1/* 2 * Copyright (c) 2003,2004,2008 The DragonFly Project. All rights reserved. 3 * Copyright (c) 2008 Jordan Gordeev. 4 * 5 * This code is derived from software contributed to The DragonFly Project 6 * by Matthew Dillon <dillon@backplane.com> 7 * 8 * Redistribution and use in source and binary forms, with or without 9 * modification, are permitted provided that the following conditions 10 * are met: 11 * 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 17 * distribution. 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. 21 * 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 33 * SUCH DAMAGE. 34 * 35 * Copyright (c) 1990 The Regents of the University of California. 36 * All rights reserved. 37 * 38 * This code is derived from software contributed to Berkeley by 39 * William Jolitz. 40 * 41 * Redistribution and use in source and binary forms, with or without 42 * modification, are permitted provided that the following conditions 43 * are met: 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. Neither the name of the University nor the names of its contributors 50 * may be used to endorse or promote products derived from this software 51 * without specific prior written permission. 52 * 53 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND 54 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE 55 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE 56 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE 57 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL 58 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS 59 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 60 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT 61 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 62 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 63 * SUCH DAMAGE. 64 * 65 * $FreeBSD: src/sys/i386/i386/swtch.s,v 1.89.2.10 2003/01/23 03:36:24 ps Exp $ 66 */ 67 68//#include "use_npx.h" 69 70#include <sys/rtprio.h> 71 72#include <machine/asmacros.h> 73#include <machine/segments.h> 74 75#include <machine/pmap.h> 76#if 0 /* JG */ 77#include <machine_base/apic/apicreg.h> 78#endif 79#include <machine/lock.h> 80 81#include "assym.s" 82 83#define MPLOCKED lock ; 84 85/* 86 * PREEMPT_OPTIMIZE 87 * 88 * This feature allows the preempting (interrupt) kernel thread to borrow 89 * %cr3 from the user process it interrupts, allowing us to do-away with 90 * two %cr3 stores, two atomic ops (pm_active is not modified), and pmap 91 * lock tests (not needed since pm_active is not modified). 92 * 93 * Unfortunately, I couldn't really measure any result so for now the 94 * optimization is disabled. 95 */ 96#undef PREEMPT_OPTIMIZE 97 98/* 99 * LWP_SWITCH_OPTIMIZE 100 * 101 * This optimization attempted to avoid a %cr3 store and atomic op, and 102 * it might have been useful on older cpus but newer cpus (and more 103 * importantly multi-core cpus) generally do not switch between LWPs on 104 * the same cpu. Multiple user threads are more likely to be distributed 105 * across multiple cpus. In cpu-bound situations the scheduler will already 106 * be in batch-mode (meaning relatively few context-switches/sec), and 107 * otherwise the lwp(s) are likely to be blocked waiting for events. 108 * 109 * On the flip side, the conditionals this option uses measurably reduce 110 * performance (just slightly, honestly). So this option is disabled. 111 */ 112#undef LWP_SWITCH_OPTIMIZE 113 114 /* 115 * Global Declarations 116 */ 117 .data 118 119 .globl panic 120 .globl lwkt_switch_return 121 122#if defined(SWTCH_OPTIM_STATS) 123 .globl swtch_optim_stats, tlb_flush_count 124swtch_optim_stats: .long 0 /* number of _swtch_optims */ 125tlb_flush_count: .long 0 126#endif 127 128 /* 129 * Code 130 */ 131 .text 132 133/* 134 * cpu_heavy_switch(struct thread *next_thread) 135 * 136 * Switch from the current thread to a new thread. This entry 137 * is normally called via the thread->td_switch function, and will 138 * only be called when the current thread is a heavy weight process. 139 * 140 * Some instructions have been reordered to reduce pipeline stalls. 141 * 142 * YYY disable interrupts once giant is removed. 143 */ 144ENTRY(cpu_heavy_switch) 145 /* 146 * Save RIP, RSP and callee-saved registers (RBX, RBP, R12-R15). 147 */ 148 movq PCPU(curthread),%rcx 149 /* On top of the stack is the return adress. */ 150 movq (%rsp),%rax /* (reorder optimization) */ 151 movq TD_PCB(%rcx),%rdx /* RDX = PCB */ 152 movq %rax,PCB_RIP(%rdx) /* return PC may be modified */ 153 movq %rbx,PCB_RBX(%rdx) 154 movq %rsp,PCB_RSP(%rdx) 155 movq %rbp,PCB_RBP(%rdx) 156 movq %r12,PCB_R12(%rdx) 157 movq %r13,PCB_R13(%rdx) 158 movq %r14,PCB_R14(%rdx) 159 movq %r15,PCB_R15(%rdx) 160 161 /* 162 * Clear the cpu bit in the pmap active mask. The restore 163 * function will set the bit in the pmap active mask. 164 * 165 * If we are switching away due to a preempt, TD_PREEMPTED(%rdi) 166 * will be non-NULL. In this situation we do want to avoid extra 167 * atomic ops and %cr3 reloads (see top of file for reasoning). 168 * 169 * NOTE: Do not try to optimize avoiding the %cr3 reload or pm_active 170 * adjustment. This mattered on uni-processor systems but in 171 * multi-core systems we are highly unlikely to be switching 172 * to another thread belonging to the same process on this cpu. 173 * 174 * (more likely the target thread is still sleeping, or if cpu- 175 * bound the scheduler is in batch mode and the switch rate is 176 * already low). 177 */ 178 movq %rcx,%rbx /* RBX = oldthread */ 179#ifdef PREEMPT_OPTIMIZE 180 /* 181 * If we are being preempted the target thread borrows our %cr3 182 * and we leave our pmap bits intact for the duration. 183 */ 184 movq TD_PREEMPTED(%rdi),%r13 185 testq %r13,%r13 186 jne 2f 187#endif 188 189 movq TD_LWP(%rcx),%rcx /* RCX = oldlwp */ 190 movq LWP_VMSPACE(%rcx), %rcx /* RCX = oldvmspace */ 191#ifdef LWP_SWITCH_OPTIMIZE 192 movq TD_LWP(%rdi),%r13 /* R13 = newlwp */ 193 testq %r13,%r13 /* might not be a heavy */ 194 jz 1f 195 cmpq LWP_VMSPACE(%r13),%rcx /* same vmspace? */ 196 je 2f 1971: 198#endif 199 movq PCPU(cpumask_simple),%rsi 200 movq PCPU(cpumask_offset),%r12 201 xorq $-1,%rsi 202 MPLOCKED andq %rsi, VM_PMAP+PM_ACTIVE(%rcx, %r12, 1) 2032: 204 205 /* 206 * Push the LWKT switch restore function, which resumes a heavy 207 * weight process. Note that the LWKT switcher is based on 208 * TD_SP, while the heavy weight process switcher is based on 209 * PCB_RSP. TD_SP is usually two ints pushed relative to 210 * PCB_RSP. We push the flags for later restore by cpu_heavy_restore. 211 */ 212 pushfq 213 cli 214 movq $cpu_heavy_restore, %rax 215 pushq %rax 216 movq %rsp,TD_SP(%rbx) 217 218 /* 219 * Save debug regs if necessary 220 */ 221 movq PCB_FLAGS(%rdx),%rax 222 andq $PCB_DBREGS,%rax 223 jz 1f /* no, skip over */ 224 movq %dr7,%rax /* yes, do the save */ 225 movq %rax,PCB_DR7(%rdx) 226 /* JG correct value? */ 227 andq $0x0000fc00, %rax /* disable all watchpoints */ 228 movq %rax,%dr7 229 movq %dr6,%rax 230 movq %rax,PCB_DR6(%rdx) 231 movq %dr3,%rax 232 movq %rax,PCB_DR3(%rdx) 233 movq %dr2,%rax 234 movq %rax,PCB_DR2(%rdx) 235 movq %dr1,%rax 236 movq %rax,PCB_DR1(%rdx) 237 movq %dr0,%rax 238 movq %rax,PCB_DR0(%rdx) 2391: 240 241 /* 242 * Save the FP state if we have used the FP. Note that calling 243 * npxsave will NULL out PCPU(npxthread). 244 */ 245 cmpq %rbx,PCPU(npxthread) 246 jne 1f 247 movq %rdi,%r12 /* save %rdi. %r12 is callee-saved */ 248 movq TD_SAVEFPU(%rbx),%rdi 249 call npxsave /* do it in a big C function */ 250 movq %r12,%rdi /* restore %rdi */ 2511: 252 253 /* 254 * Switch to the next thread, which was passed as an argument 255 * to cpu_heavy_switch(). The argument is in %rdi. 256 * Set the current thread, load the stack pointer, 257 * and 'ret' into the switch-restore function. 258 * 259 * The switch restore function expects the new thread to be in %rax 260 * and the old one to be in %rbx. 261 * 262 * There is a one-instruction window where curthread is the new 263 * thread but %rsp still points to the old thread's stack, but 264 * we are protected by a critical section so it is ok. 265 */ 266 movq %rdi,%rax /* RAX = newtd, RBX = oldtd */ 267 movq %rax,PCPU(curthread) 268 movq TD_SP(%rax),%rsp 269 ret 270END(cpu_heavy_switch) 271 272/* 273 * cpu_exit_switch(struct thread *next) 274 * 275 * The switch function is changed to this when a thread is going away 276 * for good. We have to ensure that the MMU state is not cached, and 277 * we don't bother saving the existing thread state before switching. 278 * 279 * At this point we are in a critical section and this cpu owns the 280 * thread's token, which serves as an interlock until the switchout is 281 * complete. 282 */ 283ENTRY(cpu_exit_switch) 284 285#ifdef PREEMPT_OPTIMIZE 286 /* 287 * If we were preempting we are switching back to the original thread. 288 * In this situation we already have the original thread's %cr3 and 289 * should not replace it! 290 */ 291 testl $TDF_PREEMPT_DONE, TD_FLAGS(%rdi) 292 jne 1f 293#endif 294 295 /* 296 * Get us out of the vmspace 297 */ 298 movq KPML4phys,%rcx 299 movq %cr3,%rax 300 cmpq %rcx,%rax 301 je 1f 302 303 movq %rcx,%cr3 3041: 305 movq PCPU(curthread),%rbx 306 307 /* 308 * If this is a process/lwp, deactivate the pmap after we've 309 * switched it out. 310 */ 311 movq TD_LWP(%rbx),%rcx 312 testq %rcx,%rcx 313 jz 2f 314 movq LWP_VMSPACE(%rcx), %rcx /* RCX = vmspace */ 315 316 movq PCPU(cpumask_simple),%rax 317 movq PCPU(cpumask_offset),%r12 318 xorq $-1,%rax 319 MPLOCKED andq %rax, VM_PMAP+PM_ACTIVE(%rcx, %r12, 1) 3202: 321 /* 322 * Switch to the next thread. RET into the restore function, which 323 * expects the new thread in RAX and the old in RBX. 324 * 325 * There is a one-instruction window where curthread is the new 326 * thread but %rsp still points to the old thread's stack, but 327 * we are protected by a critical section so it is ok. 328 */ 329 cli 330 movq %rdi,%rax 331 movq %rax,PCPU(curthread) 332 movq TD_SP(%rax),%rsp 333 ret 334END(cpu_exit_switch) 335 336/* 337 * cpu_heavy_restore() (current thread in %rax on entry, old thread in %rbx) 338 * 339 * We immediately move %rax to %r12. %rbx is retained throughout, and 340 * we nominally use %r14 for TD_PCB(%r12) until near the end where we 341 * switch to %rdx for that. 342 * 343 * Restore the thread after an LWKT switch. This entry is normally 344 * called via the LWKT switch restore function, which was pulled 345 * off the thread stack and jumped to. 346 * 347 * This entry is only called if the thread was previously saved 348 * using cpu_heavy_switch() (the heavy weight process thread switcher), 349 * or when a new process is initially scheduled. 350 * 351 * NOTE: The lwp may be in any state, not necessarily LSRUN, because 352 * a preemption switch may interrupt the process and then return via 353 * cpu_heavy_restore. 354 * 355 * YYY theoretically we do not have to restore everything here, a lot 356 * of this junk can wait until we return to usermode. But for now 357 * we restore everything. 358 * 359 * YYY the PCB crap is really crap, it makes startup a bitch because 360 * we can't switch away. 361 * 362 * YYY note: spl check is done in mi_switch when it splx()'s. 363 */ 364 365ENTRY(cpu_heavy_restore) 366 movq %rax,%r12 /* R12 = newtd */ 367 movq TD_PCB(%rax),%r14 /* R14 = PCB */ 368 movq %r14, PCPU(trampoline)+TR_PCB_RSP 369 movq PCB_FLAGS(%r14), %rcx 370 movq %rcx, PCPU(trampoline)+TR_PCB_FLAGS 371 movq PCB_CR3_ISO(%r14), %rcx 372 movq %rcx, PCPU(trampoline)+TR_PCB_CR3_ISO 373 movq PCB_CR3(%r14), %rcx 374 movq %rcx, PCPU(trampoline)+TR_PCB_CR3 375 popfq 376 377#if defined(SWTCH_OPTIM_STATS) 378 incl _swtch_optim_stats 379#endif 380#ifdef PREEMPT_OPTIMIZE 381 /* 382 * If restoring our thread after a preemption has returned to 383 * us, our %cr3 and pmap were borrowed and are being returned to 384 * us and no further action on those items need be taken. 385 */ 386 testl $TDF_PREEMPT_DONE, TD_FLAGS(%r12) 387 jne 4f 388#endif 389 390 /* 391 * Tell the pmap that our cpu is using the VMSPACE now. We cannot 392 * safely test/reload %cr3 until after we have set the bit in the 393 * pmap. 394 * 395 * We must do an interlocked test of the CPULOCK_EXCL at the same 396 * time. If found to be set we will have to wait for it to clear 397 * and then do a forced reload of %cr3 (even if the value matches). 398 * 399 * XXX When switching between two LWPs sharing the same vmspace 400 * the cpu_heavy_switch() code currently avoids clearing the 401 * cpu bit in PM_ACTIVE. So if the bit is already set we can 402 * avoid checking for the interlock via CPULOCK_EXCL. We currently 403 * do not perform this optimization. 404 */ 405 movq TD_LWP(%r12),%rcx 406 movq LWP_VMSPACE(%rcx),%rcx /* RCX = vmspace */ 407 408 movq PCPU(cpumask_simple),%rsi 409 movq PCPU(cpumask_offset),%r13 410 MPLOCKED orq %rsi, VM_PMAP+PM_ACTIVE(%rcx, %r13, 1) 411 412 movl VM_PMAP+PM_ACTIVE_LOCK(%rcx),%esi 413 testl $CPULOCK_EXCL,%esi 414 jz 1f 415 416 movq %rcx,%rdi /* (found to be set) */ 417 call pmap_interlock_wait /* pmap_interlock_wait(%rdi:vm) */ 418 419 /* 420 * Need unconditional load cr3 421 */ 422 movq PCB_CR3(%r14),%rcx /* RCX = desired CR3 */ 423 jmp 2f /* unconditional reload */ 4241: 425 /* 426 * Restore the MMU address space. If it is the same as the last 427 * thread we don't have to invalidate the tlb (i.e. reload cr3). 428 * 429 * XXX Temporary cludge, do NOT do this optimization! The problem 430 * is that the pm_active bit for the cpu had dropped for a small 431 * period of time, just a few cycles, but even one cycle is long 432 * enough for some other cpu doing a pmap invalidation to not see 433 * our cpu. 434 * 435 * When that happens, and we don't invltlb (by loading %cr3), we 436 * wind up with a stale TLB. 437 */ 438 movq %cr3,%rsi /* RSI = current CR3 */ 439 movq PCB_CR3(%r14),%rcx /* RCX = desired CR3 */ 440 cmpq %rsi,%rcx 441 /*je 4f*/ 4422: 443#if defined(SWTCH_OPTIM_STATS) 444 decl _swtch_optim_stats 445 incl _tlb_flush_count 446#endif 447 movq %rcx,%cr3 4484: 449 450 /* 451 * NOTE: %rbx is the previous thread and %r12 is the new thread. 452 * %rbx is retained throughout so we can return it. 453 * 454 * lwkt_switch[_return] is responsible for handling TDF_RUNNING. 455 */ 456 457 /* 458 * Deal with the PCB extension, restore the private tss 459 */ 460 movq PCB_EXT(%r14),%rdi /* check for a PCB extension */ 461 movq $1,%rcx /* maybe mark use of a private tss */ 462 testq %rdi,%rdi 463#if 0 /* JG */ 464 jnz 2f 465#endif 466 467#if 0 468 /* 469 * Going back to the common_tss. (this was already executed at 470 * the top). 471 * 472 * Set the top of the supervisor stack for the new thread 473 * in gd_thread_pcb so the trampoline code can load it into %rsp. 474 */ 475 movq %r14, PCPU(trampoline)+TR_PCB_RSP 476 movq PCB_FLAGS(%r14), %rcx 477 movq %rcx, PCPU(trampoline)+TR_PCB_FLAGS 478 movq PCB_CR3_ISO(%r14), %rcx 479 movq %rcx, PCPU(trampoline)+TR_PCB_CR3_ISO 480 movq PCB_CR3(%r14), %rcx 481 movq %rcx, PCPU(trampoline)+TR_PCB_CR3 482#endif 483 484#if 0 /* JG */ 485 cmpl $0,PCPU(private_tss) /* don't have to reload if */ 486 je 3f /* already using the common TSS */ 487 488 /* JG? */ 489 subq %rcx,%rcx /* unmark use of private tss */ 490 491 /* 492 * Get the address of the common TSS descriptor for the ltr. 493 * There is no way to get the address of a segment-accessed variable 494 * so we store a self-referential pointer at the base of the per-cpu 495 * data area and add the appropriate offset. 496 */ 497 /* JG movl? */ 498 movq $gd_common_tssd, %rdi 499 /* JG name for "%gs:0"? */ 500 addq %gs:0, %rdi 501 502 /* 503 * Move the correct TSS descriptor into the GDT slot, then reload 504 * ltr. 505 */ 5062: 507 /* JG */ 508 movl %rcx,PCPU(private_tss) /* mark/unmark private tss */ 509 movq PCPU(tss_gdt), %rbx /* entry in GDT */ 510 movq 0(%rdi), %rax 511 movq %rax, 0(%rbx) 512 movl $GPROC0_SEL*8, %esi /* GSEL(entry, SEL_KPL) */ 513 ltr %si 514#endif 515 5163: 517 /* 518 * Restore the user %gs and %fs 519 */ 520 movq PCB_FSBASE(%r14),%r9 521 cmpq PCPU(user_fs),%r9 522 je 4f 523 movq %r9,PCPU(user_fs) 524 movl $MSR_FSBASE,%ecx 525 movl PCB_FSBASE(%r14),%eax 526 movl PCB_FSBASE+4(%r14),%edx 527 wrmsr 5284: 529 movq PCB_GSBASE(%r14),%r9 530 cmpq PCPU(user_gs),%r9 531 je 5f 532 movq %r9,PCPU(user_gs) 533 movl $MSR_KGSBASE,%ecx /* later swapgs moves it to GSBASE */ 534 movl PCB_GSBASE(%r14),%eax 535 movl PCB_GSBASE+4(%r14),%edx 536 wrmsr 5375: 538 /* 539 * Actively restore FP state 540 */ 541 movq PCPU(npxthread),%r13 542 testq %r13,%r13 543 jnz 6f 544 movl TD_FLAGS(%r12),%r13d 545 andq $TDF_USINGFP,%r13 546 jz 6f 547 movq %r12,%rdi /* npxdna_quick(newtd) */ 548 call npxdna_quick 5496: 550 551 /* 552 * Restore general registers. %rbx is restored later. 553 * 554 * Switch our PCB register from %r14 to %rdx so we can restore 555 * %r14. 556 */ 557 movq %r14,%rdx 558 movq PCB_RSP(%rdx), %rsp 559 movq PCB_RBP(%rdx), %rbp 560 movq PCB_R12(%rdx), %r12 561 movq PCB_R13(%rdx), %r13 562 movq PCB_R14(%rdx), %r14 563 movq PCB_R15(%rdx), %r15 564 movq PCB_RIP(%rdx), %rax 565 movq %rax, (%rsp) 566 movw $KDSEL,%ax 567 movw %ax,%es 568 569#if 0 /* JG */ 570 /* 571 * Restore the user LDT if we have one 572 */ 573 cmpl $0, PCB_USERLDT(%edx) 574 jnz 1f 575 movl _default_ldt,%eax 576 cmpl PCPU(currentldt),%eax 577 je 2f 578 lldt _default_ldt 579 movl %eax,PCPU(currentldt) 580 jmp 2f 5811: pushl %edx 582 call set_user_ldt 583 popl %edx 5842: 585#endif 586#if 0 /* JG */ 587 /* 588 * Restore the user TLS if we have one 589 */ 590 pushl %edx 591 call set_user_TLS 592 popl %edx 593#endif 594 595 /* 596 * Restore the DEBUG register state if necessary. 597 */ 598 movq PCB_FLAGS(%rdx),%rax 599 andq $PCB_DBREGS,%rax 600 jz 1f /* no, skip over */ 601 movq PCB_DR6(%rdx),%rax /* yes, do the restore */ 602 movq %rax,%dr6 603 movq PCB_DR3(%rdx),%rax 604 movq %rax,%dr3 605 movq PCB_DR2(%rdx),%rax 606 movq %rax,%dr2 607 movq PCB_DR1(%rdx),%rax 608 movq %rax,%dr1 609 movq PCB_DR0(%rdx),%rax 610 movq %rax,%dr0 611 movq %dr7,%rax /* load dr7 so as not to disturb */ 612 /* JG correct value? */ 613 andq $0x0000fc00,%rax /* reserved bits */ 614 /* JG we've got more registers on x86_64 */ 615 movq PCB_DR7(%rdx),%rcx 616 /* JG correct value? */ 617 andq $~0x0000fc00,%rcx 618 orq %rcx,%rax 619 movq %rax,%dr7 620 621 /* 622 * Clear the QUICKRET flag when restoring a user process context 623 * so we don't try to do a quick syscall return. 624 */ 6251: 626 andl $~RQF_QUICKRET,PCPU(reqflags) 627 movq %rbx,%rax 628 movq PCB_RBX(%rdx),%rbx 629 ret 630END(cpu_heavy_restore) 631 632/* 633 * savectx(struct pcb *pcb) 634 * 635 * Update pcb, saving current processor state. 636 */ 637ENTRY(savectx) 638 /* fetch PCB */ 639 /* JG use %rdi instead of %rcx everywhere? */ 640 movq %rdi,%rcx 641 642 /* caller's return address - child won't execute this routine */ 643 movq (%rsp),%rax 644 movq %rax,PCB_RIP(%rcx) 645 646 movq %cr3,%rax 647 movq %rax,PCB_CR3(%rcx) 648 649 movq %rbx,PCB_RBX(%rcx) 650 movq %rsp,PCB_RSP(%rcx) 651 movq %rbp,PCB_RBP(%rcx) 652 movq %r12,PCB_R12(%rcx) 653 movq %r13,PCB_R13(%rcx) 654 movq %r14,PCB_R14(%rcx) 655 movq %r15,PCB_R15(%rcx) 656 657#if 1 658 /* 659 * If npxthread == NULL, then the npx h/w state is irrelevant and the 660 * state had better already be in the pcb. This is true for forks 661 * but not for dumps (the old book-keeping with FP flags in the pcb 662 * always lost for dumps because the dump pcb has 0 flags). 663 * 664 * If npxthread != NULL, then we have to save the npx h/w state to 665 * npxthread's pcb and copy it to the requested pcb, or save to the 666 * requested pcb and reload. Copying is easier because we would 667 * have to handle h/w bugs for reloading. We used to lose the 668 * parent's npx state for forks by forgetting to reload. 669 */ 670 movq PCPU(npxthread),%rax 671 testq %rax,%rax 672 jz 1f 673 674 pushq %rcx /* target pcb */ 675 movq TD_SAVEFPU(%rax),%rax /* originating savefpu area */ 676 pushq %rax 677 678 movq %rax,%rdi 679 call npxsave 680 681 popq %rax 682 popq %rcx 683 684 movq $PCB_SAVEFPU_SIZE,%rdx 685 leaq PCB_SAVEFPU(%rcx),%rcx 686 movq %rcx,%rsi 687 movq %rax,%rdi 688 call bcopy 689#endif 690 6911: 692 ret 693END(savectx) 694 695/* 696 * cpu_idle_restore() (current thread in %rax on entry, old thread in %rbx) 697 * (one-time entry) 698 * 699 * Don't bother setting up any regs other than %rbp so backtraces 700 * don't die. This restore function is used to bootstrap into the 701 * cpu_idle() LWKT only, after that cpu_lwkt_*() will be used for 702 * switching. 703 * 704 * Clear TDF_RUNNING in old thread only after we've cleaned up %cr3. 705 * This only occurs during system boot so no special handling is 706 * required for migration. 707 * 708 * If we are an AP we have to call ap_init() before jumping to 709 * cpu_idle(). ap_init() will synchronize with the BP and finish 710 * setting up various ncpu-dependant globaldata fields. This may 711 * happen on UP as well as SMP if we happen to be simulating multiple 712 * cpus. 713 */ 714ENTRY(cpu_idle_restore) 715 /* cli */ 716 movq KPML4phys,%rcx 717 xorq %rbp,%rbp /* dummy frame pointer */ 718 pushq $0 /* dummy return pc */ 719 720 /* NOTE: idle thread can never preempt */ 721 movq %rcx,%cr3 722 cmpl $0,PCPU(cpuid) 723 je 1f 724 andl $~TDF_RUNNING,TD_FLAGS(%rbx) 725 orl $TDF_RUNNING,TD_FLAGS(%rax) /* manual, no switch_return */ 726 call ap_init 727 /* 728 * ap_init can decide to enable interrupts early, but otherwise, or if 729 * we are UP, do it here. 730 */ 731 sti 732 jmp cpu_idle 733 734 /* 735 * cpu 0's idle thread entry for the first time must use normal 736 * lwkt_switch_return() semantics or a pending cpu migration on 737 * thread0 will deadlock. 738 */ 7391: 740 sti 741 pushq %rax 742 movq %rbx,%rdi 743 call lwkt_switch_return 744 popq %rax 745 jmp cpu_idle 746END(cpu_idle_restore) 747 748/* 749 * cpu_kthread_restore() (current thread is %rax on entry, previous is %rbx) 750 * (one-time execution) 751 * 752 * Don't bother setting up any regs other then %rbp so backtraces 753 * don't die. This restore function is used to bootstrap into an 754 * LWKT based kernel thread only. cpu_lwkt_switch() will be used 755 * after this. 756 * 757 * Because this switch target does not 'return' to lwkt_switch() 758 * we have to call lwkt_switch_return(otd) to clean up otd. 759 * otd is in %ebx. 760 * 761 * Since all of our context is on the stack we are reentrant and 762 * we can release our critical section and enable interrupts early. 763 */ 764ENTRY(cpu_kthread_restore) 765 sti 766 movq KPML4phys,%rcx 767 movq TD_PCB(%rax),%r13 768 xorq %rbp,%rbp 769 770#ifdef PREEMPT_OPTIMIZE 771 /* 772 * If we are preempting someone we borrow their %cr3, do not overwrite 773 * it! 774 */ 775 movq TD_PREEMPTED(%rax),%r14 776 testq %r14,%r14 777 jne 1f 778#endif 779 movq %rcx,%cr3 7801: 781 782 /* 783 * rax and rbx come from the switchout code. Call 784 * lwkt_switch_return(otd). 785 * 786 * NOTE: unlike i386, the %rsi and %rdi are not call-saved regs. 787 */ 788 pushq %rax 789 movq %rbx,%rdi 790 call lwkt_switch_return 791 popq %rax 792 decl TD_CRITCOUNT(%rax) 793 movq PCB_R12(%r13),%rdi /* argument to RBX function */ 794 movq PCB_RBX(%r13),%rax /* thread function */ 795 /* note: top of stack return address inherited by function */ 796 jmp *%rax 797END(cpu_kthread_restore) 798 799/* 800 * cpu_lwkt_switch(struct thread *) 801 * 802 * Standard LWKT switching function. Only non-scratch registers are 803 * saved and we don't bother with the MMU state or anything else. 804 * 805 * This function is always called while in a critical section. 806 * 807 * There is a one-instruction window where curthread is the new 808 * thread but %rsp still points to the old thread's stack, but 809 * we are protected by a critical section so it is ok. 810 */ 811ENTRY(cpu_lwkt_switch) 812 pushq %rbp /* JG note: GDB hacked to locate ebp rel to td_sp */ 813 pushq %rbx 814 movq PCPU(curthread),%rbx /* becomes old thread in restore */ 815 pushq %r12 816 pushq %r13 817 pushq %r14 818 pushq %r15 819 pushfq 820 cli 821 822#if 1 823 /* 824 * Save the FP state if we have used the FP. Note that calling 825 * npxsave will NULL out PCPU(npxthread). 826 * 827 * We have to deal with the FP state for LWKT threads in case they 828 * happen to get preempted or block while doing an optimized 829 * bzero/bcopy/memcpy. 830 */ 831 cmpq %rbx,PCPU(npxthread) 832 jne 1f 833 movq %rdi,%r12 /* save %rdi. %r12 is callee-saved */ 834 movq TD_SAVEFPU(%rbx),%rdi 835 call npxsave /* do it in a big C function */ 836 movq %r12,%rdi /* restore %rdi */ 8371: 838#endif 839 840 movq %rdi,%rax /* switch to this thread */ 841 pushq $cpu_lwkt_restore 842 movq %rsp,TD_SP(%rbx) 843 /* 844 * %rax contains new thread, %rbx contains old thread. 845 */ 846 movq %rax,PCPU(curthread) 847 movq TD_SP(%rax),%rsp 848 ret 849END(cpu_lwkt_switch) 850 851/* 852 * cpu_lwkt_restore() (current thread in %rax on entry) 853 * 854 * Standard LWKT restore function. This function is always called 855 * while in a critical section. 856 * 857 * WARNING! Due to preemption the restore function can be used to 'return' 858 * to the original thread. Interrupt disablement must be 859 * protected through the switch so we cannot run splz here. 860 */ 861ENTRY(cpu_lwkt_restore) 862#ifdef PREEMPT_OPTIMIZE 863 /* 864 * If we are preempting someone we borrow their %cr3 and pmap 865 */ 866 movq TD_PREEMPTED(%rax),%r14 /* kernel thread preempting? */ 867 testq %r14,%r14 868 jne 1f /* yes, borrow %cr3 from old thread */ 869#endif 870 /* 871 * Don't reload %cr3 if it hasn't changed. Since this is a LWKT 872 * thread (a kernel thread), and the kernel_pmap always permanently 873 * sets all pm_active bits, we don't have the same problem with it 874 * that we do with process pmaps. 875 */ 876 movq KPML4phys,%rcx 877 movq %cr3,%rdx 878 cmpq %rcx,%rdx 879 je 1f 880 movq %rcx,%cr3 8811: 882 /* 883 * NOTE: %rbx is the previous thread and %rax is the new thread. 884 * %rbx is retained throughout so we can return it. 885 * 886 * lwkt_switch[_return] is responsible for handling TDF_RUNNING. 887 */ 888 movq %rbx,%rax 889 popfq 890 popq %r15 891 popq %r14 892 popq %r13 893 popq %r12 894 popq %rbx 895 popq %rbp 896 ret 897END(cpu_lwkt_restore) 898