/* * Copyright (C) 2001-2003 Hewlett-Packard Co. * Contributed by Stephane Eranian * * Copyright (C) 2001 Silicon Graphics, Inc. * Contributed by Brent Casavant * * This file is part of the ELILO, the EFI Linux boot loader. * * ELILO 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 2, or (at your option) * any later version. * * ELILO 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 ELILO; see the file COPYING. If not, write to the Free * Software Foundation, 59 Temple Place - Suite 330, Boston, MA * 02111-1307, USA. * * Please check out the elilo.txt for complete documentation on how * to use this program. */ #include #include #include "elilo.h" #include "loader.h" #include "elf.h" #include "private.h" #define LD_NAME L"plain_elf64" #define PLAIN_MIN_BLOCK_SIZE sizeof(Elf64_Ehdr) /* see load_elf() for details */ #define SKIPBUFSIZE 2048 /* minimal default size of the skip buffer */ static CHAR8 *skip_buffer; /* used to skip over unneeded data */ static UINTN skip_bufsize; static UINTN elf_is_big_endian; /* true if ELF file is big endian */ static inline UINT64 bswap64(UINT64 v) { if(elf_is_big_endian) v = __ia64_swab64(v); return v; } static inline UINT32 bswap32(UINT32 v) { if(elf_is_big_endian) v = __ia64_swab32(v); return v; } static inline UINT16 bswap16(UINT16 v) { if(elf_is_big_endian) v = __ia64_swab16(v); return v; } static INTN is_valid_header(Elf64_Ehdr *ehdr) { UINT16 type, machine; if (ehdr->e_ident[EI_DATA] == ELFDATA2MSB) { type = __ia64_swab16(ehdr->e_type); machine = __ia64_swab16(ehdr->e_machine); } else { type = ehdr->e_type; machine = ehdr->e_machine; } DBG_PRT((L"class=%d type=%d data=%d machine=%d\n", ehdr->e_ident[EI_CLASS], type, ehdr->e_ident[EI_DATA], machine)); return ehdr->e_ident[EI_MAG0] == 0x7f && ehdr->e_ident[EI_MAG1] == 'E' && ehdr->e_ident[EI_MAG2] == 'L' && ehdr->e_ident[EI_MAG3] == 'F' && ehdr->e_ident[EI_CLASS] == ELFCLASS64 && type == ET_EXEC /* must be executable */ && machine == EM_IA_64 ? 0 : -1; } static INTN plain_probe(CHAR16 *kname) { Elf64_Ehdr ehdr; EFI_STATUS status; INTN ret = -1; fops_fd_t fd; UINTN size = sizeof(ehdr); status = fops_open(kname, &fd); if (EFI_ERROR(status)) return -1; status = fops_read(fd, &ehdr, &size); if (EFI_ERROR(status) || size != sizeof(ehdr)) goto error; ret = is_valid_header(&ehdr); error: fops_close(fd); return ret; } /* * move skip bytes forward in the file * this is required because we cannot assume fileops has * seek() capabilities. */ static INTN skip_bytes(fops_fd_t fd, UINTN curpos, UINTN newpos) { EFI_STATUS status; UINTN n, skip; skip = newpos - curpos; /* check if seek capability exists */ status = fops_seek(fd, newpos); if (status == EFI_SUCCESS) return 0; if (status != EFI_UNSUPPORTED) goto error; /* unsupported case */ if (skip_buffer == NULL) { skip_bufsize = MAX(skip, SKIPBUFSIZE); skip_buffer= (CHAR8 *)alloc(skip_bufsize, EfiLoaderData); if (skip_buffer == NULL) return -1; } while (skip) { n = skip > skip_bufsize? skip_bufsize : skip; status = fops_read(fd, skip_buffer, &n); if (EFI_ERROR(status)) goto error; skip -=n; } return 0; error: ERR_PRT((L"%s : cannot skip %d bytes\n", LD_NAME, n)); return -1; } static INTN load_elf(fops_fd_t fd, kdesc_t *kd) { Elf64_Ehdr ehdr; Elf64_Phdr *phdrs; EFI_STATUS status; INTN ret = ELILO_LOAD_ERROR; UINTN i, total_size = 0; UINTN pages, size, bss_sz, osize; UINTN offs = 0; VOID *low_addr = (VOID *)~0; VOID *max_addr = (VOID *)0; UINTN load_offset = 0; UINTN paddr, memsz, filesz, poffs; UINT16 phnum; Print(L"Loading Linux... "); size = sizeof(ehdr); status = fops_read(fd, &ehdr, &size); if (EFI_ERROR(status) ||size < sizeof(ehdr)) return ELILO_LOAD_ERROR; offs += size; /* * do some sanity checking on the file */ if (is_valid_header(&ehdr) == -1) { ERR_PRT((L"%s : not an elf 64-bit file\n", LD_NAME)); return ELILO_LOAD_ERROR; } /* determine file endianess */ elf_is_big_endian = ehdr.e_ident[EI_DATA] == ELFDATA2MSB ? 1 : 0; VERB_PRT(3, { Print(L"ELF file is %s\n", elf_is_big_endian ? L"big endian" : L"little endian"); Print(L"Entry point 0x%lx\n", bswap64(ehdr.e_entry)); Print(L"%d program headers\n", bswap16(ehdr.e_phnum)); Print(L"%d segment headers\n", bswap16(ehdr.e_shnum)); }); phnum = bswap16(ehdr.e_phnum); if (skip_bytes(fd, offs, bswap64(ehdr.e_phoff)) != 0) { ERR_PRT((L"%s : skip tp %ld for phdrs failed", LD_NAME, offs)); return ELILO_LOAD_ERROR; } offs = bswap64(ehdr.e_phoff); size = osize = phnum*sizeof(Elf64_Phdr); DBG_PRT((L"%s : phdrs allocate %d bytes sizeof=%d entsize=%d\n", LD_NAME, size,sizeof(Elf64_Phdr), bswap16(ehdr.e_phentsize))); phdrs = (Elf64_Phdr *)alloc(size, 0); if (phdrs == NULL) { ERR_PRT((L"%s : allocate phdrs failed", LD_NAME)); return ELILO_LOAD_ERROR; } status = fops_read(fd, phdrs, &size); if (EFI_ERROR(status) || size != osize) { ERR_PRT((L"%s : load phdrs failed", LD_NAME, status)); goto out; } offs += size; /* * First pass to figure out: * - lowest physical address * - total memory footprint */ for (i = 0; i < phnum; i++) { paddr = bswap64(phdrs[i].p_paddr); memsz = bswap64(phdrs[i].p_memsz); DBG_PRT((L"Phdr %d paddr [0x%lx-0x%lx] offset %ld" " filesz %ld memsz=%ld bss_sz=%ld p_type=%d\n", 1+i, paddr, paddr+bswap64(phdrs[i].p_filesz), bswap64(phdrs[i].p_offset), bswap64(phdrs[i].p_filesz), memsz, memsz - bswap64(phdrs[i].p_filesz), bswap32(phdrs[i].p_type))); if (bswap32(phdrs[i].p_type) != PT_LOAD) continue; if (paddr < (UINTN)low_addr) low_addr = (VOID *)paddr; if (paddr + memsz > (UINTN)max_addr) max_addr = (VOID *)paddr + memsz; } if ((UINTN)low_addr & (EFI_PAGE_SIZE - 1)) { ERR_PRT((L"%s : kernel low address 0x%lx not page aligned\n", LD_NAME, low_addr)); goto out; } /* how many bytes are needed to hold the kernel */ total_size = (UINTN)max_addr - (UINTN)low_addr; /* round up to get required number of pages */ pages = EFI_SIZE_TO_PAGES(total_size); /* keep track of location where kernel ends for * the initrd ramdisk (it will be put right after the kernel) */ kd->kstart = low_addr; kd->kend = low_addr+ (pages << EFI_PAGE_SHIFT); /* * that's the kernel entry point (virtual address) */ kd->kentry = (VOID *)bswap64(ehdr.e_entry); if (((UINTN)kd->kentry >> 61) != 0) { ERR_PRT((L"%s: <> entry point is a virtual address 0x%lx : not supported anymore\n", LD_NAME, kd->kentry)); } VERB_PRT(3, { Print(L"Lowest PhysAddr: 0x%lx\nTotalMemSize:%d bytes (%d pages)\n", low_addr, total_size, pages); Print(L"Kernel entry @ 0x%lx\n", kd->kentry); }); /* * now allocate memory for the kernel at the exact requested spot */ if (alloc_kmem(low_addr, pages) == -1) { VOID *new_addr; VERB_PRT(1, (L"%s : AllocatePages(%d, 0x%lx) for kernel failed\n", LD_NAME, pages, low_addr)); if (ia64_can_relocate() == 0) { ERR_PRT((L"relocation is disabled, cannot load kernel")); goto out; } /* * could not allocate at requested spot, try to find a * suitable location to relocate the kernel * * The maximum sized Itanium TLB translation entry is 256 MB. * If we relocate the kernel by this amount we know for sure * that alignment constraints will be satisified, regardless * of the kernel used. */ Print(L"Attempting to relocate kernel.\n"); if (find_kernel_memory(low_addr, max_addr, 256*MB, &new_addr) == -1) { ERR_PRT((L"%s : find_kernel_memory(0x%lx, 0x%lx, 0x%lx, 0x%lx) failed\n", LD_NAME, low_addr, max_addr, 256*MB, &load_offset)); goto out; } /* unsigned arithmetic */ load_offset = (UINTN) (new_addr - ROUNDDOWN((UINTN) low_addr,256*MB)); VERB_PRT(3, Print(L"low_addr=0x%lx new_addr=0x%lx offset=0x%lx", low_addr, new_addr, load_offset)); /* * correct various addesses for non-zero load_offset */ low_addr = (VOID*) ((UINTN) low_addr + load_offset); max_addr = (VOID*) ((UINTN) max_addr + load_offset); kd->kstart = (VOID *) ((UINTN) kd->kstart + load_offset); kd->kend = (VOID *) ((UINTN) kd->kend + load_offset); kd->kentry = (VOID *) ((UINTN) kd->kentry + load_offset); /* * try one last time to get memory for the kernel */ if (alloc_kmem(low_addr, pages) == -1) { ERR_PRT((L"%s : AllocatePages(%d, 0x%lx) for kernel failed\n", LD_NAME, pages, low_addr)); ERR_PRT((L"Relocation by 0x%lx bytes failed.\n", load_offset)); goto out; } } VERB_PRT(1, Print(L"Press any key to interrupt\n")); /* Second pass: * Walk through the program headers * and actually load data into physical memory */ for (i = 0; i < phnum; i++) { /* * Check for pure loadable segment; ignore if not loadable */ if (bswap32(phdrs[i].p_type) != PT_LOAD) continue; poffs = bswap64(phdrs[i].p_offset); size = poffs - offs; VERB_PRT(3, Print(L"\noff=%ld poffs=%ld size=%ld\n", offs, poffs, size)); filesz = bswap64(phdrs[i].p_filesz); /* * correct p_paddr for non-zero load offset */ phdrs[i].p_paddr = (Elf64_Addr) ((UINTN) bswap64(phdrs[i].p_paddr) + load_offset); /* * Move to the right position */ if (size && skip_bytes(fd, offs, poffs) != 0) goto out_kernel; /* * Keep track of current position in file */ offs += size; /* * How many BSS bytes to clear */ bss_sz = bswap64(phdrs[i].p_memsz) - filesz; VERB_PRT(4, { Print(L"\nHeader #%d\n", i); Print(L"offset %ld\n", poffs); Print(L"Phys addr 0x%lx\n", phdrs[i].p_paddr); /* already endian adjusted */ Print(L"BSS size %ld bytes\n", bss_sz); Print(L"skip=%ld offs=%ld\n", size, offs); }); /* * Read actual segment into memory */ ret = read_file(fd, filesz, (CHAR8 *)phdrs[i].p_paddr); if (ret == ELILO_LOAD_ABORTED) goto load_abort; if (ret == ELILO_LOAD_ERROR) goto out; if (bswap32(phdrs[i].p_flags) & PF_X) flush_dcache ((CHAR8 *)phdrs[i].p_paddr, filesz); /* * update file position */ offs += filesz; /* * Clear bss section */ if (bss_sz) Memset((VOID *) phdrs[i].p_paddr+filesz, 0, bss_sz); } free(phdrs); Print(L"..done\n"); return ELILO_LOAD_SUCCESS; load_abort: Print(L"..Aborted\n"); ret = ELILO_LOAD_ABORTED; out_kernel: /* free kernel memory */ free_kmem(); out: free(phdrs); return ret; } static INTN plain_load_kernel(CHAR16 *kname, kdesc_t *kd) { INTN ret; fops_fd_t fd; EFI_STATUS status; /* * Moving the open here simplifies the load_elf() error handling */ status = fops_open(kname, &fd); if (EFI_ERROR(status)) return ELILO_LOAD_ERROR; Print(L"Loading %s...", kname); ret = load_elf(fd, kd); fops_close(fd); /* * if the skip buffer was ever used, free it */ if (skip_buffer) { free(skip_buffer); /* in case we come back */ skip_buffer = NULL; } return ret; } loader_ops_t plain_loader={ NULL, LD_NAME, plain_probe, plain_load_kernel };