xref: /illumos-gate/usr/src/uts/intel/ml/swtch.S (revision 012e6ce759c490003aed29439cc47d3d73a99ad3)
1/*
2 * CDDL HEADER START
3 *
4 * The contents of this file are subject to the terms of the
5 * Common Development and Distribution License (the "License").
6 * You may not use this file except in compliance with the License.
7 *
8 * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9 * or http://www.opensolaris.org/os/licensing.
10 * See the License for the specific language governing permissions
11 * and limitations under the License.
12 *
13 * When distributing Covered Code, include this CDDL HEADER in each
14 * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15 * If applicable, add the following below this CDDL HEADER, with the
16 * fields enclosed by brackets "[]" replaced with your own identifying
17 * information: Portions Copyright [yyyy] [name of copyright owner]
18 *
19 * CDDL HEADER END
20 */
21/*
22 * Copyright 2007 Sun Microsystems, Inc.  All rights reserved.
23 * Use is subject to license terms.
24 */
25
26/*
27 * Copyright 2020 Joyent, Inc.
28 */
29
30/*
31 * Process switching routines.
32 */
33
34#include <sys/asm_linkage.h>
35#include <sys/asm_misc.h>
36#include <sys/regset.h>
37#include <sys/privregs.h>
38#include <sys/stack.h>
39#include <sys/segments.h>
40#include <sys/psw.h>
41
42#include "assym.h"
43
44/*
45 * resume(thread_id_t t);
46 *
47 * a thread can only run on one processor at a time. there
48 * exists a window on MPs where the current thread on one
49 * processor is capable of being dispatched by another processor.
50 * some overlap between outgoing and incoming threads can happen
51 * when they are the same thread. in this case where the threads
52 * are the same, resume() on one processor will spin on the incoming
53 * thread until resume() on the other processor has finished with
54 * the outgoing thread.
55 *
56 * The MMU context changes when the resuming thread resides in a different
57 * process.  Kernel threads are known by resume to reside in process 0.
58 * The MMU context, therefore, only changes when resuming a thread in
59 * a process different from curproc.
60 *
61 * resume_from_intr() is called when the thread being resumed was not
62 * passivated by resume (e.g. was interrupted).  This means that the
63 * resume lock is already held and that a restore context is not needed.
64 * Also, the MMU context is not changed on the resume in this case.
65 *
66 * resume_from_zombie() is the same as resume except the calling thread
67 * is a zombie and must be put on the deathrow list after the CPU is
68 * off the stack.
69 */
70
71#if LWP_PCB_FPU != 0
72#error LWP_PCB_FPU MUST be defined as 0 for code in swtch.s to work
73#endif	/* LWP_PCB_FPU != 0 */
74
75/*
76 * Save non-volatile regs other than %rsp (%rbx, %rbp, and %r12 - %r15)
77 *
78 * The stack frame must be created before the save of %rsp so that tracebacks
79 * of swtch()ed-out processes show the process as having last called swtch().
80 */
81#define SAVE_REGS(thread_t, retaddr)			\
82	movq	%rbp, T_RBP(thread_t);			\
83	movq	%rbx, T_RBX(thread_t);			\
84	movq	%r12, T_R12(thread_t);			\
85	movq	%r13, T_R13(thread_t);			\
86	movq	%r14, T_R14(thread_t);			\
87	movq	%r15, T_R15(thread_t);			\
88	pushq	%rbp;					\
89	movq	%rsp, %rbp;				\
90	movq	%rsp, T_SP(thread_t);			\
91	movq	retaddr, T_PC(thread_t);		\
92	movq	%rdi, %r12;				\
93	call	__dtrace_probe___sched_off__cpu
94
95/*
96 * Restore non-volatile regs other than %rsp (%rbx, %rbp, and %r12 - %r15)
97 *
98 * We load up %rsp from the label_t as part of the context switch, so
99 * we don't repeat that here.
100 *
101 * We don't do a 'leave,' because reloading %rsp/%rbp from the label_t
102 * already has the effect of putting the stack back the way it was when
103 * we came in.
104 */
105#define RESTORE_REGS(scratch_reg)			\
106	movq	%gs:CPU_THREAD, scratch_reg;		\
107	movq	T_RBP(scratch_reg), %rbp;		\
108	movq	T_RBX(scratch_reg), %rbx;		\
109	movq	T_R12(scratch_reg), %r12;		\
110	movq	T_R13(scratch_reg), %r13;		\
111	movq	T_R14(scratch_reg), %r14;		\
112	movq	T_R15(scratch_reg), %r15
113
114/*
115 * Get pointer to a thread's hat structure
116 */
117#define GET_THREAD_HATP(hatp, thread_t, scratch_reg)	\
118	movq	T_PROCP(thread_t), hatp;		\
119	movq	P_AS(hatp), scratch_reg;		\
120	movq	A_HAT(scratch_reg), hatp
121
122#define	TSC_READ()					\
123	call	tsc_read;				\
124	movq	%rax, %r14;
125
126/*
127 * If we are resuming an interrupt thread, store a timestamp in the thread
128 * structure.  If an interrupt occurs between tsc_read() and its subsequent
129 * store, the timestamp will be stale by the time it is stored.  We can detect
130 * this by doing a compare-and-swap on the thread's timestamp, since any
131 * interrupt occurring in this window will put a new timestamp in the thread's
132 * t_intr_start field.
133 */
134#define	STORE_INTR_START(thread_t)			\
135	testw	$T_INTR_THREAD, T_FLAGS(thread_t);	\
136	jz	1f;					\
1370:							\
138	TSC_READ();					\
139	movq	T_INTR_START(thread_t), %rax;		\
140	cmpxchgq %r14, T_INTR_START(thread_t);		\
141	jnz	0b;					\
1421:
143
144	.global	kpti_enable
145
146	ENTRY(resume)
147	movq	%gs:CPU_THREAD, %rax
148	leaq	resume_return(%rip), %r11
149
150	/*
151	 * Deal with SMAP here. A thread may be switched out at any point while
152	 * it is executing. The thread could be under on_fault() or it could be
153	 * pre-empted while performing a copy interruption. If this happens and
154	 * we're not in the context of an interrupt which happens to handle
155	 * saving and restoring rflags correctly, we may lose our SMAP related
156	 * state.
157	 *
158	 * To handle this, as part of being switched out, we first save whether
159	 * or not userland access is allowed ($PS_ACHK in rflags) and store that
160	 * in t_useracc on the kthread_t and unconditionally enable SMAP to
161	 * protect the system.
162	 *
163	 * Later, when the thread finishes resuming, we potentially disable smap
164	 * if PS_ACHK was present in rflags. See uts/intel/ml/copy.s for
165	 * more information on rflags and SMAP.
166	 */
167	pushfq
168	popq	%rsi
169	andq	$PS_ACHK, %rsi
170	movq	%rsi, T_USERACC(%rax)
171	call	smap_enable
172
173	/*
174	 * Take a moment to potentially clear the RSB buffer. This is done to
175	 * prevent various Spectre variant 2 and SpectreRSB attacks. This may
176	 * not be sufficient. Please see uts/intel/ml/retpoline.s for more
177	 * information about this.
178	 */
179	call	x86_rsb_stuff
180
181	/*
182	 * Save non-volatile registers, and set return address for current
183	 * thread to resume_return.
184	 *
185	 * %r12 = t (new thread) when done
186	 */
187	SAVE_REGS(%rax, %r11)
188
189
190	LOADCPU(%r15)				/* %r15 = CPU */
191	movq	CPU_THREAD(%r15), %r13		/* %r13 = curthread */
192
193	/*
194	 * Call savectx if thread has installed context ops.
195	 *
196	 * Note that if we have floating point context, the save op
197	 * (either fpsave_begin or fpxsave_begin) will issue the
198	 * async save instruction (fnsave or fxsave respectively)
199	 * that we fwait for below.
200	 */
201	cmpq	$0, T_CTX(%r13)		/* should current thread savectx? */
202	je	.nosavectx		/* skip call when zero */
203
204	movq	%r13, %rdi		/* arg = thread pointer */
205	call	savectx			/* call ctx ops */
206.nosavectx:
207
208	/*
209	 * Check that the curthread is not using the FPU while in the kernel.
210	 */
211	call	kernel_fpu_no_swtch
212
213        /*
214         * Call savepctx if process has installed context ops.
215         */
216	movq	T_PROCP(%r13), %r14	/* %r14 = proc */
217        cmpq    $0, P_PCTX(%r14)         /* should current thread savepctx? */
218        je      .nosavepctx              /* skip call when zero */
219
220        movq    %r14, %rdi              /* arg = proc pointer */
221        call    savepctx                 /* call ctx ops */
222.nosavepctx:
223
224	/*
225	 * Temporarily switch to the idle thread's stack
226	 */
227	movq	CPU_IDLE_THREAD(%r15), %rax	/* idle thread pointer */
228
229	/*
230	 * Set the idle thread as the current thread
231	 */
232	movq	T_SP(%rax), %rsp	/* It is safe to set rsp */
233	movq	%rax, CPU_THREAD(%r15)
234
235	/*
236	 * Switch in the hat context for the new thread
237	 *
238	 */
239	GET_THREAD_HATP(%rdi, %r12, %r11)
240	call	hat_switch
241
242	/*
243	 * Clear and unlock previous thread's t_lock
244	 * to allow it to be dispatched by another processor.
245	 */
246	movb	$0, T_LOCK(%r13)
247
248	/*
249	 * IMPORTANT: Registers at this point must be:
250	 *       %r12 = new thread
251	 *
252	 * Here we are in the idle thread, have dropped the old thread.
253	 */
254	ALTENTRY(_resume_from_idle)
255	/*
256	 * spin until dispatched thread's mutex has
257	 * been unlocked. this mutex is unlocked when
258	 * it becomes safe for the thread to run.
259	 */
260.lock_thread_mutex:
261	lock
262	btsl	$0, T_LOCK(%r12)	/* attempt to lock new thread's mutex */
263	jnc	.thread_mutex_locked	/* got it */
264
265.spin_thread_mutex:
266	pause
267	cmpb	$0, T_LOCK(%r12)	/* check mutex status */
268	jz	.lock_thread_mutex	/* clear, retry lock */
269	jmp	.spin_thread_mutex	/* still locked, spin... */
270
271.thread_mutex_locked:
272	/*
273	 * Fix CPU structure to indicate new running thread.
274	 * Set pointer in new thread to the CPU structure.
275	 */
276	LOADCPU(%r13)			/* load current CPU pointer */
277	cmpq	%r13, T_CPU(%r12)
278	je	.setup_cpu
279
280	/* cp->cpu_stats.sys.cpumigrate++ */
281	incq    CPU_STATS_SYS_CPUMIGRATE(%r13)
282	movq	%r13, T_CPU(%r12)	/* set new thread's CPU pointer */
283
284.setup_cpu:
285	/*
286	 * Setup rsp0 (kernel stack) in TSS to curthread's saved regs
287	 * structure.  If this thread doesn't have a regs structure above
288	 * the stack -- that is, if lwp_stk_init() was never called for the
289	 * thread -- this will set rsp0 to the wrong value, but it's harmless
290	 * as it's a kernel thread, and it won't actually attempt to implicitly
291	 * use the rsp0 via a privilege change.
292	 *
293	 * Note that when we have KPTI enabled on amd64, we never use this
294	 * value at all (since all the interrupts have an IST set).
295	 */
296	movq	CPU_TSS(%r13), %r14
297#if !defined(__xpv)
298	cmpq	$1, kpti_enable
299	jne	1f
300	leaq	CPU_KPTI_TR_RSP(%r13), %rax
301	jmp	2f
3021:
303	movq	T_STACK(%r12), %rax
304	addq	$REGSIZE+MINFRAME, %rax	/* to the bottom of thread stack */
3052:
306	movq	%rax, TSS_RSP0(%r14)
307#else
308	movq	T_STACK(%r12), %rax
309	addq	$REGSIZE+MINFRAME, %rax	/* to the bottom of thread stack */
310	movl	$KDS_SEL, %edi
311	movq	%rax, %rsi
312	call	HYPERVISOR_stack_switch
313#endif	/* __xpv */
314
315	movq	%r12, CPU_THREAD(%r13)	/* set CPU's thread pointer */
316	mfence				/* synchronize with mutex_exit() */
317	xorl	%ebp, %ebp		/* make $<threadlist behave better */
318	movq	T_LWP(%r12), %rax	/* set associated lwp to  */
319	movq	%rax, CPU_LWP(%r13)	/* CPU's lwp ptr */
320
321	movq	T_SP(%r12), %rsp	/* switch to outgoing thread's stack */
322	movq	T_PC(%r12), %r13	/* saved return addr */
323
324	/*
325	 * Call restorectx if context ops have been installed.
326	 */
327	cmpq	$0, T_CTX(%r12)		/* should resumed thread restorectx? */
328	jz	.norestorectx		/* skip call when zero */
329	movq	%r12, %rdi		/* arg = thread pointer */
330	call	restorectx		/* call ctx ops */
331.norestorectx:
332
333	/*
334	 * Call restorepctx if context ops have been installed for the proc.
335	 */
336	movq	T_PROCP(%r12), %rcx
337	cmpq	$0, P_PCTX(%rcx)
338	jz	.norestorepctx
339	movq	%rcx, %rdi
340	call	restorepctx
341.norestorepctx:
342
343	STORE_INTR_START(%r12)
344
345	/*
346	 * If we came into swtch with the ability to access userland pages, go
347	 * ahead and restore that fact by disabling SMAP.  Clear the indicator
348	 * flag out of paranoia.
349	 */
350	movq	T_USERACC(%r12), %rax	/* should we disable smap? */
351	cmpq	$0, %rax		/* skip call when zero */
352	jz	.nosmap
353	xorq	%rax, %rax
354	movq	%rax, T_USERACC(%r12)
355	call	smap_disable
356.nosmap:
357
358	call	smt_mark
359
360	/*
361	 * Restore non-volatile registers, then have spl0 return to the
362	 * resuming thread's PC after first setting the priority as low as
363	 * possible and blocking all interrupt threads that may be active.
364	 */
365	movq	%r13, %rax	/* save return address */
366	RESTORE_REGS(%r11)
367	pushq	%rax		/* push return address for spl0() */
368	call	__dtrace_probe___sched_on__cpu
369	jmp	spl0
370
371resume_return:
372	/*
373	 * Remove stack frame created in SAVE_REGS()
374	 */
375	addq	$CLONGSIZE, %rsp
376	ret
377	SET_SIZE(_resume_from_idle)
378	SET_SIZE(resume)
379
380	ENTRY(resume_from_zombie)
381	movq	%gs:CPU_THREAD, %rax
382	leaq	resume_from_zombie_return(%rip), %r11
383
384	/*
385	 * Save non-volatile registers, and set return address for current
386	 * thread to resume_from_zombie_return.
387	 *
388	 * %r12 = t (new thread) when done
389	 */
390	SAVE_REGS(%rax, %r11)
391
392	movq	%gs:CPU_THREAD, %r13	/* %r13 = curthread */
393
394	/* clean up the fp unit. It might be left enabled */
395
396#if defined(__xpv)		/* XXPV XXtclayton */
397	/*
398	 * Remove this after bringup.
399	 * (Too many #gp's for an instrumented hypervisor.)
400	 */
401	STTS(%rax)
402#else
403	movq	%cr0, %rax
404	testq	$CR0_TS, %rax
405	jnz	.zfpu_disabled		/* if TS already set, nothing to do */
406	fninit				/* init fpu & discard pending error */
407	orq	$CR0_TS, %rax
408	movq	%rax, %cr0
409.zfpu_disabled:
410
411#endif	/* __xpv */
412
413	/*
414	 * Temporarily switch to the idle thread's stack so that the zombie
415	 * thread's stack can be reclaimed by the reaper.
416	 */
417	movq	%gs:CPU_IDLE_THREAD, %rax /* idle thread pointer */
418	movq	T_SP(%rax), %rsp	/* get onto idle thread stack */
419
420	/*
421	 * Sigh. If the idle thread has never run thread_start()
422	 * then t_sp is mis-aligned by thread_load().
423	 */
424	andq	$_BITNOT(STACK_ALIGN-1), %rsp
425
426	/*
427	 * Set the idle thread as the current thread.
428	 */
429	movq	%rax, %gs:CPU_THREAD
430
431	/* switch in the hat context for the new thread */
432	GET_THREAD_HATP(%rdi, %r12, %r11)
433	call	hat_switch
434
435	/*
436	 * Put the zombie on death-row.
437	 */
438	movq	%r13, %rdi
439	call	reapq_add
440
441	jmp	_resume_from_idle	/* finish job of resume */
442
443resume_from_zombie_return:
444	RESTORE_REGS(%r11)		/* restore non-volatile registers */
445	call	__dtrace_probe___sched_on__cpu
446
447	/*
448	 * Remove stack frame created in SAVE_REGS()
449	 */
450	addq	$CLONGSIZE, %rsp
451	ret
452	SET_SIZE(resume_from_zombie)
453
454	ENTRY(resume_from_intr)
455	movq	%gs:CPU_THREAD, %rax
456	leaq	resume_from_intr_return(%rip), %r11
457
458	/*
459	 * Save non-volatile registers, and set return address for current
460	 * thread to resume_from_intr_return.
461	 *
462	 * %r12 = t (new thread) when done
463	 */
464	SAVE_REGS(%rax, %r11)
465
466	movq	%gs:CPU_THREAD, %r13	/* %r13 = curthread */
467	movq	%r12, %gs:CPU_THREAD	/* set CPU's thread pointer */
468	mfence				/* synchronize with mutex_exit() */
469	movq	T_SP(%r12), %rsp	/* restore resuming thread's sp */
470	xorl	%ebp, %ebp		/* make $<threadlist behave better */
471
472	/*
473	 * Unlock outgoing thread's mutex dispatched by another processor.
474	 */
475	xorl	%eax, %eax
476	xchgb	%al, T_LOCK(%r13)
477
478	STORE_INTR_START(%r12)
479
480	call	smt_mark
481
482	/*
483	 * Restore non-volatile registers, then have spl0 return to the
484	 * resuming thread's PC after first setting the priority as low as
485	 * possible and blocking all interrupt threads that may be active.
486	 */
487	movq	T_PC(%r12), %rax	/* saved return addr */
488	RESTORE_REGS(%r11);
489	pushq	%rax			/* push return address for spl0() */
490	call	__dtrace_probe___sched_on__cpu
491	jmp	spl0
492
493resume_from_intr_return:
494	/*
495	 * Remove stack frame created in SAVE_REGS()
496	 */
497	addq	$CLONGSIZE, %rsp
498	ret
499	SET_SIZE(resume_from_intr)
500
501	ENTRY(thread_start)
502	popq	%rax		/* start() */
503	popq	%rdi		/* arg */
504	popq	%rsi		/* len */
505	movq	%rsp, %rbp
506	INDIRECT_CALL_REG(rax)
507	call	thread_exit	/* destroy thread if it returns. */
508	/*NOTREACHED*/
509	SET_SIZE(thread_start)
510