1229 | /* Sniffing w/o locking */ |
1230 | if (!queue_empty(&cqp->queue)) | |
6d2010ae | 1231 | mp_cpus_call_action(); |
fe8ab488 A |
1232 | cpu_signal_handler(NULL); |
1233 | } | |
1234 | if (mp_spin_timeout(tsc_spin_start)) { | |
1235 | cpumask_t cpus_unresponsive; | |
1236 | ||
1237 | mp_cpus_call_wait_timeout = TRUE; | |
1238 | cpus_unresponsive = cpus_called & ~(*cpus_responded); | |
1239 | mp_cpus_NMIPI(cpus_unresponsive); | |
3e170ce0 | 1240 | panic("mp_cpus_call_wait() timeout, cpus: 0x%llx", |
fe8ab488 | 1241 | cpus_unresponsive); |
6d2010ae | 1242 | } |
6d2010ae A |
1243 | } |
1244 | } | |
1245 | ||
1246 | cpu_t | |
1247 | mp_cpus_call1( | |
1248 | cpumask_t cpus, | |
1249 | mp_sync_t mode, | |
1250 | void (*action_func)(void *, void *), | |
1251 | void *arg0, | |
1252 | void *arg1, | |
1253 | cpumask_t *cpus_calledp, | |
1254 | cpumask_t *cpus_notcalledp) | |
2d21ac55 A |
1255 | { |
1256 | cpu_t cpu; | |
6d2010ae | 1257 | boolean_t intrs_enabled = FALSE; |
2d21ac55 | 1258 | boolean_t call_self = FALSE; |
6d2010ae A |
1259 | cpumask_t cpus_called = 0; |
1260 | cpumask_t cpus_notcalled = 0; | |
fe8ab488 A |
1261 | cpumask_t cpus_responded = 0; |
1262 | long cpus_call_count = 0; | |
39236c6e | 1263 | uint64_t tsc_spin_start; |
fe8ab488 | 1264 | boolean_t topo_lock; |
6d2010ae A |
1265 | |
1266 | KERNEL_DEBUG_CONSTANT( | |
1267 | TRACE_MP_CPUS_CALL | DBG_FUNC_START, | |
316670eb | 1268 | cpus, mode, VM_KERNEL_UNSLIDE(action_func), arg0, arg1); |
2d21ac55 A |
1269 | |
1270 | if (!smp_initialized) { | |
1271 | if ((cpus & CPUMASK_SELF) == 0) | |
6d2010ae | 1272 | goto out; |
2d21ac55 | 1273 | if (action_func != NULL) { |
6d2010ae A |
1274 | intrs_enabled = ml_set_interrupts_enabled(FALSE); |
1275 | action_func(arg0, arg1); | |
2d21ac55 A |
1276 | ml_set_interrupts_enabled(intrs_enabled); |
1277 | } | |
6d2010ae A |
1278 | call_self = TRUE; |
1279 | goto out; | |
2d21ac55 | 1280 | } |
2d21ac55 | 1281 | |
6d2010ae A |
1282 | /* |
1283 | * Queue the call for each non-local requested cpu. | |
fe8ab488 A |
1284 | * This is performed under the topo lock to prevent changes to |
1285 | * cpus online state and to prevent concurrent rendezvouses -- | |
1286 | * although an exception is made if we're calling only the master | |
1287 | * processor since that always remains active. Note: this exception | |
1288 | * is expected for longterm timer nosync cross-calls to the master cpu. | |
6d2010ae | 1289 | */ |
fe8ab488 A |
1290 | mp_disable_preemption(); |
1291 | intrs_enabled = ml_get_interrupts_enabled(); | |
1292 | topo_lock = (cpus != cpu_to_cpumask(master_cpu)); | |
1293 | if (topo_lock) { | |
1294 | ml_set_interrupts_enabled(FALSE); | |
1295 | (void) mp_safe_spin_lock(&x86_topo_lock); | |
1296 | } | |
2d21ac55 A |
1297 | for (cpu = 0; cpu < (cpu_t) real_ncpus; cpu++) { |
1298 | if (((cpu_to_cpumask(cpu) & cpus) == 0) || | |
1299 | !cpu_datap(cpu)->cpu_running) | |
1300 | continue; | |
fe8ab488 | 1301 | tsc_spin_start = rdtsc64(); |
2d21ac55 A |
1302 | if (cpu == (cpu_t) cpu_number()) { |
1303 | /* | |
1304 | * We don't IPI ourself and if calling asynchronously, | |
1305 | * we defer our call until we have signalled all others. | |
1306 | */ | |
1307 | call_self = TRUE; | |
1308 | if (mode == SYNC && action_func != NULL) { | |
6d2010ae A |
1309 | KERNEL_DEBUG_CONSTANT( |
1310 | TRACE_MP_CPUS_CALL_LOCAL, | |
316670eb A |
1311 | VM_KERNEL_UNSLIDE(action_func), |
1312 | arg0, arg1, 0, 0); | |
6d2010ae | 1313 | action_func(arg0, arg1); |
2d21ac55 A |
1314 | } |
1315 | } else { | |
1316 | /* | |
6d2010ae A |
1317 | * Here to queue a call to cpu and IPI. |
1318 | * Spinning for request buffer unless NOSYNC. | |
2d21ac55 | 1319 | */ |
316670eb A |
1320 | mp_call_t *callp = NULL; |
1321 | mp_call_queue_t *cqp = &mp_cpus_call_head[cpu]; | |
fe8ab488 | 1322 | boolean_t intrs_inner; |
316670eb | 1323 | |
6d2010ae | 1324 | queue_call: |
316670eb A |
1325 | if (callp == NULL) |
1326 | callp = mp_call_alloc(); | |
fe8ab488 | 1327 | intrs_inner = mp_call_head_lock(cqp); |
6d2010ae | 1328 | if (mode == NOSYNC) { |
316670eb | 1329 | if (callp == NULL) { |
6d2010ae | 1330 | cpus_notcalled |= cpu_to_cpumask(cpu); |
fe8ab488 | 1331 | mp_call_head_unlock(cqp, intrs_inner); |
6d2010ae A |
1332 | KERNEL_DEBUG_CONSTANT( |
1333 | TRACE_MP_CPUS_CALL_NOBUF, | |
1334 | cpu, 0, 0, 0, 0); | |
1335 | continue; | |
1336 | } | |
fe8ab488 | 1337 | callp->maskp = NULL; |
6d2010ae | 1338 | } else { |
316670eb | 1339 | if (callp == NULL) { |
fe8ab488 | 1340 | mp_call_head_unlock(cqp, intrs_inner); |
6d2010ae A |
1341 | KERNEL_DEBUG_CONSTANT( |
1342 | TRACE_MP_CPUS_CALL_NOBUF, | |
1343 | cpu, 0, 0, 0, 0); | |
fe8ab488 | 1344 | if (!intrs_inner) { |
316670eb A |
1345 | /* Sniffing w/o locking */ |
1346 | if (!queue_empty(&cqp->queue)) | |
1347 | mp_cpus_call_action(); | |
2d21ac55 | 1348 | handle_pending_TLB_flushes(); |
6d2010ae | 1349 | } |
fe8ab488 A |
1350 | if (mp_spin_timeout(tsc_spin_start)) |
1351 | panic("mp_cpus_call1() timeout"); | |
6d2010ae | 1352 | goto queue_call; |
2d21ac55 | 1353 | } |
fe8ab488 | 1354 | callp->maskp = &cpus_responded; |
6d2010ae | 1355 | } |
316670eb A |
1356 | callp->func = action_func; |
1357 | callp->arg0 = arg0; | |
1358 | callp->arg1 = arg1; | |
1359 | mp_call_enqueue_locked(cqp, callp); | |
fe8ab488 | 1360 | cpus_call_count++; |
6d2010ae A |
1361 | cpus_called |= cpu_to_cpumask(cpu); |
1362 | i386_signal_cpu(cpu, MP_CALL, ASYNC); | |
fe8ab488 | 1363 | mp_call_head_unlock(cqp, intrs_inner); |
6d2010ae | 1364 | if (mode == SYNC) { |
fe8ab488 | 1365 | mp_cpus_call_wait(intrs_inner, cpus_called, &cpus_responded); |
2d21ac55 A |
1366 | } |
1367 | } | |
1368 | } | |
fe8ab488 A |
1369 | if (topo_lock) { |
1370 | simple_unlock(&x86_topo_lock); | |
1371 | ml_set_interrupts_enabled(intrs_enabled); | |
1372 | } | |
2d21ac55 | 1373 | |
6d2010ae A |
1374 | /* Call locally if mode not SYNC */ |
1375 | if (mode != SYNC && call_self ) { | |
1376 | KERNEL_DEBUG_CONSTANT( | |
1377 | TRACE_MP_CPUS_CALL_LOCAL, | |
316670eb | 1378 | VM_KERNEL_UNSLIDE(action_func), arg0, arg1, 0, 0); |
6d2010ae A |
1379 | if (action_func != NULL) { |
1380 | ml_set_interrupts_enabled(FALSE); | |
1381 | action_func(arg0, arg1); | |
2d21ac55 A |
1382 | ml_set_interrupts_enabled(intrs_enabled); |
1383 | } | |
2d21ac55 | 1384 | } |
2d21ac55 | 1385 | |
39236c6e A |
1386 | /* Safe to allow pre-emption now */ |
1387 | mp_enable_preemption(); | |
1388 | ||
6d2010ae | 1389 | /* For ASYNC, now wait for all signaled cpus to complete their calls */ |
fe8ab488 A |
1390 | if (mode == ASYNC) |
1391 | mp_cpus_call_wait(intrs_enabled, cpus_called, &cpus_responded); | |
6d2010ae A |
1392 | |
1393 | out: | |
fe8ab488 A |
1394 | if (call_self){ |
1395 | cpus_called |= cpu_to_cpumask(cpu); | |
1396 | cpus_call_count++; | |
1397 | } | |
6d2010ae A |
1398 | |
1399 | if (cpus_calledp) | |
1400 | *cpus_calledp = cpus_called; | |
1401 | if (cpus_notcalledp) | |
1402 | *cpus_notcalledp = cpus_notcalled; | |
1403 | ||
1404 | KERNEL_DEBUG_CONSTANT( | |
1405 | TRACE_MP_CPUS_CALL | DBG_FUNC_END, | |
fe8ab488 | 1406 | cpus_call_count, cpus_called, cpus_notcalled, 0, 0); |
2d21ac55 | 1407 | |
fe8ab488 | 1408 | return (cpu_t) cpus_call_count; |
2d21ac55 A |
1409 | } |
1410 | ||
6d2010ae | 1411 | |
2d21ac55 A |
1412 | static void |
1413 | mp_broadcast_action(void) | |
1414 | { | |
1415 | /* call action function */ | |
1416 | if (mp_bc_action_func != NULL) | |
1417 | mp_bc_action_func(mp_bc_func_arg); | |
1418 | ||
1419 | /* if we're the last one through, wake up the instigator */ | |
b0d623f7 A |
1420 | if (atomic_decl_and_test(&mp_bc_count, 1)) |
1421 | thread_wakeup(((event_t)(uintptr_t) &mp_bc_count)); | |
2d21ac55 A |
1422 | } |
1423 | ||
1424 | /* | |
1425 | * mp_broadcast() runs a given function on all active cpus. | |
1426 | * The caller blocks until the functions has run on all cpus. | |
1427 | * The caller will also block if there is another pending braodcast. | |
1428 | */ | |
1429 | void | |
1430 | mp_broadcast( | |
1431 | void (*action_func)(void *), | |
1432 | void *arg) | |
1433 | { | |
1434 | if (!smp_initialized) { | |
1435 | if (action_func != NULL) | |
1436 | action_func(arg); | |
1437 | return; | |
1438 | } | |
1439 | ||
1440 | /* obtain broadcast lock */ | |
b0d623f7 | 1441 | lck_mtx_lock(&mp_bc_lock); |
2d21ac55 A |
1442 | |
1443 | /* set static function pointers */ | |
1444 | mp_bc_action_func = action_func; | |
1445 | mp_bc_func_arg = arg; | |
1446 | ||
b0d623f7 | 1447 | assert_wait((event_t)(uintptr_t)&mp_bc_count, THREAD_UNINT); |
2d21ac55 A |
1448 | |
1449 | /* | |
1450 | * signal other processors, which will call mp_broadcast_action() | |
1451 | */ | |
1452 | simple_lock(&x86_topo_lock); | |
1453 | mp_bc_ncpus = i386_active_cpus(); /* total including this cpu */ | |
1454 | mp_bc_count = mp_bc_ncpus; | |
1455 | i386_signal_cpus(MP_BROADCAST, ASYNC); | |
1456 | ||
1457 | /* call executor function on this cpu */ | |
1458 | mp_broadcast_action(); | |
1459 | simple_unlock(&x86_topo_lock); | |
1460 | ||
1461 | /* block for all cpus to have run action_func */ | |
1462 | if (mp_bc_ncpus > 1) | |
1463 | thread_block(THREAD_CONTINUE_NULL); | |
1464 | else | |
1465 | clear_wait(current_thread(), THREAD_AWAKENED); | |
1466 | ||
1467 | /* release lock */ | |
b0d623f7 | 1468 | lck_mtx_unlock(&mp_bc_lock); |
2d21ac55 A |
1469 | } |
1470 | ||
fe8ab488 A |
1471 | void |
1472 | mp_cpus_kick(cpumask_t cpus) | |
1473 | { | |
1474 | cpu_t cpu; | |
1475 | boolean_t intrs_enabled = FALSE; | |
1476 | ||
1477 | intrs_enabled = ml_set_interrupts_enabled(FALSE); | |
1478 | mp_safe_spin_lock(&x86_topo_lock); | |
1479 | ||
1480 | for (cpu = 0; cpu < (cpu_t) real_ncpus; cpu++) { | |
1481 | if ((cpu == (cpu_t) cpu_number()) | |
1482 | || ((cpu_to_cpumask(cpu) & cpus) == 0) | |
1483 | || (!cpu_datap(cpu)->cpu_running)) | |
1484 | { | |
1485 | continue; | |
1486 | } | |
1487 | ||
1488 | lapic_send_ipi(cpu, LAPIC_VECTOR(KICK)); | |
1489 | } | |
1490 | ||
1491 | simple_unlock(&x86_topo_lock); | |
1492 | ml_set_interrupts_enabled(intrs_enabled); | |
1493 | } | |
1494 | ||
2d21ac55 A |
1495 | void |
1496 | i386_activate_cpu(void) | |
1497 | { | |
1498 | cpu_data_t *cdp = current_cpu_datap(); | |
1499 | ||
1500 | assert(!ml_get_interrupts_enabled()); | |
1501 | ||
1502 | if (!smp_initialized) { | |
1503 | cdp->cpu_running = TRUE; | |
1504 | return; | |
1505 | } | |
1506 | ||
1507 | simple_lock(&x86_topo_lock); | |
1508 | cdp->cpu_running = TRUE; | |
7e4a7d39 | 1509 | started_cpu(); |
2d21ac55 | 1510 | simple_unlock(&x86_topo_lock); |
7ddcb079 | 1511 | flush_tlb_raw(); |
2d21ac55 A |
1512 | } |
1513 | ||
1514 | void | |
1515 | i386_deactivate_cpu(void) | |
1516 | { | |
1517 | cpu_data_t *cdp = current_cpu_datap(); | |
1518 | ||
1519 | assert(!ml_get_interrupts_enabled()); | |
bd504ef0 A |
1520 | |
1521 | KERNEL_DEBUG_CONSTANT( | |
1522 | TRACE_MP_CPU_DEACTIVATE | DBG_FUNC_START, | |
1523 | 0, 0, 0, 0, 0); | |
2d21ac55 A |
1524 | |
1525 | simple_lock(&x86_topo_lock); | |
1526 | cdp->cpu_running = FALSE; | |
1527 | simple_unlock(&x86_topo_lock); | |
1528 | ||
bd504ef0 A |
1529 | /* |
1530 | * Move all of this cpu's timers to the master/boot cpu, | |
1531 | * and poke it in case there's a sooner deadline for it to schedule. | |
1532 | */ | |
c910b4d9 | 1533 | timer_queue_shutdown(&cdp->rtclock_timer.queue); |
39236c6e | 1534 | mp_cpus_call(cpu_to_cpumask(master_cpu), ASYNC, timer_queue_expire_local, NULL); |
c910b4d9 | 1535 | |
2d21ac55 | 1536 | /* |
bd504ef0 A |
1537 | * Open an interrupt window |
1538 | * and ensure any pending IPI or timer is serviced | |
2d21ac55 | 1539 | */ |
bd504ef0 A |
1540 | mp_disable_preemption(); |
1541 | ml_set_interrupts_enabled(TRUE); | |
1542 | ||
1543 | while (cdp->cpu_signals && x86_lcpu()->rtcDeadline != EndOfAllTime) | |
1544 | cpu_pause(); | |
1545 | /* | |
1546 | * Ensure there's no remaining timer deadline set | |
1547 | * - AICPM may have left one active. | |
1548 | */ | |
1549 | setPop(0); | |
1550 | ||
1551 | ml_set_interrupts_enabled(FALSE); | |
1552 | mp_enable_preemption(); | |
1553 | ||
1554 | KERNEL_DEBUG_CONSTANT( | |
1555 | TRACE_MP_CPU_DEACTIVATE | DBG_FUNC_END, | |
1556 | 0, 0, 0, 0, 0); | |
2d21ac55 A |
1557 | } |
1558 | ||
1559 | int pmsafe_debug = 1; | |
1560 | ||
55e303ae A |
1561 | #if MACH_KDP |
1562 | volatile boolean_t mp_kdp_trap = FALSE; | |
593a1d5f | 1563 | volatile unsigned long mp_kdp_ncpus; |
91447636 A |
1564 | boolean_t mp_kdp_state; |
1565 | ||
55e303ae A |
1566 | |
1567 | void | |
1568 | mp_kdp_enter(void) | |
1569 | { | |
91447636 | 1570 | unsigned int cpu; |
6d2010ae | 1571 | unsigned int ncpus = 0; |
593a1d5f | 1572 | unsigned int my_cpu; |
91447636 | 1573 | uint64_t tsc_timeout; |
55e303ae A |
1574 | |
1575 | DBG("mp_kdp_enter()\n"); | |
1576 | ||
39236c6e A |
1577 | #if DEBUG |
1578 | if (!smp_initialized) | |
1579 | simple_lock_init(&mp_kdp_lock, 0); | |
1580 | #endif | |
1581 | ||
55e303ae A |
1582 | /* |
1583 | * Here to enter the debugger. | |
1584 | * In case of races, only one cpu is allowed to enter kdp after | |
1585 | * stopping others. | |
1586 | */ | |
91447636 | 1587 | mp_kdp_state = ml_set_interrupts_enabled(FALSE); |
060df5ea | 1588 | my_cpu = cpu_number(); |
7ddcb079 A |
1589 | |
1590 | if (my_cpu == (unsigned) debugger_cpu) { | |
1591 | kprintf("\n\nRECURSIVE DEBUGGER ENTRY DETECTED\n\n"); | |
1592 | kdp_reset(); | |
1593 | return; | |
1594 | } | |
1595 | ||
060df5ea | 1596 | cpu_datap(my_cpu)->debugger_entry_time = mach_absolute_time(); |
55e303ae | 1597 | simple_lock(&mp_kdp_lock); |
060df5ea | 1598 | |
d41d1dae | 1599 | if (pmsafe_debug && !kdp_snapshot) |
2d21ac55 A |
1600 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_SAFE); |
1601 | ||
55e303ae A |
1602 | while (mp_kdp_trap) { |
1603 | simple_unlock(&mp_kdp_lock); | |
1604 | DBG("mp_kdp_enter() race lost\n"); | |
b0d623f7 A |
1605 | #if MACH_KDP |
1606 | mp_kdp_wait(TRUE, FALSE); | |
1607 | #endif | |
55e303ae A |
1608 | simple_lock(&mp_kdp_lock); |
1609 | } | |
593a1d5f | 1610 | debugger_cpu = my_cpu; |
060df5ea | 1611 | ncpus = 1; |
55e303ae A |
1612 | mp_kdp_ncpus = 1; /* self */ |
1613 | mp_kdp_trap = TRUE; | |
060df5ea | 1614 | debugger_entry_time = cpu_datap(my_cpu)->debugger_entry_time; |
55e303ae | 1615 | simple_unlock(&mp_kdp_lock); |
55e303ae | 1616 | |
0c530ab8 A |
1617 | /* |
1618 | * Deliver a nudge to other cpus, counting how many | |
1619 | */ | |
55e303ae | 1620 | DBG("mp_kdp_enter() signaling other processors\n"); |
2d21ac55 | 1621 | if (force_immediate_debugger_NMI == FALSE) { |
060df5ea | 1622 | for (cpu = 0; cpu < real_ncpus; cpu++) { |
2d21ac55 A |
1623 | if (cpu == my_cpu || !cpu_datap(cpu)->cpu_running) |
1624 | continue; | |
1625 | ncpus++; | |
1626 | i386_signal_cpu(cpu, MP_KDP, ASYNC); | |
1627 | } | |
1628 | /* | |
1629 | * Wait other processors to synchronize | |
1630 | */ | |
1631 | DBG("mp_kdp_enter() waiting for (%d) processors to suspend\n", ncpus); | |
0c530ab8 | 1632 | |
2d21ac55 A |
1633 | /* |
1634 | * This timeout is rather arbitrary; we don't want to NMI | |
1635 | * processors that are executing at potentially | |
1636 | * "unsafe-to-interrupt" points such as the trampolines, | |
1637 | * but neither do we want to lose state by waiting too long. | |
1638 | */ | |
316670eb A |
1639 | tsc_timeout = rdtsc64() + (ncpus * 1000 * 1000 * 10ULL); |
1640 | ||
1641 | if (virtualized) | |
1642 | tsc_timeout = ~0ULL; | |
0c530ab8 | 1643 | |
2d21ac55 A |
1644 | while (mp_kdp_ncpus != ncpus && rdtsc64() < tsc_timeout) { |
1645 | /* | |
1646 | * A TLB shootdown request may be pending--this would | |
1647 | * result in the requesting processor waiting in | |
1648 | * PMAP_UPDATE_TLBS() until this processor deals with it. | |
1649 | * Process it, so it can now enter mp_kdp_wait() | |
1650 | */ | |
1651 | handle_pending_TLB_flushes(); | |
1652 | cpu_pause(); | |
1653 | } | |
1654 | /* If we've timed out, and some processor(s) are still unresponsive, | |
1655 | * interrupt them with an NMI via the local APIC. | |
0c530ab8 | 1656 | */ |
2d21ac55 A |
1657 | if (mp_kdp_ncpus != ncpus) { |
1658 | for (cpu = 0; cpu < real_ncpus; cpu++) { | |
1659 | if (cpu == my_cpu || !cpu_datap(cpu)->cpu_running) | |
1660 | continue; | |
1661 | if (cpu_signal_pending(cpu, MP_KDP)) | |
1662 | cpu_NMI_interrupt(cpu); | |
1663 | } | |
1664 | } | |
55e303ae | 1665 | } |
2d21ac55 | 1666 | else |
0c530ab8 A |
1667 | for (cpu = 0; cpu < real_ncpus; cpu++) { |
1668 | if (cpu == my_cpu || !cpu_datap(cpu)->cpu_running) | |
1669 | continue; | |
2d21ac55 | 1670 | cpu_NMI_interrupt(cpu); |
0c530ab8 | 1671 | } |
0c530ab8 | 1672 | |
bd504ef0 | 1673 | DBG("mp_kdp_enter() %d processors done %s\n", |
6d2010ae | 1674 | (int)mp_kdp_ncpus, (mp_kdp_ncpus == ncpus) ? "OK" : "timed out"); |
0c530ab8 | 1675 | |
91447636 | 1676 | postcode(MP_KDP_ENTER); |
55e303ae A |
1677 | } |
1678 | ||
0c530ab8 A |
1679 | static boolean_t |
1680 | cpu_signal_pending(int cpu, mp_event_t event) | |
1681 | { | |
1682 | volatile int *signals = &cpu_datap(cpu)->cpu_signals; | |
1683 | boolean_t retval = FALSE; | |
1684 | ||
1685 | if (i_bit(event, signals)) | |
1686 | retval = TRUE; | |
1687 | return retval; | |
1688 | } | |
b0d623f7 A |
1689 | |
1690 | long kdp_x86_xcpu_invoke(const uint16_t lcpu, kdp_x86_xcpu_func_t func, | |
1691 | void *arg0, void *arg1) | |
1692 | { | |
1693 | if (lcpu > (real_ncpus - 1)) | |
1694 | return -1; | |
1695 | ||
1696 | if (func == NULL) | |
1697 | return -1; | |
1698 | ||
1699 | kdp_xcpu_call_func.func = func; | |
1700 | kdp_xcpu_call_func.ret = -1; | |
1701 | kdp_xcpu_call_func.arg0 = arg0; | |
1702 | kdp_xcpu_call_func.arg1 = arg1; | |
1703 | kdp_xcpu_call_func.cpu = lcpu; | |
1704 | DBG("Invoking function %p on CPU %d\n", func, (int32_t)lcpu); | |
1705 | while (kdp_xcpu_call_func.cpu != KDP_XCPU_NONE) | |
1706 | cpu_pause(); | |
1707 | return kdp_xcpu_call_func.ret; | |
1708 | } | |
1709 | ||
1710 | static void | |
1711 | kdp_x86_xcpu_poll(void) | |
1712 | { | |
1713 | if ((uint16_t)cpu_number() == kdp_xcpu_call_func.cpu) { | |
1714 | kdp_xcpu_call_func.ret = | |
1715 | kdp_xcpu_call_func.func(kdp_xcpu_call_func.arg0, | |
1716 | kdp_xcpu_call_func.arg1, | |
1717 | cpu_number()); | |
1718 | kdp_xcpu_call_func.cpu = KDP_XCPU_NONE; | |
1719 | } | |
1720 | } | |
0c530ab8 | 1721 | |
55e303ae | 1722 | static void |
b0d623f7 | 1723 | mp_kdp_wait(boolean_t flush, boolean_t isNMI) |
55e303ae | 1724 | { |
6601e61a | 1725 | DBG("mp_kdp_wait()\n"); |
2d21ac55 | 1726 | /* If an I/O port has been specified as a debugging aid, issue a read */ |
0c530ab8 | 1727 | panic_io_port_read(); |
bd504ef0 | 1728 | current_cpu_datap()->debugger_ipi_time = mach_absolute_time(); |
b0d623f7 | 1729 | #if CONFIG_MCA |
2d21ac55 A |
1730 | /* If we've trapped due to a machine-check, save MCA registers */ |
1731 | mca_check_save(); | |
b0d623f7 | 1732 | #endif |
2d21ac55 | 1733 | |
2d21ac55 | 1734 | atomic_incl((volatile long *)&mp_kdp_ncpus, 1); |
b0d623f7 | 1735 | while (mp_kdp_trap || (isNMI == TRUE)) { |
0c530ab8 | 1736 | /* |
2d21ac55 A |
1737 | * A TLB shootdown request may be pending--this would result |
1738 | * in the requesting processor waiting in PMAP_UPDATE_TLBS() | |
1739 | * until this processor handles it. | |
0c530ab8 A |
1740 | * Process it, so it can now enter mp_kdp_wait() |
1741 | */ | |
2d21ac55 A |
1742 | if (flush) |
1743 | handle_pending_TLB_flushes(); | |
b0d623f7 A |
1744 | |
1745 | kdp_x86_xcpu_poll(); | |
55e303ae A |
1746 | cpu_pause(); |
1747 | } | |
2d21ac55 | 1748 | |
0c530ab8 | 1749 | atomic_decl((volatile long *)&mp_kdp_ncpus, 1); |
55e303ae A |
1750 | DBG("mp_kdp_wait() done\n"); |
1751 | } | |
1752 | ||
1753 | void | |
1754 | mp_kdp_exit(void) | |
1755 | { | |
1756 | DBG("mp_kdp_exit()\n"); | |
593a1d5f | 1757 | debugger_cpu = -1; |
0c530ab8 | 1758 | atomic_decl((volatile long *)&mp_kdp_ncpus, 1); |
b0d623f7 A |
1759 | |
1760 | debugger_exit_time = mach_absolute_time(); | |
1761 | ||
55e303ae | 1762 | mp_kdp_trap = FALSE; |
39236c6e | 1763 | mfence(); |
55e303ae A |
1764 | |
1765 | /* Wait other processors to stop spinning. XXX needs timeout */ | |
1766 | DBG("mp_kdp_exit() waiting for processors to resume\n"); | |
0c530ab8 A |
1767 | while (mp_kdp_ncpus > 0) { |
1768 | /* | |
1769 | * a TLB shootdown request may be pending... this would result in the requesting | |
1770 | * processor waiting in PMAP_UPDATE_TLBS() until this processor deals with it. | |
1771 | * Process it, so it can now enter mp_kdp_wait() | |
1772 | */ | |
1773 | handle_pending_TLB_flushes(); | |
1774 | ||
55e303ae A |
1775 | cpu_pause(); |
1776 | } | |
2d21ac55 | 1777 | |
d41d1dae | 1778 | if (pmsafe_debug && !kdp_snapshot) |
2d21ac55 A |
1779 | pmSafeMode(¤t_cpu_datap()->lcpu, PM_SAFE_FL_NORMAL); |
1780 | ||
6d2010ae A |
1781 | debugger_exit_time = mach_absolute_time(); |
1782 | ||
55e303ae | 1783 | DBG("mp_kdp_exit() done\n"); |
91447636 A |
1784 | (void) ml_set_interrupts_enabled(mp_kdp_state); |
1785 | postcode(0); | |
55e303ae A |
1786 | } |
1787 | #endif /* MACH_KDP */ | |
1788 | ||
b0d623f7 A |
1789 | boolean_t |
1790 | mp_recent_debugger_activity() { | |
060df5ea A |
1791 | uint64_t abstime = mach_absolute_time(); |
1792 | return (((abstime - debugger_entry_time) < LastDebuggerEntryAllowance) || | |
1793 | ((abstime - debugger_exit_time) < LastDebuggerEntryAllowance)); | |
b0d623f7 A |
1794 | } |
1795 | ||
55e303ae A |
1796 | /*ARGSUSED*/ |
1797 | void | |
1798 | init_ast_check( | |
91447636 | 1799 | __unused processor_t processor) |
55e303ae A |
1800 | { |
1801 | } | |
1802 | ||
1803 | void | |
1804 | cause_ast_check( | |
1805 | processor_t processor) | |
1806 | { | |
b0d623f7 | 1807 | int cpu = processor->cpu_id; |
55e303ae A |
1808 | |
1809 | if (cpu != cpu_number()) { | |
1810 | i386_signal_cpu(cpu, MP_AST, ASYNC); | |
6d2010ae | 1811 | KERNEL_DEBUG_CONSTANT(MACHDBG_CODE(DBG_MACH_SCHED, MACH_REMOTE_AST), cpu, 1, 0, 0, 0); |
55e303ae A |
1812 | } |
1813 | } | |
1814 | ||
593a1d5f A |
1815 | void |
1816 | slave_machine_init(void *param) | |
91447636 A |
1817 | { |
1818 | /* | |
0c530ab8 | 1819 | * Here in process context, but with interrupts disabled. |
91447636 A |
1820 | */ |
1821 | DBG("slave_machine_init() CPU%d\n", get_cpu_number()); | |
1822 | ||
593a1d5f A |
1823 | if (param == FULL_SLAVE_INIT) { |
1824 | /* | |
1825 | * Cold start | |
1826 | */ | |
1827 | clock_init(); | |
593a1d5f | 1828 | } |
fe8ab488 | 1829 | cpu_machine_init(); /* Interrupts enabled hereafter */ |
55e303ae A |
1830 | } |
1831 | ||
b0d623f7 | 1832 | #undef cpu_number |
55e303ae A |
1833 | int cpu_number(void) |
1834 | { | |
1835 | return get_cpu_number(); | |
1836 | } | |
1837 | ||
6d2010ae A |
1838 | static void |
1839 | cpu_prewarm_init() | |
1840 | { | |
1841 | int i; | |
1842 | ||
1843 | simple_lock_init(&cpu_warm_lock, 0); | |
1844 | queue_init(&cpu_warm_call_list); | |
1845 | for (i = 0; i < NUM_CPU_WARM_CALLS; i++) { | |
1846 | enqueue_head(&cpu_warm_call_list, (queue_entry_t)&cpu_warm_call_arr[i]); | |
1847 | } | |
1848 | } | |
1849 | ||
1850 | static timer_call_t | |
1851 | grab_warm_timer_call() | |
1852 | { | |
1853 | spl_t x; | |
1854 | timer_call_t call = NULL; | |
1855 | ||
1856 | x = splsched(); | |
1857 | simple_lock(&cpu_warm_lock); | |
1858 | if (!queue_empty(&cpu_warm_call_list)) { | |
1859 | call = (timer_call_t) dequeue_head(&cpu_warm_call_list); | |
1860 | } | |
1861 | simple_unlock(&cpu_warm_lock); | |
1862 | splx(x); | |
1863 | ||
1864 | return call; | |
1865 | } | |
1866 | ||
1867 | static void | |
1868 | free_warm_timer_call(timer_call_t call) | |
1869 | { | |
1870 | spl_t x; | |
1871 | ||
1872 | x = splsched(); | |
1873 | simple_lock(&cpu_warm_lock); | |
1874 | enqueue_head(&cpu_warm_call_list, (queue_entry_t)call); | |
1875 | simple_unlock(&cpu_warm_lock); | |
1876 | splx(x); | |
1877 | } | |
1878 | ||
1879 | /* | |
1880 | * Runs in timer call context (interrupts disabled). | |
1881 | */ | |
1882 | static void | |
1883 | cpu_warm_timer_call_func( | |
1884 | call_entry_param_t p0, | |
1885 | __unused call_entry_param_t p1) | |
1886 | { | |
1887 | free_warm_timer_call((timer_call_t)p0); | |
1888 | return; | |
1889 | } | |
1890 | ||
1891 | /* | |
1892 | * Runs with interrupts disabled on the CPU we wish to warm (i.e. CPU 0). | |
1893 | */ | |
1894 | static void | |
1895 | _cpu_warm_setup( | |
1896 | void *arg) | |
1897 | { | |
1898 | cpu_warm_data_t cwdp = (cpu_warm_data_t)arg; | |
1899 | ||
39236c6e | 1900 | timer_call_enter(cwdp->cwd_call, cwdp->cwd_deadline, TIMER_CALL_SYS_CRITICAL | TIMER_CALL_LOCAL); |
6d2010ae A |
1901 | cwdp->cwd_result = 0; |
1902 | ||
1903 | return; | |
1904 | } | |
1905 | ||
1906 | /* | |
1907 | * Not safe to call with interrupts disabled. | |
1908 | */ | |
1909 | kern_return_t | |
1910 | ml_interrupt_prewarm( | |
1911 | uint64_t deadline) | |
1912 | { | |
1913 | struct cpu_warm_data cwd; | |
1914 | timer_call_t call; | |
1915 | cpu_t ct; | |
1916 | ||
1917 | if (ml_get_interrupts_enabled() == FALSE) { | |
1918 | panic("%s: Interrupts disabled?\n", __FUNCTION__); | |
1919 | } | |
1920 | ||
1921 | /* | |
1922 | * If the platform doesn't need our help, say that we succeeded. | |
1923 | */ | |
1924 | if (!ml_get_interrupt_prewake_applicable()) { | |
1925 | return KERN_SUCCESS; | |
1926 | } | |
1927 | ||
1928 | /* | |
1929 | * Grab a timer call to use. | |
1930 | */ | |
1931 | call = grab_warm_timer_call(); | |
1932 | if (call == NULL) { | |
1933 | return KERN_RESOURCE_SHORTAGE; | |
1934 | } | |
1935 | ||
1936 | timer_call_setup(call, cpu_warm_timer_call_func, call); | |
1937 | cwd.cwd_call = call; | |
1938 | cwd.cwd_deadline = deadline; | |
1939 | cwd.cwd_result = 0; | |
1940 | ||
1941 | /* | |
1942 | * For now, non-local interrupts happen on the master processor. | |
1943 | */ | |
1944 | ct = mp_cpus_call(cpu_to_cpumask(master_cpu), SYNC, _cpu_warm_setup, &cwd); | |
1945 | if (ct == 0) { | |
1946 | free_warm_timer_call(call); | |
1947 | return KERN_FAILURE; | |
1948 | } else { | |
1949 | return cwd.cwd_result; | |
1950 | } | |
1951 | } |