/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright (c) 1993, 2010, Oracle and/or its affiliates. All rights reserved. */ /* * Process switching routines. */ #include "assym.h" #include #include #include #include #include #include #include #include #include /* * resume(kthread_id_t) * * a thread can only run on one processor at a time. there * exists a window on MPs where the current thread on one * processor is capable of being dispatched by another processor. * some overlap between outgoing and incoming threads can happen * when they are the same thread. in this case where the threads * are the same, resume() on one processor will spin on the incoming * thread until resume() on the other processor has finished with * the outgoing thread. * * The MMU context changes when the resuming thread resides in a different * process. Kernel threads are known by resume to reside in process 0. * The MMU context, therefore, only changes when resuming a thread in * a process different from curproc. * * resume_from_intr() is called when the thread being resumed was not * passivated by resume (e.g. was interrupted). This means that the * resume lock is already held and that a restore context is not needed. * Also, the MMU context is not changed on the resume in this case. * * resume_from_zombie() is the same as resume except the calling thread * is a zombie and must be put on the deathrow list after the CPU is * off the stack. */ ENTRY(resume) save %sp, -SA(MINFRAME), %sp ! save ins and locals call __dtrace_probe___sched_off__cpu ! DTrace probe mov %i0, %o0 ! arg for DTrace probe membar #Sync ! flush writebuffers flushw ! flushes all but this window stn %i7, [THREAD_REG + T_PC] ! save return address stn %fp, [THREAD_REG + T_SP] ! save sp ! ! Save GSR (Graphics Status Register). ! ! Read fprs, call fp_save if FPRS_FEF set. ! This handles floating-point state saving. ! The fprs could be turned on by hw bcopy software, ! *or* by fp_disabled. Handle it either way. ! ldn [THREAD_REG + T_LWP], %o4 ! get lwp pointer rd %fprs, %g4 ! read fprs brnz,pt %o4, 0f ! if user thread skip ldn [THREAD_REG + T_CPU], %i1 ! get CPU pointer ! ! kernel thread ! ! we save fprs at the beginning the stack so we know ! where to check at resume time ldn [THREAD_REG + T_STACK], %i2 ldn [THREAD_REG + T_CTX], %g3 ! get ctx pointer andcc %g4, FPRS_FEF, %g0 ! is FPRS_FEF set bz,pt %icc, 1f ! nope, skip st %g4, [%i2 + SA(MINFRAME) + FPU_FPRS] ! save fprs ! save kernel fp state in stack add %i2, SA(MINFRAME), %o0 ! o0 = kfpu_t ptr rd %gsr, %g5 call fp_save stx %g5, [%o0 + FPU_GSR] ! store GSR ba,a,pt %icc, 1f nop 0: ! user thread ! o4 = lwp ptr ! g4 = fprs ! i1 = CPU ptr ldn [%o4 + LWP_FPU], %o0 ! fp pointer stn %fp, [THREAD_REG + T_SP] ! save sp andcc %g4, FPRS_FEF, %g0 ! is FPRS_FEF set st %g4, [%o0 + FPU_FPRS] ! store FPRS #if defined(DEBUG) || defined(NEED_FPU_EXISTS) sethi %hi(fpu_exists), %g5 ld [%g5 + %lo(fpu_exists)], %g5 brz,pn %g5, 1f ldn [THREAD_REG + T_CTX], %g3 ! get ctx pointer #endif bz,pt %icc, 1f ! most apps don't use fp ldn [THREAD_REG + T_CTX], %g3 ! get ctx pointer ldn [%o4 + LWP_FPU], %o0 ! fp pointer rd %gsr, %g5 call fp_save ! doesn't touch globals stx %g5, [%o0 + FPU_GSR] ! store GSR 1: ! ! Perform context switch callback if set. ! This handles coprocessor state saving. ! i1 = cpu ptr ! g3 = ctx pointer ! wr %g0, %g0, %fprs ! disable fpu and clear fprs brz,pt %g3, 2f ! skip call when zero ldn [%i0 + T_PROCP], %i3 ! delay slot - get proc pointer call savectx mov THREAD_REG, %o0 ! delay - arg = thread pointer 2: ldn [THREAD_REG + T_PROCP], %i2 ! load old curproc - for mmu ! ! Temporarily switch to idle thread's stack ! ldn [%i1 + CPU_IDLE_THREAD], %o0 ! idle thread pointer ldn [%o0 + T_SP], %o1 ! get onto idle thread stack sub %o1, SA(MINFRAME), %sp ! save room for ins and locals clr %fp ! ! Set the idle thread as the current thread ! mov THREAD_REG, %l3 ! save %g7 (current thread) mov %o0, THREAD_REG ! set %g7 to idle stn %o0, [%i1 + CPU_THREAD] ! set CPU's thread to idle ! ! Clear and unlock previous thread's t_lock ! to allow it to be dispatched by another processor. ! clrb [%l3 + T_LOCK] ! clear tp->t_lock ! ! IMPORTANT: Registers at this point must be: ! %i0 = new thread ! %i1 = cpu pointer ! %i2 = old proc pointer ! %i3 = new proc pointer ! ! Here we are in the idle thread, have dropped the old thread. ! ALTENTRY(_resume_from_idle) ! SET_KCONTEXTREG(reg0, reg1, reg2, reg3, reg4, label1, label2, label3) SET_KCONTEXTREG(%o0, %g1, %g2, %g3, %o3, l1, l2, l3) cmp %i2, %i3 ! resuming the same process? be,pt %xcc, 5f ! yes. nop ldx [%i3 + P_AS], %o0 ! load p->p_as ldx [%o0 + A_HAT], %i5 ! %i5 = new proc hat ! ! update cpusran field ! ld [%i1 + CPU_ID], %o4 add %i5, SFMMU_CPUSRAN, %o5 CPU_INDEXTOSET(%o5, %o4, %g1) ldx [%o5], %o2 ! %o2 = cpusran field mov 1, %g2 sllx %g2, %o4, %o4 ! %o4 = bit for this cpu andcc %o4, %o2, %g0 bnz,pn %xcc, 0f ! bit already set, go to 0 nop 3: or %o2, %o4, %o1 ! or in this cpu's bit mask casx [%o5], %o2, %o1 cmp %o2, %o1 bne,a,pn %xcc, 3b ldx [%o5], %o2 ! o2 = cpusran field membar #LoadLoad|#StoreLoad 0: ! ! disable interrupts ! ! if resume from user to kernel thread ! call sfmmu_setctx_sec ! if resume from kernel (or a different user) thread to user thread ! call sfmmu_alloc_ctx ! sfmmu_load_mmustate ! ! enable interrupts ! ! %i5 = new proc hat ! sethi %hi(ksfmmup), %o2 ldx [%o2 + %lo(ksfmmup)], %o2 rdpr %pstate, %i4 cmp %i5, %o2 ! new proc hat == ksfmmup ? bne,pt %xcc, 3f ! new proc is not kernel as, go to 3 wrpr %i4, PSTATE_IE, %pstate SET_KAS_CTXSEC_ARGS(%i5, %o0, %o1) ! new proc is kernel as call sfmmu_setctx_sec ! switch to kernel context or %o0, %o1, %o0 ba,a,pt %icc, 4f ! ! Switch to user address space. ! 3: mov %i5, %o0 ! %o0 = sfmmup mov %i1, %o2 ! %o2 = CPU set SFMMU_PRIVATE, %o3 ! %o3 = sfmmu private flag call sfmmu_alloc_ctx mov %g0, %o1 ! %o1 = allocate flag = 0 brz,a,pt %o0, 4f ! %o0 == 0, no private alloc'ed nop ldn [%i5 + SFMMU_SCDP], %o0 ! using shared contexts? brz,a,pt %o0, 4f nop ldn [%o0 + SCD_SFMMUP], %o0 ! %o0 = scdp->scd_sfmmup mov %i1, %o2 ! %o2 = CPU set SFMMU_SHARED, %o3 ! %o3 = sfmmu shared flag call sfmmu_alloc_ctx mov 1, %o1 ! %o1 = allocate flag = 1 4: call sfmmu_load_mmustate ! program MMU registers mov %i5, %o0 wrpr %g0, %i4, %pstate ! enable interrupts 5: ! ! spin until dispatched thread's mutex has ! been unlocked. this mutex is unlocked when ! it becomes safe for the thread to run. ! ldstub [%i0 + T_LOCK], %o0 ! lock curthread's t_lock 6: brnz,pn %o0, 7f ! lock failed ldx [%i0 + T_PC], %i7 ! delay - restore resuming thread's pc ! ! Fix CPU structure to indicate new running thread. ! Set pointer in new thread to the CPU structure. ! XXX - Move migration statistic out of here ! ldx [%i0 + T_CPU], %g2 ! last CPU to run the new thread cmp %g2, %i1 ! test for migration be,pt %xcc, 4f ! no migration ldn [%i0 + T_LWP], %o1 ! delay - get associated lwp (if any) ldx [%i1 + CPU_STATS_SYS_CPUMIGRATE], %g2 inc %g2 stx %g2, [%i1 + CPU_STATS_SYS_CPUMIGRATE] stx %i1, [%i0 + T_CPU] ! set new thread's CPU pointer 4: stx %i0, [%i1 + CPU_THREAD] ! set CPU's thread pointer membar #StoreLoad ! synchronize with mutex_exit() mov %i0, THREAD_REG ! update global thread register stx %o1, [%i1 + CPU_LWP] ! set CPU's lwp ptr brz,a,pn %o1, 1f ! if no lwp, branch and clr mpcb stx %g0, [%i1 + CPU_MPCB] ! ! user thread ! o1 = lwp ! i0 = new thread ! ldx [%i0 + T_STACK], %o0 stx %o0, [%i1 + CPU_MPCB] ! set CPU's mpcb pointer #ifdef CPU_MPCB_PA ldx [%o0 + MPCB_PA], %o0 stx %o0, [%i1 + CPU_MPCB_PA] #endif ! Switch to new thread's stack ldx [%i0 + T_SP], %o0 ! restore resuming thread's sp sub %o0, SA(MINFRAME), %sp ! in case of intr or trap before restore mov %o0, %fp ! ! Restore resuming thread's GSR reg and floating-point regs ! Note that the ld to the gsr register ensures that the loading of ! the floating point saved state has completed without necessity ! of a membar #Sync. ! #if defined(DEBUG) || defined(NEED_FPU_EXISTS) sethi %hi(fpu_exists), %g3 ld [%g3 + %lo(fpu_exists)], %g3 brz,pn %g3, 2f ldx [%i0 + T_CTX], %i5 ! should resumed thread restorectx? #endif ldx [%o1 + LWP_FPU], %o0 ! fp pointer ld [%o0 + FPU_FPRS], %g5 ! get fpu_fprs andcc %g5, FPRS_FEF, %g0 ! is FPRS_FEF set? bz,a,pt %icc, 9f ! no, skip fp_restore wr %g0, FPRS_FEF, %fprs ! enable fprs so fp_zero works ldx [THREAD_REG + T_CPU], %o4 ! cpu pointer call fp_restore wr %g5, %g0, %fprs ! enable fpu and restore fprs ldx [%o0 + FPU_GSR], %g5 ! load saved GSR data wr %g5, %g0, %gsr ! restore %gsr data ba,pt %icc,2f ldx [%i0 + T_CTX], %i5 ! should resumed thread restorectx? 9: ! ! Zero resuming thread's fp registers, for *all* non-fp program ! Remove all possibility of using the fp regs as a "covert channel". ! call fp_zero wr %g0, %g0, %gsr ldx [%i0 + T_CTX], %i5 ! should resumed thread restorectx? ba,pt %icc, 2f wr %g0, %g0, %fprs ! disable fprs 1: #ifdef CPU_MPCB_PA mov -1, %o1 stx %o1, [%i1 + CPU_MPCB_PA] #endif ! ! kernel thread ! i0 = new thread ! ! Switch to new thread's stack ! ldx [%i0 + T_SP], %o0 ! restore resuming thread's sp sub %o0, SA(MINFRAME), %sp ! in case of intr or trap before restore mov %o0, %fp ! ! Restore resuming thread's GSR reg and floating-point regs ! Note that the ld to the gsr register ensures that the loading of ! the floating point saved state has completed without necessity ! of a membar #Sync. ! ldx [%i0 + T_STACK], %o0 ld [%o0 + SA(MINFRAME) + FPU_FPRS], %g5 ! load fprs ldx [%i0 + T_CTX], %i5 ! should thread restorectx? andcc %g5, FPRS_FEF, %g0 ! did we save fp in stack? bz,a,pt %icc, 2f wr %g0, %g0, %fprs ! clr fprs wr %g5, %g0, %fprs ! enable fpu and restore fprs call fp_restore add %o0, SA(MINFRAME), %o0 ! o0 = kpu_t ptr ldx [%o0 + FPU_GSR], %g5 ! load saved GSR data wr %g5, %g0, %gsr ! restore %gsr data 2: ! ! Restore resuming thread's context ! i5 = ctx ptr ! brz,a,pt %i5, 8f ! skip restorectx() when zero ld [%i1 + CPU_BASE_SPL], %o0 call restorectx ! thread can not sleep on temp stack mov THREAD_REG, %o0 ! delay slot - arg = thread pointer ! ! Set priority as low as possible, blocking all interrupt threads ! that may be active. ! ld [%i1 + CPU_BASE_SPL], %o0 8: wrpr %o0, 0, %pil wrpr %g0, WSTATE_KERN, %wstate ! ! If we are resuming an interrupt thread, store a starting timestamp ! in the thread structure. ! lduh [THREAD_REG + T_FLAGS], %o0 andcc %o0, T_INTR_THREAD, %g0 bnz,pn %xcc, 0f nop 5: call __dtrace_probe___sched_on__cpu ! DTrace probe nop ret ! resume curthread restore 0: add THREAD_REG, T_INTR_START, %o2 1: ldx [%o2], %o1 RD_CLOCK_TICK(%o0,%o3,%g5,__LINE__) casx [%o2], %o1, %o0 cmp %o0, %o1 be,pt %xcc, 5b nop ! If an interrupt occurred while we were attempting to store ! the timestamp, try again. ba,pt %xcc, 1b nop ! ! lock failed - spin with regular load to avoid cache-thrashing. ! 7: brnz,a,pt %o0, 7b ! spin while locked ldub [%i0 + T_LOCK], %o0 ba %xcc, 6b ldstub [%i0 + T_LOCK], %o0 ! delay - lock curthread's mutex SET_SIZE(_resume_from_idle) SET_SIZE(resume) ENTRY(resume_from_zombie) save %sp, -SA(MINFRAME), %sp ! save ins and locals call __dtrace_probe___sched_off__cpu ! DTrace probe mov %i0, %o0 ! arg for DTrace probe ldn [THREAD_REG + T_CPU], %i1 ! cpu pointer flushw ! flushes all but this window ldn [THREAD_REG + T_PROCP], %i2 ! old procp for mmu ctx ! ! Temporarily switch to the idle thread's stack so that ! the zombie thread's stack can be reclaimed by the reaper. ! ldn [%i1 + CPU_IDLE_THREAD], %o2 ! idle thread pointer ldn [%o2 + T_SP], %o1 ! get onto idle thread stack sub %o1, SA(MINFRAME), %sp ! save room for ins and locals clr %fp ! ! Set the idle thread as the current thread. ! Put the zombie on death-row. ! mov THREAD_REG, %o0 ! save %g7 = curthread for arg mov %o2, THREAD_REG ! set %g7 to idle stn %g0, [%i1 + CPU_MPCB] ! clear mpcb #ifdef CPU_MPCB_PA mov -1, %o1 stx %o1, [%i1 + CPU_MPCB_PA] #endif call reapq_add ! reapq_add(old_thread); stn %o2, [%i1 + CPU_THREAD] ! delay - CPU's thread = idle ! ! resume_from_idle args: ! %i0 = new thread ! %i1 = cpu ! %i2 = old proc ! %i3 = new proc ! b _resume_from_idle ! finish job of resume ldn [%i0 + T_PROCP], %i3 ! new process SET_SIZE(resume_from_zombie) ENTRY(resume_from_intr) save %sp, -SA(MINFRAME), %sp ! save ins and locals ! ! We read in the fprs and call fp_save if FPRS_FEF is set ! to save the floating-point state if fprs has been ! modified by operations such as hw bcopy or fp_disabled. ! This is to resolve an issue where an interrupting thread ! doesn't retain their floating-point registers when ! switching out of the interrupt context. ! rd %fprs, %g4 ldn [THREAD_REG + T_STACK], %i2 andcc %g4, FPRS_FEF, %g0 ! is FPRS_FEF set bz,pt %icc, 4f st %g4, [%i2 + SA(MINFRAME) + FPU_FPRS] ! save fprs ! save kernel fp state in stack add %i2, SA(MINFRAME), %o0 ! %o0 = kfpu_t ptr rd %gsr, %g5 call fp_save stx %g5, [%o0 + FPU_GSR] ! store GSR 4: flushw ! flushes all but this window stn %fp, [THREAD_REG + T_SP] ! delay - save sp stn %i7, [THREAD_REG + T_PC] ! save return address ldn [%i0 + T_PC], %i7 ! restore resuming thread's pc ldn [THREAD_REG + T_CPU], %i1 ! cpu pointer ! ! Fix CPU structure to indicate new running thread. ! The pinned thread we're resuming already has the CPU pointer set. ! mov THREAD_REG, %l3 ! save old thread stn %i0, [%i1 + CPU_THREAD] ! set CPU's thread pointer membar #StoreLoad ! synchronize with mutex_exit() mov %i0, THREAD_REG ! update global thread register ! ! Switch to new thread's stack ! ldn [THREAD_REG + T_SP], %o0 ! restore resuming thread's sp sub %o0, SA(MINFRAME), %sp ! in case of intr or trap before restore mov %o0, %fp clrb [%l3 + T_LOCK] ! clear intr thread's tp->t_lock ! ! If we are resuming an interrupt thread, store a timestamp in the ! thread structure. ! lduh [THREAD_REG + T_FLAGS], %o0 andcc %o0, T_INTR_THREAD, %g0 bnz,pn %xcc, 0f ! ! We're resuming a non-interrupt thread. ! Clear CPU_INTRCNT and check if cpu_kprunrun set? ! ldub [%i1 + CPU_KPRUNRUN], %o5 ! delay brnz,pn %o5, 3f ! call kpreempt(KPREEMPT_SYNC); stub %g0, [%i1 + CPU_INTRCNT] 1: ret ! resume curthread restore 0: ! ! We're an interrupt thread. Update t_intr_start and cpu_intrcnt ! add THREAD_REG, T_INTR_START, %o2 2: ldx [%o2], %o1 RD_CLOCK_TICK(%o0,%o3,%l1,__LINE__) casx [%o2], %o1, %o0 cmp %o0, %o1 bne,pn %xcc, 2b ldn [THREAD_REG + T_INTR], %l1 ! delay ! Reset cpu_intrcnt if we aren't pinning anyone brz,a,pt %l1, 2f stub %g0, [%i1 + CPU_INTRCNT] 2: ba,pt %xcc, 1b nop 3: ! ! We're a non-interrupt thread and cpu_kprunrun is set. call kpreempt. ! call kpreempt mov KPREEMPT_SYNC, %o0 ba,pt %xcc, 1b nop SET_SIZE(resume_from_intr) /* * thread_start() * * the current register window was crafted by thread_run() to contain * an address of a procedure (in register %i7), and its args in registers * %i0 through %i5. a stack trace of this thread will show the procedure * that thread_start() invoked at the bottom of the stack. an exit routine * is stored in %l0 and called when started thread returns from its called * procedure. */ ENTRY(thread_start) mov %i0, %o0 jmpl %i7, %o7 ! call thread_run()'s start() procedure. mov %i1, %o1 call thread_exit ! destroy thread if it returns. nop unimp 0 SET_SIZE(thread_start)