hppa/hppa/trap.c

1.46        ad /*	$NetBSD: trap.c,v 1.46 2007/08/15 12:07:24 ad Exp $	*/
 1.1  fredette
 1.1  fredette /*-
 1.1  fredette  * Copyright (c) 2001, 2002 The NetBSD Foundation, Inc.
 1.1  fredette  * All rights reserved.
 1.1  fredette  *
 1.1  fredette  * This code is derived from software contributed to The NetBSD Foundation
 1.1  fredette  * by Matthew Fredette.
 1.1  fredette  *
 1.1  fredette  * Redistribution and use in source and binary forms, with or without
 1.1  fredette  * modification, are permitted provided that the following conditions
 1.1  fredette  * are met:
 1.1  fredette  * 1. Redistributions of source code must retain the above copyright
 1.1  fredette  *    notice, this list of conditions and the following disclaimer.
 1.1  fredette  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  fredette  *    notice, this list of conditions and the following disclaimer in the
 1.1  fredette  *    documentation and/or other materials provided with the distribution.
 1.1  fredette  * 3. All advertising materials mentioning features or use of this software
 1.1  fredette  *    must display the following acknowledgement:
 1.1  fredette  *      This product includes software developed by the NetBSD
 1.1  fredette  *      Foundation, Inc. and its contributors.
 1.1  fredette  * 4. Neither the name of The NetBSD Foundation nor the names of its
 1.1  fredette  *    contributors may be used to endorse or promote products derived
 1.1  fredette  *    from this software without specific prior written permission.
 1.1  fredette  *
 1.1  fredette  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
 1.1  fredette  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
 1.1  fredette  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
 1.1  fredette  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
 1.1  fredette  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 1.1  fredette  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 1.1  fredette  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 1.1  fredette  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 1.1  fredette  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 1.1  fredette  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 1.1  fredette  * POSSIBILITY OF SUCH DAMAGE.
 1.1  fredette  */
 1.1  fredette
 1.1  fredette /*	$OpenBSD: trap.c,v 1.30 2001/09/19 20:50:56 mickey Exp $	*/
 1.1  fredette
 1.1  fredette /*
 1.1  fredette  * Copyright (c) 1998-2000 Michael Shalayeff
 1.1  fredette  * All rights reserved.
 1.1  fredette  *
 1.1  fredette  * Redistribution and use in source and binary forms, with or without
 1.1  fredette  * modification, are permitted provided that the following conditions
 1.1  fredette  * are met:
 1.1  fredette  * 1. Redistributions of source code must retain the above copyright
 1.1  fredette  *    notice, this list of conditions and the following disclaimer.
 1.1  fredette  * 2. Redistributions in binary form must reproduce the above copyright
 1.1  fredette  *    notice, this list of conditions and the following disclaimer in the
 1.1  fredette  *    documentation and/or other materials provided with the distribution.
 1.1  fredette  * 3. All advertising materials mentioning features or use of this software
 1.1  fredette  *    must display the following acknowledgement:
 1.1  fredette  *	This product includes software developed by Michael Shalayeff.
 1.1  fredette  * 4. The name of the author may not be used to endorse or promote products
 1.1  fredette  *    derived from this software without specific prior written permission.
 1.1  fredette  *
 1.1  fredette  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
 1.1  fredette  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
 1.1  fredette  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
 1.1  fredette  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
 1.1  fredette  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
 1.1  fredette  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 1.1  fredette  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 1.1  fredette  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 1.1  fredette  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
 1.1  fredette  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 1.1  fredette  */
 1.8     lukem
 1.8     lukem #include <sys/cdefs.h>
1.46        ad __KERNEL_RCSID(0, "$NetBSD: trap.c,v 1.46 2007/08/15 12:07:24 ad Exp $");
 1.1  fredette
 1.1  fredette /* #define INTRDEBUG */
 1.1  fredette /* #define TRAPDEBUG */
 1.1  fredette /* #define USERTRACE */
 1.1  fredette
 1.1  fredette #include "opt_kgdb.h"
 1.1  fredette
 1.1  fredette #include <sys/param.h>
 1.1  fredette #include <sys/systm.h>
 1.1  fredette #include <sys/kernel.h>
 1.1  fredette #include <sys/syscall.h>
1.40        ad #include <sys/mutex.h>
 1.1  fredette #include <sys/ktrace.h>
 1.1  fredette #include <sys/proc.h>
 1.1  fredette #include <sys/signalvar.h>
 1.1  fredette #include <sys/user.h>
 1.1  fredette #include <sys/acct.h>
 1.1  fredette #include <sys/signal.h>
 1.1  fredette #include <sys/device.h>
 1.9       chs #include <sys/pool.h>
1.20       chs #include <sys/userret.h>
 1.1  fredette
 1.1  fredette #include <net/netisr.h>
 1.1  fredette
 1.1  fredette #ifdef KGDB
 1.1  fredette #include <sys/kgdb.h>
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette #include <uvm/uvm.h>
 1.1  fredette
 1.1  fredette #include <machine/iomod.h>
 1.1  fredette #include <machine/cpufunc.h>
 1.1  fredette #include <machine/reg.h>
 1.1  fredette #include <machine/autoconf.h>
 1.1  fredette
 1.1  fredette #include <machine/db_machdep.h>
 1.1  fredette
 1.1  fredette #include <hppa/hppa/machdep.h>
 1.1  fredette
 1.1  fredette #include <ddb/db_output.h>
1.19       chs #include <ddb/db_interface.h>
 1.1  fredette
 1.1  fredette #if defined(DEBUG) || defined(DIAGNOSTIC)
 1.1  fredette /*
 1.1  fredette  * 0x6fc1000 is a stwm r1, d(sr0, sp), which is the last
 1.1  fredette  * instruction in the function prologue that gcc -O0 uses.
 1.1  fredette  * When we have this instruction we know the relationship
 1.1  fredette  * between the stack pointer and the gcc -O0 frame pointer
 1.1  fredette  * (in r3, loaded with the initial sp) for the body of a
 1.1  fredette  * function.
 1.1  fredette  *
 1.1  fredette  * If the given instruction is a stwm r1, d(sr0, sp) where
 1.1  fredette  * d > 0, we evaluate to d, else we evaluate to zero.
 1.1  fredette  */
 1.1  fredette #define STWM_R1_D_SR0_SP(inst) \
 1.1  fredette 	(((inst) & 0xffffc001) == 0x6fc10000 ? (((inst) & 0x00003ff) >> 1) : 0)
 1.1  fredette #endif /* DEBUG || DIAGNOSTIC */
 1.1  fredette
 1.1  fredette const char *trap_type[] = {
 1.1  fredette 	"invalid",
 1.1  fredette 	"HPMC",
 1.1  fredette 	"power failure",
 1.1  fredette 	"recovery counter",
 1.1  fredette 	"external interrupt",
 1.1  fredette 	"LPMC",
 1.1  fredette 	"ITLB miss fault",
 1.1  fredette 	"instruction protection",
 1.1  fredette 	"Illegal instruction",
 1.1  fredette 	"break instruction",
 1.1  fredette 	"privileged operation",
 1.1  fredette 	"privileged register",
 1.1  fredette 	"overflow",
 1.1  fredette 	"conditional",
 1.1  fredette 	"assist exception",
 1.1  fredette 	"DTLB miss",
 1.1  fredette 	"ITLB non-access miss",
 1.1  fredette 	"DTLB non-access miss",
 1.1  fredette 	"data protection/rights/alignment",
 1.1  fredette 	"data break",
 1.1  fredette 	"TLB dirty",
 1.1  fredette 	"page reference",
 1.1  fredette 	"assist emulation",
 1.1  fredette 	"higher-priv transfer",
 1.1  fredette 	"lower-priv transfer",
 1.1  fredette 	"taken branch",
 1.1  fredette 	"data access rights",
 1.1  fredette 	"data protection",
 1.1  fredette 	"unaligned data ref",
 1.1  fredette };
 1.1  fredette int trap_types = sizeof(trap_type)/sizeof(trap_type[0]);
 1.1  fredette
1.23       chs uint8_t fpopmap[] = {
1.23       chs 	0x00, 0x00, 0x00, 0x06, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x0c, 0x00, 0x0e, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x26, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
1.23       chs 	0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
1.23       chs };
1.23       chs
 1.1  fredette int want_resched;
 1.1  fredette volatile int astpending;
 1.1  fredette
1.14       chs void pmap_hptdump(void);
1.14       chs void syscall(struct trapframe *, int *);
 1.1  fredette
 1.1  fredette #ifdef USERTRACE
 1.1  fredette /*
 1.1  fredette  * USERTRACE is a crude facility that traces the PC of
 1.1  fredette  * a single user process.  This tracing is normally
 1.1  fredette  * activated by the dispatching of a certain syscall
 1.1  fredette  * with certain arguments - see the activation code in
 1.1  fredette  * syscall().
 1.1  fredette  */
 1.1  fredette u_int rctr_next_iioq;
 1.1  fredette #endif
 1.1  fredette
1.30     perry static inline void
1.20       chs userret(struct lwp *l, register_t pc, u_quad_t oticks)
 1.1  fredette {
 1.9       chs 	struct proc *p = l->l_proc;
 1.1  fredette
 1.9       chs 	l->l_priority = l->l_usrpri;
 1.1  fredette 	if (want_resched) {
1.40        ad 		preempt();
 1.1  fredette 	}
 1.1  fredette
1.20       chs 	mi_userret(l);
1.20       chs
 1.1  fredette 	/*
 1.1  fredette 	 * If profiling, charge recent system time to the trapped pc.
 1.1  fredette 	 */
1.40        ad 	if (p->p_stflag & PST_PROFIL) {
 1.1  fredette 		extern int psratio;
 1.1  fredette
1.40        ad 		addupc_task(l, pc, (int)(p->p_sticks - oticks) * psratio);
 1.1  fredette 	}
 1.1  fredette
 1.9       chs 	curcpu()->ci_schedstate.spc_curpriority = l->l_priority;
 1.1  fredette }
 1.1  fredette
 1.1  fredette /*
 1.1  fredette  * This handles some messy kernel debugger details.
 1.1  fredette  * It dispatches into either kgdb or DDB, and knows
 1.1  fredette  * about some special things to do, like skipping over
 1.1  fredette  * break instructions and how to really set up for
 1.1  fredette  * a single-step.
 1.1  fredette  */
 1.1  fredette #if defined(KGDB) || defined(DDB)
 1.1  fredette static int
 1.1  fredette trap_kdebug(int type, int code, struct trapframe *frame)
 1.1  fredette {
 1.1  fredette 	int handled;
 1.1  fredette 	u_int tf_iioq_head_old;
 1.1  fredette 	u_int tf_iioq_tail_old;
 1.1  fredette
 1.1  fredette 	for(;;) {
 1.1  fredette
 1.1  fredette 		/* This trap has not been handled. */
 1.1  fredette 		handled = 0;
 1.1  fredette
 1.1  fredette 		/* Remember the instruction offset queue. */
 1.1  fredette 		tf_iioq_head_old = frame->tf_iioq_head;
 1.1  fredette 		tf_iioq_tail_old = frame->tf_iioq_tail;
 1.1  fredette
 1.1  fredette #ifdef	KGDB
 1.1  fredette 		/* Let KGDB handle it (if connected) */
 1.1  fredette 		if (!handled)
 1.1  fredette 			handled = kgdb_trap(type, frame);
 1.1  fredette #endif
 1.1  fredette #ifdef	DDB
 1.1  fredette 		/* Let DDB handle it. */
 1.1  fredette 		if (!handled)
 1.1  fredette 			handled = kdb_trap(type, code, frame);
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 		/* If this trap wasn't handled, return now. */
 1.1  fredette 		if (!handled)
 1.1  fredette 			return(0);
 1.1  fredette
 1.1  fredette 		/*
 1.1  fredette 		 * If the instruction offset queue head changed,
 1.1  fredette 		 * but the offset queue tail didn't, assume that
 1.1  fredette 		 * the user wants to jump to the head offset, and
 1.1  fredette 		 * adjust the tail accordingly.  This should fix
 1.1  fredette 		 * the kgdb `jump' command, and can help DDB users
 1.1  fredette 		 * who `set' the offset head but forget the tail.
 1.1  fredette 		 */
 1.1  fredette 		if (frame->tf_iioq_head != tf_iioq_head_old &&
 1.1  fredette 		    frame->tf_iioq_tail == tf_iioq_tail_old)
 1.1  fredette 			frame->tf_iioq_tail = frame->tf_iioq_head + 4;
 1.1  fredette
 1.1  fredette 		/*
 1.1  fredette 		 * This is some single-stepping support.
 1.1  fredette 		 * If we're trying to step through a nullified
 1.1  fredette 		 * instruction, just advance by hand and trap
 1.1  fredette 		 * again.  Otherwise, load the recovery counter
 1.1  fredette 		 * with zero.
 1.1  fredette 		 */
 1.1  fredette 		if (frame->tf_ipsw & PSW_R) {
 1.1  fredette #ifdef TRAPDEBUG
1.44     skrll 			printf("(single stepping at head 0x%x tail 0x%x)\n",
1.44     skrll 			    frame->tf_iioq_head, frame->tf_iioq_tail);
 1.1  fredette #endif
 1.1  fredette 			if (frame->tf_ipsw & PSW_N) {
 1.1  fredette #ifdef TRAPDEBUG
 1.1  fredette 				printf("(single stepping past nullified)\n");
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 				/* Advance the program counter. */
 1.1  fredette 				frame->tf_iioq_head = frame->tf_iioq_tail;
 1.1  fredette 				frame->tf_iioq_tail = frame->tf_iioq_head + 4;
 1.1  fredette
 1.1  fredette 				/* Clear flags. */
 1.1  fredette 				frame->tf_ipsw &= ~(PSW_N|PSW_X|PSW_Y|PSW_Z|PSW_B|PSW_T|PSW_H|PSW_L);
 1.1  fredette
 1.1  fredette 				/* Simulate another trap. */
 1.1  fredette 				type = T_RECOVERY;
 1.1  fredette 				continue;
 1.1  fredette 			}
 1.1  fredette 			frame->tf_rctr = 0;
 1.1  fredette 		}
 1.1  fredette
 1.1  fredette 		/* We handled this trap. */
 1.1  fredette 		return (1);
 1.1  fredette 	}
 1.1  fredette 	/* NOTREACHED */
 1.1  fredette }
 1.1  fredette #else	/* !KGDB && !DDB */
 1.1  fredette #define trap_kdebug(t, c, f)	(0)
 1.1  fredette #endif	/* !KGDB && !DDB */
 1.1  fredette
1.24   tsutsui #if defined(DEBUG) || defined(USERTRACE)
 1.1  fredette /*
 1.1  fredette  * These functions give a crude usermode backtrace.  They
 1.1  fredette  * really only work when code has been compiled without
 1.1  fredette  * optimization, as they assume a certain function prologue
 1.1  fredette  * sets up a frame pointer and stores the return pointer
 1.1  fredette  * and arguments in it.
 1.1  fredette  */
1.14       chs static void user_backtrace_raw(u_int, u_int);
 1.1  fredette static void
 1.1  fredette user_backtrace_raw(u_int pc, u_int fp)
 1.1  fredette {
 1.1  fredette 	int frame_number;
 1.1  fredette 	int arg_number;
 1.1  fredette
 1.3  fredette 	for (frame_number = 0;
 1.3  fredette 	     frame_number < 100 && pc > HPPA_PC_PRIV_MASK && fp;
 1.3  fredette 	     frame_number++) {
 1.3  fredette
 1.1  fredette 		printf("%3d: pc=%08x%s fp=0x%08x", frame_number,
1.44     skrll 		    pc & ~HPPA_PC_PRIV_MASK, USERMODE(pc) ? "  " : "**", fp);
 1.1  fredette 		for(arg_number = 0; arg_number < 4; arg_number++)
 1.1  fredette 			printf(" arg%d=0x%08x", arg_number,
 1.1  fredette 			    (int) fuword(HPPA_FRAME_CARG(arg_number, fp)));
 1.1  fredette 		printf("\n");
 1.1  fredette                 pc = fuword(((register_t *) fp) - 5);	/* fetch rp */
 1.1  fredette 		if (pc == -1) {
 1.1  fredette 			printf("  fuword for pc failed\n");
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette                 fp = fuword(((register_t *) fp) + 0);	/* fetch previous fp */
 1.1  fredette 		if (fp == -1) {
 1.1  fredette 			printf("  fuword for fp failed\n");
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette 	}
 1.1  fredette 	printf("  backtrace stopped with pc %08x fp 0x%08x\n", pc, fp);
 1.1  fredette }
 1.1  fredette
1.14       chs static void user_backtrace(struct trapframe *, struct lwp *, int);
 1.1  fredette static void
 1.9       chs user_backtrace(struct trapframe *tf, struct lwp *l, int type)
 1.1  fredette {
 1.9       chs 	struct proc *p = l->l_proc;
 1.1  fredette 	u_int pc, fp, inst;
 1.1  fredette
 1.1  fredette 	/*
 1.3  fredette 	 * Display any trap type that we have.
 1.3  fredette 	 */
 1.3  fredette 	if (type >= 0)
 1.3  fredette 		printf("pid %d (%s) trap #%d\n",
 1.3  fredette 		    p->p_pid, p->p_comm, type & ~T_USER);
 1.3  fredette
 1.3  fredette 	/*
 1.1  fredette 	 * Assuming that the frame pointer in r3 is valid,
 1.1  fredette 	 * dump out a stack trace.
 1.1  fredette 	 */
 1.1  fredette 	fp = tf->tf_r3;
 1.1  fredette 	printf("pid %d (%s) backtrace, starting with fp 0x%08x\n",
 1.1  fredette 		p->p_pid, p->p_comm, fp);
 1.1  fredette 	user_backtrace_raw(tf->tf_iioq_head, fp);
 1.1  fredette
 1.1  fredette 	/*
 1.1  fredette 	 * In case the frame pointer in r3 is not valid,
 1.1  fredette 	 * assuming the stack pointer is valid and the
 1.1  fredette 	 * faulting function is a non-leaf, if we can
 1.1  fredette 	 * find its prologue we can recover its frame
 1.1  fredette 	 * pointer.
 1.1  fredette 	 */
 1.1  fredette 	pc = tf->tf_iioq_head;
 1.1  fredette 	fp = tf->tf_sp - HPPA_FRAME_SIZE;
 1.1  fredette 	printf("pid %d (%s) backtrace, starting with sp 0x%08x pc 0x%08x\n",
 1.1  fredette 		p->p_pid, p->p_comm, tf->tf_sp, pc);
1.44     skrll 	for (pc &= ~HPPA_PC_PRIV_MASK; pc > 0; pc -= sizeof(inst)) {
 1.1  fredette 		inst = fuword((register_t *) pc);
 1.1  fredette 		if (inst == -1) {
 1.1  fredette 			printf("  fuword for inst at pc %08x failed\n", pc);
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette 		/* Check for the prologue instruction that sets sp. */
 1.1  fredette 		if (STWM_R1_D_SR0_SP(inst)) {
 1.1  fredette 			fp = tf->tf_sp - STWM_R1_D_SR0_SP(inst);
 1.1  fredette 			printf("  sp from fp at pc %08x: %08x\n", pc, inst);
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette 	}
 1.1  fredette 	user_backtrace_raw(tf->tf_iioq_head, fp);
 1.1  fredette }
1.24   tsutsui #endif /* DEBUG || USERTRACE */
 1.1  fredette
 1.1  fredette #ifdef DEBUG
 1.1  fredette /*
 1.1  fredette  * This sanity-checks a trapframe.  It is full of various
 1.1  fredette  * assumptions about what a healthy CPU state should be,
 1.1  fredette  * with some documented elsewhere, some not.
 1.1  fredette  */
 1.1  fredette struct trapframe *sanity_frame;
 1.9       chs struct lwp *sanity_lwp;
 1.1  fredette int sanity_checked = 0;
1.26       chs void frame_sanity_check(int, int, struct trapframe *, struct lwp *);
 1.1  fredette void
1.26       chs frame_sanity_check(int where, int type, struct trapframe *tf, struct lwp *l)
 1.1  fredette {
 1.1  fredette 	extern int kernel_text;
 1.1  fredette 	extern int etext;
 1.1  fredette 	extern register_t kpsw;
 1.1  fredette 	extern vaddr_t hpt_base;
 1.1  fredette 	extern vsize_t hpt_mask;
 1.1  fredette #define SANITY(e)					\
 1.1  fredette do {							\
 1.1  fredette 	if (sanity_frame == NULL && !(e)) {		\
 1.1  fredette 		sanity_frame = tf;			\
 1.9       chs 		sanity_lwp = l;				\
 1.1  fredette 		sanity_checked = __LINE__;		\
 1.1  fredette 	}						\
 1.1  fredette } while (/* CONSTCOND */ 0)
 1.1  fredette
 1.1  fredette 	SANITY((tf->tf_ipsw & kpsw) == kpsw);
 1.1  fredette 	SANITY(tf->tf_hptm == hpt_mask && tf->tf_vtop == hpt_base);
 1.1  fredette 	SANITY((kpsw & PSW_I) == 0 || tf->tf_eiem != 0);
 1.1  fredette 	if (tf->tf_iisq_head == HPPA_SID_KERNEL) {
1.45     skrll 		vaddr_t minsp, maxsp;
1.45     skrll
 1.1  fredette 		/*
 1.1  fredette 		 * If the trap happened in the gateway
 1.1  fredette 		 * page, we take the easy way out and
 1.1  fredette 		 * assume that the trapframe is okay.
 1.1  fredette 		 */
1.45     skrll 		if ((tf->tf_iioq_head & ~PAGE_MASK) == SYSCALLGATE)
1.45     skrll 			goto out;
1.45     skrll
1.45     skrll 		SANITY(!USERMODE(tf->tf_iioq_head));
1.45     skrll 		SANITY(!USERMODE(tf->tf_iioq_tail));
1.45     skrll
1.45     skrll 		/*
1.45     skrll 		 * Don't check the instruction queues or stack on interrupts
1.45     skrll 		 * as we could be be in the sti code (outside normal kernel
1.45     skrll 		 * text) or switching LWPs (curlwp and sp are not in sync)
1.45     skrll 		 */
1.45     skrll 		if ((type & ~T_USER) == T_INTERRUPT)
1.45     skrll 			goto out;
1.45     skrll
1.45     skrll 		SANITY(tf->tf_iioq_head >= (u_int) &kernel_text);
1.45     skrll 		SANITY(tf->tf_iioq_head < (u_int) &etext);
1.45     skrll 		SANITY(tf->tf_iioq_tail >= (u_int) &kernel_text);
1.45     skrll 		SANITY(tf->tf_iioq_tail < (u_int) &etext);
1.43      yamt
 1.1  fredette #ifdef HPPA_REDZONE
1.45     skrll 		maxsp = (u_int)(l->l_addr) + HPPA_REDZONE;
 1.1  fredette #else
1.45     skrll 		maxsp = (u_int)(l->l_addr) + USPACE;
 1.1  fredette #endif
1.45     skrll 		minsp = (u_int)(l->l_addr) + PAGE_SIZE;
1.43      yamt
1.45     skrll 		SANITY(l != NULL || (tf->tf_sp >= minsp && tf->tf_sp < maxsp));
 1.1  fredette 	} else {
 1.1  fredette 		SANITY(USERMODE(tf->tf_iioq_head));
 1.1  fredette 		SANITY(USERMODE(tf->tf_iioq_tail));
1.42  christos 		SANITY(l != NULL && tf->tf_cr30 == kvtop((void *)l->l_addr));
 1.1  fredette 	}
 1.1  fredette #undef SANITY
1.45     skrll out:
 1.1  fredette 	if (sanity_frame == tf) {
1.26       chs 		printf("insanity: where 0x%x type 0x%x tf %p lwp %p line %d "
1.26       chs 		       "sp 0x%x pc 0x%x\n",
1.26       chs 		       where, type, sanity_frame, sanity_lwp, sanity_checked,
1.22       chs 		       tf->tf_sp, tf->tf_iioq_head);
 1.4  fredette 		(void) trap_kdebug(T_IBREAK, 0, tf);
 1.1  fredette 		sanity_frame = NULL;
 1.9       chs 		sanity_lwp = NULL;
 1.1  fredette 		sanity_checked = 0;
 1.1  fredette 	}
 1.1  fredette }
 1.1  fredette #endif /* DEBUG */
 1.1  fredette
 1.1  fredette void
1.14       chs trap(int type, struct trapframe *frame)
 1.1  fredette {
1.13   tsutsui 	struct lwp *l;
1.13   tsutsui 	struct proc *p;
 1.1  fredette 	struct pcb *pcbp;
 1.9       chs 	vaddr_t va;
 1.9       chs 	struct vm_map *map;
 1.1  fredette 	struct vmspace *vm;
 1.9       chs 	vm_prot_t vftype;
 1.9       chs 	pa_space_t space;
1.22       chs 	ksiginfo_t ksi;
1.19       chs 	u_int opcode, onfault;
 1.1  fredette 	int ret;
 1.1  fredette 	const char *tts;
 1.1  fredette 	int type_raw;
 1.1  fredette #ifdef DIAGNOSTIC
 1.1  fredette 	extern int emergency_stack_start, emergency_stack_end;
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 	type_raw = type & ~T_USER;
 1.1  fredette 	opcode = frame->tf_iir;
 1.1  fredette 	if (type_raw == T_ITLBMISS || type_raw == T_ITLBMISSNA) {
 1.1  fredette 		va = frame->tf_iioq_head;
 1.1  fredette 		space = frame->tf_iisq_head;
1.17       chs 		vftype = VM_PROT_EXECUTE;
 1.1  fredette 	} else {
 1.1  fredette 		va = frame->tf_ior;
 1.1  fredette 		space = frame->tf_isr;
 1.1  fredette 		vftype = inst_store(opcode) ? VM_PROT_WRITE : VM_PROT_READ;
 1.1  fredette 	}
1.13   tsutsui
1.18       chs 	l = curlwp;
1.18       chs 	p = l ? l->l_proc : NULL;
1.36        ad 	if ((type & T_USER) != 0)
1.36        ad 		LWP_CACHE_CREDS(l, p);
 1.1  fredette
1.23       chs 	tts = (type & ~T_USER) > trap_types ? "reserved" :
1.23       chs 		trap_type[type & ~T_USER];
1.23       chs
 1.1  fredette #ifdef DIAGNOSTIC
 1.1  fredette 	/*
 1.1  fredette 	 * If we are on the emergency stack, then we either got
 1.1  fredette 	 * a fault on the kernel stack, or we're just handling
 1.1  fredette 	 * a trap for the machine check handler (which also
 1.1  fredette 	 * runs on the emergency stack).
 1.1  fredette 	 *
 1.1  fredette 	 * We *very crudely* differentiate between the two cases
 1.1  fredette 	 * by checking the faulting instruction: if it is the
 1.1  fredette 	 * function prologue instruction that stores the old
 1.1  fredette 	 * frame pointer and updates the stack pointer, we assume
 1.1  fredette 	 * that we faulted on the kernel stack.
 1.1  fredette 	 *
 1.1  fredette 	 * In this case, not completing that instruction will
 1.1  fredette 	 * probably confuse backtraces in kgdb/ddb.  Completing
 1.1  fredette 	 * it would be difficult, because we already faulted on
 1.1  fredette 	 * that part of the stack, so instead we fix up the
 1.1  fredette 	 * frame as if the function called has just returned.
 1.1  fredette 	 * This has peculiar knowledge about what values are in
 1.1  fredette 	 * what registers during the "normal gcc -g" prologue.
 1.1  fredette 	 */
 1.1  fredette 	if (&type >= &emergency_stack_start &&
 1.1  fredette 	    &type < &emergency_stack_end &&
 1.1  fredette 	    type != T_IBREAK && STWM_R1_D_SR0_SP(opcode)) {
 1.1  fredette 		/* Restore the caller's frame pointer. */
 1.1  fredette 		frame->tf_r3 = frame->tf_r1;
 1.1  fredette 		/* Restore the caller's instruction offsets. */
 1.1  fredette 		frame->tf_iioq_head = frame->tf_rp;
 1.1  fredette 		frame->tf_iioq_tail = frame->tf_iioq_head + 4;
 1.1  fredette 		goto dead_end;
 1.1  fredette 	}
 1.1  fredette #endif /* DIAGNOSTIC */
 1.1  fredette
 1.1  fredette #ifdef DEBUG
1.26       chs 	frame_sanity_check(0xdead01, type, frame, l);
 1.1  fredette #endif /* DEBUG */
 1.1  fredette
 1.1  fredette 	/* If this is a trap, not an interrupt, reenable interrupts. */
 1.1  fredette 	if (type_raw != T_INTERRUPT)
 1.1  fredette 		mtctl(frame->tf_eiem, CR_EIEM);
 1.1  fredette
 1.1  fredette 	if (frame->tf_flags & TFF_LAST)
 1.9       chs 		l->l_md.md_regs = frame;
 1.1  fredette
 1.1  fredette #ifdef TRAPDEBUG
 1.1  fredette 	if (type_raw != T_INTERRUPT && type_raw != T_IBREAK)
 1.1  fredette 		printf("trap: %d, %s for %x:%x at %x:%x, fp=%p, rp=%x\n",
 1.1  fredette 		    type, tts, space, (u_int)va, frame->tf_iisq_head,
 1.1  fredette 		    frame->tf_iioq_head, frame, frame->tf_rp);
 1.1  fredette 	else if (type_raw == T_IBREAK)
 1.1  fredette 		printf("trap: break instruction %x:%x at %x:%x, fp=%p\n",
 1.1  fredette 		    break5(opcode), break13(opcode),
 1.1  fredette 		    frame->tf_iisq_head, frame->tf_iioq_head, frame);
 1.1  fredette
 1.1  fredette 	{
 1.1  fredette 		extern int etext;
 1.1  fredette 		if (frame < (struct trapframe *)&etext) {
 1.1  fredette 			printf("trap: bogus frame ptr %p\n", frame);
 1.1  fredette 			goto dead_end;
 1.1  fredette 		}
 1.1  fredette 	}
 1.1  fredette #endif
 1.1  fredette 	switch (type) {
 1.1  fredette 	case T_NONEXIST:
 1.1  fredette 	case T_NONEXIST|T_USER:
 1.1  fredette #if !defined(DDB) && !defined(KGDB)
 1.1  fredette 		/* we've got screwed up by the central scrutinizer */
 1.1  fredette 		panic ("trap: elvis has just left the building!");
 1.1  fredette 		break;
 1.1  fredette #else
 1.1  fredette 		goto dead_end;
 1.1  fredette #endif
 1.1  fredette 	case T_RECOVERY|T_USER:
 1.1  fredette #ifdef USERTRACE
 1.1  fredette 		for(;;) {
 1.1  fredette 			if (frame->tf_iioq_head != rctr_next_iioq)
 1.1  fredette 				printf("-%08x\nr %08x",
 1.1  fredette 					rctr_next_iioq - 4,
 1.1  fredette 					frame->tf_iioq_head);
 1.1  fredette 			rctr_next_iioq = frame->tf_iioq_head + 4;
 1.1  fredette 			if (frame->tf_ipsw & PSW_N) {
 1.1  fredette 				/* Advance the program counter. */
 1.1  fredette 				frame->tf_iioq_head = frame->tf_iioq_tail;
 1.1  fredette 				frame->tf_iioq_tail = frame->tf_iioq_head + 4;
 1.1  fredette 				/* Clear flags. */
 1.1  fredette 				frame->tf_ipsw &= ~(PSW_N|PSW_X|PSW_Y|PSW_Z|PSW_B|PSW_T|PSW_H|PSW_L);
 1.1  fredette 				/* Simulate another trap. */
 1.1  fredette 				continue;
 1.1  fredette 			}
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette 		frame->tf_rctr = 0;
 1.1  fredette 		break;
 1.1  fredette #endif /* USERTRACE */
 1.1  fredette 	case T_RECOVERY:
 1.1  fredette #if !defined(DDB) && !defined(KGDB)
 1.1  fredette 		/* XXX will implement later */
 1.1  fredette 		printf ("trap: handicapped");
 1.1  fredette 		break;
 1.1  fredette #else
 1.1  fredette 		goto dead_end;
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 	case T_EMULATION | T_USER:
 1.1  fredette #ifdef FPEMUL
1.21       chs 		hppa_fpu_emulate(frame, l, opcode);
 1.1  fredette #else  /* !FPEMUL */
 1.1  fredette 		/*
 1.1  fredette 		 * We don't have FPU emulation, so signal the
 1.1  fredette 		 * process with a SIGFPE.
 1.1  fredette 		 */
1.22       chs
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGFPE;
1.22       chs 		ksi.ksi_code = SI_NOINFO;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)frame->tf_iioq_head;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette #endif /* !FPEMUL */
 1.1  fredette 		break;
 1.1  fredette
1.25       chs 	case T_DATALIGN:
1.25       chs 		if (l->l_addr->u_pcb.pcb_onfault) {
1.25       chs do_onfault:
1.25       chs 			pcbp = &l->l_addr->u_pcb;
1.25       chs 			frame->tf_iioq_tail = 4 +
1.25       chs 				(frame->tf_iioq_head =
1.25       chs 				 pcbp->pcb_onfault);
1.25       chs 			pcbp->pcb_onfault = 0;
1.25       chs 			break;
1.25       chs 		}
1.25       chs 		/*FALLTHROUGH*/
1.25       chs
 1.1  fredette #ifdef DIAGNOSTIC
 1.1  fredette 		/* these just can't happen ever */
 1.1  fredette 	case T_PRIV_OP:
 1.1  fredette 	case T_PRIV_REG:
 1.1  fredette 		/* these just can't make it to the trap() ever */
1.25       chs 	case T_HPMC:
1.25       chs 	case T_HPMC | T_USER:
 1.1  fredette 	case T_EMULATION:
1.25       chs 	case T_EXCEPTION:
 1.1  fredette #endif
 1.1  fredette 	case T_IBREAK:
 1.1  fredette 	case T_DBREAK:
 1.1  fredette 	dead_end:
 1.3  fredette 		if (type & T_USER) {
 1.3  fredette #ifdef DEBUG
 1.9       chs 			user_backtrace(frame, l, type);
 1.3  fredette #endif
1.22       chs 			KSI_INIT_TRAP(&ksi);
1.22       chs 			ksi.ksi_signo = SIGILL;
1.22       chs 			ksi.ksi_code = ILL_ILLTRP;
1.22       chs 			ksi.ksi_trap = type;
1.22       chs 			ksi.ksi_addr = (void *)frame->tf_iioq_head;
1.22       chs 			trapsignal(l, &ksi);
 1.3  fredette 			break;
 1.3  fredette 		}
 1.1  fredette 		if (trap_kdebug(type, va, frame))
 1.1  fredette 			return;
 1.1  fredette 		else if (type == T_DATALIGN)
 1.1  fredette 			panic ("trap: %s at 0x%x", tts, (u_int) va);
 1.1  fredette 		else
 1.1  fredette 			panic ("trap: no debugger for \"%s\" (%d)", tts, type);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_IBREAK | T_USER:
 1.1  fredette 	case T_DBREAK | T_USER:
 1.1  fredette 		/* pass to user debugger */
 1.1  fredette 		break;
 1.1  fredette
1.21       chs 	case T_EXCEPTION | T_USER: {	/* co-proc assist trap */
1.21       chs 		uint64_t *fpp;
1.23       chs 		uint32_t *pex, ex, inst;
1.23       chs 		int i;
1.21       chs
1.21       chs 		hppa_fpu_flush(l);
1.21       chs 		fpp = l->l_addr->u_pcb.pcb_fpregs;
1.23       chs 		pex = (uint32_t *)&fpp[1];
1.23       chs 		for (i = 1; i < 8 && !*pex; i++, pex++)
1.21       chs 			;
1.23       chs 		KASSERT(i < 8);
1.23       chs 		ex = *pex;
1.23       chs 		*pex = 0;
1.23       chs
1.21       chs 		/* reset the trap flag, as if there was none */
1.21       chs 		fpp[0] &= ~(((uint64_t)HPPA_FPU_T) << 32);
1.21       chs
1.23       chs 		/* emulate the instruction */
1.23       chs 		inst = ((uint32_t)fpopmap[ex >> 26] << 26) | (ex & 0x03ffffff);
1.21       chs 		hppa_fpu_emulate(frame, l, inst);
1.21       chs 		}
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_OVERFLOW | T_USER:
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGFPE;
1.22       chs 		ksi.ksi_code = SI_NOINFO;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_CONDITION | T_USER:
1.23       chs 		KSI_INIT_TRAP(&ksi);
1.23       chs 		ksi.ksi_signo = SIGFPE;
1.23       chs 		ksi.ksi_code = FPE_INTDIV;
1.23       chs 		ksi.ksi_trap = type;
1.23       chs 		ksi.ksi_addr = (void *)va;
1.23       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_ILLEGAL | T_USER:
 1.3  fredette #ifdef DEBUG
 1.9       chs 		user_backtrace(frame, l, type);
 1.3  fredette #endif
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGILL;
1.22       chs 		ksi.ksi_code = ILL_ILLOPC;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_PRIV_OP | T_USER:
 1.3  fredette #ifdef DEBUG
 1.9       chs 		user_backtrace(frame, l, type);
 1.3  fredette #endif
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGILL;
1.22       chs 		ksi.ksi_code = ILL_PRVOPC;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_PRIV_REG | T_USER:
 1.3  fredette #ifdef DEBUG
 1.9       chs 		user_backtrace(frame, l, type);
 1.3  fredette #endif
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGILL;
1.22       chs 		ksi.ksi_code = ILL_PRVREG;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 		/* these should never got here */
 1.1  fredette 	case T_HIGHERPL | T_USER:
 1.1  fredette 	case T_LOWERPL | T_USER:
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGSEGV;
1.22       chs 		ksi.ksi_code = SEGV_ACCERR;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_IPROT | T_USER:
 1.1  fredette 	case T_DPROT | T_USER:
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGSEGV;
1.22       chs 		ksi.ksi_code = SEGV_ACCERR;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_DATACC:   	case T_USER | T_DATACC:
 1.1  fredette 	case T_ITLBMISS:	case T_USER | T_ITLBMISS:
 1.1  fredette 	case T_DTLBMISS:	case T_USER | T_DTLBMISS:
 1.1  fredette 	case T_ITLBMISSNA:	case T_USER | T_ITLBMISSNA:
 1.1  fredette 	case T_DTLBMISSNA:	case T_USER | T_DTLBMISSNA:
 1.1  fredette 	case T_TLB_DIRTY:	case T_USER | T_TLB_DIRTY:
 1.1  fredette 		vm = p->p_vmspace;
 1.1  fredette
 1.1  fredette 		if (!vm) {
 1.1  fredette #ifdef TRAPDEBUG
 1.1  fredette 			printf("trap: no vm, p=%p\n", p);
 1.1  fredette #endif
 1.1  fredette 			goto dead_end;
 1.1  fredette 		}
 1.1  fredette
 1.1  fredette 		/*
 1.1  fredette 		 * it could be a kernel map for exec_map faults
 1.1  fredette 		 */
 1.1  fredette 		if (!(type & T_USER) && space == HPPA_SID_KERNEL)
 1.1  fredette 			map = kernel_map;
1.40        ad 		else
 1.1  fredette 			map = &vm->vm_map;
1.10        cl
1.41     skrll 		va = trunc_page(va);
 1.1  fredette
 1.1  fredette 		if (map->pmap->pmap_space != space) {
 1.1  fredette #ifdef TRAPDEBUG
1.37     skrll 			printf("trap: space mismatch %d != %d\n",
 1.1  fredette 			    space, map->pmap->pmap_space);
 1.1  fredette #endif
 1.1  fredette 			/* actually dump the user, crap the kernel */
 1.1  fredette 			goto dead_end;
 1.1  fredette 		}
 1.1  fredette
 1.1  fredette 		/* Never call uvm_fault in interrupt context. */
 1.1  fredette 		KASSERT(hppa_intr_depth == 0);
 1.1  fredette
1.19       chs 		onfault = l->l_addr->u_pcb.pcb_onfault;
1.19       chs 		l->l_addr->u_pcb.pcb_onfault = 0;
1.33  drochner 		ret = uvm_fault(map, va, vftype);
1.19       chs 		l->l_addr->u_pcb.pcb_onfault = onfault;
 1.1  fredette
 1.1  fredette #ifdef TRAPDEBUG
1.33  drochner 		printf("uvm_fault(%p, %x, %d)=%d\n",
1.33  drochner 		    map, (u_int)va, vftype, ret);
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 		/*
 1.1  fredette 		 * If this was a stack access we keep track of the maximum
 1.1  fredette 		 * accessed stack size.  Also, if uvm_fault gets a protection
 1.1  fredette 		 * failure it is due to accessing the stack region outside
 1.1  fredette 		 * the current limit and we need to reflect that as an access
 1.1  fredette 		 * error.
 1.1  fredette 		 */
1.39     skrll 		if (map != kernel_map && va >= (vaddr_t)vm->vm_minsaddr) {
1.39     skrll 			if (ret == 0)
1.39     skrll 				uvm_grow(l->l_proc, va);
1.39     skrll 			else if (ret == EACCES)
 1.1  fredette 				ret = EFAULT;
 1.1  fredette 		}
 1.1  fredette
 1.1  fredette 		if (ret != 0) {
 1.1  fredette 			if (type & T_USER) {
 1.1  fredette #ifdef DEBUG
 1.9       chs 				user_backtrace(frame, l, type);
 1.1  fredette #endif
1.22       chs 				KSI_INIT_TRAP(&ksi);
1.22       chs 				ksi.ksi_signo = SIGSEGV;
1.22       chs 				ksi.ksi_code = (ret == EACCES ?
1.22       chs 						SEGV_ACCERR : SEGV_MAPERR);
1.22       chs 				ksi.ksi_trap = type;
1.22       chs 				ksi.ksi_addr = (void *)va;
1.22       chs 				trapsignal(l, &ksi);
 1.1  fredette 			} else {
1.19       chs 				if (l->l_addr->u_pcb.pcb_onfault) {
1.25       chs 					goto do_onfault;
 1.1  fredette 				}
1.33  drochner 				panic("trap: uvm_fault(%p, %lx, %d): %d",
1.33  drochner 				    map, va, vftype, ret);
 1.1  fredette 			}
 1.1  fredette 		}
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_DATALIGN | T_USER:
 1.3  fredette #ifdef DEBUG
 1.9       chs 		user_backtrace(frame, l, type);
 1.3  fredette #endif
1.22       chs 		KSI_INIT_TRAP(&ksi);
1.22       chs 		ksi.ksi_signo = SIGBUS;
1.22       chs 		ksi.ksi_code = BUS_ADRALN;
1.22       chs 		ksi.ksi_trap = type;
1.22       chs 		ksi.ksi_addr = (void *)va;
1.22       chs 		trapsignal(l, &ksi);
 1.1  fredette 		break;
 1.1  fredette
 1.1  fredette 	case T_INTERRUPT:
 1.1  fredette 	case T_INTERRUPT|T_USER:
 1.1  fredette 		hppa_intr(frame);
 1.1  fredette 		mtctl(frame->tf_eiem, CR_EIEM);
 1.1  fredette 		break;
1.22       chs
 1.1  fredette 	case T_LOWERPL:
 1.1  fredette 	case T_DPROT:
 1.1  fredette 	case T_IPROT:
 1.1  fredette 	case T_OVERFLOW:
 1.1  fredette 	case T_CONDITION:
 1.1  fredette 	case T_ILLEGAL:
 1.1  fredette 	case T_HIGHERPL:
 1.1  fredette 	case T_TAKENBR:
 1.1  fredette 	case T_POWERFAIL:
 1.1  fredette 	case T_LPMC:
 1.1  fredette 	case T_PAGEREF:
 1.1  fredette 	case T_DATAPID:  	case T_DATAPID  | T_USER:
 1.1  fredette 		if (0 /* T-chip */) {
 1.1  fredette 			break;
 1.1  fredette 		}
 1.1  fredette 		/* FALLTHROUGH to unimplemented */
 1.1  fredette 	default:
 1.1  fredette 		panic ("trap: unimplemented \'%s\' (%d)", tts, type);
 1.1  fredette 	}
 1.1  fredette
 1.1  fredette 	if (type & T_USER)
 1.9       chs 		userret(l, l->l_md.md_regs->tf_iioq_head, 0);
 1.1  fredette
 1.1  fredette #ifdef DEBUG
1.26       chs 	frame_sanity_check(0xdead02, type, frame, l);
1.43      yamt 	if (frame->tf_flags & TFF_LAST && (curlwp->l_flag & LW_IDLE) == 0)
1.26       chs 		frame_sanity_check(0xdead03, type, curlwp->l_md.md_regs,
1.26       chs 				   curlwp);
 1.1  fredette #endif /* DEBUG */
 1.1  fredette }
 1.1  fredette
 1.1  fredette void
1.14       chs child_return(void *arg)
 1.1  fredette {
 1.9       chs 	struct lwp *l = arg;
 1.1  fredette
 1.9       chs 	userret(l, l->l_md.md_regs->tf_iioq_head, 0);
1.46        ad 	ktrsysret(SYS_fork, 0, 0);
 1.1  fredette #ifdef DEBUG
1.26       chs 	frame_sanity_check(0xdead04, 0, l->l_md.md_regs, l);
 1.1  fredette #endif /* DEBUG */
 1.1  fredette }
 1.1  fredette
 1.1  fredette /*
 1.1  fredette  * call actual syscall routine
 1.1  fredette  * from the low-level syscall handler:
 1.1  fredette  * - all HPPA_FRAME_NARGS syscall's arguments supposed to be copied onto
 1.1  fredette  *   our stack, this wins compared to copyin just needed amount anyway
 1.1  fredette  * - register args are copied onto stack too
 1.1  fredette  */
 1.1  fredette void
1.14       chs syscall(struct trapframe *frame, int *args)
 1.1  fredette {
 1.9       chs 	struct lwp *l;
 1.9       chs 	struct proc *p;
 1.9       chs 	const struct sysent *callp;
 1.1  fredette 	int nsys, code, argsize, error;
 1.1  fredette 	int tmp;
 1.1  fredette 	int rval[2];
 1.1  fredette
 1.1  fredette 	uvmexp.syscalls++;
 1.1  fredette
 1.1  fredette #ifdef DEBUG
1.26       chs 	frame_sanity_check(0xdead04, 0, frame, curlwp);
 1.1  fredette #endif /* DEBUG */
 1.1  fredette
 1.1  fredette 	if (!USERMODE(frame->tf_iioq_head))
 1.1  fredette 		panic("syscall");
 1.1  fredette
 1.9       chs 	l = curlwp;
 1.9       chs 	p = l->l_proc;
 1.9       chs 	l->l_md.md_regs = frame;
 1.1  fredette 	nsys = p->p_emul->e_nsysent;
 1.1  fredette 	callp = p->p_emul->e_sysent;
 1.1  fredette 	code = frame->tf_t1;
1.36        ad 	LWP_CACHE_CREDS(l, p);
 1.1  fredette
 1.1  fredette 	/*
 1.1  fredette 	 * Restarting a system call is touchy on the HPPA,
 1.1  fredette 	 * because syscall arguments are passed in registers
 1.1  fredette 	 * and the program counter of the syscall "point"
 1.1  fredette 	 * isn't easily divined.
 1.1  fredette 	 *
 1.1  fredette 	 * We handle the first problem by assuming that we
 1.1  fredette 	 * will have to restart this system call, so we
 1.1  fredette 	 * stuff the first four words of the original arguments
 1.1  fredette 	 * back into the frame as arg0...arg3, which is where
 1.1  fredette 	 * we found them in the first place.  Any further
 1.1  fredette 	 * arguments are (still) on the user's stack and the
 1.1  fredette 	 * syscall code will fetch them from there (again).
 1.1  fredette 	 *
 1.1  fredette 	 * The program counter problem is addressed below.
 1.1  fredette 	 */
 1.1  fredette 	frame->tf_arg0 = args[0];
 1.1  fredette 	frame->tf_arg1 = args[1];
 1.1  fredette 	frame->tf_arg2 = args[2];
 1.1  fredette 	frame->tf_arg3 = args[3];
 1.1  fredette
 1.1  fredette 	/*
 1.1  fredette 	 * Some special handling for the syscall(2) and
 1.1  fredette 	 * __syscall(2) system calls.
 1.1  fredette 	 */
 1.1  fredette 	switch (code) {
 1.1  fredette 	case SYS_syscall:
 1.1  fredette 		code = *args;
 1.1  fredette 		args += 1;
 1.1  fredette 		break;
 1.1  fredette 	case SYS___syscall:
 1.1  fredette 		if (callp != sysent)
 1.1  fredette 			break;
 1.1  fredette 		/*
 1.1  fredette 		 * NB: even though __syscall(2) takes a quad_t
 1.1  fredette 		 * containing the system call number, because
 1.1  fredette 		 * our argument copying word-swaps 64-bit arguments,
 1.1  fredette 		 * the least significant word of that quad_t
 1.1  fredette 		 * is the first word in the argument array.
 1.1  fredette 		 */
 1.1  fredette 		code = *args;
 1.1  fredette 		args += 2;
 1.1  fredette 	}
 1.1  fredette
 1.1  fredette 	/*
 1.1  fredette 	 * Stacks growing from lower addresses to higher
 1.1  fredette 	 * addresses are not really such a good idea, because
 1.1  fredette 	 * it makes it impossible to overlay a struct on top
 1.1  fredette 	 * of C stack arguments (the arguments appear in
 1.1  fredette 	 * reversed order).
 1.1  fredette 	 *
 1.1  fredette 	 * You can do the obvious thing (as locore.S does) and
 1.1  fredette 	 * copy argument words one by one, laying them out in
 1.1  fredette 	 * the "right" order in the destination buffer, but this
 1.1  fredette 	 * ends up word-swapping multi-word arguments (like off_t).
 1.1  fredette 	 *
 1.1  fredette 	 * To compensate, we have some automatically-generated
 1.1  fredette 	 * code that word-swaps these multi-word arguments.
 1.1  fredette 	 * Right now the script that generates this code is
 1.1  fredette 	 * in Perl, because I don't know awk.
 1.1  fredette 	 *
 1.1  fredette 	 * FIXME - this works only on native binaries and
 1.1  fredette 	 * will probably screw up any and all emulation.
 1.1  fredette 	 */
 1.1  fredette 	switch (code) {
 1.1  fredette 	/*
 1.1  fredette 	 * BEGIN automatically generated
 1.1  fredette 	 * by /home/fredette/project/hppa/makescargfix.pl
 1.1  fredette 	 * do not edit!
 1.1  fredette 	 */
 1.1  fredette 	case SYS_pread:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(void *) buf;
 1.1  fredette 		 * 	syscallarg(size_t) nbyte;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) offset;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[4];
 1.1  fredette 		args[4] = args[4 + 1];
 1.1  fredette 		args[4 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_pwrite:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(const void *) buf;
 1.1  fredette 		 * 	syscallarg(size_t) nbyte;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) offset;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[4];
 1.1  fredette 		args[4] = args[4 + 1];
 1.1  fredette 		args[4 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_mmap:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(void *) addr;
 1.1  fredette 		 * 	syscallarg(size_t) len;
 1.1  fredette 		 * 	syscallarg(int) prot;
 1.1  fredette 		 * 	syscallarg(int) flags;
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(long) pad;
 1.1  fredette 		 * 	syscallarg(off_t) pos;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[6];
 1.1  fredette 		args[6] = args[6 + 1];
 1.1  fredette 		args[6 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_lseek:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) offset;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[2];
 1.1  fredette 		args[2] = args[2 + 1];
 1.1  fredette 		args[2 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_truncate:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(const char *) path;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) length;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[2];
 1.1  fredette 		args[2] = args[2 + 1];
 1.1  fredette 		args[2 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_ftruncate:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) length;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[2];
 1.1  fredette 		args[2] = args[2 + 1];
 1.1  fredette 		args[2 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_preadv:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(const struct iovec *) iovp;
 1.1  fredette 		 * 	syscallarg(int) iovcnt;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) offset;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[4];
 1.1  fredette 		args[4] = args[4 + 1];
 1.1  fredette 		args[4 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	case SYS_pwritev:
 1.1  fredette 		/*
 1.1  fredette 		 * 	syscallarg(int) fd;
 1.1  fredette 		 * 	syscallarg(const struct iovec *) iovp;
 1.1  fredette 		 * 	syscallarg(int) iovcnt;
 1.1  fredette 		 * 	syscallarg(int) pad;
 1.1  fredette 		 * 	syscallarg(off_t) offset;
 1.1  fredette 		 */
 1.1  fredette 		tmp = args[4];
 1.1  fredette 		args[4] = args[4 + 1];
 1.1  fredette 		args[4 + 1] = tmp;
 1.1  fredette 		break;
 1.1  fredette 	default:
 1.1  fredette 		break;
 1.1  fredette 	/*
 1.1  fredette 	 * END automatically generated
 1.1  fredette 	 * by /home/fredette/project/hppa/makescargfix.pl
 1.1  fredette 	 * do not edit!
 1.1  fredette 	 */
 1.1  fredette 	}
 1.1  fredette
 1.1  fredette #ifdef USERTRACE
 1.1  fredette 	if (0) {
1.35     skrll 		user_backtrace(frame, l, -1);
 1.1  fredette 		frame->tf_ipsw |= PSW_R;
 1.1  fredette 		frame->tf_rctr = 0;
 1.1  fredette 		printf("r %08x", frame->tf_iioq_head);
 1.1  fredette 		rctr_next_iioq = frame->tf_iioq_head + 4;
 1.1  fredette 	}
 1.1  fredette #endif
 1.1  fredette
 1.1  fredette 	if (code < 0 || code >= nsys)
 1.1  fredette 		callp += p->p_emul->e_nosys;	/* bad syscall # */
 1.1  fredette 	else
 1.1  fredette 		callp += code;
 1.1  fredette 	argsize = callp->sy_argsize;
 1.1  fredette
1.12    simonb 	if ((error = trace_enter(l, code, code, NULL, args)) != 0)
1.27  christos 		goto out;
 1.1  fredette
 1.1  fredette 	rval[0] = 0;
 1.1  fredette 	rval[1] = 0;
1.27  christos 	error = (*callp->sy_call)(l, args, rval);
1.27  christos out:
1.27  christos 	switch (error) {
 1.1  fredette 	case 0:
 1.9       chs 		l = curlwp;			/* changes on exec() */
 1.9       chs 		frame = l->l_md.md_regs;
 1.1  fredette 		frame->tf_ret0 = rval[0];
 1.1  fredette 		frame->tf_ret1 = rval[1];
 1.1  fredette 		frame->tf_t1 = 0;
 1.1  fredette 		break;
 1.1  fredette 	case ERESTART:
 1.1  fredette 		/*
 1.1  fredette 		 * Now we have to wind back the instruction
 1.1  fredette 		 * offset queue to the point where the system
 1.1  fredette 		 * call will be made again.  This is inherently
 1.1  fredette 		 * tied to the SYSCALL macro.
 1.1  fredette 		 *
 1.1  fredette 		 * Currently, the part of the SYSCALL macro
 1.1  fredette 		 * that we want to rerun reads as:
 1.1  fredette 		 *
 1.1  fredette 		 *	ldil	L%SYSCALLGATE, r1
 1.1  fredette 		 *	ble	4(sr7, r1)
 1.1  fredette 		 *	ldi	__CONCAT(SYS_,x), t1
 1.1  fredette 		 *	ldw	HPPA_FRAME_ERP(sr0,sp), rp
 1.1  fredette 		 *
 1.1  fredette 		 * And our offset queue head points to the
 1.1  fredette 		 * final ldw instruction.  So we need to
 1.1  fredette 		 * subtract twelve to reach the ldil.
 1.1  fredette 		 */
 1.1  fredette 		frame->tf_iioq_head -= 12;
 1.1  fredette 		frame->tf_iioq_tail = frame->tf_iioq_head + 4;
 1.1  fredette 		break;
 1.1  fredette 	case EJUSTRETURN:
 1.1  fredette 		p = curproc;
 1.1  fredette 		break;
 1.1  fredette 	default:
 1.1  fredette 		if (p->p_emul->e_errno)
 1.1  fredette 			error = p->p_emul->e_errno[error];
 1.1  fredette 		frame->tf_t1 = error;
 1.1  fredette 		break;
 1.1  fredette 	}
 1.2  christos
 1.9       chs 	trace_exit(l, code, args, rval, error);
 1.2  christos
 1.9       chs 	userret(l, frame->tf_iioq_head, 0);
 1.1  fredette #ifdef DEBUG
1.26       chs 	frame_sanity_check(0xdead05, 0, frame, l);
 1.1  fredette #endif /* DEBUG */
 1.9       chs }
 1.9       chs
 1.9       chs /*
 1.9       chs  * Start a new LWP
 1.9       chs  */
 1.9       chs void
1.14       chs startlwp(void *arg)
 1.9       chs {
 1.9       chs 	int err;
 1.9       chs 	ucontext_t *uc = arg;
 1.9       chs 	struct lwp *l = curlwp;
 1.9       chs
 1.9       chs 	err = cpu_setmcontext(l, &uc->uc_mcontext, uc->uc_flags);
 1.9       chs #if DIAGNOSTIC
 1.9       chs 	if (err) {
 1.9       chs 		printf("Error %d from cpu_setmcontext.", err);
 1.9       chs 	}
 1.9       chs #endif
 1.9       chs 	pool_put(&lwp_uc_pool, uc);
 1.9       chs
 1.9       chs 	userret(l, l->l_md.md_regs->tf_iioq_head, 0);
 1.9       chs }