Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/drm/sis/@/ia64/ia64/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/drm/sis/@/ia64/ia64/trap.c |
/*- * Copyright (c) 2005 Marcel Moolenaar * 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. * * 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. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/ia64/ia64/trap.c 225474 2011-09-11 16:05:09Z kib $"); #include "opt_ddb.h" #include <sys/param.h> #include <sys/systm.h> #include <sys/kdb.h> #include <sys/ktr.h> #include <sys/sysproto.h> #include <sys/kernel.h> #include <sys/proc.h> #include <sys/exec.h> #include <sys/lock.h> #include <sys/mutex.h> #include <sys/sched.h> #include <sys/smp.h> #include <sys/vmmeter.h> #include <sys/sysent.h> #include <sys/signalvar.h> #include <sys/syscall.h> #include <sys/pioctl.h> #include <sys/ptrace.h> #include <sys/sysctl.h> #include <vm/vm.h> #include <vm/vm_kern.h> #include <vm/vm_page.h> #include <vm/vm_map.h> #include <vm/vm_extern.h> #include <vm/vm_param.h> #include <sys/ptrace.h> #include <machine/cpu.h> #include <machine/md_var.h> #include <machine/reg.h> #include <machine/pal.h> #include <machine/fpu.h> #include <machine/efi.h> #include <machine/pcb.h> #ifdef SMP #include <machine/smp.h> #endif #include <security/audit/audit.h> #include <ia64/disasm/disasm.h> static int print_usertrap = 0; SYSCTL_INT(_machdep, OID_AUTO, print_usertrap, CTLFLAG_RW, &print_usertrap, 0, ""); static void break_syscall(struct trapframe *tf); /* * EFI-Provided FPSWA interface (Floating Point SoftWare Assist) */ extern struct fpswa_iface *fpswa_iface; static const char *ia64_vector_names[] = { "VHPT Translation", /* 0 */ "Instruction TLB", /* 1 */ "Data TLB", /* 2 */ "Alternate Instruction TLB", /* 3 */ "Alternate Data TLB", /* 4 */ "Data Nested TLB", /* 5 */ "Instruction Key Miss", /* 6 */ "Data Key Miss", /* 7 */ "Dirty-Bit", /* 8 */ "Instruction Access-Bit", /* 9 */ "Data Access-Bit", /* 10 */ "Break Instruction", /* 11 */ "External Interrupt", /* 12 */ "Reserved 13", /* 13 */ "Reserved 14", /* 14 */ "Reserved 15", /* 15 */ "Reserved 16", /* 16 */ "Reserved 17", /* 17 */ "Reserved 18", /* 18 */ "Reserved 19", /* 19 */ "Page Not Present", /* 20 */ "Key Permission", /* 21 */ "Instruction Access Rights", /* 22 */ "Data Access Rights", /* 23 */ "General Exception", /* 24 */ "Disabled FP-Register", /* 25 */ "NaT Consumption", /* 26 */ "Speculation", /* 27 */ "Reserved 28", /* 28 */ "Debug", /* 29 */ "Unaligned Reference", /* 30 */ "Unsupported Data Reference", /* 31 */ "Floating-point Fault", /* 32 */ "Floating-point Trap", /* 33 */ "Lower-Privilege Transfer Trap", /* 34 */ "Taken Branch Trap", /* 35 */ "Single Step Trap", /* 36 */ "Reserved 37", /* 37 */ "Reserved 38", /* 38 */ "Reserved 39", /* 39 */ "Reserved 40", /* 40 */ "Reserved 41", /* 41 */ "Reserved 42", /* 42 */ "Reserved 43", /* 43 */ "Reserved 44", /* 44 */ "IA-32 Exception", /* 45 */ "IA-32 Intercept", /* 46 */ "IA-32 Interrupt", /* 47 */ "Reserved 48", /* 48 */ "Reserved 49", /* 49 */ "Reserved 50", /* 50 */ "Reserved 51", /* 51 */ "Reserved 52", /* 52 */ "Reserved 53", /* 53 */ "Reserved 54", /* 54 */ "Reserved 55", /* 55 */ "Reserved 56", /* 56 */ "Reserved 57", /* 57 */ "Reserved 58", /* 58 */ "Reserved 59", /* 59 */ "Reserved 60", /* 60 */ "Reserved 61", /* 61 */ "Reserved 62", /* 62 */ "Reserved 63", /* 63 */ "Reserved 64", /* 64 */ "Reserved 65", /* 65 */ "Reserved 66", /* 66 */ "Reserved 67", /* 67 */ }; struct bitname { uint64_t mask; const char* name; }; static void printbits(uint64_t mask, struct bitname *bn, int count) { int i, first = 1; uint64_t bit; for (i = 0; i < count; i++) { /* * Handle fields wider than one bit. */ bit = bn[i].mask & ~(bn[i].mask - 1); if (bn[i].mask > bit) { if (first) first = 0; else printf(","); printf("%s=%ld", bn[i].name, (mask & bn[i].mask) / bit); } else if (mask & bit) { if (first) first = 0; else printf(","); printf("%s", bn[i].name); } } } struct bitname psr_bits[] = { {IA64_PSR_BE, "be"}, {IA64_PSR_UP, "up"}, {IA64_PSR_AC, "ac"}, {IA64_PSR_MFL, "mfl"}, {IA64_PSR_MFH, "mfh"}, {IA64_PSR_IC, "ic"}, {IA64_PSR_I, "i"}, {IA64_PSR_PK, "pk"}, {IA64_PSR_DT, "dt"}, {IA64_PSR_DFL, "dfl"}, {IA64_PSR_DFH, "dfh"}, {IA64_PSR_SP, "sp"}, {IA64_PSR_PP, "pp"}, {IA64_PSR_DI, "di"}, {IA64_PSR_SI, "si"}, {IA64_PSR_DB, "db"}, {IA64_PSR_LP, "lp"}, {IA64_PSR_TB, "tb"}, {IA64_PSR_RT, "rt"}, {IA64_PSR_CPL, "cpl"}, {IA64_PSR_IS, "is"}, {IA64_PSR_MC, "mc"}, {IA64_PSR_IT, "it"}, {IA64_PSR_ID, "id"}, {IA64_PSR_DA, "da"}, {IA64_PSR_DD, "dd"}, {IA64_PSR_SS, "ss"}, {IA64_PSR_RI, "ri"}, {IA64_PSR_ED, "ed"}, {IA64_PSR_BN, "bn"}, {IA64_PSR_IA, "ia"}, }; static void printpsr(uint64_t psr) { printbits(psr, psr_bits, sizeof(psr_bits)/sizeof(psr_bits[0])); } struct bitname isr_bits[] = { {IA64_ISR_CODE, "code"}, {IA64_ISR_VECTOR, "vector"}, {IA64_ISR_X, "x"}, {IA64_ISR_W, "w"}, {IA64_ISR_R, "r"}, {IA64_ISR_NA, "na"}, {IA64_ISR_SP, "sp"}, {IA64_ISR_RS, "rs"}, {IA64_ISR_IR, "ir"}, {IA64_ISR_NI, "ni"}, {IA64_ISR_SO, "so"}, {IA64_ISR_EI, "ei"}, {IA64_ISR_ED, "ed"}, }; static void printisr(uint64_t isr) { printbits(isr, isr_bits, sizeof(isr_bits)/sizeof(isr_bits[0])); } static void printtrap(int vector, struct trapframe *tf, int isfatal, int user) { printf("\n"); printf("%s %s trap (cpu %d):\n", isfatal? "fatal" : "handled", user ? "user" : "kernel", PCPU_GET(cpuid)); printf("\n"); printf(" trap vector = 0x%x (%s)\n", vector, ia64_vector_names[vector]); printf(" cr.iip = 0x%lx\n", tf->tf_special.iip); printf(" cr.ipsr = 0x%lx (", tf->tf_special.psr); printpsr(tf->tf_special.psr); printf(")\n"); printf(" cr.isr = 0x%lx (", tf->tf_special.isr); printisr(tf->tf_special.isr); printf(")\n"); printf(" cr.ifa = 0x%lx\n", tf->tf_special.ifa); if (tf->tf_special.psr & IA64_PSR_IS) { printf(" ar.cflg = 0x%lx\n", ia64_get_cflg()); printf(" ar.csd = 0x%lx\n", ia64_get_csd()); printf(" ar.ssd = 0x%lx\n", ia64_get_ssd()); } printf(" curthread = %p\n", curthread); if (curthread != NULL) printf(" pid = %d, comm = %s\n", curthread->td_proc->p_pid, curthread->td_name); printf("\n"); } /* * We got a trap caused by a break instruction and the immediate was 0. * This indicates that we may have a break.b with some non-zero immediate. * The break.b doesn't cause the immediate to be put in cr.iim. Hence, * we need to disassemble the bundle and return the immediate found there. * This may be a 0 value anyway. Return 0 for any error condition. This * will result in a SIGILL, which is pretty much the best thing to do. */ static uint64_t trap_decode_break(struct trapframe *tf) { struct asm_bundle bundle; struct asm_inst *inst; int slot; if (!asm_decode(tf->tf_special.iip, &bundle)) return (0); slot = ((tf->tf_special.psr & IA64_PSR_RI) == IA64_PSR_RI_0) ? 0 : ((tf->tf_special.psr & IA64_PSR_RI) == IA64_PSR_RI_1) ? 1 : 2; inst = bundle.b_inst + slot; /* * Sanity checking: It must be a break instruction and the operand * that has the break value must be an immediate. */ if (inst->i_op != ASM_OP_BREAK || inst->i_oper[1].o_type != ASM_OPER_IMM) return (0); return (inst->i_oper[1].o_value); } void trap_panic(int vector, struct trapframe *tf) { printtrap(vector, tf, 1, TRAPF_USERMODE(tf)); #ifdef KDB kdb_trap(vector, 0, tf); #endif panic("trap"); } /* * */ int do_ast(struct trapframe *tf) { ia64_disable_intr(); while (curthread->td_flags & (TDF_ASTPENDING|TDF_NEEDRESCHED)) { ia64_enable_intr(); ast(tf); ia64_disable_intr(); } /* * Keep interrupts disabled. We return r10 as a favor to the EPC * syscall code so that it can quicky determine if the syscall * needs to be restarted or not. */ return (tf->tf_scratch.gr10); } /* * Trap is called from exception.s to handle most types of processor traps. */ /*ARGSUSED*/ void trap(int vector, struct trapframe *tf) { struct proc *p; struct thread *td; uint64_t ucode; int error, sig, user; ksiginfo_t ksi; user = TRAPF_USERMODE(tf) ? 1 : 0; PCPU_INC(cnt.v_trap); td = curthread; p = td->td_proc; ucode = 0; if (user) { ia64_set_fpsr(IA64_FPSR_DEFAULT); td->td_pticks = 0; td->td_frame = tf; if (td->td_ucred != p->p_ucred) cred_update_thread(td); } else { KASSERT(cold || td->td_ucred != NULL, ("kernel trap doesn't have ucred")); #ifdef KDB if (kdb_active) kdb_reenter(); #endif } sig = 0; switch (vector) { case IA64_VEC_VHPT: /* * This one is tricky. We should hardwire the VHPT, but * don't at this time. I think we're mostly lucky that * the VHPT is mapped. */ trap_panic(vector, tf); break; case IA64_VEC_ITLB: case IA64_VEC_DTLB: case IA64_VEC_EXT_INTR: /* We never call trap() with these vectors. */ trap_panic(vector, tf); break; case IA64_VEC_ALT_ITLB: case IA64_VEC_ALT_DTLB: /* * These should never happen, because regions 0-4 use the * VHPT. If we get one of these it means we didn't program * the region registers correctly. */ trap_panic(vector, tf); break; case IA64_VEC_NESTED_DTLB: /* * When the nested TLB handler encounters an unexpected * condition, it'll switch to the backup stack and transfer * here. All we need to do is panic. */ trap_panic(vector, tf); break; case IA64_VEC_IKEY_MISS: case IA64_VEC_DKEY_MISS: case IA64_VEC_KEY_PERMISSION: /* * We don't use protection keys, so we should never get * these faults. */ trap_panic(vector, tf); break; case IA64_VEC_DIRTY_BIT: case IA64_VEC_INST_ACCESS: case IA64_VEC_DATA_ACCESS: /* * We get here if we read or write to a page of which the * PTE does not have the access bit or dirty bit set and * we can not find the PTE in our datastructures. This * either means we have a stale PTE in the TLB, or we lost * the PTE in our datastructures. */ trap_panic(vector, tf); break; case IA64_VEC_BREAK: if (user) { ucode = (int)tf->tf_special.ifa & 0x1FFFFF; if (ucode == 0) { /* * A break.b doesn't cause the immediate to be * stored in cr.iim (and saved in the TF in * tf_special.ifa). We need to decode the * instruction to find out what the immediate * was. Note that if the break instruction * didn't happen to be a break.b, but any * other break with an immediate of 0, we * will do unnecessary work to get the value * we already had. Not an issue, because a * break 0 is invalid. */ ucode = trap_decode_break(tf); } if (ucode < 0x80000) { /* Software interrupts. */ switch (ucode) { case 0: /* Unknown error. */ sig = SIGILL; break; case 1: /* Integer divide by zero. */ sig = SIGFPE; ucode = FPE_INTDIV; break; case 2: /* Integer overflow. */ sig = SIGFPE; ucode = FPE_INTOVF; break; case 3: /* Range check/bounds check. */ sig = SIGFPE; ucode = FPE_FLTSUB; break; case 6: /* Decimal overflow. */ case 7: /* Decimal divide by zero. */ case 8: /* Packed decimal error. */ case 9: /* Invalid ASCII digit. */ case 10: /* Invalid decimal digit. */ sig = SIGFPE; ucode = FPE_FLTINV; break; case 4: /* Null pointer dereference. */ case 5: /* Misaligned data. */ case 11: /* Paragraph stack overflow. */ sig = SIGSEGV; break; default: sig = SIGILL; break; } } else if (ucode < 0x100000) { /* Debugger breakpoint. */ tf->tf_special.psr &= ~IA64_PSR_SS; sig = SIGTRAP; } else if (ucode == 0x100000) { break_syscall(tf); return; /* do_ast() already called. */ } else if (ucode == 0x180000) { mcontext_t mc; error = copyin((void*)tf->tf_scratch.gr8, &mc, sizeof(mc)); if (!error) { set_mcontext(td, &mc); return; /* Don't call do_ast()!!! */ } sig = SIGSEGV; ucode = tf->tf_scratch.gr8; } else sig = SIGILL; } else { #ifdef KDB if (kdb_trap(vector, 0, tf)) return; panic("trap"); #else trap_panic(vector, tf); #endif } break; case IA64_VEC_PAGE_NOT_PRESENT: case IA64_VEC_INST_ACCESS_RIGHTS: case IA64_VEC_DATA_ACCESS_RIGHTS: { vm_offset_t va; struct vmspace *vm; vm_map_t map; vm_prot_t ftype; int rv; rv = 0; va = trunc_page(tf->tf_special.ifa); if (va >= VM_MAXUSER_ADDRESS) { /* * Don't allow user-mode faults for kernel virtual * addresses, including the gateway page. */ if (user) goto no_fault_in; map = kernel_map; } else { vm = (p != NULL) ? p->p_vmspace : NULL; if (vm == NULL) goto no_fault_in; map = &vm->vm_map; } if (tf->tf_special.isr & IA64_ISR_X) ftype = VM_PROT_EXECUTE; else if (tf->tf_special.isr & IA64_ISR_W) ftype = VM_PROT_WRITE; else ftype = VM_PROT_READ; if (map != kernel_map) { /* * Keep swapout from messing with us during this * critical time. */ PROC_LOCK(p); ++p->p_lock; PROC_UNLOCK(p); /* Fault in the user page: */ rv = vm_fault(map, va, ftype, VM_FAULT_NORMAL); PROC_LOCK(p); --p->p_lock; PROC_UNLOCK(p); } else { /* * Don't have to worry about process locking or * stacks in the kernel. */ rv = vm_fault(map, va, ftype, VM_FAULT_NORMAL); } if (rv == KERN_SUCCESS) goto out; no_fault_in: if (!user) { /* Check for copyin/copyout fault. */ if (td != NULL && td->td_pcb->pcb_onfault != 0) { tf->tf_special.iip = td->td_pcb->pcb_onfault; tf->tf_special.psr &= ~IA64_PSR_RI; td->td_pcb->pcb_onfault = 0; goto out; } trap_panic(vector, tf); } ucode = va; sig = (rv == KERN_PROTECTION_FAILURE) ? SIGBUS : SIGSEGV; break; } case IA64_VEC_GENERAL_EXCEPTION: { int code; if (!user) trap_panic(vector, tf); code = tf->tf_special.isr & (IA64_ISR_CODE & 0xf0ull); switch (code) { case 0x0: /* Illegal Operation Fault. */ sig = ia64_emulate(tf, td); break; default: sig = SIGILL; break; } if (sig == 0) goto out; ucode = vector; break; } case IA64_VEC_SPECULATION: /* * The branching behaviour of the chk instruction is not * implemented by the processor. All we need to do is * compute the target address of the branch and make sure * that control is transfered to that address. * We should do this in the IVT table and not by entring * the kernel... */ tf->tf_special.iip += tf->tf_special.ifa << 4; tf->tf_special.psr &= ~IA64_PSR_RI; goto out; case IA64_VEC_NAT_CONSUMPTION: case IA64_VEC_UNSUPP_DATA_REFERENCE: if (user) { ucode = vector; sig = SIGILL; } else trap_panic(vector, tf); break; case IA64_VEC_DISABLED_FP: { if (user) ia64_highfp_enable(td, tf); else trap_panic(vector, tf); goto out; } case IA64_VEC_DEBUG: case IA64_VEC_SINGLE_STEP_TRAP: tf->tf_special.psr &= ~IA64_PSR_SS; if (!user) { #ifdef KDB if (kdb_trap(vector, 0, tf)) return; panic("trap"); #else trap_panic(vector, tf); #endif } sig = SIGTRAP; break; case IA64_VEC_UNALIGNED_REFERENCE: /* * If user-land, do whatever fixups, printing, and * signalling is appropriate (based on system-wide * and per-process unaligned-access-handling flags). */ if (user) { sig = unaligned_fixup(tf, td); if (sig == 0) goto out; ucode = tf->tf_special.ifa; /* VA */ } else { /* Check for copyin/copyout fault. */ if (td != NULL && td->td_pcb->pcb_onfault != 0) { tf->tf_special.iip = td->td_pcb->pcb_onfault; tf->tf_special.psr &= ~IA64_PSR_RI; td->td_pcb->pcb_onfault = 0; goto out; } trap_panic(vector, tf); } break; case IA64_VEC_FLOATING_POINT_FAULT: case IA64_VEC_FLOATING_POINT_TRAP: { struct fpswa_bundle bundle; struct fpswa_fpctx fpctx; struct fpswa_ret ret; char *ip; u_long fault; /* Always fatal in kernel. Should never happen. */ if (!user) trap_panic(vector, tf); if (fpswa_iface == NULL) { sig = SIGFPE; ucode = 0; break; } ip = (char *)tf->tf_special.iip; if (vector == IA64_VEC_FLOATING_POINT_TRAP && (tf->tf_special.psr & IA64_PSR_RI) == 0) ip -= 16; error = copyin(ip, &bundle, sizeof(bundle)); if (error) { sig = SIGBUS; /* EFAULT, basically */ ucode = 0; /* exception summary */ break; } /* f6-f15 are saved in exception_save */ fpctx.mask_low = 0xffc0; /* bits 6 - 15 */ fpctx.mask_high = 0; fpctx.fp_low_preserved = NULL; fpctx.fp_low_volatile = &tf->tf_scratch_fp.fr6; fpctx.fp_high_preserved = NULL; fpctx.fp_high_volatile = NULL; fault = (vector == IA64_VEC_FLOATING_POINT_FAULT) ? 1 : 0; /* * We have the high FP registers disabled while in the * kernel. Enable them for the FPSWA handler only. */ ia64_enable_highfp(); /* The docs are unclear. Is Fpswa reentrant? */ ret = fpswa_iface->if_fpswa(fault, &bundle, &tf->tf_special.psr, &tf->tf_special.fpsr, &tf->tf_special.isr, &tf->tf_special.pr, &tf->tf_special.cfm, &fpctx); ia64_disable_highfp(); /* * Update ipsr and iip to next instruction. We only * have to do that for faults. */ if (fault && (ret.status == 0 || (ret.status & 2))) { int ei; ei = (tf->tf_special.isr >> 41) & 0x03; if (ei == 0) { /* no template for this case */ tf->tf_special.psr &= ~IA64_ISR_EI; tf->tf_special.psr |= IA64_ISR_EI_1; } else if (ei == 1) { /* MFI or MFB */ tf->tf_special.psr &= ~IA64_ISR_EI; tf->tf_special.psr |= IA64_ISR_EI_2; } else if (ei == 2) { /* MMF */ tf->tf_special.psr &= ~IA64_ISR_EI; tf->tf_special.iip += 0x10; } } if (ret.status == 0) { goto out; } else if (ret.status == -1) { printf("FATAL: FPSWA err1 %lx, err2 %lx, err3 %lx\n", ret.err1, ret.err2, ret.err3); panic("fpswa fatal error on fp fault"); } else { sig = SIGFPE; ucode = 0; /* XXX exception summary */ break; } } case IA64_VEC_LOWER_PRIVILEGE_TRANSFER: /* * The lower-privilege transfer trap is used by the EPC * syscall code to trigger re-entry into the kernel when the * process should be single stepped. The problem is that * there's no way to set single stepping directly without * using the rfi instruction. So instead we enable the * lower-privilege transfer trap and when we get here we * know that the process is about to enter userland (and * has already lowered its privilege). * However, there's another gotcha. When the process has * lowered it's privilege it's still running in the gateway * page. If we enable single stepping, we'll be stepping * the code in the gateway page. In and by itself this is * not a problem, but it's an address debuggers won't know * anything about. Hence, it can only cause confusion. * We know that we need to branch to get out of the gateway * page, so what we do here is enable the taken branch * trap and just let the process continue. When we branch * out of the gateway page we'll get back into the kernel * and then we enable single stepping. * Since this a rather round-about way of enabling single * stepping, don't make things even more complicated by * calling userret() and do_ast(). We do that later... */ tf->tf_special.psr &= ~IA64_PSR_LP; tf->tf_special.psr |= IA64_PSR_TB; return; case IA64_VEC_TAKEN_BRANCH_TRAP: /* * Don't assume there aren't any branches other than the * branch that takes us out of the gateway page. Check the * iip and enable single stepping only when it's an user * address. */ if (tf->tf_special.iip >= VM_MAXUSER_ADDRESS) return; tf->tf_special.psr &= ~IA64_PSR_TB; tf->tf_special.psr |= IA64_PSR_SS; return; case IA64_VEC_IA32_EXCEPTION: case IA64_VEC_IA32_INTERCEPT: case IA64_VEC_IA32_INTERRUPT: sig = SIGEMT; ucode = tf->tf_special.iip; break; default: /* Reserved vectors get here. Should never happen of course. */ trap_panic(vector, tf); break; } KASSERT(sig != 0, ("foo")); if (print_usertrap) printtrap(vector, tf, 1, user); ksiginfo_init(&ksi); ksi.ksi_signo = sig; ksi.ksi_code = ucode; trapsignal(td, &ksi); out: if (user) { userret(td, tf); mtx_assert(&Giant, MA_NOTOWNED); do_ast(tf); } return; } /* * Handle break instruction based system calls. */ void break_syscall(struct trapframe *tf) { uint64_t *bsp, *tfp; uint64_t iip, psr; int error, nargs; /* Save address of break instruction. */ iip = tf->tf_special.iip; psr = tf->tf_special.psr; /* Advance to the next instruction. */ tf->tf_special.psr += IA64_PSR_RI_1; if ((tf->tf_special.psr & IA64_PSR_RI) > IA64_PSR_RI_2) { tf->tf_special.iip += 16; tf->tf_special.psr &= ~IA64_PSR_RI; } /* * Copy the arguments on the register stack into the trapframe * to avoid having interleaved NaT collections. */ tfp = &tf->tf_scratch.gr16; nargs = tf->tf_special.cfm & 0x7f; bsp = (uint64_t*)(curthread->td_kstack + tf->tf_special.ndirty + (tf->tf_special.bspstore & 0x1ffUL)); bsp -= (((uintptr_t)bsp & 0x1ff) < (nargs << 3)) ? (nargs + 1): nargs; while (nargs--) { *tfp++ = *bsp++; if (((uintptr_t)bsp & 0x1ff) == 0x1f8) bsp++; } error = syscall(tf); if (error == ERESTART) { tf->tf_special.iip = iip; tf->tf_special.psr = psr; } do_ast(tf); } int cpu_fetch_syscall_args(struct thread *td, struct syscall_args *sa) { struct proc *p; struct trapframe *tf; p = td->td_proc; tf = td->td_frame; sa->code = tf->tf_scratch.gr15; sa->args = &tf->tf_scratch.gr16; /* * syscall() and __syscall() are handled the same on * the ia64, as everything is 64-bit aligned, anyway. */ if (sa->code == SYS_syscall || sa->code == SYS___syscall) { /* * Code is first argument, followed by actual args. */ sa->code = sa->args[0]; sa->args++; } if (p->p_sysent->sv_mask) sa->code &= p->p_sysent->sv_mask; if (sa->code >= p->p_sysent->sv_size) sa->callp = &p->p_sysent->sv_table[0]; else sa->callp = &p->p_sysent->sv_table[sa->code]; sa->narg = sa->callp->sy_narg; td->td_retval[0] = 0; td->td_retval[1] = 0; return (0); } #include "../../kern/subr_syscall.c" /* * Process a system call. * * See syscall.s for details as to how we get here. In order to support * the ERESTART case, we return the error to our caller. They deal with * the hairy details. */ int syscall(struct trapframe *tf) { struct syscall_args sa; struct thread *td; int error; td = curthread; td->td_frame = tf; ia64_set_fpsr(IA64_FPSR_DEFAULT); tf->tf_scratch.gr10 = EJUSTRETURN; error = syscallenter(td, &sa); syscallret(td, error, &sa); return (error); }