/* linux.c - boot Linux */ /* * GRUB -- GRand Unified Bootloader * Copyright (C) 2003,2004,2005,2007,2009 Free Software Foundation, Inc. * * GRUB is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * GRUB is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GRUB. If not, see . */ #include #include #include #include #include #include #include #include #include #include #include GRUB_MOD_LICENSE ("GPLv3+"); #define ELF32_LOADMASK (0xc0000000UL) #define ELF64_LOADMASK (0xc000000000000000ULL) static grub_dl_t my_mod; static int loaded; static grub_addr_t initrd_addr; static grub_size_t initrd_size; static grub_addr_t linux_addr; static grub_size_t linux_size; static char *linux_args; typedef void (*kernel_entry_t) (void *, unsigned long, int (void *), unsigned long, unsigned long); static grub_addr_t grub_linux_claimmap_iterate (grub_addr_t target, grub_size_t size, grub_size_t align) { grub_addr_t found_addr = (grub_addr_t) -1; auto int NESTED_FUNC_ATTR alloc_mem (grub_uint64_t addr, grub_uint64_t len, grub_memory_type_t type); int NESTED_FUNC_ATTR alloc_mem (grub_uint64_t addr, grub_uint64_t len, grub_memory_type_t type) { grub_uint64_t end = addr + len; addr = ALIGN_UP (addr, align); target = ALIGN_UP (target, align); /* Target above the memory chunk. */ if (type != GRUB_MEMORY_AVAILABLE || target > end) return 0; /* Target inside the memory chunk. */ if (target >= addr && target < end && size <= end - target) { if (grub_claimmap (target, size) == GRUB_ERR_NONE) { found_addr = target; return 1; } grub_print_error (); } /* Target below the memory chunk. */ if (target < addr && addr + size <= end) { if (grub_claimmap (addr, size) == GRUB_ERR_NONE) { found_addr = addr; return 1; } grub_print_error (); } return 0; } grub_machine_mmap_iterate (alloc_mem); return found_addr; } static grub_err_t grub_linux_boot (void) { kernel_entry_t linuxmain; grub_ssize_t actual; /* Set the command line arguments. */ grub_ieee1275_set_property (grub_ieee1275_chosen, "bootargs", linux_args, grub_strlen (linux_args) + 1, &actual); grub_dprintf ("loader", "Entry point: 0x%x\n", linux_addr); grub_dprintf ("loader", "Initrd at: 0x%x, size 0x%x\n", initrd_addr, initrd_size); grub_dprintf ("loader", "Boot arguments: %s\n", linux_args); grub_dprintf ("loader", "Jumping to Linux...\n"); /* Boot the kernel. */ linuxmain = (kernel_entry_t) linux_addr; linuxmain ((void *) initrd_addr, initrd_size, grub_ieee1275_entry_fn, 0, 0); return GRUB_ERR_NONE; } static grub_err_t grub_linux_release_mem (void) { grub_free (linux_args); linux_args = 0; if (linux_addr && grub_ieee1275_release (linux_addr, linux_size)) return grub_error (GRUB_ERR_OUT_OF_MEMORY, "cannot release memory"); if (initrd_addr && grub_ieee1275_release (initrd_addr, initrd_size)) return grub_error (GRUB_ERR_OUT_OF_MEMORY, "cannot release memory"); linux_addr = 0; initrd_addr = 0; return GRUB_ERR_NONE; } static grub_err_t grub_linux_unload (void) { grub_err_t err; err = grub_linux_release_mem (); grub_dl_unref (my_mod); loaded = 0; return err; } static grub_err_t grub_linux_load32 (grub_elf_t elf, const char *filename) { Elf32_Addr base_addr; grub_addr_t seg_addr; grub_uint32_t align; grub_uint32_t offset; Elf32_Addr entry; linux_size = grub_elf32_size (elf, filename, &base_addr, &align); if (linux_size == 0) return grub_errno; /* Pad it; the kernel scribbles over memory beyond its load address. */ linux_size += 0x100000; /* Linux's entry point incorrectly contains a virtual address. */ entry = elf->ehdr.ehdr32.e_entry & ~ELF32_LOADMASK; /* Linux's incorrectly contains a virtual address. */ base_addr &= ~ELF32_LOADMASK; offset = entry - base_addr; /* On some systems, firmware occupies the memory we're trying to use. * Happily, Linux can be loaded anywhere (it relocates itself). Iterate * until we find an open area. */ seg_addr = grub_linux_claimmap_iterate (base_addr & ~ELF32_LOADMASK, linux_size, align); if (seg_addr == (grub_addr_t) -1) return grub_error (GRUB_ERR_OUT_OF_MEMORY, "couldn't claim memory"); linux_addr = seg_addr + offset; /* Now load the segments into the area we claimed. */ auto grub_err_t offset_phdr (Elf32_Phdr *phdr, grub_addr_t *addr, int *do_load); grub_err_t offset_phdr (Elf32_Phdr *phdr, grub_addr_t *addr, int *do_load) { if (phdr->p_type != PT_LOAD) { *do_load = 0; return 0; } *do_load = 1; *addr = (phdr->p_paddr - base_addr) + seg_addr; return 0; } return grub_elf32_load (elf, filename, offset_phdr, 0, 0); } static grub_err_t grub_linux_load64 (grub_elf_t elf, const char *filename) { Elf64_Addr base_addr; grub_addr_t seg_addr; grub_uint64_t align; grub_uint64_t offset; Elf64_Addr entry; linux_size = grub_elf64_size (elf, filename, &base_addr, &align); if (linux_size == 0) return grub_errno; /* Pad it; the kernel scribbles over memory beyond its load address. */ linux_size += 0x100000; base_addr &= ~ELF64_LOADMASK; entry = elf->ehdr.ehdr64.e_entry & ~ELF64_LOADMASK; offset = entry - base_addr; /* Linux's incorrectly contains a virtual address. */ /* On some systems, firmware occupies the memory we're trying to use. * Happily, Linux can be loaded anywhere (it relocates itself). Iterate * until we find an open area. */ seg_addr = grub_linux_claimmap_iterate (base_addr & ~ELF64_LOADMASK, linux_size, align); if (seg_addr == (grub_addr_t) -1) return grub_error (GRUB_ERR_OUT_OF_MEMORY, "couldn't claim memory"); linux_addr = seg_addr + offset; /* Now load the segments into the area we claimed. */ auto grub_err_t offset_phdr (Elf64_Phdr *phdr, grub_addr_t *addr, int *do_load); grub_err_t offset_phdr (Elf64_Phdr *phdr, grub_addr_t *addr, int *do_load) { if (phdr->p_type != PT_LOAD) { *do_load = 0; return 0; } *do_load = 1; *addr = (phdr->p_paddr - base_addr) + seg_addr; return 0; } return grub_elf64_load (elf, filename, offset_phdr, 0, 0); } static grub_err_t grub_cmd_linux (grub_command_t cmd __attribute__ ((unused)), int argc, char *argv[]) { grub_elf_t elf = 0; int size; grub_dl_ref (my_mod); if (argc == 0) { grub_error (GRUB_ERR_BAD_ARGUMENT, N_("filename expected")); goto out; } elf = grub_elf_open (argv[0]); if (! elf) goto out; if (elf->ehdr.ehdr32.e_type != ET_EXEC && elf->ehdr.ehdr32.e_type != ET_DYN) { grub_error (GRUB_ERR_UNKNOWN_OS, N_("this ELF file is not of the right type")); goto out; } /* Release the previously used memory. */ grub_loader_unset (); if (grub_elf_is_elf32 (elf)) grub_linux_load32 (elf, argv[0]); else if (grub_elf_is_elf64 (elf)) grub_linux_load64 (elf, argv[0]); else { grub_error (GRUB_ERR_BAD_FILE_TYPE, N_("invalid arch-dependent ELF magic")); goto out; } size = grub_loader_cmdline_size(argc, argv); linux_args = grub_malloc (size + sizeof (LINUX_IMAGE)); if (! linux_args) goto out; /* Create kernel command line. */ grub_memcpy (linux_args, LINUX_IMAGE, sizeof (LINUX_IMAGE)); grub_create_loader_cmdline (argc, argv, linux_args + sizeof (LINUX_IMAGE) - 1, size); out: if (elf) grub_elf_close (elf); if (grub_errno != GRUB_ERR_NONE) { grub_linux_release_mem (); grub_dl_unref (my_mod); loaded = 0; } else { grub_loader_set (grub_linux_boot, grub_linux_unload, 1); initrd_addr = 0; loaded = 1; } return grub_errno; } static grub_err_t grub_cmd_initrd (grub_command_t cmd __attribute__ ((unused)), int argc, char *argv[]) { grub_file_t *files = 0; grub_size_t size = 0; grub_addr_t first_addr; grub_addr_t addr; int i; int nfiles = 0; grub_uint8_t *ptr; if (argc == 0) { grub_error (GRUB_ERR_BAD_ARGUMENT, N_("filename expected")); goto fail; } if (!loaded) { grub_error (GRUB_ERR_BAD_ARGUMENT, N_("you need to load the kernel first")); goto fail; } files = grub_zalloc (argc * sizeof (files[0])); if (!files) goto fail; for (i = 0; i < argc; i++) { grub_file_filter_disable_compression (); files[i] = grub_file_open (argv[i]); if (! files[i]) goto fail; nfiles++; size += ALIGN_UP (grub_file_size (files[i]), 4); } first_addr = linux_addr + linux_size; /* Attempt to claim at a series of addresses until successful in the same way that grub_rescue_cmd_linux does. */ addr = grub_linux_claimmap_iterate (first_addr, size, 0x100000); if (addr == (grub_addr_t) -1) goto fail; grub_dprintf ("loader", "Loading initrd at 0x%x, size 0x%x\n", addr, size); ptr = (void *) addr; for (i = 0; i < nfiles; i++) { grub_ssize_t cursize = grub_file_size (files[i]); if (grub_file_read (files[i], ptr, cursize) != cursize) { grub_ieee1275_release (addr, size); if (!grub_errno) grub_error (GRUB_ERR_FILE_READ_ERROR, N_("premature end of file %s"), argv[i]); goto fail; } ptr += cursize; grub_memset (ptr, 0, ALIGN_UP_OVERHEAD (cursize, 4)); ptr += ALIGN_UP_OVERHEAD (cursize, 4); } initrd_addr = addr; initrd_size = size; fail: for (i = 0; i < nfiles; i++) grub_file_close (files[i]); grub_free (files); return grub_errno; } static grub_command_t cmd_linux, cmd_initrd; GRUB_MOD_INIT(linux) { cmd_linux = grub_register_command ("linux", grub_cmd_linux, 0, N_("Load Linux.")); cmd_initrd = grub_register_command ("initrd", grub_cmd_initrd, 0, N_("Load initrd.")); my_mod = mod; } GRUB_MOD_FINI(linux) { grub_unregister_command (cmd_linux); grub_unregister_command (cmd_initrd); }