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/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (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 * * $FreeBSD: release/9.1.0/sys/cddl/dev/dtrace/i386/dtrace_subr.c 223758 2011-07-04 12:04:52Z attilio $ * */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include <sys/param.h> #include <sys/systm.h> #include <sys/types.h> #include <sys/cpuset.h> #include <sys/kernel.h> #include <sys/malloc.h> #include <sys/kmem.h> #include <sys/smp.h> #include <sys/dtrace_impl.h> #include <sys/dtrace_bsd.h> #include <machine/clock.h> #include <machine/frame.h> #include <vm/pmap.h> extern uintptr_t kernelbase; extern uintptr_t dtrace_in_probe_addr; extern int dtrace_in_probe; int dtrace_invop(uintptr_t, uintptr_t *, uintptr_t); typedef struct dtrace_invop_hdlr { int (*dtih_func)(uintptr_t, uintptr_t *, uintptr_t); struct dtrace_invop_hdlr *dtih_next; } dtrace_invop_hdlr_t; dtrace_invop_hdlr_t *dtrace_invop_hdlr; int dtrace_invop(uintptr_t addr, uintptr_t *stack, uintptr_t eax) { dtrace_invop_hdlr_t *hdlr; int rval; for (hdlr = dtrace_invop_hdlr; hdlr != NULL; hdlr = hdlr->dtih_next) if ((rval = hdlr->dtih_func(addr, stack, eax)) != 0) return (rval); return (0); } void dtrace_invop_add(int (*func)(uintptr_t, uintptr_t *, uintptr_t)) { dtrace_invop_hdlr_t *hdlr; hdlr = kmem_alloc(sizeof (dtrace_invop_hdlr_t), KM_SLEEP); hdlr->dtih_func = func; hdlr->dtih_next = dtrace_invop_hdlr; dtrace_invop_hdlr = hdlr; } void dtrace_invop_remove(int (*func)(uintptr_t, uintptr_t *, uintptr_t)) { dtrace_invop_hdlr_t *hdlr = dtrace_invop_hdlr, *prev = NULL; for (;;) { if (hdlr == NULL) panic("attempt to remove non-existent invop handler"); if (hdlr->dtih_func == func) break; prev = hdlr; hdlr = hdlr->dtih_next; } if (prev == NULL) { ASSERT(dtrace_invop_hdlr == hdlr); dtrace_invop_hdlr = hdlr->dtih_next; } else { ASSERT(dtrace_invop_hdlr != hdlr); prev->dtih_next = hdlr->dtih_next; } kmem_free(hdlr, 0); } void dtrace_toxic_ranges(void (*func)(uintptr_t base, uintptr_t limit)) { (*func)(0, kernelbase); } void dtrace_xcall(processorid_t cpu, dtrace_xcall_t func, void *arg) { cpuset_t cpus; if (cpu == DTRACE_CPUALL) cpus = all_cpus; else CPU_SETOF(cpu, &cpus); smp_rendezvous_cpus(cpus, smp_no_rendevous_barrier, func, smp_no_rendevous_barrier, arg); } static void dtrace_sync_func(void) { } void dtrace_sync(void) { dtrace_xcall(DTRACE_CPUALL, (dtrace_xcall_t)dtrace_sync_func, NULL); } #ifdef notyet int (*dtrace_fasttrap_probe_ptr)(struct regs *); int (*dtrace_pid_probe_ptr)(struct regs *); int (*dtrace_return_probe_ptr)(struct regs *); void dtrace_user_probe(struct regs *rp, caddr_t addr, processorid_t cpuid) { krwlock_t *rwp; proc_t *p = curproc; extern void trap(struct regs *, caddr_t, processorid_t); if (USERMODE(rp->r_cs) || (rp->r_ps & PS_VM)) { if (curthread->t_cred != p->p_cred) { cred_t *oldcred = curthread->t_cred; /* * DTrace accesses t_cred in probe context. t_cred * must always be either NULL, or point to a valid, * allocated cred structure. */ curthread->t_cred = crgetcred(); crfree(oldcred); } } if (rp->r_trapno == T_DTRACE_RET) { uint8_t step = curthread->t_dtrace_step; uint8_t ret = curthread->t_dtrace_ret; uintptr_t npc = curthread->t_dtrace_npc; if (curthread->t_dtrace_ast) { aston(curthread); curthread->t_sig_check = 1; } /* * Clear all user tracing flags. */ curthread->t_dtrace_ft = 0; /* * If we weren't expecting to take a return probe trap, kill * the process as though it had just executed an unassigned * trap instruction. */ if (step == 0) { tsignal(curthread, SIGILL); return; } /* * If we hit this trap unrelated to a return probe, we're * just here to reset the AST flag since we deferred a signal * until after we logically single-stepped the instruction we * copied out. */ if (ret == 0) { rp->r_pc = npc; return; } /* * We need to wait until after we've called the * dtrace_return_probe_ptr function pointer to set %pc. */ rwp = &CPU->cpu_ft_lock; rw_enter(rwp, RW_READER); if (dtrace_return_probe_ptr != NULL) (void) (*dtrace_return_probe_ptr)(rp); rw_exit(rwp); rp->r_pc = npc; } else if (rp->r_trapno == T_DTRACE_PROBE) { rwp = &CPU->cpu_ft_lock; rw_enter(rwp, RW_READER); if (dtrace_fasttrap_probe_ptr != NULL) (void) (*dtrace_fasttrap_probe_ptr)(rp); rw_exit(rwp); } else if (rp->r_trapno == T_BPTFLT) { uint8_t instr; rwp = &CPU->cpu_ft_lock; /* * The DTrace fasttrap provider uses the breakpoint trap * (int 3). We let DTrace take the first crack at handling * this trap; if it's not a probe that DTrace knowns about, * we call into the trap() routine to handle it like a * breakpoint placed by a conventional debugger. */ rw_enter(rwp, RW_READER); if (dtrace_pid_probe_ptr != NULL && (*dtrace_pid_probe_ptr)(rp) == 0) { rw_exit(rwp); return; } rw_exit(rwp); /* * If the instruction that caused the breakpoint trap doesn't * look like an int 3 anymore, it may be that this tracepoint * was removed just after the user thread executed it. In * that case, return to user land to retry the instuction. */ if (fuword8((void *)(rp->r_pc - 1), &instr) == 0 && instr != FASTTRAP_INSTR) { rp->r_pc--; return; } trap(rp, addr, cpuid); } else { trap(rp, addr, cpuid); } } void dtrace_safe_synchronous_signal(void) { kthread_t *t = curthread; struct regs *rp = lwptoregs(ttolwp(t)); size_t isz = t->t_dtrace_npc - t->t_dtrace_pc; ASSERT(t->t_dtrace_on); /* * If we're not in the range of scratch addresses, we're not actually * tracing user instructions so turn off the flags. If the instruction * we copied out caused a synchonous trap, reset the pc back to its * original value and turn off the flags. */ if (rp->r_pc < t->t_dtrace_scrpc || rp->r_pc > t->t_dtrace_astpc + isz) { t->t_dtrace_ft = 0; } else if (rp->r_pc == t->t_dtrace_scrpc || rp->r_pc == t->t_dtrace_astpc) { rp->r_pc = t->t_dtrace_pc; t->t_dtrace_ft = 0; } } int dtrace_safe_defer_signal(void) { kthread_t *t = curthread; struct regs *rp = lwptoregs(ttolwp(t)); size_t isz = t->t_dtrace_npc - t->t_dtrace_pc; ASSERT(t->t_dtrace_on); /* * If we're not in the range of scratch addresses, we're not actually * tracing user instructions so turn off the flags. */ if (rp->r_pc < t->t_dtrace_scrpc || rp->r_pc > t->t_dtrace_astpc + isz) { t->t_dtrace_ft = 0; return (0); } /* * If we've executed the original instruction, but haven't performed * the jmp back to t->t_dtrace_npc or the clean up of any registers * used to emulate %rip-relative instructions in 64-bit mode, do that * here and take the signal right away. We detect this condition by * seeing if the program counter is the range [scrpc + isz, astpc). */ if (t->t_dtrace_astpc - rp->r_pc < t->t_dtrace_astpc - t->t_dtrace_scrpc - isz) { #ifdef __amd64 /* * If there is a scratch register and we're on the * instruction immediately after the modified instruction, * restore the value of that scratch register. */ if (t->t_dtrace_reg != 0 && rp->r_pc == t->t_dtrace_scrpc + isz) { switch (t->t_dtrace_reg) { case REG_RAX: rp->r_rax = t->t_dtrace_regv; break; case REG_RCX: rp->r_rcx = t->t_dtrace_regv; break; case REG_R8: rp->r_r8 = t->t_dtrace_regv; break; case REG_R9: rp->r_r9 = t->t_dtrace_regv; break; } } #endif rp->r_pc = t->t_dtrace_npc; t->t_dtrace_ft = 0; return (0); } /* * Otherwise, make sure we'll return to the kernel after executing * the copied out instruction and defer the signal. */ if (!t->t_dtrace_step) { ASSERT(rp->r_pc < t->t_dtrace_astpc); rp->r_pc += t->t_dtrace_astpc - t->t_dtrace_scrpc; t->t_dtrace_step = 1; } t->t_dtrace_ast = 1; return (1); } #endif static int64_t tgt_cpu_tsc; static int64_t hst_cpu_tsc; static int64_t tsc_skew[MAXCPU]; static uint64_t nsec_scale; /* See below for the explanation of this macro. */ #define SCALE_SHIFT 28 static void dtrace_gethrtime_init_cpu(void *arg) { uintptr_t cpu = (uintptr_t) arg; if (cpu == curcpu) tgt_cpu_tsc = rdtsc(); else hst_cpu_tsc = rdtsc(); } static void dtrace_gethrtime_init(void *arg) { cpuset_t map; struct pcpu *pc; uint64_t tsc_f; int i; /* * Get TSC frequency known at this moment. * This should be constant if TSC is invariant. * Otherwise tick->time conversion will be inaccurate, but * will preserve monotonic property of TSC. */ tsc_f = atomic_load_acq_64(&tsc_freq); /* * The following line checks that nsec_scale calculated below * doesn't overflow 32-bit unsigned integer, so that it can multiply * another 32-bit integer without overflowing 64-bit. * Thus minimum supported TSC frequency is 62.5MHz. */ KASSERT(tsc_f > (NANOSEC >> (32 - SCALE_SHIFT)), ("TSC frequency is too low")); /* * We scale up NANOSEC/tsc_f ratio to preserve as much precision * as possible. * 2^28 factor was chosen quite arbitrarily from practical * considerations: * - it supports TSC frequencies as low as 62.5MHz (see above); * - it provides quite good precision (e < 0.01%) up to THz * (terahertz) values; */ nsec_scale = ((uint64_t)NANOSEC << SCALE_SHIFT) / tsc_f; /* The current CPU is the reference one. */ sched_pin(); tsc_skew[curcpu] = 0; CPU_FOREACH(i) { if (i == curcpu) continue; pc = pcpu_find(i); CPU_SETOF(PCPU_GET(cpuid), &map); CPU_SET(pc->pc_cpuid, &map); smp_rendezvous_cpus(map, NULL, dtrace_gethrtime_init_cpu, smp_no_rendevous_barrier, (void *)(uintptr_t) i); tsc_skew[i] = tgt_cpu_tsc - hst_cpu_tsc; } sched_unpin(); } SYSINIT(dtrace_gethrtime_init, SI_SUB_SMP, SI_ORDER_ANY, dtrace_gethrtime_init, NULL); /* * DTrace needs a high resolution time function which can * be called from a probe context and guaranteed not to have * instrumented with probes itself. * * Returns nanoseconds since boot. */ uint64_t dtrace_gethrtime() { uint64_t tsc; uint32_t lo; uint32_t hi; /* * We split TSC value into lower and higher 32-bit halves and separately * scale them with nsec_scale, then we scale them down by 2^28 * (see nsec_scale calculations) taking into account 32-bit shift of * the higher half and finally add. */ tsc = rdtsc() + tsc_skew[curcpu]; lo = tsc; hi = tsc >> 32; return (((lo * nsec_scale) >> SCALE_SHIFT) + ((hi * nsec_scale) << (32 - SCALE_SHIFT))); } uint64_t dtrace_gethrestime(void) { printf("%s(%d): XXX\n",__func__,__LINE__); return (0); } /* Function to handle DTrace traps during probes. See i386/i386/trap.c */ int dtrace_trap(struct trapframe *frame, u_int type) { /* * A trap can occur while DTrace executes a probe. Before * executing the probe, DTrace blocks re-scheduling and sets * a flag in it's per-cpu flags to indicate that it doesn't * want to fault. On returning from the probe, the no-fault * flag is cleared and finally re-scheduling is enabled. * * Check if DTrace has enabled 'no-fault' mode: * */ if ((cpu_core[curcpu].cpuc_dtrace_flags & CPU_DTRACE_NOFAULT) != 0) { /* * There are only a couple of trap types that are expected. * All the rest will be handled in the usual way. */ switch (type) { /* General protection fault. */ case T_PROTFLT: /* Flag an illegal operation. */ cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_ILLOP; /* * Offset the instruction pointer to the instruction * following the one causing the fault. */ frame->tf_eip += dtrace_instr_size((u_char *) frame->tf_eip); return (1); /* Page fault. */ case T_PAGEFLT: /* Flag a bad address. */ cpu_core[curcpu].cpuc_dtrace_flags |= CPU_DTRACE_BADADDR; cpu_core[curcpu].cpuc_dtrace_illval = rcr2(); /* * Offset the instruction pointer to the instruction * following the one causing the fault. */ frame->tf_eip += dtrace_instr_size((u_char *) frame->tf_eip); return (1); default: /* Handle all other traps in the usual way. */ break; } } /* Handle the trap in the usual way. */ return (0); }