/* * Copyright (c) 1998 Mark Newton * Copyright (c) 1994 Christos Zoulas * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * * $FreeBSD$ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #undef sigcode #undef szsigcode extern int svr4_szsigcode; extern char svr4_sigcode[]; extern int _udatasel, _ucodesel; static void svr4_getsiginfo __P((union svr4_siginfo *, int, u_long, caddr_t)); #if !defined(__NetBSD__) /* taken from /sys/arch/i386/include/psl.h on NetBSD-1.3 */ # define PSL_MBZ 0xffc08028 # define PSL_USERSTATIC (PSL_USER | PSL_MBZ | PSL_IOPL | PSL_NT | PSL_VM | PSL_VIF | PSL_VIP) # define USERMODE(c, f) (ISPL(c) == SEL_UPL) #endif #if defined(__NetBSD__) void svr4_setregs(p, epp, stack) struct proc *p; struct exec_package *epp; u_long stack; { register struct pcb *pcb = &p->p_addr->u_pcb; pcb->pcb_savefpu.sv_env.en_cw = __SVR4_NPXCW__; setregs(p, epp, stack, 0UL); } #endif /* __NetBSD__ */ void svr4_getcontext(p, uc, mask, oonstack) struct proc *p; struct svr4_ucontext *uc; sigset_t *mask; int oonstack; { struct trapframe *tf = p->p_frame; svr4_greg_t *r = uc->uc_mcontext.greg; struct svr4_sigaltstack *s = &uc->uc_stack; #if defined(DONE_MORE_SIGALTSTACK_WORK) struct sigacts *psp; struct sigaltstack *sf; #endif PROC_LOCK(p); #if defined(DONE_MORE_SIGALTSTACK_WORK) psp = p->p_sigacts; sf = &p->p_sigstk; #endif memset(uc, 0, sizeof(struct svr4_ucontext)); uc->uc_link = p->p_emuldata; /* * Set the general purpose registers */ #ifdef VM86 if (tf->tf_eflags & PSL_VM) { r[SVR4_X86_GS] = tf->tf_vm86_gs; r[SVR4_X86_FS] = tf->tf_vm86_fs; r[SVR4_X86_ES] = tf->tf_vm86_es; r[SVR4_X86_DS] = tf->tf_vm86_ds; r[SVR4_X86_EFL] = get_vflags(p); } else #endif { #if defined(__NetBSD__) __asm("movl %%gs,%w0" : "=r" (r[SVR4_X86_GS])); __asm("movl %%fs,%w0" : "=r" (r[SVR4_X86_FS])); #else r[SVR4_X86_GS] = rgs(); r[SVR4_X86_FS] = tf->tf_fs; #endif r[SVR4_X86_ES] = tf->tf_es; r[SVR4_X86_DS] = tf->tf_ds; r[SVR4_X86_EFL] = tf->tf_eflags; } r[SVR4_X86_EDI] = tf->tf_edi; r[SVR4_X86_ESI] = tf->tf_esi; r[SVR4_X86_EBP] = tf->tf_ebp; r[SVR4_X86_ESP] = tf->tf_esp; r[SVR4_X86_EBX] = tf->tf_ebx; r[SVR4_X86_EDX] = tf->tf_edx; r[SVR4_X86_ECX] = tf->tf_ecx; r[SVR4_X86_EAX] = tf->tf_eax; r[SVR4_X86_TRAPNO] = tf->tf_trapno; r[SVR4_X86_ERR] = tf->tf_err; r[SVR4_X86_EIP] = tf->tf_eip; r[SVR4_X86_CS] = tf->tf_cs; r[SVR4_X86_UESP] = 0; r[SVR4_X86_SS] = tf->tf_ss; /* * Set the signal stack */ #if defined(DONE_MORE_SIGALTSTACK_WORK) bsd_to_svr4_sigaltstack(sf, s); #else s->ss_sp = (void *)(((u_long) tf->tf_esp) & ~(16384 - 1)); s->ss_size = 16384; s->ss_flags = 0; #endif PROC_UNLOCK(p); /* * Set the signal mask */ bsd_to_svr4_sigset(mask, &uc->uc_sigmask); /* * Set the flags */ uc->uc_flags = SVR4_UC_SIGMASK|SVR4_UC_CPU|SVR4_UC_STACK; } /* * Set to ucontext specified. Reset signal mask and * stack state from context. * Return to previous pc and psl as specified by * context left by sendsig. Check carefully to * make sure that the user has not modified the * psl to gain improper privileges or to cause * a machine fault. */ int svr4_setcontext(p, uc) struct proc *p; struct svr4_ucontext *uc; { #if defined(DONE_MORE_SIGALTSTACK_WORK) struct sigacts *psp; #endif register struct trapframe *tf; svr4_greg_t *r = uc->uc_mcontext.greg; struct svr4_sigaltstack *s = &uc->uc_stack; struct sigaltstack *sf; sigset_t mask; PROC_LOCK(p); #if defined(DONE_MORE_SIGALTSTACK_WORK) psp = p->p_sigacts; #endif sf = &p->p_sigstk; /* * XXX: * Should we check the value of flags to determine what to restore? * What to do with uc_link? * What to do with floating point stuff? * Should we bother with the rest of the registers that we * set to 0 right now? */ if ((uc->uc_flags & SVR4_UC_CPU) == 0) return 0; DPRINTF(("svr4_setcontext(%d)\n", p->p_pid)); tf = p->p_frame; /* * Restore register context. */ #ifdef VM86 #warning "VM86 doesn't work yet, please don't try to use it." if (r[SVR4_X86_EFL] & PSL_VM) { tf->tf_vm86_gs = r[SVR4_X86_GS]; tf->tf_vm86_fs = r[SVR4_X86_FS]; tf->tf_vm86_es = r[SVR4_X86_ES]; tf->tf_vm86_ds = r[SVR4_X86_DS]; set_vflags(p, r[SVR4_X86_EFL]); } else #endif { /* * Check for security violations. If we're returning to * protected mode, the CPU will validate the segment registers * automatically and generate a trap on violations. We handle * the trap, rather than doing all of the checking here. */ if (((r[SVR4_X86_EFL] ^ tf->tf_eflags) & PSL_USERSTATIC) != 0 || !USERMODE(r[SVR4_X86_CS], r[SVR4_X86_EFL])) return (EINVAL); #if defined(__NetBSD__) /* %fs and %gs were restored by the trampoline. */ #else /* %gs was restored by the trampoline. */ tf->tf_fs = r[SVR4_X86_FS]; #endif tf->tf_es = r[SVR4_X86_ES]; tf->tf_ds = r[SVR4_X86_DS]; tf->tf_eflags = r[SVR4_X86_EFL]; } tf->tf_edi = r[SVR4_X86_EDI]; tf->tf_esi = r[SVR4_X86_ESI]; tf->tf_ebp = r[SVR4_X86_EBP]; tf->tf_ebx = r[SVR4_X86_EBX]; tf->tf_edx = r[SVR4_X86_EDX]; tf->tf_ecx = r[SVR4_X86_ECX]; tf->tf_eax = r[SVR4_X86_EAX]; tf->tf_trapno = r[SVR4_X86_TRAPNO]; tf->tf_err = r[SVR4_X86_ERR]; tf->tf_eip = r[SVR4_X86_EIP]; tf->tf_cs = r[SVR4_X86_CS]; tf->tf_ss = r[SVR4_X86_SS]; tf->tf_esp = r[SVR4_X86_ESP]; p->p_emuldata = uc->uc_link; /* * restore signal stack */ if (uc->uc_flags & SVR4_UC_STACK) { svr4_to_bsd_sigaltstack(s, sf); } /* * restore signal mask */ if (uc->uc_flags & SVR4_UC_SIGMASK) { #if defined(DEBUG_SVR4) { int i; for (i = 0; i < 4; i++) DPRINTF(("\tuc_sigmask[%d] = %lx\n", i, uc->uc_sigmask.bits[i])); } #endif svr4_to_bsd_sigset(&uc->uc_sigmask, &mask); SIG_CANTMASK(mask); p->p_sigmask = mask; } PROC_UNLOCK(p); return 0; /*EJUSTRETURN;*/ } static void svr4_getsiginfo(si, sig, code, addr) union svr4_siginfo *si; int sig; u_long code; caddr_t addr; { si->si_signo = bsd_to_svr4_sig[sig]; si->si_errno = 0; si->si_addr = addr; switch (code) { case T_PRIVINFLT: si->si_code = SVR4_ILL_PRVOPC; si->si_trap = SVR4_T_PRIVINFLT; break; case T_BPTFLT: si->si_code = SVR4_TRAP_BRKPT; si->si_trap = SVR4_T_BPTFLT; break; case T_ARITHTRAP: si->si_code = SVR4_FPE_INTOVF; si->si_trap = SVR4_T_DIVIDE; break; case T_PROTFLT: si->si_code = SVR4_SEGV_ACCERR; si->si_trap = SVR4_T_PROTFLT; break; case T_TRCTRAP: si->si_code = SVR4_TRAP_TRACE; si->si_trap = SVR4_T_TRCTRAP; break; case T_PAGEFLT: si->si_code = SVR4_SEGV_ACCERR; si->si_trap = SVR4_T_PAGEFLT; break; case T_ALIGNFLT: si->si_code = SVR4_BUS_ADRALN; si->si_trap = SVR4_T_ALIGNFLT; break; case T_DIVIDE: si->si_code = SVR4_FPE_FLTDIV; si->si_trap = SVR4_T_DIVIDE; break; case T_OFLOW: si->si_code = SVR4_FPE_FLTOVF; si->si_trap = SVR4_T_DIVIDE; break; case T_BOUND: si->si_code = SVR4_FPE_FLTSUB; si->si_trap = SVR4_T_BOUND; break; case T_DNA: si->si_code = SVR4_FPE_FLTINV; si->si_trap = SVR4_T_DNA; break; case T_FPOPFLT: si->si_code = SVR4_FPE_FLTINV; si->si_trap = SVR4_T_FPOPFLT; break; case T_SEGNPFLT: si->si_code = SVR4_SEGV_MAPERR; si->si_trap = SVR4_T_SEGNPFLT; break; case T_STKFLT: si->si_code = SVR4_ILL_BADSTK; si->si_trap = SVR4_T_STKFLT; break; default: si->si_code = 0; si->si_trap = 0; #if defined(DEBUG_SVR4) printf("sig %d code %ld\n", sig, code); /* panic("svr4_getsiginfo");*/ #endif break; } } /* * Send an interrupt to process. * * Stack is set up to allow sigcode stored * in u. to call routine. After the handler is * done svr4 will call setcontext for us * with the user context we just set up, and we * will return to the user pc, psl. */ void svr4_sendsig(catcher, sig, mask, code) sig_t catcher; int sig; sigset_t *mask; u_long code; { register struct proc *p = curproc; register struct trapframe *tf; struct svr4_sigframe *fp, frame; struct sigacts *psp; int oonstack; #if defined(DEBUG_SVR4) printf("svr4_sendsig(%d)\n", sig); #endif PROC_LOCK(p); psp = p->p_sigacts; tf = p->p_frame; oonstack = sigonstack(tf->tf_esp); /* * Allocate space for the signal handler context. */ if ((p->p_flag & P_ALTSTACK) && !oonstack && SIGISMEMBER(psp->ps_sigonstack, sig)) { fp = (struct svr4_sigframe *)(p->p_sigstk.ss_sp + p->p_sigstk.ss_size - sizeof(struct svr4_sigframe)); p->p_sigstk.ss_flags |= SS_ONSTACK; } else { fp = (struct svr4_sigframe *)tf->tf_esp - 1; } PROC_UNLOCK(p); /* * Build the argument list for the signal handler. * Notes: * - we always build the whole argument list, even when we * don't need to [when SA_SIGINFO is not set, we don't need * to pass all sf_si and sf_uc] * - we don't pass the correct signal address [we need to * modify many kernel files to enable that] */ svr4_getcontext(p, &frame.sf_uc, mask, oonstack); #if defined(DEBUG_SVR4) printf("obtained ucontext\n"); #endif svr4_getsiginfo(&frame.sf_si, sig, code, (caddr_t) tf->tf_eip); #if defined(DEBUG_SVR4) printf("obtained siginfo\n"); #endif frame.sf_signum = frame.sf_si.si_signo; frame.sf_sip = &fp->sf_si; frame.sf_ucp = &fp->sf_uc; frame.sf_handler = catcher; #if defined(DEBUG_SVR4) printf("sig = %d, sip %p, ucp = %p, handler = %p\n", frame.sf_signum, frame.sf_sip, frame.sf_ucp, frame.sf_handler); #endif if (copyout(&frame, fp, sizeof(frame)) != 0) { /* * Process has trashed its stack; give it an illegal * instruction to halt it in its tracks. */ PROC_LOCK(p); sigexit(p, SIGILL); /* NOTREACHED */ } #if defined(__NetBSD__) /* * Build context to run handler in. */ tf->tf_es = GSEL(GUSERLDT_SEL, SEL_UPL); tf->tf_ds = GSEL(GUSERLDT_SEL, SEL_UPL); tf->tf_eip = (int)(((char *)PS_STRINGS) - svr4_szsigcode); tf->tf_cs = GSEL(GUSERLDT_SEL, SEL_UPL); tf->tf_eflags &= ~(PSL_T|PSL_VM|PSL_AC); tf->tf_esp = (int)fp; tf->tf_ss = GSEL(GUSERLDT_SEL, SEL_UPL); #else tf->tf_esp = (int)fp; tf->tf_eip = (int)(((char *)PS_STRINGS) - *(p->p_sysent->sv_szsigcode)); tf->tf_cs = _ucodesel; tf->tf_ds = _udatasel; tf->tf_es = _udatasel; tf->tf_fs = _udatasel; load_gs(_udatasel); tf->tf_ss = _udatasel; #endif } int svr4_sys_sysarch(p, v) struct proc *p; struct svr4_sys_sysarch_args *v; { struct svr4_sys_sysarch_args *uap = v; #if 0 /* USER_LDT */ #if defined(__NetBSD__) caddr_t sg = stackgap_init(p->p_emul); #else caddr_t sg = stackgap_init(); #endif int error; #endif switch (uap->op) { case SVR4_SYSARCH_FPHW: return 0; case SVR4_SYSARCH_DSCR: #if 0 /* USER_LDT */ #warning "USER_LDT doesn't work - are you sure you want this?" { struct i386_set_ldt_args sa, *sap; struct sys_sysarch_args ua; struct svr4_ssd ssd; union descriptor bsd; if ((error = copyin(SCARG(uap, a1), &ssd, sizeof(ssd))) != 0) { printf("Cannot copy arg1\n"); return error; } printf("s=%x, b=%x, l=%x, a1=%x a2=%x\n", ssd.selector, ssd.base, ssd.limit, ssd.access1, ssd.access2); /* We can only set ldt's for now. */ if (!ISLDT(ssd.selector)) { printf("Not an ldt\n"); return EPERM; } /* Oh, well we don't cleanup either */ if (ssd.access1 == 0) return 0; bsd.sd.sd_lobase = ssd.base & 0xffffff; bsd.sd.sd_hibase = (ssd.base >> 24) & 0xff; bsd.sd.sd_lolimit = ssd.limit & 0xffff; bsd.sd.sd_hilimit = (ssd.limit >> 16) & 0xf; bsd.sd.sd_type = ssd.access1 & 0x1f; bsd.sd.sd_dpl = (ssd.access1 >> 5) & 0x3; bsd.sd.sd_p = (ssd.access1 >> 7) & 0x1; bsd.sd.sd_xx = ssd.access2 & 0x3; bsd.sd.sd_def32 = (ssd.access2 >> 2) & 0x1; bsd.sd.sd_gran = (ssd.access2 >> 3)& 0x1; sa.start = IDXSEL(ssd.selector); sa.desc = stackgap_alloc(&sg, sizeof(union descriptor)); sa.num = 1; sap = stackgap_alloc(&sg, sizeof(struct i386_set_ldt_args)); if ((error = copyout(&sa, sap, sizeof(sa))) != 0) { printf("Cannot copyout args\n"); return error; } SCARG(&ua, op) = I386_SET_LDT; SCARG(&ua, parms) = (char *) sap; if ((error = copyout(&bsd, sa.desc, sizeof(bsd))) != 0) { printf("Cannot copyout desc\n"); return error; } return sys_sysarch(p, &ua, retval); } #endif default: printf("svr4_sysarch(%d), a1 %p\n", uap->op, uap->a1); return 0; } }