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[/] [or1k_old/] [trunk/] [rc203soc/] [sw/] [uClinux/] [arch/] [m68k/] [boot/] [atari/] [bootstrap.c] - Rev 1782
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/* ** bootstrap.c -- Load and launch the Atari Linux kernel ** ** Copyright 1993 by Arjan Knor ** ** This file is subject to the terms and conditions of the GNU General Public ** License. See the file COPYING in the main directory of this archive ** for more details. ** ** History: ** 10 Dec 1995 BOOTP/TFTP support (Roman) ** 03 Oct 1995 Allow kernel to be loaded to TT ram again (Andreas) ** 11 Jul 1995 Add support for ELF format kernel (Andreas) ** 16 Jun 1995 Adapted to Linux 1.2: kernel always loaded into ST ram ** (Andreas) ** 14 Nov 1994 YANML (Yet Another New Memory Layout :-) kernel ** start address is KSTART_ADDR + PAGE_SIZE, this ** does not need the ugly kludge with ** -fwritable-strings (++andreas) ** 09 Sep 1994 Adapted to the new memory layout: All the boot_info entry ** mentions all ST-Ram and the mover is located somewhere ** in the middle of memory (roman) ** Added the default arguments file known from the other ** bootstrap version ** 19 Feb 1994 Changed everything so that it works? (rdv) ** 14 Mar 1994 New mini-copy routine used (rdv) */ #include <stdio.h> #include <stdlib.h> #include <unistd.h> #include <stddef.h> #include <string.h> #include <ctype.h> #include "sysvars.h" #include <osbind.h> #include <sys/types.h> #include <sys/file.h> /* linux specific include files */ #include <linux/a.out.h> #include <linux/elf.h> #include <asm/page.h> #define _LINUX_TYPES_H /* Hack to prevent including <linux/types.h> */ #include <asm/bootinfo.h> /* Atari bootstrap include file */ #include "bootstrap.h" #define MIN_RAMSIZE (3) /* 3 MB */ #define TEMP_STACKSIZE 256 extern char *optarg; extern int optind; static void get_default_args( int *argc, char ***argv ); /* This is missing in <unistd.h> */ extern int sync (void); struct bootinfo bi; u_long *cookiejar; u_long userstk; /* getcookie -- function to get the value of the given cookie. */ static int getcookie(char *cookie, u_long *value) { int i = 0; while(cookiejar[i] != 0L) { if(cookiejar[i] == *(u_long *)cookie) { *value = cookiejar[i + 1]; return 1; } i += 2; } return -1; } static void usage(void) { fprintf(stderr, "Usage:\n" "\tbootstrap [-dst] [-k kernel_executable] [-r ramdisk_file]" " [option...]\n"); exit(EXIT_FAILURE); } /* * Copy the kernel and the ramdisk to their final resting places. * * I assume that the kernel data and the ramdisk reside somewhere * in the middle of the memory. * * This program itself should be somewhere in the first 4096 bytes of memory * where the kernel never will be. In this way it can never be overwritten * by itself. * * At this point the registers have: * a0: the start of the final kernel * a1: the start of the current kernel * a2: the end of the final ramdisk * a3: the end of the current ramdisk * d0: the kernel size * d1: the ramdisk size */ asm (" .text .globl _copyall, _copyallend _copyall: movel a0,a4 /* save the start of the kernel for booting */ 1: movel a1@+,a0@+ /* copy the kernel starting at the beginning */ subql #4,d0 jcc 1b tstl d1 beq 3f 2: movel a3@-,a2@- /* copy the ramdisk starting at the end */ subql #4,d1 jcc 2b 3: jmp a4@ /* jump to the start of the kernel */ _copyallend: "); extern char copyall, copyallend; /* Test for a Medusa: This is the only machine on which address 0 is * writeable! * ...err! On the Afterburner040 (for the Falcon) it's the same... So we do * another test with 0x00ff82fe, that gives a bus error on the Falcon, but is * in the range where the Medusa always asserts DTACK. */ int test_medusa( void ) { int rv = 0; __asm__ __volatile__ ( "movel 0x8,a0\n\t" "movel sp,a1\n\t" "moveb 0x0,d1\n\t" "movel #Lberr,0x8\n\t" "moveq #0,%0\n\t" "clrb 0x0\n\t" "nop \n\t" "moveb d1,0x0\n\t" "nop \n\t" "tstb 0x00ff82fe\n\t" "nop \n\t" "moveq #1,%0\n" "Lberr:\t" "movel a1,sp\n\t" "movel a0,0x8" : "=d" (rv) : /* no inputs */ : "d1", "a0", "a1", "memory" ); return( rv ); } void get_medusa_bank_sizes( u_long *bank1, u_long *bank2 ) { static u_long save_addr; u_long test_base, saved_contents[16]; #define TESTADDR(i) (*((u_long *)((char *)test_base + i*8*MB))) #define TESTPAT 0x12345678 unsigned short oldflags; int i; /* This ensures at least that none of the test addresses conflicts * with the test code itself */ test_base = ((unsigned long)&save_addr & 0x007fffff) | 0x20000000; *bank1 = *bank2 = 0; /* Interrupts must be disabled because arbitrary addresses may be * temporarily overwritten, even code of an interrupt handler */ __asm__ __volatile__ ( "movew sr,%0; oriw #0x700,sr" : "=g" (oldflags) : ); disable_cache(); /* save contents of the test addresses */ for( i = 0; i < 16; ++i ) saved_contents[i] = TESTADDR(i); /* write 0s into all test addresses */ for( i = 0; i < 16; ++i ) TESTADDR(i) = 0; /* test for bank 1 */ #if 0 /* This is Freddi's original test, but it didn't work. */ TESTADDR(0) = TESTADDR(1) = TESTPAT; if (TESTADDR(1) == TESTPAT) { if (TESTADDR(2) == TESTPAT) *bank1 = 8*MB; else if (TESTADDR(3) == TESTPAT) *bank1 = 16*MB; else *bank1 = 32*MB; } else { if (TESTADDR(2) == TESTPAT) *bank1 = 0; else *bank1 = 16*MB; } #else TESTADDR(0) = TESTPAT; if (TESTADDR(1) == TESTPAT) *bank1 = 8*MB; else if (TESTADDR(2) == TESTPAT) *bank1 = 16*MB; else if (TESTADDR(4) == TESTPAT) *bank1 = 32*MB; else *bank1 = 64*MB; #endif /* test for bank2 */ if (TESTADDR(8) != 0) *bank2 = 0; else { TESTADDR(8) = TESTPAT; if (TESTADDR(9) != 0) { if (TESTADDR(10) == TESTPAT) *bank2 = 8*MB; else *bank2 = 32*MB; } else { TESTADDR(9) = TESTPAT; if (TESTADDR(10) == TESTPAT) *bank2 = 16*MB; else *bank2 = 64*MB; } } /* restore contents of the test addresses and restore interrupt mask */ for( i = 0; i < 16; ++i ) TESTADDR(i) = saved_contents[i]; __asm__ __volatile__ ( "movew %0,sr" : : "g" (oldflags) ); } #undef TESTADDR #undef TESTPAT #ifdef USE_BOOTP # include "bootp.h" #else # define kread read # define klseek lseek # define kclose close #endif /* ++andreas: this must be inline due to Super */ static inline void boot_exit (int) __attribute__ ((noreturn)); static inline void boot_exit(int status) { /* first go back to user mode */ (void)Super(userstk); getchar(); exit(status); } int main(int argc, char *argv[]) { int debugflag = 0, ch, kfd, rfd = -1, i, ignore_ttram = 0; int load_to_stram = 0; char *ramdisk_name, *kernel_name, *memptr; u_long ST_ramsize, TT_ramsize, memreq; u_long cpu_type, fpu_type, mch_type, mint; struct exec kexec; int elf_kernel = 0; Elf32_Ehdr kexec_elf; Elf32_Phdr *kernel_phdrs = NULL; u_long start_mem, mem_size, rd_size, text_offset = 0, kernel_size; #ifdef USE_BOOTP int prefer_bootp = 1, kname_set = 0; #endif ramdisk_name = NULL; kernel_name = "vmlinux"; /* print the startup message */ puts("\fLinux/68k Atari Bootstrap version 1.6" #ifdef USE_BOOTP " (with BOOTP)" #endif ); puts("Copyright 1993,1994 by Arjan Knor, Robert de Vries, Roman Hodek, Andreas Schwab\n"); /* ++roman: If no arguments on the command line, read them from * file */ if (argc == 1) get_default_args( &argc, &argv ); /* machine is Atari */ bi.machtype = MACH_ATARI; /* check arguments */ #ifdef USE_BOOTP while ((ch = getopt(argc, argv, "bdtsk:r:")) != EOF) #else while ((ch = getopt(argc, argv, "dtsk:r:")) != EOF) #endif switch (ch) { case 'd': debugflag = 1; break; case 't': ignore_ttram = 1; break; case 's': load_to_stram = 1; break; case 'k': kernel_name = optarg; #ifdef USE_BOOTP kname_set = 1; #endif break; case 'r': ramdisk_name = optarg; break; #ifdef USE_BOOTP case 'b': prefer_bootp = 1; break; #endif case '?': default: usage(); } argc -= optind; argv += optind; /* We have to access some system variables to get * the information we need, so we must switch to * supervisor mode first. */ userstk = Super(0L); /* get the info we need from the cookie-jar */ cookiejar = *_p_cookies; if(cookiejar == 0L) { /* if we find no cookies, it's probably an ST */ fprintf(stderr, "Error: No cookiejar found. Is this an ST?\n"); boot_exit(EXIT_FAILURE); } /* Exit if MiNT/MultiTOS is running. */ if(getcookie("MiNT", &mint) != -1) { puts("Warning: MiNT is running\n"); #if 0 puts("Linux cannot be started when MiNT is running. Aborting...\n"); boot_exit(EXIT_FAILURE); #endif } /* get _CPU, _FPU and _MCH */ getcookie("_CPU", &cpu_type); getcookie("_FPU", &fpu_type); getcookie("_MCH", &mch_type); /* check if we are on a 68030/40 with FPU */ if ((cpu_type != 30 && cpu_type != 40 && cpu_type != 60) || (fpu_type >> 16) < 2) { puts("Machine type currently not supported. Aborting..."); boot_exit(EXIT_FAILURE); } switch(cpu_type) { case 0: case 10: break; case 20: bi.cputype = CPU_68020; break; case 30: bi.cputype = CPU_68030; break; case 40: bi.cputype = CPU_68040; break; case 60: bi.cputype = CPU_68060; break; default: fprintf(stderr, "Error: Unknown CPU type. Aborting...\n"); boot_exit(EXIT_FAILURE); break; } printf("CPU: %ld; ", cpu_type + 68000); printf("FPU: "); /* check for FPU; in case of a '040 or '060, don't look at _FPU itself, * some software may set it to wrong values (68882 or the like) */ if (cpu_type == 40) { bi.cputype |= FPU_68040; puts( "68040\n" ); } else if (cpu_type == 60) { bi.cputype |= FPU_68060; puts( "68060\n" ); } else { switch ((fpu_type >> 16) & 6) { case 0: puts("not present\n"); break; case 2: /* try to determine real type */ if (fpu_idle_frame_size () != 0x18) goto m68882; /* fall through */ case 4: bi.cputype |= FPU_68881; puts("68881\n"); break; case 6: m68882: bi.cputype |= FPU_68882; puts("68882\n"); break; default: puts("Unknown FPU type. Assuming no FPU."); break; } } memset(&bi.bi_atari.hw_present, 0, sizeof(bi.bi_atari.hw_present)); /* Get the amounts of ST- and TT-RAM. */ /* The size must be a multiple of 1MB. */ i = 0; if (!test_medusa()) { struct { unsigned short version; /* version - currently 1 */ unsigned long fr_start; /* start addr FastRAM */ unsigned long fr_len; /* length FastRAM */ } *magn_cookie; struct { unsigned long version; unsigned long fr_start; /* start addr */ unsigned long fr_len; /* length */ } *fx_cookie; TT_ramsize = 0; if (!ignore_ttram) { /* "Original" or properly emulated TT-Ram */ if (*ramtop) { /* the 'ramtop' variable at 0x05a4 is not * officially documented. We use it anyway * because it is the only way to get the TTram size. * (It is zero if there is no TTram.) */ bi.memory[i].addr = TT_RAM_BASE; bi.memory[i].size = (*ramtop - TT_RAM_BASE) & ~(MB - 1); TT_ramsize = bi.memory[i].size / MB; i++; printf("TT-RAM: %ld Mb; ", TT_ramsize); } /* test for MAGNUM alternate RAM * added 26.9.1995 M. Schwingen, rincewind@discworld.oche.de */ if (getcookie("MAGN", (u_long *)&magn_cookie) != -1) { bi.memory[i].addr = magn_cookie->fr_start; bi.memory[i].size = magn_cookie->fr_len & ~(MB - 1); TT_ramsize += bi.memory[i].size / MB; printf("MAGNUM alternate RAM: %ld Mb; ", bi.memory[i].size/MB); i++; } /* BlowUps FX */ if (getcookie("BPFX", (u_long *)&fx_cookie) != -1 && fx_cookie) { /* if fx is set (cookie call above), * we assume that BlowUps FX-card * is installed. (Nat!) */ bi.memory[i].addr = fx_cookie->fr_start; bi.memory[i].size = fx_cookie->fr_len & ~(MB - 1); printf("FX alternate RAM: %ld Mb; ", bi.memory[i].size/MB); i++; } } bi.memory[i].addr = 0; bi.memory[i].size = *phystop & ~(MB - 1); ST_ramsize = bi.memory[i].size / MB; i++; printf("ST-RAM: %ld Mb\n", ST_ramsize ); bi.num_memory = i; if (load_to_stram && i > 1) { /* Put ST-RAM first in the list of mem blocks */ struct mem_info temp = bi.memory[i - 1]; bi.memory[i - 1] = bi.memory[0]; bi.memory[0] = temp; } } else { u_long bank1, bank2, medusa_st_ram; get_medusa_bank_sizes( &bank1, &bank2 ); medusa_st_ram = *phystop & ~(MB - 1); bank1 -= medusa_st_ram; TT_ramsize = 0; bi.memory[i].addr = 0; bi.memory[i].size = medusa_st_ram; ST_ramsize = bi.memory[i].size / MB; i++; printf("Medusa pseudo ST-RAM from bank 1: %ld Mb; ", ST_ramsize ); if (!ignore_ttram && bank1 > 0) { bi.memory[i].addr = 0x20000000 + medusa_st_ram; bi.memory[i].size = bank1; TT_ramsize += bank1; i++; printf("TT-RAM bank 1: %ld Mb; ", bank1/MB ); } if (!ignore_ttram && bank2 > 0) { bi.memory[i].addr = 0x24000000; bi.memory[i].size = bank2; TT_ramsize += bank2; i++; printf("TT-RAM bank 2: %ld Mb; ", bank2/MB ); } bi.num_memory = i; printf("\n"); } /* verify that there is enough RAM; ST- and TT-RAM combined */ if (ST_ramsize + TT_ramsize < MIN_RAMSIZE) { puts("Not enough RAM. Aborting..."); boot_exit(10); } #if 0 /* Get language/keyboard info */ /* TODO: do we need this ? */ /* Could be used to auto-select keyboard map later on. (rdv) */ if (getcookie("_AKP",&language) == -1) { /* Get the language info from the OS-header */ os_header = *_sysbase; os_header = os_header->os_beg; lang = (os_header->os_conf) >> 1; printf("Language: "); switch(lang) { case HOL: puts("Dutch"); break; /* Own country first :-) */ case USA: puts("American"); break; case SWG: puts("Switzerland (German)"); break; case FRG: puts("German"); break; case FRA: puts("French"); break; case SWF: puts("Switzerland (French)"); break; case UK: puts("English"); break; case SPA: puts("Spanish"); break; case ITA: puts("Italian"); break; case SWE: puts("Swedish"); break; case TUR: puts("Turkey"); break; case FIN: puts("Finnish"); break; case NOR: puts("Norwegian"); break; case DEN: puts("Danish"); break; case SAU: puts("Saudi-Arabian"); break; default: puts("Unknown"); break; } } else { printf("Language: "); switch(language & 0x0F) { case 1: printf("German "); break; case 2: printf("French "); break; case 4: printf("Spanish "); break; case 5: printf("Italian "); break; case 7: printf("Swiss French "); break; case 8: printf("Swiss German "); break; default: printf("English "); } printf("Keyboard type :"); switch(language >> 8) { case 1: printf("German "); break; case 2: printf("French "); break; case 4: printf("Spanish "); break; case 5: printf("Italian "); break; case 7: printf("Swiss French "); break; case 8: printf("Swiss German "); break; default: printf("English "); } printf("\n"); } #endif /* Pass contents of the _MCH cookie to the kernel */ bi.bi_atari.mch_cookie = mch_type; /* * Copy command line options into the kernel command line. */ i = 0; while (argc--) { if ((i+strlen(*argv)+1) < CL_SIZE) { i += strlen(*argv) + 1; if (bi.command_line[0]) strcat (bi.command_line, " "); strcat (bi.command_line, *argv++); } } printf ("Command line is '%s'\n", bi.command_line); start_mem = bi.memory[0].addr; mem_size = bi.memory[0].size; /* tell us where the kernel will go */ printf("\nThe kernel will be located at 0x%08lx\n", start_mem); #ifdef TEST /* ** Temporary exit point for testing */ boot_exit(-1); #endif /* TEST */ #ifdef USE_BOOTP kfd = -1; if (prefer_bootp) { /* First try to get a remote kernel, then use a local kernel (if * present) */ if (get_remote_kernel( kname_set ? kernel_name : NULL ) < 0) { printf( "\nremote boot failed; trying local kernel\n" ); if ((kfd = open (kernel_name, O_RDONLY)) == -1) { fprintf (stderr, "Unable to open kernel file %s\n", kernel_name); boot_exit (EXIT_FAILURE); } } } else { /* Try BOOTP if local kernel cannot be opened */ if ((kfd = open (kernel_name, O_RDONLY)) == -1) { printf( "\nlocal kernel failed; trying remote boot\n" ); if (get_remote_kernel( kname_set ? kernel_name : NULL ) < 0) { fprintf (stderr, "Unable to remote boot and " "to open kernel file %s\n", kernel_name); boot_exit (EXIT_FAILURE); } } } #else /* open kernel executable and read exec header */ if ((kfd = open (kernel_name, O_RDONLY)) == -1) { fprintf (stderr, "Unable to open kernel file %s\n", kernel_name); boot_exit (EXIT_FAILURE); } #endif if (kread (kfd, (void *)&kexec, sizeof(kexec)) != sizeof(kexec)) { fprintf (stderr, "Unable to read exec header from %s\n", kernel_name); boot_exit (EXIT_FAILURE); } switch (N_MAGIC(kexec)) { case ZMAGIC: text_offset = N_TXTOFF(kexec); break; case QMAGIC: text_offset = sizeof(kexec); /* the text size includes the exec header; remove this */ kexec.a_text -= sizeof(kexec); break; default: /* Try to parse it as an ELF header */ klseek (kfd, 0, SEEK_SET); if (kread (kfd, (void *)&kexec_elf, sizeof (kexec_elf)) == sizeof (kexec_elf) && memcmp (&kexec_elf.e_ident[EI_MAG0], ELFMAG, SELFMAG) == 0) { elf_kernel = 1; /* A few plausibility checks */ if (kexec_elf.e_type != ET_EXEC || kexec_elf.e_machine != EM_68K || kexec_elf.e_version != EV_CURRENT) { fprintf (stderr, "Invalid ELF header contents in kernel\n"); boot_exit (EXIT_FAILURE); } /* Load the program headers */ kernel_phdrs = (Elf32_Phdr *) Malloc (kexec_elf.e_phnum * sizeof (Elf32_Phdr)); if (kernel_phdrs == NULL) { fprintf (stderr, "Unable to allocate memory for program headers\n"); boot_exit (EXIT_FAILURE); } klseek (kfd, kexec_elf.e_phoff, SEEK_SET); if (kread (kfd, (void *) kernel_phdrs, kexec_elf.e_phnum * sizeof (*kernel_phdrs)) != kexec_elf.e_phnum * sizeof (*kernel_phdrs)) { fprintf (stderr, "Unable to read program headers from %s\n", kernel_name); boot_exit (EXIT_FAILURE); } break; } fprintf (stderr, "Wrong magic number %lo in kernel header\n", N_MAGIC(kexec)); boot_exit (EXIT_FAILURE); } /* Load the kernel one page after start of mem */ start_mem += PAGE_SIZE; mem_size -= PAGE_SIZE; /* Align bss size to multiple of four */ if (!elf_kernel) kexec.a_bss = (kexec.a_bss + 3) & ~3; /* init ramdisk */ if(ramdisk_name) { if((rfd = open(ramdisk_name, O_RDONLY)) == -1) { fprintf(stderr, "Unable to open ramdisk file %s\n", ramdisk_name); boot_exit(EXIT_FAILURE); } bi.ramdisk_size = (lseek(rfd, 0, SEEK_END) + 1023) / 1024; } else bi.ramdisk_size = 0; rd_size = bi.ramdisk_size << 10; if (mem_size - rd_size < MB && bi.num_memory > 1) /* If running low on ST ram load ramdisk into alternate ram. */ bi.ramdisk_addr = (u_long) bi.memory[1].addr + bi.memory[1].size - rd_size; else /* Else hopefully there is enough ST ram. */ bi.ramdisk_addr = (u_long)start_mem + mem_size - rd_size; /* calculate the total required amount of memory */ if (elf_kernel) { u_long min_addr = 0xffffffff, max_addr = 0; for (i = 0; i < kexec_elf.e_phnum; i++) { if (min_addr > kernel_phdrs[i].p_vaddr) min_addr = kernel_phdrs[i].p_vaddr; if (max_addr < kernel_phdrs[i].p_vaddr + kernel_phdrs[i].p_memsz) max_addr = kernel_phdrs[i].p_vaddr + kernel_phdrs[i].p_memsz; } /* This is needed for newer linkers that include the header in the first segment. */ if (min_addr == 0) { min_addr = PAGE_SIZE; kernel_phdrs[0].p_vaddr += PAGE_SIZE; kernel_phdrs[0].p_offset += PAGE_SIZE; kernel_phdrs[0].p_filesz -= PAGE_SIZE; kernel_phdrs[0].p_memsz -= PAGE_SIZE; } kernel_size = max_addr - min_addr; } else kernel_size = kexec.a_text + kexec.a_data + kexec.a_bss; memreq = kernel_size + sizeof (bi) + rd_size; /* allocate RAM for the kernel */ if (!(memptr = (char *)Malloc (memreq))) { fprintf (stderr, "Unable to allocate memory for kernel and ramdisk\n"); boot_exit (EXIT_FAILURE); } else fprintf(stderr, "kernel at address %lx\n", (u_long) memptr); (void)memset(memptr, 0, memreq); /* read the text and data segments from the kernel image */ if (elf_kernel) { for (i = 0; i < kexec_elf.e_phnum; i++) { if (klseek (kfd, kernel_phdrs[i].p_offset, SEEK_SET) == -1) { fprintf (stderr, "Failed to seek to segment %d\n", i); boot_exit (EXIT_FAILURE); } if (kread (kfd, memptr + kernel_phdrs[i].p_vaddr - PAGE_SIZE, kernel_phdrs[i].p_filesz) != kernel_phdrs[i].p_filesz) { fprintf (stderr, "Failed to read segment %d\n", i); boot_exit (EXIT_FAILURE); } } } else { if (klseek (kfd, text_offset, SEEK_SET) == -1) { fprintf (stderr, "Failed to seek to text\n"); Mfree ((void *)memptr); boot_exit (EXIT_FAILURE); } if (kread (kfd, memptr, kexec.a_text) != kexec.a_text) { fprintf (stderr, "Failed to read text\n"); Mfree ((void *)memptr); boot_exit (EXIT_FAILURE); } /* data follows immediately after text */ if (kread (kfd, memptr + kexec.a_text, kexec.a_data) != kexec.a_data) { fprintf (stderr, "Failed to read data\n"); Mfree ((void *)memptr); boot_exit (EXIT_FAILURE); } } kclose (kfd); /* copy the boot_info struct to the end of the kernel image */ memcpy ((void *)(memptr + kernel_size), &bi, sizeof(bi)); /* read the ramdisk image */ if (rfd != -1) { if (lseek (rfd, 0, SEEK_SET) == -1) { fprintf (stderr, "Failed to seek to beginning of ramdisk file\n"); Mfree ((void *)memptr); boot_exit (EXIT_FAILURE); } if (read (rfd, memptr + kernel_size + sizeof (bi), rd_size) != rd_size) { fprintf (stderr, "Failed to read ramdisk file\n"); Mfree ((void *)memptr); boot_exit (EXIT_FAILURE); } close (rfd); } /* for those who want to debug */ if (debugflag) { if (bi.ramdisk_size) printf ("RAM disk at %#lx, size is %ldK\n", (u_long)memptr + kernel_size, bi.ramdisk_size); if (elf_kernel) { for (i = 0; i < kexec_elf.e_phnum; i++) { printf ("Kernel segment %d at %#lx, size %ld\n", i, start_mem + kernel_phdrs[i].p_vaddr - PAGE_SIZE, kernel_phdrs[i].p_memsz); } } else { printf ("\nKernel text at %#lx, code size %d\n", start_mem, kexec.a_text); printf ("Kernel data at %#lx, data size %d\n", start_mem + kexec.a_text, kexec.a_data ); printf ("Kernel bss at %#lx, bss size %d\n", start_mem + kexec.a_text + kexec.a_data, kexec.a_bss ); } printf ("\nboot_info is at %#lx\n", start_mem + kernel_size); printf ("\nKernel entry is %#lx\n", elf_kernel ? kexec_elf.e_entry : kexec.a_entry); printf ("ramdisk dest top is %#lx\n", bi.ramdisk_addr + rd_size); printf ("ramdisk lower limit is %#lx\n", (u_long)(memptr + kernel_size)); printf ("ramdisk src top is %#lx\n", (u_long)(memptr + kernel_size) + rd_size); printf ("Type a key to continue the Linux boot..."); fflush (stdout); getchar(); } printf("Booting Linux...\n"); sync (); /* turn off interrupts... */ disable_interrupts(); /* turn off caches... */ disable_cache(); /* ..and any MMU translation */ disable_mmu(); /* ++guenther: allow reset if launched with MiNT */ *(long*)0x426 = 0; /* copy mover code to a safe place if needed */ memcpy ((void *) 0x400, ©all, ©allend - ©all); /* setup stack */ change_stack ((void *) PAGE_SIZE); /* * On the Atari you can have two situations: * 1. One piece of contiguous RAM (Falcon) * 2. Two pieces of contiguous RAM (TT) * In case 2 you can load your program into ST-ram and load your data in * any old RAM you have left. * In case 1 you could overwrite your own program when copying the * kernel and ramdisk to their final positions. * To solve this the mover code is copied to a safe place first. * Then this program jumps to the mover code. After the mover code * has finished it jumps to the start of the kernel in its new position. * I thought the memory just after the interrupt vector table was a safe * place because it is used by TOS to store some system variables. * This range goes from 0x400 to approx. 0x5B0. * This is more than enough for the miniscule mover routine (16 bytes). */ jump_to_mover((char *) start_mem, memptr, (char *) bi.ramdisk_addr + rd_size, memptr + memreq, kernel_size + sizeof (bi), rd_size, (void *) 0x400); for (;;); /* NOTREACHED */ } #define MAXARGS 30 static void get_default_args( int *argc, char ***argv ) { FILE *f; static char *nargv[MAXARGS]; char arg[256], *p; int c, quote, state; if (!(f = fopen( "bootargs", "r" ))) return; *argc = 1; if (***argv) nargv[0] = **argv; else nargv[0] = "bootstrap"; *argv = nargv; quote = state = 0; p = arg; while( (c = fgetc(f)) != EOF ) { if (state == 0) { /* outside args, skip whitespace */ if (!isspace(c)) { state = 1; p = arg; } } if (state) { /* inside an arg: copy it into 'arg', obeying quoting */ if (!quote && (c == '\'' || c == '"')) quote = c; else if (quote && c == quote) quote = 0; else if (!quote && isspace(c)) { /* end of this arg */ *p = 0; nargv[(*argc)++] = strdup(arg); state = 0; } else *p++ = c; } } if (state) { /* last arg finished by EOF! */ *p = 0; nargv[(*argc)++] = strdup(arg); } fclose( f ); nargv[*argc] = 0; }