/* * Prepare context switch from oldlwp to newlwp. * This code is shared by cpu_switch and cpu_switchto. */ struct lwp * cpu_switch_prepare(struct lwp *oldlwp, struct lwp *newlwp) { newlwp->l_stat = LSONPROC; if (newlwp != oldlwp) { struct proc *p = newlwp->l_proc; curpcb = newlwp->l_md.md_pcb; pmap_activate(newlwp); /* Check for Restartable Atomic Sequences. */ if (!LIST_EMPTY(&p->p_raslist)) { caddr_t pc; pc = ras_lookup(p, (caddr_t)newlwp->l_md.md_regs->tf_spc); if (pc != (caddr_t) -1) newlwp->l_md.md_regs->tf_spc = (int) pc; } } curlwp = newlwp; return (newlwp); }
/* * Find the highest-priority runnable process and switch to it. */ int cpu_switch(struct lwp *l1, struct lwp *newl) { int which; struct prochd *q; struct lwp *l2; struct proc *p2; /* * We enter here with interrupts blocked and sched_lock held. */ #if 0 printf("cpu_switch: %p ->", l1); #endif curlwp = NULL; curpcb = NULL; while (sched_whichqs == 0) idle(); which = ffs(sched_whichqs) - 1; q = &sched_qs[which]; l2 = q->ph_link; remrunqueue(l2); want_resched = 0; #ifdef LOCKDEBUG sched_unlock_idle(); #endif /* p->p_cpu initialized in fork1() for single-processor */ l2->l_stat = LSONPROC; curlwp = l2; curpcb = &curlwp->l_addr->u_pcb; #if 0 printf(" %p\n", l2); #endif if (l2 == l1) return (0); pmap_deactivate(l1); pmap_activate(l2); /* Check for Restartable Atomic Sequences. */ p2 = l2->l_proc; if (!LIST_EMPTY(&p2->p_raslist)) { struct trapframe *tf = l2->l_addr->u_pcb.pcb_tf; caddr_t pc; pc = ras_lookup(p2, (caddr_t) tf->tf_pc); if (pc != (caddr_t) -1) tf->tf_pc = (register_t) pc; } cpu_loswitch(&l1->l_addr->u_pcb.pcb_sf, l2->l_addr->u_pcb.pcb_sf); /* We only get back here after the other process has run. */ return (1); }
void cpu_getmcontext(struct lwp *l, mcontext_t *mcp, unsigned int *flags) { const struct trapframe *tf = l->l_md.md_utf; __greg_t *gr = mcp->__gregs; __greg_t ras_pc; /* Save register context. Dont copy R0 - it is always 0 */ memcpy(&gr[_REG_AT], &tf->tf_regs[_R_AST], sizeof(mips_reg_t) * 31); gr[_REG_MDLO] = tf->tf_regs[_R_MULLO]; gr[_REG_MDHI] = tf->tf_regs[_R_MULHI]; gr[_REG_CAUSE] = tf->tf_regs[_R_CAUSE]; gr[_REG_EPC] = tf->tf_regs[_R_PC]; gr[_REG_SR] = tf->tf_regs[_R_SR]; mcp->_mc_tlsbase = (intptr_t)l->l_private; if ((ras_pc = (intptr_t)ras_lookup(l->l_proc, (void *) (intptr_t)gr[_REG_EPC])) != -1) gr[_REG_EPC] = ras_pc; *flags |= _UC_CPU | _UC_TLSBASE; /* Save floating point register context, if any. */ KASSERT(l == curlwp); if (fpu_used_p()) { size_t fplen; /* * If this process is the current FP owner, dump its * context to the PCB first. */ fpu_save(); /* * The PCB FP regs struct includes the FP CSR, so use the * size of __fpregs.__fp_r when copying. */ #if !defined(__mips_o32) if (_MIPS_SIM_NEWABI_P(l->l_proc->p_md.md_abi)) { #endif fplen = sizeof(struct fpreg); #if !defined(__mips_o32) } else { fplen = sizeof(struct fpreg_oabi); } #endif struct pcb * const pcb = lwp_getpcb(l); memcpy(&mcp->__fpregs, &pcb->pcb_fpregs, fplen); *flags |= _UC_FPU; } }
/* * Called from cpu_switchto after olwp's state has been saved. * Prepare context switch to nlwp. */ void cpu_switch_prepare(struct lwp *olwp, struct lwp *nlwp) { struct proc *p = nlwp->l_proc; /* Check for Restartable Atomic Sequences. */ if (p->p_raslist != NULL) { void *pc; pc = ras_lookup(p, (void *)nlwp->l_md.md_regs->tf_spc); if (pc != (void *) -1) nlwp->l_md.md_regs->tf_spc = (int) pc; } }
void cpu_getmcontext32(struct lwp *l, mcontext32_t *mcp, unsigned int *flags) { const struct trapframe *tf = l->l_md.md_regs; __greg32_t *gr = mcp->__gregs; __greg32_t ras_eip; /* Save register context. */ gr[_REG32_GS] = tf->tf_gs; gr[_REG32_FS] = tf->tf_fs; gr[_REG32_ES] = tf->tf_es; gr[_REG32_DS] = tf->tf_ds; gr[_REG32_EFL] = tf->tf_rflags; gr[_REG32_EDI] = tf->tf_rdi; gr[_REG32_ESI] = tf->tf_rsi; gr[_REG32_EBP] = tf->tf_rbp; gr[_REG32_EBX] = tf->tf_rbx; gr[_REG32_EDX] = tf->tf_rdx; gr[_REG32_ECX] = tf->tf_rcx; gr[_REG32_EAX] = tf->tf_rax; gr[_REG32_EIP] = tf->tf_rip; gr[_REG32_CS] = tf->tf_cs; gr[_REG32_ESP] = tf->tf_rsp; gr[_REG32_UESP] = tf->tf_rsp; gr[_REG32_SS] = tf->tf_ss; gr[_REG32_TRAPNO] = tf->tf_trapno; gr[_REG32_ERR] = tf->tf_err; if ((ras_eip = (__greg32_t)(uintptr_t)ras_lookup(l->l_proc, (void *) (uintptr_t)gr[_REG32_EIP])) != -1) gr[_REG32_EIP] = ras_eip; *flags |= _UC_CPU; mcp->_mc_tlsbase = (uint32_t)(uintptr_t)l->l_private; *flags |= _UC_TLSBASE; /* Save floating point register context, if any. */ if ((l->l_md.md_flags & MDL_USEDFPU) != 0) { struct pcb *pcb = lwp_getpcb(l); if (pcb->pcb_fpcpu) { fpusave_lwp(l, true); } memcpy(&mcp->__fpregs, &pcb->pcb_savefpu.fp_fxsave, sizeof (pcb->pcb_savefpu.fp_fxsave)); *flags |= _UC_FPU; } }
void hppa_ras(struct lwp *l) { struct proc *p; struct trapframe *tf; intptr_t rasaddr; p = l->l_proc; tf = l->l_md.md_regs; rasaddr = (intptr_t)ras_lookup(p, (void *)tf->tf_iioq_head); if (rasaddr != -1) { rasaddr |= HPPA_PC_PRIV_USER; tf->tf_iioq_head = rasaddr; tf->tf_iioq_tail = rasaddr + 4; } }
void cpu_getmcontext(struct lwp *l, mcontext_t *mcp, unsigned int *flags) { const struct trapframe *tf = l->l_md.md_regs; __greg_t *gr = mcp->__gregs; __greg_t ras_pc; /* Save register context. */ gr[_REG_GBR] = tf->tf_gbr; gr[_REG_PC] = tf->tf_spc; gr[_REG_SR] = tf->tf_ssr; gr[_REG_MACL] = tf->tf_macl; gr[_REG_MACH] = tf->tf_mach; gr[_REG_PR] = tf->tf_pr; gr[_REG_R14] = tf->tf_r14; gr[_REG_R13] = tf->tf_r13; gr[_REG_R12] = tf->tf_r12; gr[_REG_R11] = tf->tf_r11; gr[_REG_R10] = tf->tf_r10; gr[_REG_R9] = tf->tf_r9; gr[_REG_R8] = tf->tf_r8; gr[_REG_R7] = tf->tf_r7; gr[_REG_R6] = tf->tf_r6; gr[_REG_R5] = tf->tf_r5; gr[_REG_R4] = tf->tf_r4; gr[_REG_R3] = tf->tf_r3; gr[_REG_R2] = tf->tf_r2; gr[_REG_R1] = tf->tf_r1; gr[_REG_R0] = tf->tf_r0; gr[_REG_R15] = tf->tf_r15; if ((ras_pc = (__greg_t)ras_lookup(l->l_proc, (void *) gr[_REG_PC])) != -1) gr[_REG_PC] = ras_pc; *flags |= (_UC_CPU|_UC_TLSBASE); /* FPU context is currently not handled by the kernel. */ memset(&mcp->__fpregs, 0, sizeof (mcp->__fpregs)); }
/* * trap(frame): exception, fault, and trap interface to BSD kernel. * * This common code is called from assembly language IDT gate entry routines * that prepare a suitable stack frame, and restore this frame after the * exception has been processed. Note that the effect is as if the arguments * were passed call by reference. */ void trap(struct trapframe *frame) { struct lwp *l = curlwp; struct proc *p; struct pcb *pcb; extern char fusubail[], kcopy_fault[], return_address_fault[], IDTVEC(osyscall)[]; struct trapframe *vframe; ksiginfo_t ksi; void *onfault; int type, error; uint32_t cr2; bool pfail; if (__predict_true(l != NULL)) { pcb = lwp_getpcb(l); p = l->l_proc; } else { /* * this can happen eg. on break points in early on boot. */ pcb = NULL; p = NULL; } type = frame->tf_trapno; #ifdef DEBUG if (trapdebug) { trap_print(frame, l); } #endif if (type != T_NMI && !KERNELMODE(frame->tf_cs, frame->tf_eflags)) { type |= T_USER; l->l_md.md_regs = frame; pcb->pcb_cr2 = 0; LWP_CACHE_CREDS(l, p); } #ifdef KDTRACE_HOOKS /* * A trap can occur while DTrace executes a probe. Before * executing the probe, DTrace blocks re-scheduling and sets * a flag in its per-cpu flags to indicate that it doesn't * want to fault. On returning from the the probe, the no-fault * flag is cleared and finally re-scheduling is enabled. * * If the DTrace kernel module has registered a trap handler, * call it and if it returns non-zero, assume that it has * handled the trap and modified the trap frame so that this * function can return normally. */ if ((type == T_PROTFLT || type == T_PAGEFLT) && dtrace_trap_func != NULL) { if ((*dtrace_trap_func)(frame, type)) { return; } } #endif switch (type) { case T_ASTFLT: /*FALLTHROUGH*/ default: we_re_toast: if (type == T_TRCTRAP) check_dr0(); else trap_print(frame, l); if (kdb_trap(type, 0, frame)) return; if (kgdb_trap(type, frame)) return; /* * If this is a breakpoint, don't panic if we're not connected. */ if (type == T_BPTFLT && kgdb_disconnected()) { printf("kgdb: ignored %s\n", trap_type[type]); return; } panic("trap"); /*NOTREACHED*/ case T_PROTFLT: case T_SEGNPFLT: case T_ALIGNFLT: case T_TSSFLT: if (p == NULL) goto we_re_toast; /* Check for copyin/copyout fault. */ onfault = onfault_handler(pcb, frame); if (onfault != NULL) { copyefault: error = EFAULT; copyfault: frame->tf_eip = (uintptr_t)onfault; frame->tf_eax = error; return; } /* * Check for failure during return to user mode. * This can happen loading invalid values into the segment * registers, or during the 'iret' itself. * * We do this by looking at the instruction we faulted on. * The specific instructions we recognize only happen when * returning from a trap, syscall, or interrupt. */ kernelfault: KSI_INIT_TRAP(&ksi); ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_ACCERR; ksi.ksi_trap = type; switch (*(u_char *)frame->tf_eip) { case 0xcf: /* iret */ /* * The 'iret' instruction faulted, so we have the * 'user' registers saved after the kernel %eip:%cs:%fl * of the 'iret' and below that the user %eip:%cs:%fl * the 'iret' was processing. * We must delete the 3 words of kernel return address * from the stack to generate a normal stack frame * (eg for sending a SIGSEGV). */ vframe = (void *)((int *)frame + 3); if (KERNELMODE(vframe->tf_cs, vframe->tf_eflags)) goto we_re_toast; memmove(vframe, frame, offsetof(struct trapframe, tf_eip)); /* Set the faulting address to the user %eip */ ksi.ksi_addr = (void *)vframe->tf_eip; break; case 0x8e: switch (*(uint32_t *)frame->tf_eip) { case 0x8e242c8e: /* mov (%esp,%gs), then */ case 0x0424648e: /* mov 0x4(%esp),%fs */ case 0x0824448e: /* mov 0x8(%esp),%es */ case 0x0c245c8e: /* mov 0xc(%esp),%ds */ break; default: goto we_re_toast; } /* * We faulted loading one if the user segment registers. * The stack frame containing the user registers is * still valid and is just below the %eip:%cs:%fl of * the kernel fault frame. */ vframe = (void *)(&frame->tf_eflags + 1); if (KERNELMODE(vframe->tf_cs, vframe->tf_eflags)) goto we_re_toast; /* There is no valid address for the fault */ break; default: goto we_re_toast; } /* * We might have faulted trying to execute the * trampoline for a local (nested) signal handler. * Only generate SIGSEGV if the user %cs isn't changed. * (This is only strictly necessary in the 'iret' case.) */ if (!pmap_exec_fixup(&p->p_vmspace->vm_map, vframe, pcb)) { /* Save outer frame for any signal return */ l->l_md.md_regs = vframe; (*p->p_emul->e_trapsignal)(l, &ksi); } /* Return to user by reloading the user frame */ trap_return_fault_return(vframe); /* NOTREACHED */ case T_PROTFLT|T_USER: /* protection fault */ case T_TSSFLT|T_USER: case T_SEGNPFLT|T_USER: case T_STKFLT|T_USER: case T_ALIGNFLT|T_USER: KSI_INIT_TRAP(&ksi); ksi.ksi_addr = (void *)rcr2(); switch (type) { case T_SEGNPFLT|T_USER: case T_STKFLT|T_USER: ksi.ksi_signo = SIGBUS; ksi.ksi_code = BUS_ADRERR; break; case T_TSSFLT|T_USER: ksi.ksi_signo = SIGBUS; ksi.ksi_code = BUS_OBJERR; break; case T_ALIGNFLT|T_USER: ksi.ksi_signo = SIGBUS; ksi.ksi_code = BUS_ADRALN; break; case T_PROTFLT|T_USER: #ifdef VM86 if (frame->tf_eflags & PSL_VM) { vm86_gpfault(l, type & ~T_USER); goto out; } #endif /* * If pmap_exec_fixup does something, * let's retry the trap. */ if (pmap_exec_fixup(&p->p_vmspace->vm_map, frame, pcb)){ goto out; } ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_ACCERR; break; default: KASSERT(0); break; } goto trapsignal; case T_PRIVINFLT|T_USER: /* privileged instruction fault */ case T_FPOPFLT|T_USER: /* coprocessor operand fault */ KSI_INIT_TRAP(&ksi); ksi.ksi_signo = SIGILL; ksi.ksi_addr = (void *) frame->tf_eip; switch (type) { case T_PRIVINFLT|T_USER: ksi.ksi_code = ILL_PRVOPC; break; case T_FPOPFLT|T_USER: ksi.ksi_code = ILL_COPROC; break; default: ksi.ksi_code = 0; break; } goto trapsignal; case T_ASTFLT|T_USER: /* Allow process switch. */ //curcpu()->ci_data.cpu_nast++; if (l->l_pflag & LP_OWEUPC) { l->l_pflag &= ~LP_OWEUPC; ADDUPROF(l); } /* Allow a forced task switch. */ if (curcpu()->ci_want_resched) { preempt(); } goto out; case T_BOUND|T_USER: case T_OFLOW|T_USER: case T_DIVIDE|T_USER: KSI_INIT_TRAP(&ksi); ksi.ksi_signo = SIGFPE; ksi.ksi_addr = (void *)frame->tf_eip; switch (type) { case T_BOUND|T_USER: ksi.ksi_code = FPE_FLTSUB; break; case T_OFLOW|T_USER: ksi.ksi_code = FPE_INTOVF; break; case T_DIVIDE|T_USER: ksi.ksi_code = FPE_INTDIV; break; default: ksi.ksi_code = 0; break; } goto trapsignal; case T_PAGEFLT: /* Allow page faults in kernel mode. */ if (__predict_false(l == NULL)) goto we_re_toast; /* * fusubail is used by [fs]uswintr() to prevent page faulting * from inside the profiling interrupt. */ onfault = pcb->pcb_onfault; if (onfault == fusubail || onfault == return_address_fault) { goto copyefault; } if (cpu_intr_p() || (l->l_pflag & LP_INTR) != 0) { goto we_re_toast; } cr2 = rcr2(); goto faultcommon; case T_PAGEFLT|T_USER: { /* page fault */ register vaddr_t va; register struct vmspace *vm; register struct vm_map *map; vm_prot_t ftype; extern struct vm_map *kernel_map; cr2 = rcr2(); faultcommon: vm = p->p_vmspace; if (__predict_false(vm == NULL)) { goto we_re_toast; } pcb->pcb_cr2 = cr2; va = trunc_page((vaddr_t)cr2); /* * It is only a kernel address space fault iff: * 1. (type & T_USER) == 0 and * 2. pcb_onfault not set or * 3. pcb_onfault set but supervisor space fault * The last can occur during an exec() copyin where the * argument space is lazy-allocated. */ if (type == T_PAGEFLT && va >= KERNBASE) map = kernel_map; else map = &vm->vm_map; if (frame->tf_err & PGEX_W) ftype = VM_PROT_WRITE; else if (frame->tf_err & PGEX_X) ftype = VM_PROT_EXECUTE; else ftype = VM_PROT_READ; #ifdef DIAGNOSTIC if (map == kernel_map && va == 0) { printf("trap: bad kernel access at %lx\n", va); goto we_re_toast; } #endif /* Fault the original page in. */ onfault = pcb->pcb_onfault; pcb->pcb_onfault = NULL; error = uvm_fault(map, va, ftype); pcb->pcb_onfault = onfault; if (error == 0) { if (map != kernel_map && (void *)va >= vm->vm_maxsaddr) uvm_grow(p, va); pfail = false; while (type == T_PAGEFLT) { /* * we need to switch pmap now if we're in * the middle of copyin/out. * * but we don't need to do so for kcopy as * it never touch userspace. */ kpreempt_disable(); if (curcpu()->ci_want_pmapload) { onfault = onfault_handler(pcb, frame); if (onfault != kcopy_fault) { pmap_load(); } } /* * We need to keep the pmap loaded and * so avoid being preempted until back * into the copy functions. Disable * interrupts at the hardware level before * re-enabling preemption. Interrupts * will be re-enabled by 'iret' when * returning back out of the trap stub. * They'll only be re-enabled when the * program counter is once again in * the copy functions, and so visible * to cpu_kpreempt_exit(). */ #ifndef XEN x86_disable_intr(); #endif l->l_nopreempt--; if (l->l_nopreempt > 0 || !l->l_dopreempt || pfail) { return; } #ifndef XEN x86_enable_intr(); #endif /* * If preemption fails for some reason, * don't retry it. The conditions won't * change under our nose. */ pfail = kpreempt(0); } goto out; } if (type == T_PAGEFLT) { onfault = onfault_handler(pcb, frame); if (onfault != NULL) goto copyfault; printf("uvm_fault(%p, %#lx, %d) -> %#x\n", map, va, ftype, error); goto kernelfault; } KSI_INIT_TRAP(&ksi); ksi.ksi_trap = type & ~T_USER; ksi.ksi_addr = (void *)cr2; switch (error) { case EINVAL: ksi.ksi_signo = SIGBUS; ksi.ksi_code = BUS_ADRERR; break; case EACCES: ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_ACCERR; error = EFAULT; break; case ENOMEM: ksi.ksi_signo = SIGKILL; printf("UVM: pid %d.%d (%s), uid %d killed: " "out of swap\n", p->p_pid, l->l_lid, p->p_comm, l->l_cred ? kauth_cred_geteuid(l->l_cred) : -1); break; default: ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_MAPERR; break; } #ifdef TRAP_SIGDEBUG printf("pid %d.%d (%s): signal %d at eip %x addr %lx " "error %d\n", p->p_pid, l->l_lid, p->p_comm, ksi.ksi_signo, frame->tf_eip, va, error); #endif (*p->p_emul->e_trapsignal)(l, &ksi); break; } case T_TRCTRAP: /* Check whether they single-stepped into a lcall. */ if (frame->tf_eip == (int)IDTVEC(osyscall)) return; if (frame->tf_eip == (int)IDTVEC(osyscall) + 1) { frame->tf_eflags &= ~PSL_T; return; } goto we_re_toast; case T_BPTFLT|T_USER: /* bpt instruction fault */ case T_TRCTRAP|T_USER: /* trace trap */ /* * Don't go single-stepping into a RAS. */ if (p->p_raslist == NULL || (ras_lookup(p, (void *)frame->tf_eip) == (void *)-1)) { KSI_INIT_TRAP(&ksi); ksi.ksi_signo = SIGTRAP; ksi.ksi_trap = type & ~T_USER; if (type == (T_BPTFLT|T_USER)) ksi.ksi_code = TRAP_BRKPT; else ksi.ksi_code = TRAP_TRACE; ksi.ksi_addr = (void *)frame->tf_eip; (*p->p_emul->e_trapsignal)(l, &ksi); } break; case T_NMI: if (nmi_dispatch(frame)) return; /* NMI can be hooked up to a pushbutton for debugging */ if (kgdb_trap(type, frame)) return; if (kdb_trap(type, 0, frame)) return; /* machine/parity/power fail/"kitchen sink" faults */ #if NMCA > 0 mca_nmi(); #endif x86_nmi(); } if ((type & T_USER) == 0) return; out: userret(l); return; trapsignal: ksi.ksi_trap = type & ~T_USER; (*p->p_emul->e_trapsignal)(l, &ksi); userret(l); }
void cpu_getmcontext(struct lwp *l, mcontext_t *mcp, unsigned int *flags) { struct trapframe *tf = l->l_md.md_regs; struct pcb *pcb = lwp_getpcb(l); __greg_t *gr = mcp->__gregs; __greg_t ras_pc; gr[0] = tf->tf_ipsw; gr[1] = tf->tf_r1; gr[2] = tf->tf_rp; gr[3] = tf->tf_r3; gr[4] = tf->tf_r4; gr[5] = tf->tf_r5; gr[6] = tf->tf_r6; gr[7] = tf->tf_r7; gr[8] = tf->tf_r8; gr[9] = tf->tf_r9; gr[10] = tf->tf_r10; gr[11] = tf->tf_r11; gr[12] = tf->tf_r12; gr[13] = tf->tf_r13; gr[14] = tf->tf_r14; gr[15] = tf->tf_r15; gr[16] = tf->tf_r16; gr[17] = tf->tf_r17; gr[18] = tf->tf_r18; gr[19] = tf->tf_t4; gr[20] = tf->tf_t3; gr[21] = tf->tf_t2; gr[22] = tf->tf_t1; gr[23] = tf->tf_arg3; gr[24] = tf->tf_arg2; gr[25] = tf->tf_arg1; gr[26] = tf->tf_arg0; gr[27] = tf->tf_dp; gr[28] = tf->tf_ret0; gr[29] = tf->tf_ret1; gr[30] = tf->tf_sp; gr[31] = tf->tf_r31; gr[_REG_SAR] = tf->tf_sar; gr[_REG_PCSQH] = tf->tf_iisq_head; gr[_REG_PCSQT] = tf->tf_iisq_tail; gr[_REG_PCOQH] = tf->tf_iioq_head; gr[_REG_PCOQT] = tf->tf_iioq_tail; gr[_REG_SR0] = tf->tf_sr0; gr[_REG_SR1] = tf->tf_sr1; gr[_REG_SR2] = tf->tf_sr2; gr[_REG_SR3] = tf->tf_sr3; gr[_REG_SR4] = tf->tf_sr4; gr[_REG_CR27] = tf->tf_cr27; #if 0 gr[_REG_CR26] = tf->tf_cr26; #endif ras_pc = (__greg_t)ras_lookup(l->l_proc, (void *)(gr[_REG_PCOQH] & ~HPPA_PC_PRIV_MASK)); if (ras_pc != -1) { ras_pc |= HPPA_PC_PRIV_USER; gr[_REG_PCOQH] = ras_pc; gr[_REG_PCOQT] = ras_pc + 4; } *flags |= _UC_CPU | _UC_TLSBASE; if (l->l_md.md_flags & 0) { return; } hppa_fpu_flush(l); memcpy(&mcp->__fpregs, pcb->pcb_fpregs, sizeof(mcp->__fpregs)); *flags |= _UC_FPU; }
/*ARGSUSED*/ void trap(struct frame *fp, int type, u_int code, u_int v) { extern char fubail[], subail[]; struct lwp *l; struct proc *p; struct pcb *pcb; void *onfault; ksiginfo_t ksi; int s; int rv; u_quad_t sticks = 0 /* XXX initializer works around compiler bug */; curcpu()->ci_data.cpu_ntrap++; l = curlwp; p = l->l_proc; pcb = lwp_getpcb(l); KSI_INIT_TRAP(&ksi); ksi.ksi_trap = type & ~T_USER; if (USERMODE(fp->f_sr)) { type |= T_USER; sticks = p->p_sticks; l->l_md.md_regs = fp->f_regs; LWP_CACHE_CREDS(l, p); } switch (type) { default: dopanic: printf("trap type %d, code = 0x%x, v = 0x%x\n", type, code, v); printf("%s program counter = 0x%x\n", (type & T_USER) ? "user" : "kernel", fp->f_pc); /* * Let the kernel debugger see the trap frame that * caused us to panic. This is a convenience so * one can see registers at the point of failure. */ s = splhigh(); #ifdef KGDB /* If connected, step or cont returns 1 */ if (kgdb_trap(type, fp)) goto kgdb_cont; #endif #ifdef DDB (void)kdb_trap(type, (db_regs_t *)fp); #endif #ifdef KGDB kgdb_cont: #endif splx(s); if (panicstr) { printf("trap during panic!\n"); #ifdef DEBUG /* XXX should be a machine-dependent hook */ printf("(press a key)\n"); (void)cngetc(); #endif } regdump((struct trapframe *)fp, 128); type &= ~T_USER; if ((u_int)type < trap_types) panic(trap_type[type]); panic("trap"); case T_BUSERR: /* kernel bus error */ onfault = pcb->pcb_onfault; if (onfault == 0) goto dopanic; rv = EFAULT; /* FALLTHROUGH */ copyfault: /* * If we have arranged to catch this fault in any of the * copy to/from user space routines, set PC to return to * indicated location and set flag informing buserror code * that it may need to clean up stack frame. */ fp->f_stackadj = exframesize[fp->f_format]; fp->f_format = fp->f_vector = 0; fp->f_pc = (int)onfault; fp->f_regs[D0] = rv; return; case T_BUSERR|T_USER: /* bus error */ case T_ADDRERR|T_USER: /* address error */ ksi.ksi_addr = (void *)v; ksi.ksi_signo = SIGBUS; ksi.ksi_code = (type == (T_BUSERR|T_USER)) ? BUS_OBJERR : BUS_ADRERR; break; case T_COPERR: /* kernel coprocessor violation */ case T_FMTERR|T_USER: /* do all RTE errors come in as T_USER? */ case T_FMTERR: /* ...just in case... */ /* * The user has most likely trashed the RTE or FP state info * in the stack frame of a signal handler. */ printf("pid %d: kernel %s exception\n", p->p_pid, type==T_COPERR ? "coprocessor" : "format"); type |= T_USER; mutex_enter(p->p_lock); SIGACTION(p, SIGILL).sa_handler = SIG_DFL; sigdelset(&p->p_sigctx.ps_sigignore, SIGILL); sigdelset(&p->p_sigctx.ps_sigcatch, SIGILL); sigdelset(&l->l_sigmask, SIGILL); mutex_exit(p->p_lock); ksi.ksi_signo = SIGILL; ksi.ksi_addr = (void *)(int)fp->f_format; /* XXX was ILL_RESAD_FAULT */ ksi.ksi_code = (type == T_COPERR) ? ILL_COPROC : ILL_ILLOPC; break; case T_COPERR|T_USER: /* user coprocessor violation */ /* What is a proper response here? */ ksi.ksi_signo = SIGFPE; ksi.ksi_code = FPE_FLTINV; break; case T_FPERR|T_USER: /* 68881 exceptions */ /* * We pass along the 68881 status register which locore stashed * in code for us. */ ksi.ksi_signo = SIGFPE; ksi.ksi_code = fpsr2siginfocode(code); break; /* * FPU faults in supervisor mode. */ case T_ILLINST: /* fnop generates this, apparently. */ case T_FPEMULI: case T_FPEMULD: { extern label_t *nofault; if (nofault) /* If we're probing. */ longjmp(nofault); if (type == T_ILLINST) printf("Kernel Illegal Instruction trap.\n"); else printf("Kernel FPU trap.\n"); goto dopanic; } case T_FPEMULI|T_USER: /* unimplemented FP instruction */ case T_FPEMULD|T_USER: /* unimplemented FP data type */ #ifdef FPU_EMULATE if (fpu_emulate(fp, &pcb->pcb_fpregs, &ksi) == 0) ; /* XXX - Deal with tracing? (fp->f_sr & PSL_T) */ break; #elif defined(M68040) /* XXX need to FSAVE */ printf("pid %d(%s): unimplemented FP %s at %x (EA %x)\n", p->p_pid, p->p_comm, fp->f_format == 2 ? "instruction" : "data type", fp->f_pc, fp->f_fmt2.f_iaddr); /* XXX need to FRESTORE */ ksi.ksi_signo = SIGFPE; ksi.ksi_code = FPE_FLTINV; break; #else /* FALLTHROUGH */ #endif case T_ILLINST|T_USER: /* illegal instruction fault */ case T_PRIVINST|T_USER: /* privileged instruction fault */ ksi.ksi_addr = (void *)(int)fp->f_format; /* XXX was ILL_PRIVIN_FAULT */ ksi.ksi_signo = SIGILL; ksi.ksi_code = (type == (T_PRIVINST|T_USER)) ? ILL_PRVOPC : ILL_ILLOPC; break; case T_ZERODIV|T_USER: /* Divide by zero */ ksi.ksi_addr = (void *)(int)fp->f_format; /* XXX was FPE_INTDIV_TRAP */ ksi.ksi_signo = SIGFPE; ksi.ksi_code = FPE_FLTDIV; break; case T_CHKINST|T_USER: /* CHK instruction trap */ ksi.ksi_addr = (void *)(int)fp->f_format; /* XXX was FPE_SUBRNG_TRAP */ ksi.ksi_signo = SIGFPE; break; case T_TRAPVINST|T_USER: /* TRAPV instruction trap */ ksi.ksi_addr = (void *)(int)fp->f_format; /* XXX was FPE_INTOVF_TRAP */ ksi.ksi_signo = SIGFPE; break; /* * XXX: Trace traps are a nightmare. * * HP-UX uses trap #1 for breakpoints, * NetBSD/m68k uses trap #2, * SUN 3.x uses trap #15, * DDB and KGDB uses trap #15 (for kernel breakpoints; * handled elsewhere). * * NetBSD and HP-UX traps both get mapped by locore.s into T_TRACE. * SUN 3.x traps get passed through as T_TRAP15 and are not really * supported yet. * * XXX: We should never get kernel-mode T_TRAP15 * XXX: because locore.s now gives them special treatment. */ case T_TRAP15: /* kernel breakpoint */ #ifdef DEBUG printf("unexpected kernel trace trap, type = %d\n", type); printf("program counter = 0x%x\n", fp->f_pc); #endif fp->f_sr &= ~PSL_T; return; case T_TRACE|T_USER: /* user trace trap */ #ifdef COMPAT_SUNOS /* * SunOS uses Trap #2 for a "CPU cache flush". * Just flush the on-chip caches and return. */ if (p->p_emul == &emul_sunos) { ICIA(); DCIU(); return; } #endif /* FALLTHROUGH */ case T_TRACE: /* tracing a trap instruction */ case T_TRAP15|T_USER: /* SUN user trace trap */ /* * Don't go stepping into a RAS. */ if (p->p_raslist != NULL && (ras_lookup(p, (void *)fp->f_pc) != (void *)-1)) goto out; fp->f_sr &= ~PSL_T; ksi.ksi_signo = SIGTRAP; break; case T_ASTFLT: /* system async trap, cannot happen */ goto dopanic; case T_ASTFLT|T_USER: /* user async trap */ astpending = 0; /* * We check for software interrupts first. This is because * they are at a higher level than ASTs, and on a VAX would * interrupt the AST. We assume that if we are processing * an AST that we must be at IPL0 so we don't bother to * check. Note that we ensure that we are at least at SIR * IPL while processing the SIR. */ spl1(); /* fall into... */ case T_SSIR: /* software interrupt */ case T_SSIR|T_USER: /* * If this was not an AST trap, we are all done. */ if (type != (T_ASTFLT|T_USER)) { curcpu()->ci_data.cpu_ntrap--; return; } spl0(); if (l->l_pflag & LP_OWEUPC) { l->l_pflag &= ~LP_OWEUPC; ADDUPROF(l); } if (curcpu()->ci_want_resched) preempt(); goto out; case T_MMUFLT: /* kernel mode page fault */ /* * If we were doing profiling ticks or other user mode * stuff from interrupt code, Just Say No. */ onfault = pcb->pcb_onfault; if (onfault == fubail || onfault == subail) { rv = EFAULT; goto copyfault; } /* fall into ... */ case T_MMUFLT|T_USER: /* page fault */ { vaddr_t va; struct vmspace *vm = p->p_vmspace; struct vm_map *map; vm_prot_t ftype; extern struct vm_map *kernel_map; onfault = pcb->pcb_onfault; #ifdef DEBUG if ((mmudebug & MDB_WBFOLLOW) || MDB_ISPID(p->p_pid)) printf("trap: T_MMUFLT pid=%d, code=%x, v=%x, pc=%x, sr=%x\n", p->p_pid, code, v, fp->f_pc, fp->f_sr); #endif /* * It is only a kernel address space fault iff: * 1. (type & T_USER) == 0 and * 2. pcb_onfault not set or * 3. pcb_onfault set but supervisor space data fault * The last can occur during an exec() copyin where the * argument space is lazy-allocated. */ if ((type & T_USER) == 0 && (onfault == NULL || KDFAULT(code))) map = kernel_map; else { map = vm ? &vm->vm_map : kernel_map; } if (WRFAULT(code)) ftype = VM_PROT_WRITE; else ftype = VM_PROT_READ; va = trunc_page((vaddr_t)v); if (map == kernel_map && va == 0) { printf("trap: bad kernel %s access at 0x%x\n", (ftype & VM_PROT_WRITE) ? "read/write" : "read", v); goto dopanic; } pcb->pcb_onfault = NULL; rv = uvm_fault(map, va, ftype); pcb->pcb_onfault = onfault; #ifdef DEBUG if (rv && MDB_ISPID(p->p_pid)) printf("uvm_fault(%p, 0x%lx, 0x%x) -> 0x%x\n", map, va, ftype, rv); #endif /* * If this was a stack access we keep track of the maximum * accessed stack size. Also, if vm_fault gets a protection * failure it is due to accessing the stack region outside * the current limit and we need to reflect that as an access * error. */ if (rv == 0) { if (map != kernel_map && (void *)va >= vm->vm_maxsaddr) uvm_grow(p, va); if (type == T_MMUFLT) { if (ucas_ras_check(&fp->F_t)) { return; } #ifdef M68040 if (cputype == CPU_68040) (void) writeback(fp, 1); #endif return; } goto out; } if (rv == EACCES) { ksi.ksi_code = SEGV_ACCERR; rv = EFAULT; } else ksi.ksi_code = SEGV_MAPERR; if (type == T_MMUFLT) { if (onfault) goto copyfault; printf("uvm_fault(%p, 0x%lx, 0x%x) -> 0x%x\n", map, va, ftype, rv); printf(" type %x, code [mmu,,ssw]: %x\n", type, code); goto dopanic; } ksi.ksi_addr = (void *)v; switch (rv) { case ENOMEM: printf("UVM: pid %d (%s), uid %d killed: out of swap\n", p->p_pid, p->p_comm, l->l_cred ? kauth_cred_geteuid(l->l_cred) : -1); ksi.ksi_signo = SIGKILL; break; case EINVAL: ksi.ksi_signo = SIGBUS; ksi.ksi_code = BUS_ADRERR; break; case EACCES: ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_ACCERR; break; default: ksi.ksi_signo = SIGSEGV; ksi.ksi_code = SEGV_MAPERR; break; } break; } } if (ksi.ksi_signo) trapsignal(l, &ksi); if ((type & T_USER) == 0) return; out: userret(l, fp, sticks, v, 1); }
/* * Process debugging system call. */ int sys_ptrace(struct lwp *l, const struct sys_ptrace_args *uap, register_t *retval) { /* { syscallarg(int) req; syscallarg(pid_t) pid; syscallarg(void *) addr; syscallarg(int) data; } */ struct proc *p = l->l_proc; struct lwp *lt; struct proc *t; /* target process */ struct uio uio; struct iovec iov; struct ptrace_io_desc piod; struct ptrace_lwpinfo pl; struct vmspace *vm; int error, write, tmp, req, pheld; int signo; ksiginfo_t ksi; #ifdef COREDUMP char *path; #endif error = 0; req = SCARG(uap, req); /* * If attaching or detaching, we need to get a write hold on the * proclist lock so that we can re-parent the target process. */ mutex_enter(proc_lock); /* "A foolish consistency..." XXX */ if (req == PT_TRACE_ME) { t = p; mutex_enter(t->p_lock); } else { /* Find the process we're supposed to be operating on. */ if ((t = p_find(SCARG(uap, pid), PFIND_LOCKED)) == NULL) { mutex_exit(proc_lock); return (ESRCH); } /* XXX-elad */ mutex_enter(t->p_lock); error = kauth_authorize_process(l->l_cred, KAUTH_PROCESS_CANSEE, t, KAUTH_ARG(KAUTH_REQ_PROCESS_CANSEE_ENTRY), NULL, NULL); if (error) { mutex_exit(proc_lock); mutex_exit(t->p_lock); return (ESRCH); } } /* * Grab a reference on the process to prevent it from execing or * exiting. */ if (!rw_tryenter(&t->p_reflock, RW_READER)) { mutex_exit(proc_lock); mutex_exit(t->p_lock); return EBUSY; } /* Make sure we can operate on it. */ switch (req) { case PT_TRACE_ME: /* Saying that you're being traced is always legal. */ break; case PT_ATTACH: /* * You can't attach to a process if: * (1) it's the process that's doing the attaching, */ if (t->p_pid == p->p_pid) { error = EINVAL; break; } /* * (2) it's a system process */ if (t->p_flag & PK_SYSTEM) { error = EPERM; break; } /* * (3) it's already being traced, or */ if (ISSET(t->p_slflag, PSL_TRACED)) { error = EBUSY; break; } /* * (4) the tracer is chrooted, and its root directory is * not at or above the root directory of the tracee */ mutex_exit(t->p_lock); /* XXXSMP */ tmp = proc_isunder(t, l); mutex_enter(t->p_lock); /* XXXSMP */ if (!tmp) { error = EPERM; break; } break; case PT_READ_I: case PT_READ_D: case PT_WRITE_I: case PT_WRITE_D: case PT_IO: #ifdef PT_GETREGS case PT_GETREGS: #endif #ifdef PT_SETREGS case PT_SETREGS: #endif #ifdef PT_GETFPREGS case PT_GETFPREGS: #endif #ifdef PT_SETFPREGS case PT_SETFPREGS: #endif #ifdef __HAVE_PTRACE_MACHDEP PTRACE_MACHDEP_REQUEST_CASES #endif /* * You can't read/write the memory or registers of a process * if the tracer is chrooted, and its root directory is not at * or above the root directory of the tracee. */ mutex_exit(t->p_lock); /* XXXSMP */ tmp = proc_isunder(t, l); mutex_enter(t->p_lock); /* XXXSMP */ if (!tmp) { error = EPERM; break; } /*FALLTHROUGH*/ case PT_CONTINUE: case PT_KILL: case PT_DETACH: case PT_LWPINFO: case PT_SYSCALL: #ifdef COREDUMP case PT_DUMPCORE: #endif #ifdef PT_STEP case PT_STEP: #endif /* * You can't do what you want to the process if: * (1) It's not being traced at all, */ if (!ISSET(t->p_slflag, PSL_TRACED)) { error = EPERM; break; } /* * (2) it's being traced by procfs (which has * different signal delivery semantics), */ if (ISSET(t->p_slflag, PSL_FSTRACE)) { uprintf("file system traced\n"); error = EBUSY; break; } /* * (3) it's not being traced by _you_, or */ if (t->p_pptr != p) { uprintf("parent %d != %d\n", t->p_pptr->p_pid, p->p_pid); error = EBUSY; break; } /* * (4) it's not currently stopped. */ if (t->p_stat != SSTOP || !t->p_waited /* XXXSMP */) { uprintf("stat %d flag %d\n", t->p_stat, !t->p_waited); error = EBUSY; break; } break; default: /* It was not a legal request. */ error = EINVAL; break; } if (error == 0) error = kauth_authorize_process(l->l_cred, KAUTH_PROCESS_PTRACE, t, KAUTH_ARG(req), NULL, NULL); if (error != 0) { mutex_exit(proc_lock); mutex_exit(t->p_lock); rw_exit(&t->p_reflock); return error; } /* Do single-step fixup if needed. */ FIX_SSTEP(t); /* * XXX NJWLWP * * The entire ptrace interface needs work to be useful to a * process with multiple LWPs. For the moment, we'll kluge * this; memory access will be fine, but register access will * be weird. */ lt = LIST_FIRST(&t->p_lwps); KASSERT(lt != NULL); lwp_addref(lt); /* * Which locks do we need held? XXX Ugly. */ switch (req) { #ifdef PT_STEP case PT_STEP: #endif case PT_CONTINUE: case PT_DETACH: case PT_KILL: case PT_SYSCALL: case PT_ATTACH: case PT_TRACE_ME: pheld = 1; break; default: mutex_exit(proc_lock); mutex_exit(t->p_lock); pheld = 0; break; } /* Now do the operation. */ write = 0; *retval = 0; tmp = 0; switch (req) { case PT_TRACE_ME: /* Just set the trace flag. */ SET(t->p_slflag, PSL_TRACED); t->p_opptr = t->p_pptr; break; case PT_WRITE_I: /* XXX no separate I and D spaces */ case PT_WRITE_D: #if defined(__HAVE_RAS) /* * Can't write to a RAS */ if (ras_lookup(t, SCARG(uap, addr)) != (void *)-1) { error = EACCES; break; } #endif write = 1; tmp = SCARG(uap, data); /* FALLTHROUGH */ case PT_READ_I: /* XXX no separate I and D spaces */ case PT_READ_D: /* write = 0 done above. */ iov.iov_base = (void *)&tmp; iov.iov_len = sizeof(tmp); uio.uio_iov = &iov; uio.uio_iovcnt = 1; uio.uio_offset = (off_t)(unsigned long)SCARG(uap, addr); uio.uio_resid = sizeof(tmp); uio.uio_rw = write ? UIO_WRITE : UIO_READ; UIO_SETUP_SYSSPACE(&uio); error = process_domem(l, lt, &uio); if (!write) *retval = tmp; break; case PT_IO: error = copyin(SCARG(uap, addr), &piod, sizeof(piod)); if (error) break; switch (piod.piod_op) { case PIOD_READ_D: case PIOD_READ_I: uio.uio_rw = UIO_READ; break; case PIOD_WRITE_D: case PIOD_WRITE_I: /* * Can't write to a RAS */ if (ras_lookup(t, SCARG(uap, addr)) != (void *)-1) { return (EACCES); } uio.uio_rw = UIO_WRITE; break; default: error = EINVAL; break; } if (error) break; error = proc_vmspace_getref(l->l_proc, &vm); if (error) break; iov.iov_base = piod.piod_addr; iov.iov_len = piod.piod_len; uio.uio_iov = &iov; uio.uio_iovcnt = 1; uio.uio_offset = (off_t)(unsigned long)piod.piod_offs; uio.uio_resid = piod.piod_len; uio.uio_vmspace = vm; error = process_domem(l, lt, &uio); piod.piod_len -= uio.uio_resid; (void) copyout(&piod, SCARG(uap, addr), sizeof(piod)); uvmspace_free(vm); break; #ifdef COREDUMP case PT_DUMPCORE: if ((path = SCARG(uap, addr)) != NULL) { char *dst; int len = SCARG(uap, data); if (len < 0 || len >= MAXPATHLEN) { error = EINVAL; break; } dst = malloc(len + 1, M_TEMP, M_WAITOK); if ((error = copyin(path, dst, len)) != 0) { free(dst, M_TEMP); break; } path = dst; path[len] = '\0'; } error = coredump(lt, path); if (path) free(path, M_TEMP); break; #endif #ifdef PT_STEP case PT_STEP: /* * From the 4.4BSD PRM: * "Execution continues as in request PT_CONTINUE; however * as soon as possible after execution of at least one * instruction, execution stops again. [ ... ]" */ #endif case PT_CONTINUE: case PT_SYSCALL: case PT_DETACH: if (req == PT_SYSCALL) { if (!ISSET(t->p_slflag, PSL_SYSCALL)) { SET(t->p_slflag, PSL_SYSCALL); #ifdef __HAVE_SYSCALL_INTERN (*t->p_emul->e_syscall_intern)(t); #endif } } else { if (ISSET(t->p_slflag, PSL_SYSCALL)) { CLR(t->p_slflag, PSL_SYSCALL); #ifdef __HAVE_SYSCALL_INTERN (*t->p_emul->e_syscall_intern)(t); #endif } } p->p_trace_enabled = trace_is_enabled(p); /* * From the 4.4BSD PRM: * "The data argument is taken as a signal number and the * child's execution continues at location addr as if it * incurred that signal. Normally the signal number will * be either 0 to indicate that the signal that caused the * stop should be ignored, or that value fetched out of * the process's image indicating which signal caused * the stop. If addr is (int *)1 then execution continues * from where it stopped." */ /* Check that the data is a valid signal number or zero. */ if (SCARG(uap, data) < 0 || SCARG(uap, data) >= NSIG) { error = EINVAL; break; } uvm_lwp_hold(lt); /* If the address parameter is not (int *)1, set the pc. */ if ((int *)SCARG(uap, addr) != (int *)1) if ((error = process_set_pc(lt, SCARG(uap, addr))) != 0) { uvm_lwp_rele(lt); break; } #ifdef PT_STEP /* * Arrange for a single-step, if that's requested and possible. */ error = process_sstep(lt, req == PT_STEP); if (error) { uvm_lwp_rele(lt); break; } #endif uvm_lwp_rele(lt); if (req == PT_DETACH) { CLR(t->p_slflag, PSL_TRACED|PSL_FSTRACE|PSL_SYSCALL); /* give process back to original parent or init */ if (t->p_opptr != t->p_pptr) { struct proc *pp = t->p_opptr; proc_reparent(t, pp ? pp : initproc); } /* not being traced any more */ t->p_opptr = NULL; } signo = SCARG(uap, data); sendsig: /* Finally, deliver the requested signal (or none). */ if (t->p_stat == SSTOP) { /* * Unstop the process. If it needs to take a * signal, make all efforts to ensure that at * an LWP runs to see it. */ t->p_xstat = signo; proc_unstop(t); } else if (signo != 0) { KSI_INIT_EMPTY(&ksi); ksi.ksi_signo = signo; kpsignal2(t, &ksi); } break; case PT_KILL: /* just send the process a KILL signal. */ signo = SIGKILL; goto sendsig; /* in PT_CONTINUE, above. */ case PT_ATTACH: /* * Go ahead and set the trace flag. * Save the old parent (it's reset in * _DETACH, and also in kern_exit.c:wait4() * Reparent the process so that the tracing * proc gets to see all the action. * Stop the target. */ t->p_opptr = t->p_pptr; if (t->p_pptr != p) { struct proc *parent = t->p_pptr; if (parent->p_lock < t->p_lock) { if (!mutex_tryenter(parent->p_lock)) { mutex_exit(t->p_lock); mutex_enter(parent->p_lock); } } else if (parent->p_lock > t->p_lock) { mutex_enter(parent->p_lock); } parent->p_slflag |= PSL_CHTRACED; proc_reparent(t, p); if (parent->p_lock != t->p_lock) mutex_exit(parent->p_lock); } SET(t->p_slflag, PSL_TRACED); signo = SIGSTOP; goto sendsig; case PT_LWPINFO: if (SCARG(uap, data) != sizeof(pl)) { error = EINVAL; break; } error = copyin(SCARG(uap, addr), &pl, sizeof(pl)); if (error) break; tmp = pl.pl_lwpid; lwp_delref(lt); mutex_enter(t->p_lock); if (tmp == 0) lt = LIST_FIRST(&t->p_lwps); else { lt = lwp_find(t, tmp); if (lt == NULL) { mutex_exit(t->p_lock); error = ESRCH; break; } lt = LIST_NEXT(lt, l_sibling); } while (lt != NULL && lt->l_stat == LSZOMB) lt = LIST_NEXT(lt, l_sibling); pl.pl_lwpid = 0; pl.pl_event = 0; if (lt) { lwp_addref(lt); pl.pl_lwpid = lt->l_lid; if (lt->l_lid == t->p_sigctx.ps_lwp) pl.pl_event = PL_EVENT_SIGNAL; } mutex_exit(t->p_lock); error = copyout(&pl, SCARG(uap, addr), sizeof(pl)); break; #ifdef PT_SETREGS case PT_SETREGS: write = 1; #endif #ifdef PT_GETREGS case PT_GETREGS: /* write = 0 done above. */ #endif #if defined(PT_SETREGS) || defined(PT_GETREGS) tmp = SCARG(uap, data); if (tmp != 0 && t->p_nlwps > 1) { lwp_delref(lt); mutex_enter(t->p_lock); lt = lwp_find(t, tmp); if (lt == NULL) { mutex_exit(t->p_lock); error = ESRCH; break; } lwp_addref(lt); mutex_exit(t->p_lock); } if (!process_validregs(lt)) error = EINVAL; else { error = proc_vmspace_getref(l->l_proc, &vm); if (error) break; iov.iov_base = SCARG(uap, addr); iov.iov_len = sizeof(struct reg); uio.uio_iov = &iov; uio.uio_iovcnt = 1; uio.uio_offset = 0; uio.uio_resid = sizeof(struct reg); uio.uio_rw = write ? UIO_WRITE : UIO_READ; uio.uio_vmspace = vm; error = process_doregs(l, lt, &uio); uvmspace_free(vm); } break; #endif #ifdef PT_SETFPREGS case PT_SETFPREGS: write = 1; #endif #ifdef PT_GETFPREGS case PT_GETFPREGS: /* write = 0 done above. */ #endif #if defined(PT_SETFPREGS) || defined(PT_GETFPREGS) tmp = SCARG(uap, data); if (tmp != 0 && t->p_nlwps > 1) { lwp_delref(lt); mutex_enter(t->p_lock); lt = lwp_find(t, tmp); if (lt == NULL) { mutex_exit(t->p_lock); error = ESRCH; break; } lwp_addref(lt); mutex_exit(t->p_lock); } if (!process_validfpregs(lt)) error = EINVAL; else { error = proc_vmspace_getref(l->l_proc, &vm); if (error) break; iov.iov_base = SCARG(uap, addr); iov.iov_len = sizeof(struct fpreg); uio.uio_iov = &iov; uio.uio_iovcnt = 1; uio.uio_offset = 0; uio.uio_resid = sizeof(struct fpreg); uio.uio_rw = write ? UIO_WRITE : UIO_READ; uio.uio_vmspace = vm; error = process_dofpregs(l, lt, &uio); uvmspace_free(vm); } break; #endif #ifdef __HAVE_PTRACE_MACHDEP PTRACE_MACHDEP_REQUEST_CASES error = ptrace_machdep_dorequest(l, lt, req, SCARG(uap, addr), SCARG(uap, data)); break; #endif } if (pheld) { mutex_exit(t->p_lock); mutex_exit(proc_lock); } if (lt != NULL) lwp_delref(lt); rw_exit(&t->p_reflock); return error; }