luna68k/luna68k/machdep.c

1.3   msaitoh /* $NetBSD: machdep.c,v 1.3 2000/01/19 02:52:18 msaitoh Exp $ */
1.1  nisimura
1.1  nisimura /*-
1.1  nisimura  * Copyright (c) 2000 The NetBSD Foundation, Inc.
1.1  nisimura  * All rights reserved.
1.1  nisimura  *
1.1  nisimura  * This code is derived from software contributed to The NetBSD Foundation
1.1  nisimura  * by Tohru Nishimura.
1.1  nisimura  *
1.1  nisimura  * Redistribution and use in source and binary forms, with or without
1.1  nisimura  * modification, are permitted provided that the following conditions
1.1  nisimura  * are met:
1.1  nisimura  * 1. Redistributions of source code must retain the above copyright
1.1  nisimura  *    notice, this list of conditions and the following disclaimer.
1.1  nisimura  * 2. Redistributions in binary form must reproduce the above copyright
1.1  nisimura  *    notice, this list of conditions and the following disclaimer in the
1.1  nisimura  *    documentation and/or other materials provided with the distribution.
1.1  nisimura  * 3. All advertising materials mentioning features or use of this software
1.1  nisimura  *    must display the following acknowledgement:
1.1  nisimura  *	This product includes software developed by the NetBSD
1.1  nisimura  *	Foundation, Inc. and its contributors.
1.1  nisimura  * 4. Neither the name of The NetBSD Foundation nor the names of its
1.1  nisimura  *    contributors may be used to endorse or promote products derived
1.1  nisimura  *    from this software without specific prior written permission.
1.1  nisimura  *
1.1  nisimura  * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
1.1  nisimura  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.1  nisimura  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.1  nisimura  * PURPOSE ARE DISCLAIMED.  IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
1.1  nisimura  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.1  nisimura  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.1  nisimura  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.1  nisimura  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.1  nisimura  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.1  nisimura  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.1  nisimura  * POSSIBILITY OF SUCH DAMAGE.
1.1  nisimura  */
1.1  nisimura
1.1  nisimura #include <sys/cdefs.h>			/* RCS ID & Copyright macro defns */
1.1  nisimura
1.3   msaitoh __KERNEL_RCSID(0, "$NetBSD: machdep.c,v 1.3 2000/01/19 02:52:18 msaitoh Exp $");
1.1  nisimura
1.1  nisimura #include "opt_ddb.h"
1.1  nisimura
1.1  nisimura #include <sys/param.h>
1.1  nisimura #include <sys/systm.h>
1.1  nisimura #include <sys/kernel.h>
1.1  nisimura #include <sys/map.h>
1.1  nisimura #include <sys/proc.h>
1.1  nisimura #include <sys/buf.h>
1.1  nisimura #include <sys/reboot.h>
1.1  nisimura #include <sys/conf.h>
1.1  nisimura #include <sys/file.h>
1.1  nisimura #include <sys/clist.h>
1.1  nisimura #include <sys/callout.h>
1.1  nisimura #include <sys/device.h>
1.1  nisimura #include <sys/malloc.h>
1.1  nisimura #include <sys/mbuf.h>
1.1  nisimura #include <sys/msgbuf.h>
1.1  nisimura #include <sys/ioctl.h>
1.1  nisimura #include <sys/tty.h>
1.1  nisimura #include <sys/mount.h>
1.1  nisimura #include <sys/user.h>
1.1  nisimura #include <sys/exec.h>
1.1  nisimura #include <sys/core.h>
1.1  nisimura #include <sys/kcore.h>
1.1  nisimura #include <sys/vnode.h>
1.1  nisimura #include <sys/syscallargs.h>
1.1  nisimura #ifdef	KGDB
1.1  nisimura #include <sys/kgdb.h>
1.1  nisimura #endif
1.1  nisimura
1.1  nisimura #include <vm/vm.h>
1.1  nisimura #include <vm/vm_map.h>
1.1  nisimura #include <vm/vm_kern.h>
1.1  nisimura #include <vm/vm_page.h>
1.1  nisimura
1.1  nisimura #include <uvm/uvm_extern.h>
1.1  nisimura
1.1  nisimura #include <sys/sysctl.h>
1.1  nisimura
1.1  nisimura #include <machine/cpu.h>
1.1  nisimura #include <machine/reg.h>
1.1  nisimura #include <machine/psl.h>
1.1  nisimura #include <machine/pte.h>
1.1  nisimura #include <machine/kcore.h>	/* XXX should be pulled in by sys/kcore.h */
1.1  nisimura
1.1  nisimura #include <dev/cons.h>
1.1  nisimura
1.1  nisimura #if defined(DDB)
1.1  nisimura #include <machine/db_machdep.h>
1.1  nisimura #include <ddb/db_sym.h>
1.1  nisimura #include <ddb/db_extern.h>
1.1  nisimura #endif
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Info for CTL_HW
1.1  nisimura  */
1.1  nisimura char	machine[] = MACHINE;
1.1  nisimura char	cpu_model[60];
1.1  nisimura extern char version[];
1.1  nisimura
1.1  nisimura extern char kernel_text[];
1.1  nisimura extern char etext[];
1.1  nisimura
1.1  nisimura vm_map_t exec_map = NULL;
1.1  nisimura vm_map_t mb_map = NULL;
1.1  nisimura vm_map_t phys_map = NULL;
1.1  nisimura
1.1  nisimura caddr_t	msgbufaddr;
1.1  nisimura int	maxmem;			/* max memory per process */
1.1  nisimura int	physmem;		/* set by locore */
1.1  nisimura /*
1.1  nisimura  * safepri is a safe priority for sleep to set for a spin-wait
1.1  nisimura  * during autoconfiguration or after a panic.
1.1  nisimura  */
1.1  nisimura int	safepri = PSL_LOWIPL;
1.1  nisimura
1.1  nisimura void luna68k_init __P((void));
1.1  nisimura void identifycpu __P((void));
1.1  nisimura void dumpsys __P((void));
1.1  nisimura
1.1  nisimura void straytrap __P((int, u_short));
1.1  nisimura void nmihand __P((struct frame));
1.1  nisimura
1.1  nisimura int  cpu_dumpsize __P((void));
1.1  nisimura int  cpu_dump __P((int (*)(dev_t, daddr_t, caddr_t, size_t), daddr_t *));
1.1  nisimura void cpu_init_kcore_hdr __P((void));
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Machine-independent crash dump header info.
1.1  nisimura  */
1.1  nisimura cpu_kcore_hdr_t cpu_kcore_hdr;
1.1  nisimura
1.1  nisimura int	machtype;	/* model: 1 for LUNA-1, 2 for LUNA-2 */
1.1  nisimura int	sysconsole;	/* console: 0 for ttya, 1 for video */
1.1  nisimura
1.1  nisimura extern struct consdev syscons;
1.1  nisimura extern void omfb_cnattach __P((void));
1.1  nisimura extern void ws_cnattach __P((void));
1.1  nisimura extern void syscnattach __P((int));
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * On the 68020/68030, the value of delay_divisor is roughly
1.1  nisimura  * 2048 / cpuspeed (where cpuspeed is in MHz).
1.1  nisimura  *
1.1  nisimura  * On the 68040/68060(?), the value of delay_divisor is roughly
1.1  nisimura  * 759 / cpuspeed (where cpuspeed is in MHz).
1.1  nisimura  * XXX -- is the above formula correct?
1.1  nisimura  */
1.1  nisimura int	cpuspeed = 25;		/* only used for printing later */
1.1  nisimura int	delay_divisor = 300;	/* for delay() loop count */
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Early initialization, before main() is called.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura luna68k_init()
1.1  nisimura {
1.1  nisimura 	int i;
1.1  nisimura
1.1  nisimura 	extern paddr_t avail_start, avail_end;
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Tell the VM system about available physical memory.  The
1.1  nisimura 	 * luna68k only has one segment.
1.1  nisimura 	 */
1.1  nisimura 	uvm_page_physload(atop(avail_start), atop(avail_end),
1.1  nisimura 	    atop(avail_start), atop(avail_end), VM_FREELIST_DEFAULT);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize error message buffer (at end of core).
1.1  nisimura 	 * avail_end was pre-decremented in pmap_bootstrap to compensate.
1.1  nisimura 	 */
1.1  nisimura 	for (i = 0; i < btoc(MSGBUFSIZE); i++)
1.1  nisimura 		pmap_enter(pmap_kernel(), (vaddr_t)msgbufaddr + i * NBPG,
1.1  nisimura 		    avail_end + i * NBPG, VM_PROT_READ|VM_PROT_WRITE,
1.1  nisimura 		    VM_PROT_READ|VM_PROT_WRITE|PMAP_WIRED);
1.1  nisimura 	initmsgbuf(msgbufaddr, m68k_round_page(MSGBUFSIZE));
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Console initialization: called early on from main,
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura consinit()
1.1  nisimura {
1.1  nisimura 	volatile unsigned char *pio0 = (void *)0x49000000;
1.1  nisimura 	int sw1, i;
1.1  nisimura 	char *cp;
1.1  nisimura 	extern char bootarg[64];
1.1  nisimura
1.1  nisimura 	pio0[3] = 0xb6;
1.1  nisimura 	pio0[2] = 1 << 6;		/* enable parity check */
1.1  nisimura
1.1  nisimura 	pio0[3] = 0xb6;
1.1  nisimura 	sw1 = pio0[0];			/* dipssw1 value */
1.1  nisimura 	sw1 ^= 0xff;
1.1  nisimura 	sysconsole = !(sw1 & 0x2);	/* console selection */
1.1  nisimura
1.1  nisimura 	boothowto = 0;
1.1  nisimura 	i = 0;
1.1  nisimura 	/*
1.1  nisimura 	 * 'bootarg' has;
1.1  nisimura 	 *   "<args of x command> ENADDR=<addr> HOST=<host> SERVER=<name>"
1.1  nisimura 	 * where <addr> is MAC address of which network loader used (not
1.1  nisimura 	 * necessarily same as one at 0x4101.FFE0), <host> and <name>
1.1  nisimura 	 * are the values of HOST and SERVER environment variables,
1.1  nisimura 	 *
1.1  nisimura 	 * NetBSD/luna68k cares only the first argment; any of "sda".
1.1  nisimura 	 */
1.1  nisimura 	for (cp = bootarg; *cp != ' '; cp++) {
1.1  nisimura 		switch (*cp) {
1.1  nisimura 		case 's':
1.1  nisimura 			boothowto |= RB_SINGLE;
1.1  nisimura 			break;
1.1  nisimura 		case 'd':
1.1  nisimura 			boothowto |= RB_KDB;
1.1  nisimura 			break;
1.1  nisimura 		case 'a':
1.1  nisimura 			boothowto |= RB_ASKNAME;
1.1  nisimura 			break;
1.1  nisimura 		}
1.1  nisimura 		if (i++ >= sizeof(bootarg))
1.1  nisimura 			break;
1.1  nisimura 	}
1.2  nisimura #if 0 /* overload 1:sw1, which now means 'go ROM monitor' after poweron */
1.1  nisimura 	if (boothowto == 0)
1.1  nisimura 		boothowto = (sw1 & 0x1) ? RB_SINGLE : 0;
1.2  nisimura #endif
1.1  nisimura
1.1  nisimura 	if (sysconsole == 0)
1.1  nisimura 		syscnattach(0);
1.1  nisimura 	else {
1.1  nisimura 		omfb_cnattach();
1.1  nisimura 		ws_cnattach();
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura #ifdef DDB
1.1  nisimura 	{
1.1  nisimura 		extern int end;
1.1  nisimura 		extern int *esym;
1.1  nisimura
1.1  nisimura 		ddb_init(*(int *)&end, ((int *)&end) + 1, esym);
1.1  nisimura 	}
1.1  nisimura 	if (boothowto & RB_KDB)
1.1  nisimura 		cpu_Debugger();
1.1  nisimura #endif
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * cpu_startup: allocate memory for variable-sized tables.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura cpu_startup()
1.1  nisimura {
1.1  nisimura 	int i;
1.1  nisimura 	caddr_t v;
1.1  nisimura 	int base, residual;
1.1  nisimura 	vaddr_t minaddr, maxaddr;
1.1  nisimura 	vsize_t size;
1.1  nisimura 	char pbuf[9];
1.1  nisimura 	extern void greeting __P((void));
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize the kernel crash dump header.
1.1  nisimura 	 */
1.1  nisimura 	cpu_init_kcore_hdr();
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Good {morning,afternoon,evening,night}.
1.1  nisimura 	 */
1.1  nisimura 	printf(version);
1.1  nisimura 	identifycpu();
1.1  nisimura
1.1  nisimura 	format_bytes(pbuf, sizeof(pbuf), ctob(physmem));
1.1  nisimura 	printf("total memory = %s\n", pbuf);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Find out how much space we need, allocate it,
1.1  nisimura 	 * and then give everything true virtual addresses.
1.1  nisimura 	 */
1.1  nisimura 	size = (int)allocsys(NULL, NULL);
1.1  nisimura 	if ((v = (caddr_t)uvm_km_alloc(kernel_map, round_page(size))) == 0)
1.1  nisimura 		panic("startup: no room for tables");
1.1  nisimura 	if (allocsys(v, NULL) - v != size)
1.1  nisimura 		panic("startup: table size inconsistency");
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Now allocate buffers proper.  They are different than the above
1.1  nisimura 	 * in that they usually occupy more virtual memory than physical.
1.1  nisimura 	 */
1.1  nisimura 	size = MAXBSIZE * nbuf;
1.1  nisimura 	if (uvm_map(kernel_map, (vaddr_t *) &buffers, round_page(size),
1.1  nisimura 		    NULL, UVM_UNKNOWN_OFFSET,
1.1  nisimura 		    UVM_MAPFLAG(UVM_PROT_NONE, UVM_PROT_NONE, UVM_INH_NONE,
1.1  nisimura 				UVM_ADV_NORMAL, 0)) != KERN_SUCCESS)
1.1  nisimura 		panic("startup: cannot allocate VM for buffers");
1.1  nisimura 	minaddr = (vaddr_t)buffers;
1.1  nisimura 	if ((bufpages / nbuf) >= btoc(MAXBSIZE)) {
1.1  nisimura 		/* don't want to alloc more physical mem than needed */
1.1  nisimura 		bufpages = btoc(MAXBSIZE) * nbuf;
1.1  nisimura 	}
1.1  nisimura 	base = bufpages / nbuf;
1.1  nisimura 	residual = bufpages % nbuf;
1.1  nisimura 	for (i = 0; i < nbuf; i++) {
1.1  nisimura 		vsize_t curbufsize;
1.1  nisimura 		vaddr_t curbuf;
1.1  nisimura 		struct vm_page *pg;
1.1  nisimura
1.1  nisimura 		/*
1.1  nisimura 		 * Each buffer has MAXBSIZE bytes of VM space allocated.  Of
1.1  nisimura 		 * that MAXBSIZE space, we allocate and map (base+1) pages
1.1  nisimura 		 * for the first "residual" buffers, and then we allocate
1.1  nisimura 		 * "base" pages for the rest.
1.1  nisimura 		 */
1.1  nisimura 		curbuf = (vsize_t) buffers + (i * MAXBSIZE);
1.1  nisimura 		curbufsize = NBPG * ((i < residual) ? (base+1) : base);
1.1  nisimura
1.1  nisimura 		while (curbufsize) {
1.1  nisimura 			pg = uvm_pagealloc(NULL, 0, NULL, 0);
1.1  nisimura 			if (pg == NULL)
1.1  nisimura 				panic("cpu_startup: not enough memory for "
1.1  nisimura 				    "buffer cache");
1.1  nisimura 			pmap_kenter_pa(curbuf, VM_PAGE_TO_PHYS(pg),
1.1  nisimura 					VM_PROT_READ|VM_PROT_WRITE);
1.1  nisimura 			curbuf += PAGE_SIZE;
1.1  nisimura 			curbufsize -= PAGE_SIZE;
1.1  nisimura 		}
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Allocate a submap for exec arguments.  This map effectively
1.1  nisimura 	 * limits the number of processes exec'ing at any time.
1.1  nisimura 	 */
1.1  nisimura 	exec_map = uvm_km_suballoc(kernel_map, &minaddr, &maxaddr,
1.1  nisimura 				   16*NCARGS, VM_MAP_PAGEABLE, FALSE, NULL);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Allocate a submap for physio
1.1  nisimura 	 */
1.1  nisimura 	phys_map = uvm_km_suballoc(kernel_map, &minaddr, &maxaddr,
1.1  nisimura 				   VM_PHYS_SIZE, 0, FALSE, NULL);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Finally, allocate mbuf cluster submap.
1.1  nisimura 	 */
1.1  nisimura 	mb_map = uvm_km_suballoc(kernel_map, &minaddr, &maxaddr,
1.1  nisimura 				 nmbclusters * mclbytes, VM_MAP_INTRSAFE,
1.1  nisimura 				 FALSE, NULL);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize callouts
1.1  nisimura 	 */
1.1  nisimura 	callfree = callout;
1.1  nisimura 	for (i = 1; i < ncallout; i++)
1.1  nisimura 		callout[i-1].c_next = &callout[i];
1.1  nisimura 	callout[i-1].c_next = NULL;
1.1  nisimura
1.1  nisimura 	format_bytes(pbuf, sizeof(pbuf), ptoa(uvmexp.free));
1.1  nisimura 	printf("avail memory = %s\n", pbuf);
1.1  nisimura 	format_bytes(pbuf, sizeof(pbuf), bufpages * NBPG);
1.1  nisimura 	printf("using %d buffers containing %s of memory\n", nbuf, pbuf);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Tell the VM system that the area before the text segment
1.1  nisimura 	 * is invalid.
1.1  nisimura 	 *
1.1  nisimura 	 * XXX Should just change KERNBASE and VM_MIN_KERNEL_ADDRESS,
1.1  nisimura 	 * XXX but not right now.
1.1  nisimura 	 */
1.1  nisimura 	if (uvm_map_protect(kernel_map, 0, round_page(&kernel_text),
1.1  nisimura 	    UVM_PROT_NONE, TRUE) != KERN_SUCCESS)
1.1  nisimura 		panic("can't mark pre-text pages off-limits");
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Tell the VM system that writing to kernel text isn't allowed.
1.1  nisimura 	 * If we don't, we might end up COW'ing the text segment!
1.1  nisimura 	 */
1.1  nisimura 	if (uvm_map_protect(kernel_map, trunc_page(&kernel_text),
1.1  nisimura 	    trunc_page(&etext), UVM_PROT_READ|UVM_PROT_EXEC, TRUE)
1.1  nisimura 	    != KERN_SUCCESS)
1.1  nisimura 		panic("can't protect kernel text");
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Set up buffers, so they can be used to read disk labels.
1.1  nisimura 	 */
1.1  nisimura 	bufinit();
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Say "Hi" to the world
1.1  nisimura 	 */
1.1  nisimura 	greeting();
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Set registers on exec.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura setregs(p, pack, stack)
1.1  nisimura 	register struct proc *p;
1.1  nisimura 	struct exec_package *pack;
1.1  nisimura 	u_long stack;
1.1  nisimura {
1.1  nisimura 	struct frame *frame = (struct frame *)p->p_md.md_regs;
1.1  nisimura 	extern int fputype;
1.1  nisimura
1.1  nisimura 	frame->f_sr = PSL_USERSET;
1.1  nisimura 	frame->f_pc = pack->ep_entry & ~1;
1.1  nisimura 	frame->f_regs[D0] = 0;
1.1  nisimura 	frame->f_regs[D1] = 0;
1.1  nisimura 	frame->f_regs[D2] = 0;
1.1  nisimura 	frame->f_regs[D3] = 0;
1.1  nisimura 	frame->f_regs[D4] = 0;
1.1  nisimura 	frame->f_regs[D5] = 0;
1.1  nisimura 	frame->f_regs[D6] = 0;
1.1  nisimura 	frame->f_regs[D7] = 0;
1.1  nisimura 	frame->f_regs[A0] = 0;
1.1  nisimura 	frame->f_regs[A1] = 0;
1.1  nisimura 	frame->f_regs[A2] = (int)PS_STRINGS;
1.1  nisimura 	frame->f_regs[A3] = 0;
1.1  nisimura 	frame->f_regs[A4] = 0;
1.1  nisimura 	frame->f_regs[A5] = 0;
1.1  nisimura 	frame->f_regs[A6] = 0;
1.1  nisimura 	frame->f_regs[SP] = stack;
1.1  nisimura
1.1  nisimura 	/* restore a null state frame */
1.1  nisimura 	p->p_addr->u_pcb.pcb_fpregs.fpf_null = 0;
1.1  nisimura 	if (fputype)
1.1  nisimura 		m68881_restore(&p->p_addr->u_pcb.pcb_fpregs);
1.1  nisimura }
1.1  nisimura
1.1  nisimura void
1.1  nisimura identifycpu()
1.1  nisimura {
1.1  nisimura 	extern int cputype;
1.1  nisimura 	char *cpu;
1.1  nisimura
1.1  nisimura 	bzero(cpu_model, sizeof(cpu_model));
1.1  nisimura 	switch (cputype) {
1.1  nisimura 	case CPU_68030:
1.1  nisimura 		cpu = "MC68030 CPU+MMU, MC68882 FPU";
1.1  nisimura 		machtype = LUNA_I;
1.1  nisimura 		cpuspeed = 20; delay_divisor = 102;	/* 20MHz 68030 */
1.1  nisimura 		hz = 60;
1.1  nisimura 		break;
1.1  nisimura #ifdef M68040
1.1  nisimura 	case CPU_68040:
1.1  nisimura 		cpu = "MC68040 CPU+MMU+FPU, 4k on-chip physical I/D caches";
1.1  nisimura 		machtype = LUNA_II;
1.1  nisimura 		cpuspeed = 25; delay_divisor = 300;	/* 25MHz 68040 */
1.1  nisimura 		break;
1.1  nisimura #endif
1.1  nisimura 	default:
1.1  nisimura 		panic("unknown CPU type");
1.1  nisimura 	}
1.1  nisimura 	strcpy(cpu_model, cpu);
1.1  nisimura 	printf("%s\n", cpu_model);
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * machine dependent system variables.
1.1  nisimura  */
1.1  nisimura int
1.1  nisimura cpu_sysctl(name, namelen, oldp, oldlenp, newp, newlen, p)
1.1  nisimura 	int *name;
1.1  nisimura 	u_int namelen;
1.1  nisimura 	void *oldp;
1.1  nisimura 	size_t *oldlenp;
1.1  nisimura 	void *newp;
1.1  nisimura 	size_t newlen;
1.1  nisimura 	struct proc *p;
1.1  nisimura {
1.1  nisimura 	dev_t consdev;
1.1  nisimura
1.1  nisimura 	/* all sysctl names at this level are terminal */
1.1  nisimura 	if (namelen != 1)
1.1  nisimura 		return (ENOTDIR);		/* overloaded */
1.1  nisimura
1.1  nisimura 	switch (name[0]) {
1.1  nisimura 	case CPU_CONSDEV:
1.1  nisimura 		if (cn_tab != NULL)
1.1  nisimura 			consdev = cn_tab->cn_dev;
1.1  nisimura 		else
1.1  nisimura 			consdev = NODEV;
1.1  nisimura 		return (sysctl_rdstruct(oldp, oldlenp, newp, &consdev,
1.1  nisimura 		    sizeof consdev));
1.1  nisimura 	default:
1.1  nisimura 		return (EOPNOTSUPP);
1.1  nisimura 	}
1.1  nisimura 	/* NOTREACHED */
1.1  nisimura }
1.1  nisimura
1.1  nisimura int	waittime = -1;
1.1  nisimura
1.1  nisimura void
1.1  nisimura cpu_reboot(howto, bootstr)
1.1  nisimura 	volatile int howto; /* XXX to shutup GCC XXX */
1.1  nisimura 	char *bootstr;
1.1  nisimura {
1.1  nisimura 	extern void doboot __P((void));
1.1  nisimura
1.1  nisimura 	/* take a snap shot before clobbering any registers */
1.1  nisimura 	if (curproc && curproc->p_addr)
1.1  nisimura 		savectx(&curproc->p_addr->u_pcb);
1.1  nisimura
1.1  nisimura 	/* If system is hold, just halt. */
1.1  nisimura 	if (cold) {
1.1  nisimura 		howto |= RB_HALT;
1.1  nisimura 		goto haltsys;
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	boothowto = howto;
1.1  nisimura 	if ((howto & RB_NOSYNC) == 0 && waittime < 0) {
1.1  nisimura 		waittime = 0;
1.1  nisimura 		vfs_shutdown();
1.1  nisimura 		/*
1.1  nisimura 		 * If we've been adjusting the clock, the todr
1.1  nisimura 		 * will be out of synch; adjust it now.
1.1  nisimura 		 */
1.1  nisimura 		resettodr();
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	/* Disable interrupts. */
1.1  nisimura 	splhigh();
1.1  nisimura
1.1  nisimura 	/* If rebooting and a dump is requested, do it. */
1.1  nisimura 	if (howto & RB_DUMP)
1.1  nisimura 		dumpsys();
1.1  nisimura
1.1  nisimura haltsys:
1.1  nisimura 	/* Run any shutdown hooks. */
1.1  nisimura 	doshutdownhooks();
1.1  nisimura
1.1  nisimura 	/* Finally, halt/reboot the system. */
1.1  nisimura 	if ((howto & RB_POWERDOWN) == RB_POWERDOWN) {
1.1  nisimura 		u_int8_t *pio = (void *)0x4d000000;
1.1  nisimura
1.1  nisimura 		printf("power is going down.\n");
1.1  nisimura 		DELAY(100000);
1.1  nisimura 		pio[3] = 0x94;
1.1  nisimura 		pio[2] = 0 << 4;
1.1  nisimura 		for (;;) /* NOP */;
1.1  nisimura 	}
1.1  nisimura 	if (howto & RB_HALT) {
1.1  nisimura 		printf("System halted.	Hit any key to reboot.\n\n");
1.1  nisimura 		(void)cngetc();
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	printf("rebooting...\n");
1.1  nisimura 	DELAY(100000);
1.1  nisimura 	doboot();
1.1  nisimura 	/*NOTREACHED*/
1.1  nisimura 	while (1) ;
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Initialize the kernel crash dump header.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura cpu_init_kcore_hdr()
1.1  nisimura {
1.1  nisimura 	cpu_kcore_hdr_t *h = &cpu_kcore_hdr;
1.1  nisimura 	struct m68k_kcore_hdr *m = &h->un._m68k;
1.1  nisimura 	extern char end[];
1.1  nisimura
1.1  nisimura 	bzero(&cpu_kcore_hdr, sizeof(cpu_kcore_hdr));
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize the `dispatcher' portion of the header.
1.1  nisimura 	 */
1.1  nisimura 	strcpy(h->name, machine);
1.1  nisimura 	h->page_size = NBPG;
1.1  nisimura 	h->kernbase = KERNBASE;
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Fill in information about our MMU configuration.
1.1  nisimura 	 */
1.1  nisimura 	m->mmutype	= mmutype;
1.1  nisimura 	m->sg_v		= SG_V;
1.1  nisimura 	m->sg_frame	= SG_FRAME;
1.1  nisimura 	m->sg_ishift	= SG_ISHIFT;
1.1  nisimura 	m->sg_pmask	= SG_PMASK;
1.1  nisimura 	m->sg40_shift1	= SG4_SHIFT1;
1.1  nisimura 	m->sg40_mask2	= SG4_MASK2;
1.1  nisimura 	m->sg40_shift2	= SG4_SHIFT2;
1.1  nisimura 	m->sg40_mask3	= SG4_MASK3;
1.1  nisimura 	m->sg40_shift3	= SG4_SHIFT3;
1.1  nisimura 	m->sg40_addr1	= SG4_ADDR1;
1.1  nisimura 	m->sg40_addr2	= SG4_ADDR2;
1.1  nisimura 	m->pg_v		= PG_V;
1.1  nisimura 	m->pg_frame	= PG_FRAME;
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize pointer to kernel segment table.
1.1  nisimura 	 */
1.1  nisimura 	m->sysseg_pa = (u_int32_t)(pmap_kernel()->pm_stpa);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Initialize relocation value such that:
1.1  nisimura 	 *
1.1  nisimura 	 *	pa = (va - KERNBASE) + reloc
1.1  nisimura 	 *
1.1  nisimura 	 * Since we're linked and loaded at the same place,
1.1  nisimura 	 * and the kernel is mapped va == pa, this is 0.
1.1  nisimura 	 */
1.1  nisimura 	m->reloc = 0;
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Define the end of the relocatable range.
1.1  nisimura 	 */
1.1  nisimura 	m->relocend = (u_int32_t)end;
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * The luna68k has one contiguous memory segment.
1.1  nisimura 	 */
1.1  nisimura 	m->ram_segs[0].start = 0 /* lowram */;
1.1  nisimura 	m->ram_segs[0].size  = ctob(physmem);
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Compute the size of the machine-dependent crash dump header.
1.1  nisimura  * Returns size in disk blocks.
1.1  nisimura  */
1.1  nisimura int
1.1  nisimura cpu_dumpsize()
1.1  nisimura {
1.1  nisimura 	int size;
1.1  nisimura
1.1  nisimura 	size = ALIGN(sizeof(kcore_seg_t)) + ALIGN(sizeof(cpu_kcore_hdr_t));
1.1  nisimura 	return (btodb(roundup(size, dbtob(1))));
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Called by dumpsys() to dump the machine-dependent header.
1.1  nisimura  */
1.1  nisimura int
1.1  nisimura cpu_dump(dump, blknop)
1.1  nisimura 	int (*dump) __P((dev_t, daddr_t, caddr_t, size_t));
1.1  nisimura 	daddr_t *blknop;
1.1  nisimura {
1.1  nisimura 	int buf[dbtob(1) / sizeof(int)];
1.1  nisimura 	cpu_kcore_hdr_t *chdr;
1.1  nisimura 	kcore_seg_t *kseg;
1.1  nisimura 	int error;
1.1  nisimura
1.1  nisimura 	kseg = (kcore_seg_t *)buf;
1.1  nisimura 	chdr = (cpu_kcore_hdr_t *)&buf[ALIGN(sizeof(kcore_seg_t)) /
1.1  nisimura 	    sizeof(int)];
1.1  nisimura
1.1  nisimura 	/* Create the segment header. */
1.1  nisimura 	CORE_SETMAGIC(*kseg, KCORE_MAGIC, MID_MACHINE, CORE_CPU);
1.1  nisimura 	kseg->c_size = dbtob(1) - ALIGN(sizeof(kcore_seg_t));
1.1  nisimura
1.1  nisimura 	bcopy(&cpu_kcore_hdr, chdr, sizeof(cpu_kcore_hdr_t));
1.1  nisimura 	error = (*dump)(dumpdev, *blknop, (caddr_t)buf, sizeof(buf));
1.1  nisimura 	*blknop += btodb(sizeof(buf));
1.1  nisimura 	return (error);
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * These variables are needed by /sbin/savecore
1.1  nisimura  */
1.1  nisimura u_long	dumpmag = 0x8fca0101;	/* magic number */
1.1  nisimura int	dumpsize = 0;		/* pages */
1.1  nisimura long	dumplo = 0;		/* blocks */
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * This is called by main to set dumplo and dumpsize.
1.1  nisimura  * Dumps always skip the first NBPG of disk space
1.1  nisimura  * in case there might be a disk label stored there.
1.1  nisimura  * If there is extra space, put dump at the end to
1.1  nisimura  * reduce the chance that swapping trashes it.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura cpu_dumpconf()
1.1  nisimura {
1.1  nisimura 	int chdrsize;	/* size of dump header */
1.1  nisimura 	int nblks;	/* size of dump area */
1.1  nisimura 	int maj;
1.1  nisimura
1.1  nisimura 	if (dumpdev == NODEV)
1.1  nisimura 		return;
1.1  nisimura 	maj = major(dumpdev);
1.1  nisimura 	if (maj < 0 || maj >= nblkdev)
1.1  nisimura 		panic("dumpconf: bad dumpdev=0x%x", dumpdev);
1.1  nisimura 	if (bdevsw[maj].d_psize == NULL)
1.1  nisimura 		return;
1.1  nisimura 	nblks = (*bdevsw[maj].d_psize)(dumpdev);
1.1  nisimura 	chdrsize = cpu_dumpsize();
1.1  nisimura
1.1  nisimura 	dumpsize = btoc(cpu_kcore_hdr.un._m68k.ram_segs[0].size);
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Check do see if we will fit.  Note we always skip the
1.1  nisimura 	 * first NBPG in case there is a disk label there.
1.1  nisimura 	 */
1.1  nisimura 	if (nblks < (ctod(dumpsize) + chdrsize + ctod(1))) {
1.1  nisimura 		dumpsize = 0;
1.1  nisimura 		dumplo = -1;
1.1  nisimura 		return;
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	/*
1.1  nisimura 	 * Put dump at the end of the partition.
1.1  nisimura 	 */
1.1  nisimura 	dumplo = (nblks - 1) - ctod(dumpsize) - chdrsize;
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Dump physical memory onto the dump device.  Called by cpu_reboot().
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura dumpsys()
1.1  nisimura {
1.1  nisimura 	daddr_t blkno;		/* current block to write */
1.1  nisimura 				/* dump routine */
1.1  nisimura 	int (*dump) __P((dev_t, daddr_t, caddr_t, size_t));
1.1  nisimura 	int pg;			/* page being dumped */
1.1  nisimura 	paddr_t maddr;		/* PA being dumped */
1.1  nisimura 	int error;		/* error code from (*dump)() */
1.1  nisimura
1.1  nisimura 	/* XXX initialized here because of gcc lossage */
1.1  nisimura 	maddr = 0 /* lowram */;
1.1  nisimura 	pg = 0;
1.1  nisimura
1.1  nisimura 	/* Don't put dump messages in msgbuf. */
1.1  nisimura 	msgbufenabled = 0;
1.1  nisimura
1.1  nisimura 	/* Make sure dump device is valid. */
1.1  nisimura 	if (dumpdev == NODEV)
1.1  nisimura 		return;
1.1  nisimura 	if (dumpsize == 0) {
1.1  nisimura 		cpu_dumpconf();
1.1  nisimura 		if (dumpsize == 0)
1.1  nisimura 			return;
1.1  nisimura 	}
1.1  nisimura 	if (dumplo <= 0) {
1.1  nisimura 		printf("\ndump to dev %u,%u not possible\n", major(dumpdev),
1.1  nisimura 		    minor(dumpdev));
1.1  nisimura 		return;
1.1  nisimura 	}
1.1  nisimura 	dump = bdevsw[major(dumpdev)].d_dump;
1.1  nisimura 	blkno = dumplo;
1.1  nisimura
1.1  nisimura 	printf("\ndumping to dev %u,%u offset %ld\n", major(dumpdev),
1.1  nisimura 	    minor(dumpdev), dumplo);
1.1  nisimura
1.1  nisimura 	printf("dump ");
1.1  nisimura
1.1  nisimura 	/* Write the dump header. */
1.1  nisimura 	error = cpu_dump(dump, &blkno);
1.1  nisimura 	if (error)
1.1  nisimura 		goto bad;
1.1  nisimura
1.1  nisimura 	for (pg = 0; pg < dumpsize; pg++) {
1.1  nisimura #define NPGMB	(1024*1024/NBPG)
1.1  nisimura 		/* print out how many MBs we have dumped */
1.1  nisimura 		if (pg && (pg % NPGMB) == 0)
1.1  nisimura 			printf("%d ", pg / NPGMB);
1.1  nisimura #undef NPGMB
1.1  nisimura 		pmap_enter(pmap_kernel(), (vaddr_t)vmmap, maddr,
1.1  nisimura 		    VM_PROT_READ, VM_PROT_READ|PMAP_WIRED);
1.1  nisimura
1.1  nisimura 		error = (*dump)(dumpdev, blkno, vmmap, NBPG);
1.1  nisimura  bad:
1.1  nisimura 		switch (error) {
1.1  nisimura 		case 0:
1.1  nisimura 			maddr += NBPG;
1.1  nisimura 			blkno += btodb(NBPG);
1.1  nisimura 			break;
1.1  nisimura
1.1  nisimura 		case ENXIO:
1.1  nisimura 			printf("device bad\n");
1.1  nisimura 			return;
1.1  nisimura
1.1  nisimura 		case EFAULT:
1.1  nisimura 			printf("device not ready\n");
1.1  nisimura 			return;
1.1  nisimura
1.1  nisimura 		case EINVAL:
1.1  nisimura 			printf("area improper\n");
1.1  nisimura 			return;
1.1  nisimura
1.1  nisimura 		case EIO:
1.1  nisimura 			printf("i/o error\n");
1.1  nisimura 			return;
1.1  nisimura
1.1  nisimura 		case EINTR:
1.1  nisimura 			printf("aborted from console\n");
1.1  nisimura 			return;
1.1  nisimura
1.1  nisimura 		default:
1.1  nisimura 			printf("error %d\n", error);
1.1  nisimura 			return;
1.1  nisimura 		}
1.1  nisimura 	}
1.1  nisimura 	printf("succeeded\n");
1.1  nisimura }
1.1  nisimura
1.1  nisimura void
1.1  nisimura straytrap(pc, evec)
1.1  nisimura 	int pc;
1.1  nisimura 	u_short evec;
1.1  nisimura {
1.1  nisimura 	printf("unexpected trap (vector offset %x) from %x\n",
1.1  nisimura 	       evec & 0xFFF, pc);
1.1  nisimura }
1.1  nisimura
1.1  nisimura int	*nofault;
1.1  nisimura
1.1  nisimura int
1.1  nisimura badaddr(addr, nbytes)
1.1  nisimura 	register caddr_t addr;
1.1  nisimura 	int nbytes;
1.1  nisimura {
1.1  nisimura 	register int i;
1.1  nisimura 	label_t faultbuf;
1.1  nisimura
1.1  nisimura #ifdef lint
1.1  nisimura 	i = *addr; if (i) return (0);
1.1  nisimura #endif
1.1  nisimura
1.1  nisimura 	nofault = (int *) &faultbuf;
1.1  nisimura 	if (setjmp((label_t *)nofault)) {
1.1  nisimura 		nofault = (int *) 0;
1.1  nisimura 		return(1);
1.1  nisimura 	}
1.1  nisimura
1.1  nisimura 	switch (nbytes) {
1.1  nisimura 	case 1:
1.1  nisimura 		i = *(volatile char *)addr;
1.1  nisimura 		break;
1.1  nisimura
1.1  nisimura 	case 2:
1.1  nisimura 		i = *(volatile short *)addr;
1.1  nisimura 		break;
1.1  nisimura
1.1  nisimura 	case 4:
1.1  nisimura 		i = *(volatile int *)addr;
1.1  nisimura 		break;
1.1  nisimura
1.1  nisimura 	default:
1.1  nisimura 		panic("badaddr: bad request");
1.1  nisimura 	}
1.1  nisimura 	nofault = (int *) 0;
1.1  nisimura 	return (0);
1.1  nisimura }
1.1  nisimura
1.1  nisimura void luna68k_abort __P((char *));
1.1  nisimura
1.1  nisimura static int innmihand;	/* simple mutex */
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Level 7 interrupts are caused by e.g. the ABORT switch.
1.1  nisimura  *
1.1  nisimura  * If we have DDB, then break into DDB on ABORT.  In a production
1.1  nisimura  * environment, bumping the ABORT switch would be bad, so we enable
1.1  nisimura  * panic'ing on ABORT with the kernel option "PANICBUTTON".
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura nmihand(frame)
1.1  nisimura 	struct frame frame;
1.1  nisimura {
1.1  nisimura 	/* Prevent unwanted recursion */
1.1  nisimura 	if (innmihand)
1.1  nisimura 		return;
1.1  nisimura 	innmihand = 1;
1.1  nisimura
1.1  nisimura 	luna68k_abort("ABORT SWITCH");
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Common code for handling ABORT signals from buttons, switches,
1.1  nisimura  * serial lines, etc.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura luna68k_abort(cp)
1.1  nisimura 	char *cp;
1.1  nisimura {
1.1  nisimura #ifdef DDB
1.1  nisimura 	printf("%s\n", cp);
1.1  nisimura 	cpu_Debugger();
1.1  nisimura #else
1.1  nisimura #ifdef PANICBUTTON
1.1  nisimura 	panic(cp);
1.1  nisimura #else
1.1  nisimura 	printf("%s ignored\n", cp);
1.1  nisimura #endif /* PANICBUTTON */
1.1  nisimura #endif /* DDB */
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * cpu_exec_aout_makecmds():
1.1  nisimura  *	cpu-dependent a.out format hook for execve().
1.1  nisimura  *
1.1  nisimura  * Determine of the given exec package refers to something which we
1.1  nisimura  * understand and, if so, set up the vmcmds for it.
1.1  nisimura  */
1.1  nisimura int
1.1  nisimura cpu_exec_aout_makecmds(p, epp)
1.1  nisimura 	struct proc *p;
1.1  nisimura 	struct exec_package *epp;
1.1  nisimura {
1.1  nisimura 	int error = ENOEXEC;
1.1  nisimura #ifdef COMPAT_SUNOS
1.1  nisimura 	extern sunos_exec_aout_makecmds
1.1  nisimura 	__P((struct proc *, struct exec_package *));
1.1  nisimura 	if ((error = sunos_exec_aout_makecmds(p, epp)) == 0)
1.1  nisimura 		return 0;
1.1  nisimura #endif
1.1  nisimura 	return error;
1.1  nisimura }
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * Return the best possible estimate of the time in the timeval
1.1  nisimura  * to which tvp points.	 Unfortunately, we can't read the hardware registers.
1.1  nisimura  * We guarantee that the time will be greater than the value obtained by a
1.1  nisimura  * previous call.
1.1  nisimura  */
1.1  nisimura void
1.1  nisimura microtime(tvp)
1.1  nisimura 	register struct timeval *tvp;
1.1  nisimura {
1.1  nisimura 	int s = splclock();
1.1  nisimura 	static struct timeval lasttime;
1.1  nisimura
1.1  nisimura 	*tvp = time;
1.1  nisimura #ifdef notdef
1.1  nisimura 	tvp->tv_usec += clkread();
1.3   msaitoh 	while (tvp->tv_usec >= 1000000) {
1.1  nisimura 		tvp->tv_sec++;
1.1  nisimura 		tvp->tv_usec -= 1000000;
1.1  nisimura 	}
1.1  nisimura #endif
1.1  nisimura 	if (tvp->tv_sec == lasttime.tv_sec &&
1.1  nisimura 	    tvp->tv_usec <= lasttime.tv_usec &&
1.3   msaitoh 	    (tvp->tv_usec = lasttime.tv_usec + 1) >= 1000000) {
1.1  nisimura 		tvp->tv_sec++;
1.1  nisimura 		tvp->tv_usec -= 1000000;
1.1  nisimura 	}
1.1  nisimura 	lasttime = *tvp;
1.1  nisimura 	splx(s);
1.1  nisimura }
1.1  nisimura
1.2  nisimura #if 1
1.1  nisimura
1.1  nisimura struct consdev *cn_tab = &syscons;
1.1  nisimura
1.1  nisimura #else
1.1  nisimura
1.1  nisimura /*
1.1  nisimura  * romcons is useful until m68k TC register is initialized.
1.1  nisimura  */
1.1  nisimura int  romcngetc __P((dev_t));
1.1  nisimura void romcnputc __P((dev_t, int));
1.1  nisimura
1.1  nisimura struct consdev romcons = {
1.1  nisimura 	NULL,
1.1  nisimura 	NULL,
1.1  nisimura 	romcngetc,
1.1  nisimura 	romcnputc,
1.1  nisimura 	nullcnpollc,
1.1  nisimura 	makedev(7, 0), /* XXX */
1.1  nisimura 	CN_DEAD,
1.1  nisimura };
1.1  nisimura struct consdev *cn_tab = &romcons;
1.1  nisimura
1.2  nisimura #define __		((int **)0x41000000)
1.2  nisimura #define GETC()		(*(int (*)())__[6])()
1.2  nisimura #define PUTC(x)		(*(void (*)())__[7])(x)
1.2  nisimura
1.2  nisimura #define ROMPUTC(x) \
1.2  nisimura ({					\
1.2  nisimura 	register _r;			\
1.2  nisimura 	asm volatile ("			\
1.2  nisimura 		movc	vbr,%0		; \
1.2  nisimura 		movel	%0,sp@-		; \
1.2  nisimura 		clrl	%0		; \
1.2  nisimura 		movc	%0,vbr"		\
1.2  nisimura 		: "=r" (_r));		\
1.2  nisimura 	PUTC(x);			\
1.2  nisimura 	asm volatile ("			\
1.2  nisimura 		movel	sp@+,%0		; \
1.2  nisimura 		movc	%0,vbr"		\
1.2  nisimura 		: "=r" (_r));		\
1.2  nisimura })
1.2  nisimura
1.2  nisimura #define ROMGETC() \
1.2  nisimura ({					\
1.2  nisimura 	register _r, _c;		\
1.2  nisimura 	asm volatile ("			\
1.2  nisimura 		movc	vbr,%0		; \
1.2  nisimura 		movel	%0,sp@-		; \
1.2  nisimura 		clrl	%0		; \
1.2  nisimura 		movc	%0,vbr"		\
1.2  nisimura 		: "=r" (_r));		\
1.2  nisimura 	_c = GETC();			\
1.2  nisimura 	asm volatile ("			\
1.2  nisimura 		movel	sp@+,%0		; \
1.2  nisimura 		movc	%0,vbr"		\
1.2  nisimura 		: "=r" (_r));		\
1.2  nisimura 	_c;				\
1.2  nisimura })
1.1  nisimura
1.1  nisimura void
1.1  nisimura romcnputc(dev, c)
1.1  nisimura 	dev_t dev;
1.1  nisimura 	int c;
1.1  nisimura {
1.2  nisimura 	int s;
1.2  nisimura
1.2  nisimura 	s = splhigh();
1.1  nisimura 	ROMPUTC(c);
1.2  nisimura 	splx(s);
1.1  nisimura }
1.1  nisimura
1.1  nisimura int
1.1  nisimura romcngetc(dev)
1.1  nisimura 	dev_t dev;
1.1  nisimura {
1.2  nisimura 	int s, c;
1.1  nisimura
1.1  nisimura 	do {
1.2  nisimura 		s = splhigh();
1.1  nisimura 		c = ROMGETC();
1.2  nisimura 		splx(s);
1.1  nisimura 	} while (c == -1);
1.1  nisimura 	return c;
1.1  nisimura }
1.1  nisimura #endif