示例#1
0
文件: hwd.c 项目: kylelutz/link-os
/* Return amount of RAM in bytes */
long ramsize(void)
{
    static long size = 0;
    if(!size){
        size = probe_memory(RAM_BASE,RAM_MAX_SIZE);
    }
    return size;
}
示例#2
0
文件: stage2.c 项目: HTshandou/newos
int _start(char *boot_args, char *monitor)
{
	unsigned int bootdir_pages;

	memset(&ka, 0, sizeof(ka));

	init_nextmon(monitor);
	dprintf("\nNewOS stage2: args '%s', monitor %p\n", boot_args, monitor);

	probe_memory(&ka);

	dprintf("tc 0x%x\n", get_tc());
	dprintf("urp 0x%x\n", get_urp());
	dprintf("srp 0x%x\n", get_srp());

	// calculate how big the bootdir is
	{
		int entry;
		bootdir_pages = 0;
		for (entry = 0; entry < BOOTDIR_MAX_ENTRIES; entry++) {
			if (bootdir[entry].be_type == BE_TYPE_NONE)
				break;

			bootdir_pages += bootdir[entry].be_size;
		}
		ka.bootdir_addr.start = (unsigned long)bootdir;
		ka.bootdir_addr.size = bootdir_pages * PAGE_SIZE;
		dprintf("bootdir: start %p, size 0x%x\n", (char *)ka.bootdir_addr.start, ka.bootdir_addr.size);
	}

	// begin to set up the physical page allocation range data structures
	ka.num_phys_alloc_ranges = 1;
	ka.phys_alloc_range[0].start = ka.bootdir_addr.start;
	ka.phys_alloc_range[0].size = ka.bootdir_addr.size;

	// allocate a stack for the kernel when we jump into it
	ka.cpu_kstack[0].start = allocate_page(&ka);
	ka.cpu_kstack[0].size = PAGE_SIZE;

	ka.num_cpus = 1;

	return 0;
}
示例#3
0
文件: ip22-mc.c 项目: 12zz/linux
void __init sgimc_init(void)
{
	u32 tmp;

	/* ioremap can't fail */
	sgimc = (struct sgimc_regs *)
		ioremap(SGIMC_BASE, sizeof(struct sgimc_regs));

	printk(KERN_INFO "MC: SGI memory controller Revision %d\n",
	       (int) sgimc->systemid & SGIMC_SYSID_MASKREV);

	/* Place the MC into a known state.  This must be done before
	 * interrupts are first enabled etc.
	 */

	/* Step 0: Make sure we turn off the watchdog in case it's
	 *	   still running (which might be the case after a
	 *	   soft reboot).
	 */
	tmp = sgimc->cpuctrl0;
	tmp &= ~SGIMC_CCTRL0_WDOG;
	sgimc->cpuctrl0 = tmp;

	/* Step 1: The CPU/GIO error status registers will not latch
	 *	   up a new error status until the register has been
	 *	   cleared by the cpu.	These status registers are
	 *	   cleared by writing any value to them.
	 */
	sgimc->cstat = sgimc->gstat = 0;

	/* Step 2: Enable all parity checking in cpu control register
	 *	   zero.
	 */
	/* don't touch parity settings for IP28 */
	tmp = sgimc->cpuctrl0;
#ifndef CONFIG_SGI_IP28
	tmp |= SGIMC_CCTRL0_EPERRGIO | SGIMC_CCTRL0_EPERRMEM;
#endif
	tmp |= SGIMC_CCTRL0_R4KNOCHKPARR;
	sgimc->cpuctrl0 = tmp;

	/* Step 3: Setup the MC write buffer depth, this is controlled
	 *	   in cpu control register 1 in the lower 4 bits.
	 */
	tmp = sgimc->cpuctrl1;
	tmp &= ~0xf;
	tmp |= 0xd;
	sgimc->cpuctrl1 = tmp;

	/* Step 4: Initialize the RPSS divider register to run as fast
	 *	   as it can correctly operate.	 The register is laid
	 *	   out as follows:
	 *
	 *	   ----------------------------------------
	 *	   |  RESERVED	|   INCREMENT	| DIVIDER |
	 *	   ----------------------------------------
	 *	    31	      16 15	       8 7	 0
	 *
	 *	   DIVIDER determines how often a 'tick' happens,
	 *	   INCREMENT determines by how the RPSS increment
	 *	   registers value increases at each 'tick'. Thus,
	 *	   for IP22 we get INCREMENT=1, DIVIDER=1 == 0x101
	 */
	sgimc->divider = 0x101;

	/* Step 5: Initialize GIO64 arbitrator configuration register.
	 *
	 * NOTE: HPC init code in sgihpc_init() must run before us because
	 *	 we need to know Guiness vs. FullHouse and the board
	 *	 revision on this machine. You have been warned.
	 */

	/* First the basic invariants across all GIO64 implementations. */
	tmp = sgimc->giopar & SGIMC_GIOPAR_GFX64; /* keep gfx 64bit settings */
	tmp |= SGIMC_GIOPAR_HPC64;	/* All 1st HPC's interface at 64bits */
	tmp |= SGIMC_GIOPAR_ONEBUS;	/* Only one physical GIO bus exists */

	if (ip22_is_fullhouse()) {
		/* Fullhouse specific settings. */
		if (SGIOC_SYSID_BOARDREV(sgioc->sysid) < 2) {
			tmp |= SGIMC_GIOPAR_HPC264;	/* 2nd HPC at 64bits */
			tmp |= SGIMC_GIOPAR_PLINEEXP0;	/* exp0 pipelines */
			tmp |= SGIMC_GIOPAR_MASTEREXP1; /* exp1 masters */
			tmp |= SGIMC_GIOPAR_RTIMEEXP0;	/* exp0 is realtime */
		} else {
			tmp |= SGIMC_GIOPAR_HPC264;	/* 2nd HPC 64bits */
			tmp |= SGIMC_GIOPAR_PLINEEXP0;	/* exp[01] pipelined */
			tmp |= SGIMC_GIOPAR_PLINEEXP1;
			tmp |= SGIMC_GIOPAR_MASTEREISA; /* EISA masters */
		}
	} else {
		/* Guiness specific settings. */
		tmp |= SGIMC_GIOPAR_EISA64;	/* MC talks to EISA at 64bits */
		tmp |= SGIMC_GIOPAR_MASTEREISA; /* EISA bus can act as master */
	}
	sgimc->giopar = tmp;	/* poof */

	probe_memory();
}