evbmips/rasoc/machdep.c

1.2  matt /*	$NetBSD: machdep.c,v 1.2 2011/07/28 15:50:13 matt Exp $	*/
1.2  matt /*-
1.2  matt  * Copyright (c) 2011 CradlePoint Technology, Inc.
1.2  matt  * All rights reserved.
1.2  matt  *
1.2  matt  *
1.2  matt  * Redistribution and use in source and binary forms, with or without
1.2  matt  * modification, are permitted provided that the following conditions
1.2  matt  * are met:
1.2  matt  * 1. Redistributions of source code must retain the above copyright
1.2  matt  *    notice, this list of conditions and the following disclaimer.
1.2  matt  * 2. Redistributions in binary form must reproduce the above copyright
1.2  matt  *    notice, this list of conditions and the following disclaimer in the
1.2  matt  *    documentation and/or other materials provided with the distribution.
1.2  matt  *
1.2  matt  * THIS SOFTWARE IS PROVIDED BY CRADLEPOINT TECHNOLOGY, INC. AND CONTRIBUTORS
1.2  matt  * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
1.2  matt  * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
1.2  matt  * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS
1.2  matt  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
1.2  matt  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
1.2  matt  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
1.2  matt  * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
1.2  matt  * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
1.2  matt  * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
1.2  matt  * POSSIBILITY OF SUCH DAMAGE.
1.2  matt  */
1.2  matt
1.2  matt #include <sys/cdefs.h>			/* RCS ID & Copyright macro defns */
1.2  matt __KERNEL_RCSID(0, "$NetBSD: machdep.c,v 1.2 2011/07/28 15:50:13 matt Exp $");
1.2  matt
1.2  matt #include <sys/param.h>
1.2  matt #include <sys/boot_flag.h>
1.2  matt #include <sys/buf.h>
1.2  matt #include <sys/device.h>
1.2  matt #include <sys/mount.h>
1.2  matt #include <sys/kcore.h>
1.2  matt #include <sys/reboot.h>
1.2  matt #include <sys/systm.h>
1.2  matt #include <sys/kernel.h>
1.2  matt #include <sys/termios.h>
1.2  matt
1.2  matt #include <uvm/uvm_extern.h>
1.2  matt
1.2  matt #include <dev/cons.h>
1.2  matt
1.2  matt #include <mips/cache.h>
1.2  matt #include <mips/locore.h>
1.2  matt #include <mips/cpuregs.h>
1.2  matt
1.2  matt #include <mips/ralink/ralink_reg.h>
1.2  matt #include <mips/ralink/ralink_var.h>
1.2  matt
1.2  matt /* structures we define/alloc for other files in the kernel */
1.2  matt struct vm_map *mb_map = NULL;
1.2  matt struct vm_map *phys_map = NULL;
1.2  matt struct cpu_info cpu_info_store;
1.2  matt int physmem;		/* # pages of physical memory */
1.2  matt int mem_cluster_cnt = 0;
1.2  matt phys_ram_seg_t mem_clusters[VM_PHYSSEG_MAX];
1.2  matt
1.2  matt /* structures others define for us */
1.2  matt extern struct user *proc0paddr;
1.2  matt
1.2  matt void mach_init(void);
1.2  matt
1.2  matt static inline uint32_t
1.2  matt sysctl_read(u_int offset)
1.2  matt {
1.2  matt 	return *RA_IOREG_VADDR(RA_SYSCTL_BASE, offset);
1.2  matt }
1.2  matt
1.2  matt static inline void
1.2  matt sysctl_write(u_int offset, uint32_t val)
1.2  matt {
1.2  matt 	*RA_IOREG_VADDR(RA_SYSCTL_BASE, offset) = val;
1.2  matt }
1.2  matt
1.2  matt static void
1.2  matt cal_timer(void)
1.2  matt {
1.2  matt 	uint32_t cntfreq;
1.2  matt
1.2  matt 	cntfreq = curcpu()->ci_cpu_freq = RA_CLOCK_RATE;
1.2  matt
1.2  matt 	/* MIPS 4Kc CP0 counts every other clock */
1.2  matt 	if (mips_options.mips_cpu_flags & CPU_MIPS_DOUBLE_COUNT)
1.2  matt 		cntfreq /= 2;
1.2  matt
1.2  matt 	curcpu()->ci_cycles_per_hz = (cntfreq + hz / 2) / hz;
1.2  matt
1.2  matt 	/* Compute number of cycles per 1us (1/MHz). 0.5MHz is for roundup. */
1.2  matt 	curcpu()->ci_divisor_delay = ((cntfreq + 500000) / 1000000);
1.2  matt }
1.2  matt
1.2  matt void
1.2  matt mach_init(void)
1.2  matt {
1.2  matt 	vaddr_t kernend;
1.2  matt 	psize_t memsize;
1.2  matt
1.2  matt 	extern char kernel_text[];
1.2  matt 	extern char edata[], end[];	/* From Linker */
1.2  matt
1.2  matt 	/* clear the BSS segment */
1.2  matt 	kernend = mips_round_page(end);
1.2  matt
1.2  matt 	memset(edata, 0, kernend - (vaddr_t)edata);
1.2  matt
1.2  matt #ifdef RA_CONSOLE_EARLY
1.2  matt 	/*
1.2  matt 	 * set up early console
1.2  matt 	 *  cannot printf until sometime (?) in mips_vector_init
1.2  matt 	 *  meanwhile can use the ra_console_putc primitive if necessary
1.2  matt 	 */
1.2  matt 	ra_console_early();
1.2  matt #endif
1.2  matt
1.2  matt 	/* set CPU model info for sysctl_hw */
1.2  matt 	uint32_t tmp;
1.2  matt 	tmp = sysctl_read(RA_SYSCTL_ID0);
1.2  matt 	memcpy(&cpu_model[0], &tmp, 4);
1.2  matt 	tmp = sysctl_read(RA_SYSCTL_ID1);
1.2  matt 	memcpy(&cpu_model[4], &tmp, 4);
1.2  matt 	cpu_model[9] = 0;
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Set up the exception vectors and CPU-specific function
1.2  matt 	 * vectors early on.  We need the wbflush() vector set up
1.2  matt 	 * before comcnattach() is called (or at least before the
1.2  matt 	 * first printf() after that is called).
1.2  matt 	 * Sets up mips_cpu_flags that may be queried by other
1.2  matt 	 * functions called during startup.
1.2  matt 	 * Also clears the I+D caches.
1.2  matt 	 */
1.2  matt 	mips_vector_init(NULL, false);
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Calibrate timers.
1.2  matt 	 */
1.2  matt 	cal_timer();
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Set the VM page size.
1.2  matt 	 */
1.2  matt 	uvm_setpagesize();
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Look at arguments passed to us and compute boothowto.
1.2  matt 	 */
1.2  matt 	boothowto = RB_AUTOBOOT;
1.2  matt #ifdef KADB
1.2  matt 	boothowto |= RB_KDB;
1.2  matt #endif
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Determine the memory size.
1.2  matt 	 *
1.2  matt 	 * Note: Reserve the first page!  That's where the trap
1.2  matt 	 * vectors are located.
1.2  matt 	 */
1.2  matt 	memsize = RTMEMSIZE * 1024 * 1024;
1.2  matt
1.2  matt 	physmem = btoc(memsize);
1.2  matt
1.2  matt 	mem_clusters[mem_cluster_cnt].start = PAGE_SIZE;
1.2  matt 	mem_clusters[mem_cluster_cnt].size =
1.2  matt 		memsize - mem_clusters[mem_cluster_cnt].start;
1.2  matt 	mem_cluster_cnt++;
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Load the memory into the VM system
1.2  matt 	 */
1.2  matt 	mips_page_physload((vaddr_t)kernel_text, kernend,
1.2  matt 	    mem_clusters, mem_cluster_cnt,
1.2  matt 	    NULL, 0);
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Initialize message buffer (at end of core).
1.2  matt 	 */
1.2  matt 	mips_init_msgbuf();
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Initialize the virtual memory system.
1.2  matt 	 */
1.2  matt 	pmap_bootstrap();
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Init mapping for u page(s) for proc0.
1.2  matt 	 */
1.2  matt 	mips_init_lwp0_uarea();
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Initialize busses.
1.2  matt 	 */
1.2  matt 	ra_bus_init();
1.2  matt
1.2  matt #ifdef DDB
1.2  matt 	if (boothowto & RB_KDB)
1.2  matt 		Debugger();
1.2  matt #endif
1.2  matt }
1.2  matt
1.2  matt void
1.2  matt cpu_startup(void)
1.2  matt {
1.2  matt 	char pbuf[9];
1.2  matt 	vaddr_t minaddr, maxaddr;
1.2  matt #ifdef DEBUG
1.2  matt 	extern int pmapdebug;		/* XXX */
1.2  matt 	int opmapdebug = pmapdebug;
1.2  matt
1.2  matt 	pmapdebug = 0;		/* Shut up pmap debug during bootstrap */
1.2  matt #endif
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Good {morning,afternoon,evening,night}.
1.2  matt 	 */
1.2  matt 	printf("%s%s", copyright, version);
1.2  matt 	printf("Boot processor: %s\n", cpu_model);
1.2  matt 	format_bytes(pbuf, sizeof(pbuf), RTMEMSIZE * 1024 * 1024);
1.2  matt 	printf("total memory = %s\n", pbuf);
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Allocate a submap for physio
1.2  matt 	 */
1.2  matt 	minaddr = 0;
1.2  matt 	phys_map = uvm_km_suballoc(kernel_map, &minaddr, &maxaddr,
1.2  matt 		VM_PHYS_SIZE, 0, FALSE, NULL);
1.2  matt
1.2  matt 	/*
1.2  matt 	 * No need to allocate an mbuf cluster submap.  Mbuf clusters
1.2  matt 	 * are allocated via the pool allocator, and we use KSEG to
1.2  matt 	 * map those pages.
1.2  matt 	 */
1.2  matt
1.2  matt #ifdef DEBUG
1.2  matt 	pmapdebug = opmapdebug;
1.2  matt #endif
1.2  matt 	format_bytes(pbuf, sizeof(pbuf), ptoa(uvmexp.free));
1.2  matt 	printf("avail memory = %s\n", pbuf);
1.2  matt }
1.2  matt
1.2  matt void
1.2  matt cpu_reboot(int howto, char *bootstr)
1.2  matt {
1.2  matt 	static int waittime = -1;
1.2  matt
1.2  matt 	/* Take a snapshot before clobbering any registers. */
1.2  matt 	savectx(lwp_getpcb(curlwp));
1.2  matt
1.2  matt 	/* If "always halt" was specified as a boot flag, obey. */
1.2  matt 	if (boothowto & RB_HALT)
1.2  matt 		howto |= RB_HALT;
1.2  matt
1.2  matt 	boothowto = howto;
1.2  matt
1.2  matt 	/* If system is cold, just halt. */
1.2  matt 	if (cold) {
1.2  matt 		boothowto |= RB_HALT;
1.2  matt 		goto haltsys;
1.2  matt 	}
1.2  matt
1.2  matt 	if ((boothowto & RB_NOSYNC) == 0 && waittime < 0) {
1.2  matt 		waittime = 0;
1.2  matt
1.2  matt 		/*
1.2  matt 		 * Synchronize the disks....
1.2  matt 		 */
1.2  matt 		vfs_shutdown();
1.2  matt
1.2  matt 		/*
1.2  matt 		 * If we've been adjusting the clock, the todr
1.2  matt 		 * will be out of synch; adjust it now.
1.2  matt 		 */
1.2  matt 		resettodr();
1.2  matt 	}
1.2  matt
1.2  matt 	/* Disable interrupts. */
1.2  matt 	splhigh();
1.2  matt
1.2  matt 	if (boothowto & RB_DUMP)
1.2  matt 		dumpsys();
1.2  matt
1.2  matt  haltsys:
1.2  matt 	/* Run any shutdown hooks. */
1.2  matt 	doshutdownhooks();
1.2  matt
1.2  matt 	pmf_system_shutdown(boothowto);
1.2  matt
1.2  matt 	/*
1.2  matt 	 * Firmware may autoboot (depending on settings), and we cannot pass
1.2  matt 	 * flags to it (at least I haven't figured out how to yet), so
1.2  matt 	 * we "pseudo-halt" now.
1.2  matt 	 */
1.2  matt 	if (boothowto & RB_HALT) {
1.2  matt 		printf("\n");
1.2  matt 		printf("The operating system has halted.\n");
1.2  matt 		printf("Please press any key to reboot.\n\n");
1.2  matt 		cnpollc(1);	/* For proper keyboard command handling */
1.2  matt 		cngetc();
1.2  matt 		cnpollc(0);
1.2  matt 	}
1.2  matt
1.2  matt 	printf("reseting board...\n\n");
1.2  matt 	mips_icache_sync_all();
1.2  matt 	mips_dcache_wbinv_all();
1.2  matt
1.2  matt 	sysctl_write(RA_SYSCTL_RST, 1);  /* SoC Reset */
1.2  matt 	sysctl_write(RA_SYSCTL_RST, 0);
1.2  matt
1.2  matt #if 0
1.2  matt 	__asm volatile("jr	%0" :: "r"(MIPS_RESET_EXC_VEC));
1.2  matt #endif
1.2  matt 	printf("Oops, back from reset\n\nSpinning...");
1.2  matt 	for (;;)
1.2  matt 		/* spin forever */ ;	/* XXX */
1.2  matt 	/*NOTREACHED*/
1.2  matt }
1.2  matt
1.2  matt #define NO_SECURITY_MAGIC	0x27051958
1.2  matt #define SERIAL_MAGIC		0x100000
1.2  matt int
1.2  matt ra_check_memo_reg(int key)
1.2  matt {
1.2  matt 	uint32_t magic;
1.2  matt
1.2  matt 	/*
1.2  matt 	 * These registers may be overwritten.  Keep the value around in case
1.2  matt 	 * it is used later.  Bitmask 1 == security, 2 = serial
1.2  matt 	 */
1.2  matt 	static int keyvalue;
1.2  matt
1.2  matt 	switch (key) {
1.2  matt 	case NO_SECURITY:
1.2  matt 		magic = sysctl_read(RA_SYSCTL_MEMO0);
1.2  matt 		if ((NO_SECURITY_MAGIC == magic) || ((keyvalue & 1) != 0)) {
1.2  matt 			keyvalue |= 1;
1.2  matt 			return 1;
1.2  matt 		}
1.2  matt 		return 0;
1.2  matt 		break;
1.2  matt
1.2  matt 	case SERIAL_CONSOLE:
1.2  matt 		magic = sysctl_read(RA_SYSCTL_MEMO1);
1.2  matt 		if (((SERIAL_MAGIC & magic) != 0) || ((keyvalue & 2) != 0)) {
1.2  matt 			keyvalue |= 2;
1.2  matt 			return 1;
1.2  matt 		}
1.2  matt 		return 0;
1.2  matt 		break;
1.2  matt
1.2  matt 	default:
1.2  matt 		return 0;
1.2  matt 	}
1.2  matt
1.2  matt }