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[/] [openrisc/] [trunk/] [rtos/] [rtems/] [c/] [src/] [lib/] [libbsp/] [powerpc/] [shared/] [bootloader/] [misc.c] - Rev 173
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/* * head.S -- Bootloader Entry point * * Copyright (C) 1998, 1999 Gabriel Paubert, paubert@iram.es * * Modified to compile in RTEMS development environment * by Eric Valette * * Copyright (C) 1999 Eric Valette. valette@crf.canon.fr * * The license and distribution terms for this file may be * found in found in the file LICENSE in this distribution or at * http://www.OARcorp.com/rtems/license.html. * * $Id: misc.c,v 1.2 2001-09-27 12:01:06 chris Exp $ */ #include <sys/types.h> #include <string.h> #include <libcpu/cpu.h> #include "bootldr.h" #include <libcpu/spr.h> #include "zlib.h" #include <libcpu/page.h> #include <libcpu/byteorder.h> SPR_RW(DEC) SPR_RO(PVR) struct inode; struct wait_queue; struct buffer_head; typedef struct { int counter; } atomic_t; typedef struct page { /* these must be first (free area handling) */ struct page *next; struct page *prev; struct inode *inode; unsigned long offset; struct page *next_hash; atomic_t count; unsigned long flags; /* atomic flags, some possibly updated asynchronously */ struct wait_queue *wait; struct page **pprev_hash; struct buffer_head * buffers; } mem_map_t; extern opaque mm_private, pci_private, v86_private, console_private; #define CONSOLE_ON_SERIAL "console=ttyS0" extern struct console_io vacuum_console_functions; extern opaque log_console_setup, serial_console_setup, vga_console_setup; boot_data __bd = {0, 0, 0, 0, 0, 0, 0, 0, 32, 0, 0, 0, 0, 0, 0, &mm_private, NULL, &pci_private, NULL, &v86_private, "root=/dev/hdc1" }; static void exit(void) __attribute__((noreturn)); static void exit(void) { printk("\nOnly way out is to press the reset button!\n"); asm volatile("": : :"memory"); while(1); } void hang(const char *s, u_long x, ctxt *p) { u_long *r1; #ifdef DEBUG print_all_maps("\nMemory mappings at exception time:\n"); #endif printk("%s %lx NIP: %p LR: %p\n" "Callback trace (stack:return address)\n", s, x, (void *) p->nip, (void *) p->lr); asm volatile("lwz %0,0(1); lwz %0,0(%0); lwz %0,0(%0)": "=b" (r1)); while(r1) { printk(" %p:%p\n", r1, (void *) r1[1]); r1 = (u_long *) *r1; } exit(); }; void *zalloc(void *x, unsigned items, unsigned size) { void *p = salloc(items*size); if (!p) { printk("oops... not enough memory for gunzip\n"); } return p; } void zfree(void *x, void *addr, unsigned nb) { sfree(addr); } #define HEAD_CRC 2 #define EXTRA_FIELD 4 #define ORIG_NAME 8 #define COMMENT 0x10 #define RESERVED 0xe0 #define DEFLATED 8 void gunzip(void *dst, int dstlen, unsigned char *src, int *lenp) { z_stream s; int r, i, flags; /* skip header */ i = 10; flags = src[3]; if (src[2] != DEFLATED || (flags & RESERVED) != 0) { printk("bad gzipped data\n"); exit(); } if ((flags & EXTRA_FIELD) != 0) i = 12 + src[10] + (src[11] << 8); if ((flags & ORIG_NAME) != 0) while (src[i++] != 0) ; if ((flags & COMMENT) != 0) while (src[i++] != 0) ; if ((flags & HEAD_CRC) != 0) i += 2; if (i >= *lenp) { printk("gunzip: ran out of data in header\n"); exit(); } s.zalloc = zalloc; s.zfree = zfree; r = inflateInit2(&s, -MAX_WBITS); if (r != Z_OK) { printk("inflateInit2 returned %d\n", r); exit(); } s.next_in = src + i; s.avail_in = *lenp - i; s.next_out = dst; s.avail_out = dstlen; r = inflate(&s, Z_FINISH); if (r != Z_OK && r != Z_STREAM_END) { printk("inflate returned %d\n", r); exit(); } *lenp = s.next_out - (unsigned char *) dst; inflateEnd(&s); } void decompress_kernel(int kernel_size, void * zimage_start, int len, void * initrd_start, int initrd_len ) { u_char *parea; RESIDUAL* rescopy; int zimage_size= len; /* That's a mess, we have to copy the residual data twice just in * case it happens to be in the low memory area where the kernel * is going to be unpacked. Later we have to copy it back to * lower addresses because only the lowest part of memory is mapped * during boot. */ parea=__palloc(kernel_size, PA_LOW); if(!parea) { printk("Not enough memory to uncompress the kernel."); exit(); } /* Note that this clears the bss as a side effect, so some code * with ugly special case for SMP could be removed from the kernel! */ memset(parea, 0, kernel_size); printk("\nUncompressing the kernel...\n"); rescopy=salloc(sizeof(RESIDUAL)); /* Let us hope that residual data is aligned on word boundary */ *rescopy = *bd->residual; bd->residual = (void *)PAGE_ALIGN(kernel_size); gunzip(parea, kernel_size, zimage_start, &zimage_size); bd->of_entry = 0; bd->load_address = 0; bd->r6 = (char *)bd->residual+PAGE_ALIGN(sizeof(RESIDUAL)); bd->r7 = bd->r6+strlen(bd->cmd_line); if ( initrd_len ) { /* We have to leave some room for the hash table and for the * whole array of struct page. The hash table would be better * located at the end of memory if possible. With some bridges * DMA from the last pages of memory is slower because * prefetching from PCI has to be disabled to avoid accessing * non existing memory. So it is the ideal place to put the * hash table. */ unsigned tmp = rescopy->TotalMemory; /* It's equivalent to tmp & (-tmp), but using the negation * operator on unsigned variables looks so ugly. */ if ((tmp & (~tmp+1)) != tmp) tmp <<= 1; /* Next power of 2 */ tmp /= 256; /* Size of hash table */ if (tmp> (2<<20)) tmp=2<<20; tmp = tmp*2 + 0x40000; /* Alignment can double size + 256 kB */ tmp += (rescopy->TotalMemory / PAGE_SIZE) * sizeof(struct page); bd->load_address = (void *)PAGE_ALIGN((int)bd->r7 + tmp); bd->of_entry = (char *)bd->load_address+initrd_len; } #ifdef DEBUG printk("Kernel at 0x%p, size=0x%x\n", NULL, kernel_size); printk("Initrd at 0x%p, size=0x%x\n",bd->load_address, initrd_len); printk("Residual data at 0x%p\n", bd->residual); printk("Command line at 0x%p\n",bd->r6); #endif printk("done\nNow booting...\n"); MMUoff(); /* We need to access address 0 ! */ codemove(0, parea, kernel_size, bd->cache_lsize); codemove(bd->residual, rescopy, sizeof(RESIDUAL), bd->cache_lsize); codemove(bd->r6, bd->cmd_line, sizeof(bd->cmd_line), bd->cache_lsize); /* codemove checks for 0 length */ codemove(bd->load_address, initrd_start, initrd_len, bd->cache_lsize); } void setup_hw(void) { char *cp, ch; register RESIDUAL * res; /* PPC_DEVICE * nvram; */ struct pci_dev *default_vga; int timer, err; u_short default_vga_cmd; static unsigned int indic; indic = 0; res=bd->residual; default_vga=NULL; default_vga_cmd = 0; #define vpd res->VitalProductData if (_read_PVR()>>16 != 1) { if ( res && vpd.ProcessorBusHz ) { ticks_per_ms = vpd.ProcessorBusHz/ (vpd.TimeBaseDivisor ? vpd.TimeBaseDivisor : 4000); } else { ticks_per_ms = 16500; /* assume 66 MHz on bus */ } } select_console(CONSOLE_LOG); /* We check that the keyboard is present and immediately * select the serial console if not. */ err = kbdreset(); if (err) select_console(CONSOLE_SERIAL); printk("\nModel: %s\nSerial: %s\n" "Processor/Bus frequencies (Hz): %ld/%ld\n" "Time Base Divisor: %ld\n" "Memory Size: %lx\n", vpd.PrintableModel, vpd.Serial, vpd.ProcessorHz, vpd.ProcessorBusHz, (vpd.TimeBaseDivisor ? vpd.TimeBaseDivisor : 4000), res->TotalMemory); printk("Original MSR: %lx\nOriginal HID0: %lx\nOriginal R31: %lx\n", bd->o_msr, bd->o_hid0, bd->o_r31); /* This reconfigures all the PCI subsystem */ pci_init(); /* The Motorola NT firmware does not set the correct mem size */ if ( vpd.FirmwareSupplier == 0x10000 ) { int memsize; memsize = find_max_mem(bd->pci_devices); if ( memsize != res->TotalMemory ) { printk("Changed Memory size from %lx to %x\n", res->TotalMemory, memsize); res->TotalMemory = memsize; res->GoodMemory = memsize; } } #define ENABLE_VGA_USAGE #undef ENABLE_VGA_USAGE #ifdef ENABLE_VGA_USAGE /* Find the primary VGA device, chosing the first one found * if none is enabled. The basic loop structure has been copied * from linux/drivers/char/bttv.c by Alan Cox. */ for (p = bd->pci_devices; p; p = p->next) { u_short cmd; if (p->class != PCI_CLASS_NOT_DEFINED_VGA && ((p->class) >> 16 != PCI_BASE_CLASS_DISPLAY)) continue; if (p->bus->number != 0) { printk("VGA device not on bus 0 not initialized!\n"); continue; } /* Only one can be active in text mode, which for now will * be assumed as equivalent to having I/O response enabled. */ pci_read_config_word(p, PCI_COMMAND, &cmd); if(cmd & PCI_COMMAND_IO || !default_vga) { default_vga=p; default_vga_cmd=cmd; } } /* Disable the enabled VGA device, if any. */ if (default_vga) pci_write_config_word(default_vga, PCI_COMMAND, default_vga_cmd& ~(PCI_COMMAND_IO|PCI_COMMAND_MEMORY)); init_v86(); /* Same loop copied from bttv.c, this time doing the serious work */ for (p = bd->pci_devices; p; p = p->next) { u_short cmd; if (p->class != PCI_CLASS_NOT_DEFINED_VGA && ((p->class) >> 16 != PCI_BASE_CLASS_DISPLAY)) continue; if (p->bus->number != 0) continue; pci_read_config_word(p, PCI_COMMAND, &cmd); pci_write_config_word(p, PCI_COMMAND, cmd|PCI_COMMAND_IO|PCI_COMMAND_MEMORY); printk("Calling the emulator.\n"); em86_main(p); pci_write_config_word(p, PCI_COMMAND, cmd); } cleanup_v86_mess(); #endif /* Reenable the primary VGA device */ if (default_vga) { pci_write_config_word(default_vga, PCI_COMMAND, default_vga_cmd| (PCI_COMMAND_IO|PCI_COMMAND_MEMORY)); if (err) { printk("Keyboard error %d, using serial console!\n", err); } else { select_console(CONSOLE_VGA); } } else if (!err) { select_console(CONSOLE_SERIAL); if (bd->cmd_line[0] == '\0') { strcat(&bd->cmd_line[0], CONSOLE_ON_SERIAL); } else { int s = strlen (bd->cmd_line); bd->cmd_line[s + 1] = ' '; bd->cmd_line[s + 2] = '\0'; strcat(&bd->cmd_line[0], CONSOLE_ON_SERIAL); } } #if 0 /* In the future we may use the NVRAM to store default * kernel parameters. */ nvram=residual_find_device(~0UL, NULL, SystemPeripheral, NVRAM, ~0UL, 0); if (nvram) { PnP_TAG_PACKET * pkt; switch (nvram->DevId.Interface) { case IndirectNVRAM: pkt=PnP_find_packet(res->DevicePnpHeap +nvram->AllocatedOffset, ) } } #endif printk("\nRTEMS 4.x/PPC load: "); timer = 0; cp = bd->cmd_line+strlen(bd->cmd_line); while (timer++ < 5*1000) { if (debug_tstc()) { while ((ch = debug_getc()) != '\n' && ch != '\r') { if (ch == '\b' || ch == 0177) { if (cp != bd->cmd_line) { cp--; printk("\b \b"); } } else { *cp++ = ch; debug_putc(ch); } } break; /* Exit 'timer' loop */ } udelay(1000); /* 1 msec */ } *cp = 0; } /* Functions to deal with the residual data */ static int same_DevID(unsigned short vendor, unsigned short Number, char * str) { static unsigned const char hexdigit[]="0123456789ABCDEF"; if (strlen(str)!=7) return 0; if ( ( ((vendor>>10)&0x1f)+'A'-1 == str[0]) && ( ((vendor>>5)&0x1f)+'A'-1 == str[1]) && ( (vendor&0x1f)+'A'-1 == str[2]) && (hexdigit[(Number>>12)&0x0f] == str[3]) && (hexdigit[(Number>>8)&0x0f] == str[4]) && (hexdigit[(Number>>4)&0x0f] == str[5]) && (hexdigit[Number&0x0f] == str[6]) ) return 1; return 0; } PPC_DEVICE *residual_find_device(unsigned long BusMask, unsigned char * DevID, int BaseType, int SubType, int Interface, int n) { int i; RESIDUAL *res = bd->residual; if ( !res || !res->ResidualLength ) return NULL; for (i=0; i<res->ActualNumDevices; i++) { #define Dev res->Devices[i].DeviceId if ( (Dev.BusId&BusMask) && (BaseType==-1 || Dev.BaseType==BaseType) && (SubType==-1 || Dev.SubType==SubType) && (Interface==-1 || Dev.Interface==Interface) && (DevID==NULL || same_DevID((Dev.DevId>>16)&0xffff, Dev.DevId&0xffff, DevID)) && !(n--) ) return res->Devices+i; #undef Dev } return 0; } PnP_TAG_PACKET *PnP_find_packet(unsigned char *p, unsigned packet_tag, int n) { unsigned mask, masked_tag, size; if(!p) return 0; if (tag_type(packet_tag)) mask=0xff; else mask=0xF8; masked_tag = packet_tag&mask; for(; *p != END_TAG; p+=size) { if ((*p & mask) == masked_tag && !(n--)) return (PnP_TAG_PACKET *) p; if (tag_type(*p)) size=ld_le16((unsigned short *)(p+1))+3; else size=tag_small_count(*p)+1; } return 0; /* not found */ } PnP_TAG_PACKET *PnP_find_small_vendor_packet(unsigned char *p, unsigned packet_type, int n) { int next=0; while (p) { p = (unsigned char *) PnP_find_packet(p, 0x70, next); if (p && p[1]==packet_type && !(n--)) return (PnP_TAG_PACKET *) p; next = 1; }; return 0; /* not found */ } PnP_TAG_PACKET *PnP_find_large_vendor_packet(unsigned char *p, unsigned packet_type, int n) { int next=0; while (p) { p = (unsigned char *) PnP_find_packet(p, 0x84, next); if (p && p[3]==packet_type && !(n--)) return (PnP_TAG_PACKET *) p; next = 1; }; return 0; /* not found */ } /* Find out the amount of installed memory. For MPC105 and IBM 660 this * can be done by finding the bank with the highest memory ending address */ int find_max_mem( struct pci_dev *dev ) { u_char banks,tmp; int i, top, max; max = 0; for ( ; dev; dev = dev->next) { if ( ((dev->vendor == PCI_VENDOR_ID_MOTOROLA) && (dev->device == PCI_DEVICE_ID_MOTOROLA_MPC105)) || ((dev->vendor == PCI_VENDOR_ID_IBM) && (dev->device == 0x0037/*IBM 660 Bridge*/)) ) { pci_read_config_byte(dev, 0xa0, &banks); for (i = 0; i < 8; i++) { if ( banks & (1<<i) ) { pci_read_config_byte(dev, 0x90+i, &tmp); top = tmp; pci_read_config_byte(dev, 0x98+i, &tmp); top |= (tmp&3)<<8; if ( top > max ) max = top; } } if ( max ) return ((max+1)<<20); else return(0); } } return(0); }