2 * Copyright (c) 2003,2004,2008 The DragonFly Project. All rights reserved.
3 * Copyright (c) 2008 Jordan Gordeev.
5 * This code is derived from software contributed to The DragonFly Project
6 * by Matthew Dillon <dillon@backplane.com>
8 * Redistribution and use in source and binary forms, with or without
9 * modification, are permitted provided that the following conditions
12 * 1. Redistributions of source code must retain the above copyright
13 * notice, this list of conditions and the following disclaimer.
14 * 2. Redistributions in binary form must reproduce the above copyright
15 * notice, this list of conditions and the following disclaimer in
16 * the documentation and/or other materials provided with the
18 * 3. Neither the name of The DragonFly Project nor the names of its
19 * contributors may be used to endorse or promote products derived
20 * from this software without specific, prior written permission.
22 * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
23 * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
24 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
25 * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
26 * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
27 * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING,
28 * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
29 * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
30 * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
31 * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
32 * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
35 * Copyright (c) 1990 The Regents of the University of California.
36 * All rights reserved.
38 * This code is derived from software contributed to Berkeley by
41 * Redistribution and use in source and binary forms, with or without
42 * modification, are permitted provided that the following conditions
44 * 1. Redistributions of source code must retain the above copyright
45 * notice, this list of conditions and the following disclaimer.
46 * 2. Redistributions in binary form must reproduce the above copyright
47 * notice, this list of conditions and the following disclaimer in the
48 * documentation and/or other materials provided with the distribution.
49 * 3. All advertising materials mentioning features or use of this software
50 * must display the following acknowledgement:
51 * This product includes software developed by the University of
52 * California, Berkeley and its contributors.
53 * 4. Neither the name of the University nor the names of its contributors
54 * may be used to endorse or promote products derived from this software
55 * without specific prior written permission.
57 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
58 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
59 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
60 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
61 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
62 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
63 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
64 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
65 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
66 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
69 * $FreeBSD: src/sys/i386/i386/swtch.s,v 1.89.2.10 2003/01/23 03:36:24 ps Exp $
72 //#include "use_npx.h"
74 #include <sys/rtprio.h>
76 #include <machine/asmacros.h>
77 #include <machine/segments.h>
79 #include <machine/pmap.h>
80 #include <machine/lock.h>
82 #define CHECKNZ(expr, scratch_reg) \
83 movq expr, scratch_reg; testq scratch_reg, scratch_reg; jnz 7f; int $3; 7:
87 #define MPLOCKED lock ;
92 .globl lwkt_switch_return
94 #if defined(SWTCH_OPTIM_STATS)
95 .globl swtch_optim_stats, tlb_flush_count
96 swtch_optim_stats: .long 0 /* number of _swtch_optims */
97 tlb_flush_count: .long 0
104 * cpu_heavy_switch(struct thread *next_thread)
106 * Switch from the current thread to a new thread. This entry
107 * is normally called via the thread->td_switch function, and will
108 * only be called when the current thread is a heavy weight process.
110 * Some instructions have been reordered to reduce pipeline stalls.
112 * YYY disable interrupts once giant is removed.
114 ENTRY(cpu_heavy_switch)
116 * Save RIP, RSP and callee-saved registers (RBX, RBP, R12-R15).
118 movq PCPU(curthread),%rcx
119 /* On top of the stack is the return adress. */
120 movq (%rsp),%rax /* (reorder optimization) */
121 movq TD_PCB(%rcx),%rdx /* RDX = PCB */
122 movq %rax,PCB_RIP(%rdx) /* return PC may be modified */
123 movq %rbx,PCB_RBX(%rdx)
124 movq %rsp,PCB_RSP(%rdx)
125 movq %rbp,PCB_RBP(%rdx)
126 movq %r12,PCB_R12(%rdx)
127 movq %r13,PCB_R13(%rdx)
128 movq %r14,PCB_R14(%rdx)
129 movq %r15,PCB_R15(%rdx)
131 movq %rcx,%rbx /* RBX = curthread */
132 movq TD_LWP(%rcx),%rcx
133 movslq PCPU(cpuid), %rax
134 movq LWP_VMSPACE(%rcx), %rcx /* RCX = vmspace */
135 MPLOCKED btrq %rax, VM_PMAP+PM_ACTIVE(%rcx)
138 * Push the LWKT switch restore function, which resumes a heavy
139 * weight process. Note that the LWKT switcher is based on
140 * TD_SP, while the heavy weight process switcher is based on
141 * PCB_RSP. TD_SP is usually two ints pushed relative to
142 * PCB_RSP. We push the flags for later restore by cpu_heavy_restore.
145 movq $cpu_heavy_restore, %rax
147 movq %rsp,TD_SP(%rbx)
150 * Save debug regs if necessary
152 movq PCB_FLAGS(%rdx),%rax
153 andq $PCB_DBREGS,%rax
154 jz 1f /* no, skip over */
155 movq %dr7,%rax /* yes, do the save */
156 movq %rax,PCB_DR7(%rdx)
157 /* JG correct value? */
158 andq $0x0000fc00, %rax /* disable all watchpoints */
161 movq %rax,PCB_DR6(%rdx)
163 movq %rax,PCB_DR3(%rdx)
165 movq %rax,PCB_DR2(%rdx)
167 movq %rax,PCB_DR1(%rdx)
169 movq %rax,PCB_DR0(%rdx)
174 * Save the FP state if we have used the FP. Note that calling
175 * npxsave will NULL out PCPU(npxthread).
177 cmpq %rbx,PCPU(npxthread)
179 movq %rdi,%r12 /* save %rdi. %r12 is callee-saved */
180 movq TD_SAVEFPU(%rbx),%rdi
181 call npxsave /* do it in a big C function */
182 movq %r12,%rdi /* restore %rdi */
187 * Switch to the next thread, which was passed as an argument
188 * to cpu_heavy_switch(). The argument is in %rdi.
189 * Set the current thread, load the stack pointer,
190 * and 'ret' into the switch-restore function.
192 * The switch restore function expects the new thread to be in %rax
193 * and the old one to be in %rbx.
195 * There is a one-instruction window where curthread is the new
196 * thread but %rsp still points to the old thread's stack, but
197 * we are protected by a critical section so it is ok.
199 movq %rdi,%rax /* RAX = newtd, RBX = oldtd */
200 movq %rax,PCPU(curthread)
201 movq TD_SP(%rax),%rsp
206 * cpu_exit_switch(struct thread *next)
208 * The switch function is changed to this when a thread is going away
209 * for good. We have to ensure that the MMU state is not cached, and
210 * we don't bother saving the existing thread state before switching.
212 * At this point we are in a critical section and this cpu owns the
213 * thread's token, which serves as an interlock until the switchout is
216 ENTRY(cpu_exit_switch)
218 * Get us out of the vmspace
225 /* JG no increment of statistics counters? see cpu_heavy_restore */
229 movq PCPU(curthread),%rbx
232 * If this is a process/lwp, deactivate the pmap after we've
235 movq TD_LWP(%rbx),%rcx
238 movslq PCPU(cpuid), %rax
239 movq LWP_VMSPACE(%rcx), %rcx /* RCX = vmspace */
240 MPLOCKED btrq %rax, VM_PMAP+PM_ACTIVE(%rcx)
243 * Switch to the next thread. RET into the restore function, which
244 * expects the new thread in RAX and the old in RBX.
246 * There is a one-instruction window where curthread is the new
247 * thread but %rsp still points to the old thread's stack, but
248 * we are protected by a critical section so it is ok.
251 movq %rax,PCPU(curthread)
252 movq TD_SP(%rax),%rsp
257 * cpu_heavy_restore() (current thread in %rax on entry)
259 * Restore the thread after an LWKT switch. This entry is normally
260 * called via the LWKT switch restore function, which was pulled
261 * off the thread stack and jumped to.
263 * This entry is only called if the thread was previously saved
264 * using cpu_heavy_switch() (the heavy weight process thread switcher),
265 * or when a new process is initially scheduled.
267 * NOTE: The lwp may be in any state, not necessarily LSRUN, because
268 * a preemption switch may interrupt the process and then return via
271 * YYY theoretically we do not have to restore everything here, a lot
272 * of this junk can wait until we return to usermode. But for now
273 * we restore everything.
275 * YYY the PCB crap is really crap, it makes startup a bitch because
276 * we can't switch away.
278 * YYY note: spl check is done in mi_switch when it splx()'s.
281 ENTRY(cpu_heavy_restore)
283 movq TD_PCB(%rax),%rdx /* RDX = PCB */
284 movq TD_LWP(%rax),%rcx
286 #if defined(SWTCH_OPTIM_STATS)
287 incl _swtch_optim_stats
290 * Tell the pmap that our cpu is using the VMSPACE now. We cannot
291 * safely test/reload %cr3 until after we have set the bit in the
292 * pmap (remember, we do not hold the MP lock in the switch code).
294 movq LWP_VMSPACE(%rcx), %rcx /* RCX = vmspace */
295 movslq PCPU(cpuid), %rsi
296 MPLOCKED btsq %rsi, VM_PMAP+PM_ACTIVE(%rcx)
299 * Restore the MMU address space. If it is the same as the last
300 * thread we don't have to invalidate the tlb (i.e. reload cr3).
301 * YYY which naturally also means that the PM_ACTIVE bit had better
302 * already have been set before we set it above, check? YYY
306 movq PCB_CR3(%rdx),%rcx
309 #if defined(SWTCH_OPTIM_STATS)
310 decl _swtch_optim_stats
311 incl _tlb_flush_count
317 * NOTE: %rbx is the previous thread and %eax is the new thread.
318 * %rbx is retained throughout so we can return it.
320 * lwkt_switch[_return] is responsible for handling TDF_RUNNING.
325 * Deal with the PCB extension, restore the private tss
327 movq PCB_EXT(%rdx),%rdi /* check for a PCB extension */
328 movq $1,%rcx /* maybe mark use of a private tss */
335 * Going back to the common_tss. We may need to update TSS_ESP0
336 * which sets the top of the supervisor stack when entering from
337 * usermode. The PCB is at the top of the stack but we need another
338 * 16 bytes to take vm86 into account.
341 movq %rcx, PCPU(common_tss) + TSS_RSP0
342 movq %rcx, PCPU(rsp0)
345 cmpl $0,PCPU(private_tss) /* don't have to reload if */
346 je 3f /* already using the common TSS */
349 subq %rcx,%rcx /* unmark use of private tss */
352 * Get the address of the common TSS descriptor for the ltr.
353 * There is no way to get the address of a segment-accessed variable
354 * so we store a self-referential pointer at the base of the per-cpu
355 * data area and add the appropriate offset.
358 movq $gd_common_tssd, %rdi
359 /* JG name for "%gs:0"? */
363 * Move the correct TSS descriptor into the GDT slot, then reload
368 movl %rcx,PCPU(private_tss) /* mark/unmark private tss */
369 movq PCPU(tss_gdt), %rcx /* entry in GDT */
372 movl $GPROC0_SEL*8, %esi /* GSEL(entry, SEL_KPL) */
380 * Restore the user %gs and %fs
382 movq PCB_FSBASE(%rdx),%r9
383 cmpq PCPU(user_fs),%r9
386 movq %r9,PCPU(user_fs)
387 movl $MSR_FSBASE,%ecx
388 movl PCB_FSBASE(%r10),%eax
389 movl PCB_FSBASE+4(%r10),%edx
393 movq PCB_GSBASE(%rdx),%r9
394 cmpq PCPU(user_gs),%r9
397 movq %r9,PCPU(user_gs)
398 movl $MSR_KGSBASE,%ecx /* later swapgs moves it to GSBASE */
399 movl PCB_GSBASE(%r10),%eax
400 movl PCB_GSBASE+4(%r10),%edx
407 * Restore general registers. %rbx is restored later.
409 movq PCB_RSP(%rdx), %rsp
410 movq PCB_RBP(%rdx), %rbp
411 movq PCB_R12(%rdx), %r12
412 movq PCB_R13(%rdx), %r13
413 movq PCB_R14(%rdx), %r14
414 movq PCB_R15(%rdx), %r15
415 movq PCB_RIP(%rdx), %rax
420 * Restore the user LDT if we have one
422 cmpl $0, PCB_USERLDT(%edx)
424 movl _default_ldt,%eax
425 cmpl PCPU(currentldt),%eax
428 movl %eax,PCPU(currentldt)
437 * Restore the user TLS if we have one
445 * Restore the DEBUG register state if necessary.
447 movq PCB_FLAGS(%rdx),%rax
448 andq $PCB_DBREGS,%rax
449 jz 1f /* no, skip over */
450 movq PCB_DR6(%rdx),%rax /* yes, do the restore */
452 movq PCB_DR3(%rdx),%rax
454 movq PCB_DR2(%rdx),%rax
456 movq PCB_DR1(%rdx),%rax
458 movq PCB_DR0(%rdx),%rax
460 movq %dr7,%rax /* load dr7 so as not to disturb */
461 /* JG correct value? */
462 andq $0x0000fc00,%rax /* reserved bits */
463 /* JG we've got more registers on x86_64 */
464 movq PCB_DR7(%rdx),%rcx
465 /* JG correct value? */
466 andq $~0x0000fc00,%rcx
471 movq PCB_RBX(%rdx),%rbx
477 * savectx(struct pcb *pcb)
479 * Update pcb, saving current processor state.
483 /* JG use %rdi instead of %rcx everywhere? */
486 /* caller's return address - child won't execute this routine */
488 movq %rax,PCB_RIP(%rcx)
489 movq %rbx,PCB_RBX(%rcx)
490 movq %rsp,PCB_RSP(%rcx)
491 movq %rbp,PCB_RBP(%rcx)
492 movq %r12,PCB_R12(%rcx)
493 movq %r13,PCB_R13(%rcx)
494 movq %r14,PCB_R14(%rcx)
495 movq %r15,PCB_R15(%rcx)
499 * If npxthread == NULL, then the npx h/w state is irrelevant and the
500 * state had better already be in the pcb. This is true for forks
501 * but not for dumps (the old book-keeping with FP flags in the pcb
502 * always lost for dumps because the dump pcb has 0 flags).
504 * If npxthread != NULL, then we have to save the npx h/w state to
505 * npxthread's pcb and copy it to the requested pcb, or save to the
506 * requested pcb and reload. Copying is easier because we would
507 * have to handle h/w bugs for reloading. We used to lose the
508 * parent's npx state for forks by forgetting to reload.
510 movq PCPU(npxthread),%rax
514 pushq %rcx /* target pcb */
515 movq TD_SAVEFPU(%rax),%rax /* originating savefpu area */
524 movq $PCB_SAVEFPU_SIZE,%rdx
525 leaq PCB_SAVEFPU(%rcx),%rcx
536 * cpu_idle_restore() (current thread in %rax on entry) (one-time execution)
538 * Don't bother setting up any regs other than %rbp so backtraces
539 * don't die. This restore function is used to bootstrap into the
540 * cpu_idle() LWKT only, after that cpu_lwkt_*() will be used for
543 * Clear TDF_RUNNING in old thread only after we've cleaned up %cr3.
544 * This only occurs during system boot so no special handling is
545 * required for migration.
547 * If we are an AP we have to call ap_init() before jumping to
548 * cpu_idle(). ap_init() will synchronize with the BP and finish
549 * setting up various ncpu-dependant globaldata fields. This may
550 * happen on UP as well as SMP if we happen to be simulating multiple
553 ENTRY(cpu_idle_restore)
559 andl $~TDF_RUNNING,TD_FLAGS(%rbx)
560 orl $TDF_RUNNING,TD_FLAGS(%rax) /* manual, no switch_return */
569 * cpu_kthread_restore() (current thread is %rax on entry) (one-time execution)
571 * Don't bother setting up any regs other then %rbp so backtraces
572 * don't die. This restore function is used to bootstrap into an
573 * LWKT based kernel thread only. cpu_lwkt_switch() will be used
576 * Because this switch target does not 'return' to lwkt_switch()
577 * we have to call lwkt_switch_return(otd) to clean up otd.
580 * Since all of our context is on the stack we are reentrant and
581 * we can release our critical section and enable interrupts early.
583 ENTRY(cpu_kthread_restore)
585 movq TD_PCB(%rax),%r13
589 * rax and rbx come from the switchout code. Call
590 * lwkt_switch_return(otd).
592 * NOTE: unlike i386, %rsi and %rdi are not call-saved regs.
596 call lwkt_switch_return
598 decl TD_CRITCOUNT(%rax)
599 movq PCB_R12(%r13),%rdi /* argument to RBX function */
600 movq PCB_RBX(%r13),%rax /* thread function */
601 /* note: top of stack return address inherited by function */
606 * cpu_lwkt_switch(struct thread *)
608 * Standard LWKT switching function. Only non-scratch registers are
609 * saved and we don't bother with the MMU state or anything else.
611 * This function is always called while in a critical section.
613 * There is a one-instruction window where curthread is the new
614 * thread but %rsp still points to the old thread's stack, but
615 * we are protected by a critical section so it is ok.
619 ENTRY(cpu_lwkt_switch)
620 pushq %rbp /* JG note: GDB hacked to locate ebp relative to td_sp */
621 /* JG we've got more registers on x86_64 */
623 movq PCPU(curthread),%rbx
632 * Save the FP state if we have used the FP. Note that calling
633 * npxsave will NULL out PCPU(npxthread).
635 * We have to deal with the FP state for LWKT threads in case they
636 * happen to get preempted or block while doing an optimized
637 * bzero/bcopy/memcpy.
639 cmpq %rbx,PCPU(npxthread)
641 movq %rdi,%r12 /* save %rdi. %r12 is callee-saved */
642 movq TD_SAVEFPU(%rbx),%rdi
643 call npxsave /* do it in a big C function */
644 movq %r12,%rdi /* restore %rdi */
648 movq %rdi,%rax /* switch to this thread */
649 pushq $cpu_lwkt_restore
650 movq %rsp,TD_SP(%rbx)
651 movq %rax,PCPU(curthread)
652 movq TD_SP(%rax),%rsp
655 * %rax contains new thread, %rbx contains old thread.
661 * cpu_lwkt_restore() (current thread in %rax on entry)
663 * Standard LWKT restore function. This function is always called
664 * while in a critical section.
666 * Warning: due to preemption the restore function can be used to
667 * 'return' to the original thread. Interrupt disablement must be
668 * protected through the switch so we cannot run splz here.
670 ENTRY(cpu_lwkt_restore)
672 * NOTE: %rbx is the previous thread and %eax is the new thread.
673 * %rbx is retained throughout so we can return it.
675 * lwkt_switch[_return] is responsible for handling TDF_RUNNING.
690 * Make AP become the idle loop.
692 ENTRY(bootstrap_idle)
693 movq PCPU(curthread),%rax
695 movq TD_SP(%rax),%rsp