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/* |
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* Copyright (C) 2003-2007 Anders Gavare. All rights reserved. |
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* |
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* Redistribution and use in source and binary forms, with or without |
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* modification, are permitted provided that the following conditions are met: |
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* |
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* 1. Redistributions of source code must retain the above copyright |
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* notice, this list of conditions and the following disclaimer. |
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* 2. Redistributions in binary form must reproduce the above copyright |
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* notice, this list of conditions and the following disclaimer in the |
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* documentation and/or other materials provided with the distribution. |
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* 3. The name of the author may not be used to endorse or promote products |
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* derived from this software without specific prior written permission. |
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* |
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* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND |
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* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE |
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* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE |
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* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE |
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* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
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* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS |
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* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) |
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* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT |
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* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY |
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* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF |
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* SUCH DAMAGE. |
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* |
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* |
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* $Id: file.c,v 1.140 2007/02/10 14:29:54 debug Exp $ |
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* |
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* This file contains functions which load executable images into (emulated) |
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* memory. File formats recognized so far are: |
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* |
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* a.out old format used by OpenBSD 2.x pmax kernels |
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* Mach-O MacOS X format, etc. |
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* ecoff old format used by Ultrix, Windows NT, etc |
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* srec Motorola SREC format |
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* raw raw binaries, "address:[skiplen:[entrypoint:]]filename" |
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* ELF 32-bit and 64-bit ELFs |
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* |
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* If a file is not of one of the above mentioned formats, it is assumed |
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* to be symbol data generated by 'nm' or 'nm -S'. |
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*/ |
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|
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#include <stdio.h> |
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#include <stdlib.h> |
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#include <string.h> |
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#include <sys/types.h> |
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|
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#include "cpu.h" |
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#include "exec_aout.h" |
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#include "exec_ecoff.h" |
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#include "exec_elf.h" |
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#include "machine.h" |
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#include "memory.h" |
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#include "misc.h" |
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#include "symbol.h" |
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|
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|
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extern int quiet_mode; |
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extern int verbose; |
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|
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|
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/* ELF machine types as strings: (same as exec_elf.h) */ |
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#define N_ELF_MACHINE_TYPES 84 |
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static char *elf_machine_type[N_ELF_MACHINE_TYPES] = { |
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"NONE", "M32", "SPARC", "386", /* 0..3 */ |
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"68K", "88K", "486", "860", /* 4..7 */ |
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"MIPS", "S370", "MIPS_RS3_LE", "RS6000", /* 8..11 */ |
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"unknown12", "unknown13", "unknown14", "PARISC", /* 12..15 */ |
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"NCUBE", "VPP500", "SPARC32PLUS", "960", /* 16..19 */ |
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"PPC", "PPC64", "unknown22", "unknown23", /* 20..23 */ |
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"unknown24", "unknown25", "unknown26", "unknown27", /* 24..27 */ |
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"unknown28", "unknown29", "unknown30", "unknown31", /* 28..31 */ |
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"unknown32", "unknown33", "unknown34", "unknown35", /* 32..35 */ |
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"V800", "FR20", "RH32", "RCE", /* 36..39 */ |
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"ARM", "ALPHA", "SH", "SPARCV9", /* 40..43 */ |
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"TRICORE", "ARC", "H8_300", "H8_300H", /* 44..47 */ |
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"H8S", "H8_500", "IA_64", "MIPS_X", /* 48..51 */ |
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"COLDFIRE", "68HC12", "unknown54", "unknown55", /* 52..55 */ |
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"unknown56", "unknown57", "unknown58", "unknown59", /* 56..59 */ |
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"unknown60", "unknown61", "AMD64", "unknown63", /* 60..63 */ |
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"unknown64", "unknown65", "unknown66", "unknown67", /* 64..67 */ |
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"unknown68", "unknown69", "unknown70", "unknown71", /* 68..71 */ |
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"unknown72", "unknown73", "unknown74", "unknown75", /* 72..75 */ |
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"unknown76", "unknown77", "unknown78", "unknown79", /* 76..79 */ |
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"unknown80", "unknown81", "unknown82", "AVR" /* 80..83 */ |
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}; |
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|
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|
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/* |
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* This should be increased by every routine here that actually loads an |
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* executable file into memory. (For example, loading a symbol file should |
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* NOT increase this.) |
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*/ |
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static int n_executables_loaded = 0; |
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|
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|
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struct aout_symbol { |
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uint32_t strindex; |
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uint32_t type; |
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uint32_t addr; |
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}; |
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|
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/* Special symbol format used by Microsoft-ish COFF files: */ |
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struct ms_sym { |
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unsigned char name[8]; |
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unsigned char value[4]; |
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unsigned char section[2]; |
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unsigned char type[2]; |
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unsigned char storage_class; |
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unsigned char n_aux_syms; |
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}; |
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|
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|
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#define unencode(var,dataptr,typ) { \ |
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int Wi; unsigned char Wb; \ |
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unsigned char *Wp = (unsigned char *) dataptr; \ |
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int Wlen = sizeof(typ); \ |
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var = 0; \ |
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for (Wi=0; Wi<Wlen; Wi++) { \ |
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if (encoding == ELFDATA2LSB) \ |
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Wb = Wp[Wlen-1 - Wi]; \ |
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else \ |
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Wb = Wp[Wi]; \ |
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if (Wi == 0 && (Wb & 0x80)) { \ |
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var --; /* set var to -1 :-) */ \ |
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var <<= 8; \ |
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} \ |
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var |= Wb; \ |
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if (Wi < Wlen-1) \ |
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var <<= 8; \ |
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} \ |
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} |
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|
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|
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#define AOUT_FLAG_DECOSF1 1 |
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#define AOUT_FLAG_FROM_BEGINNING 2 |
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#define AOUT_FLAG_VADDR_ZERO_HACK 4 |
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#define AOUT_FLAG_NO_SIZES 8 |
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/* |
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* file_load_aout(): |
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* |
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* Loads an a.out binary image into the emulated memory. The entry point |
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* (read from the a.out header) is stored in the specified CPU's registers. |
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* |
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* TODO: This has to be rewritten / corrected to support multiple a.out |
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* formats, where text/data are aligned differently. |
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*/ |
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static void file_load_aout(struct machine *m, struct memory *mem, |
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char *filename, int flags, |
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uint64_t *entrypointp, int arch, int *byte_orderp) |
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{ |
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struct exec aout_header; |
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FILE *f; |
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int len; |
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int encoding = ELFDATA2LSB; |
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uint32_t entry, datasize, textsize; |
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int32_t symbsize = 0; |
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uint32_t vaddr, total_len; |
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unsigned char buf[65536]; |
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unsigned char *syms; |
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|
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if (m->cpus[0]->byte_order == EMUL_BIG_ENDIAN) |
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encoding = ELFDATA2MSB; |
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|
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f = fopen(filename, "r"); |
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if (f == NULL) { |
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perror(filename); |
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exit(1); |
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} |
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|
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if (flags & AOUT_FLAG_DECOSF1) { |
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fread(&buf, 1, 32, f); |
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vaddr = buf[16] + (buf[17] << 8) + |
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(buf[18] << 16) + ((uint64_t)buf[19] << 24); |
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entry = buf[20] + (buf[21] << 8) + |
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(buf[22] << 16) + ((uint64_t)buf[23] << 24); |
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debug("OSF1 a.out, load address 0x%08lx, " |
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"entry point 0x%08x\n", (long)vaddr, (long)entry); |
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symbsize = 0; |
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fseek(f, 0, SEEK_END); |
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/* This is of course wrong, but should work anyway: */ |
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textsize = ftello(f) - 512; |
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datasize = 0; |
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fseek(f, 512, SEEK_SET); |
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} else if (flags & AOUT_FLAG_NO_SIZES) { |
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fseek(f, 0, SEEK_END); |
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textsize = ftello(f) - 32; |
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datasize = 0; |
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vaddr = entry = 0; |
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fseek(f, 32, SEEK_SET); |
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} else { |
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len = fread(&aout_header, 1, sizeof(aout_header), f); |
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if (len != sizeof(aout_header)) { |
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fprintf(stderr, "%s: not a complete a.out image\n", |
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filename); |
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exit(1); |
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} |
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|
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unencode(entry, &aout_header.a_entry, uint32_t); |
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debug("a.out, entry point 0x%08lx\n", (long)entry); |
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vaddr = entry; |
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|
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if (flags & AOUT_FLAG_VADDR_ZERO_HACK) |
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vaddr = 0; |
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|
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unencode(textsize, &aout_header.a_text, uint32_t); |
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unencode(datasize, &aout_header.a_data, uint32_t); |
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debug("text + data = %i + %i bytes\n", textsize, datasize); |
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|
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unencode(symbsize, &aout_header.a_syms, uint32_t); |
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} |
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|
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if (flags & AOUT_FLAG_FROM_BEGINNING) { |
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fseek(f, 0, SEEK_SET); |
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vaddr &= ~0xfff; |
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} |
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|
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/* Load text and data: */ |
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total_len = textsize + datasize; |
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while (total_len != 0) { |
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len = total_len > sizeof(buf) ? sizeof(buf) : total_len; |
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len = fread(buf, 1, len, f); |
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|
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/* printf("fread len=%i vaddr=%x buf[0..]=%02x %02x %02x\n", |
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(int)len, (int)vaddr, buf[0], buf[1], buf[2]); */ |
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|
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if (len > 0) { |
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int len2 = 0; |
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uint64_t vaddr1 = vaddr & |
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((1 << BITS_PER_MEMBLOCK) - 1); |
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uint64_t vaddr2 = (vaddr + |
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len) & ((1 << BITS_PER_MEMBLOCK) - 1); |
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if (vaddr2 < vaddr1) { |
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len2 = len - vaddr2; |
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m->cpus[0]->memory_rw(m->cpus[0], mem, vaddr, |
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&buf[0], len2, MEM_WRITE, NO_EXCEPTIONS); |
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} |
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m->cpus[0]->memory_rw(m->cpus[0], mem, vaddr + len2, |
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&buf[len2], len-len2, MEM_WRITE, NO_EXCEPTIONS); |
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} else { |
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if (flags & AOUT_FLAG_DECOSF1) |
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break; |
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else { |
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fprintf(stderr, "could not read from %s\n", |
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filename); |
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exit(1); |
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} |
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} |
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|
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vaddr += len; |
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total_len -= len; |
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} |
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|
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if (symbsize != 0) { |
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struct aout_symbol *aout_symbol_ptr; |
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int i, n_symbols; |
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uint32_t type, addr, str_index; |
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uint32_t strings_len; |
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char *string_symbols; |
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off_t oldpos; |
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|
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debug("symbols: %i bytes @ 0x%x\n", symbsize, (int)ftello(f)); |
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syms = malloc(symbsize); |
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if (syms == NULL) { |
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fprintf(stderr, "out of memory\n"); |
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exit(1); |
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} |
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len = fread(syms, 1, symbsize, f); |
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if (len != symbsize) { |
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fprintf(stderr, "error reading symbols from %s\n", |
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filename); |
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exit(1); |
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} |
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|
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oldpos = ftello(f); |
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fseek(f, 0, SEEK_END); |
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strings_len = ftello(f) - oldpos; |
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fseek(f, oldpos, SEEK_SET); |
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debug("strings: %i bytes @ 0x%x\n", strings_len,(int)ftello(f)); |
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string_symbols = malloc(strings_len); |
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if (string_symbols == NULL) { |
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fprintf(stderr, "out of memory\n"); |
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exit(1); |
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} |
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fread(string_symbols, 1, strings_len, f); |
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|
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aout_symbol_ptr = (struct aout_symbol *) syms; |
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n_symbols = symbsize / sizeof(struct aout_symbol); |
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i = 0; |
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while (i < n_symbols) { |
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unencode(str_index, &aout_symbol_ptr[i].strindex, |
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uint32_t); |
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unencode(type, &aout_symbol_ptr[i].type, uint32_t); |
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unencode(addr, &aout_symbol_ptr[i].addr, uint32_t); |
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|
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/* debug("symbol type 0x%04x @ 0x%08x: %s\n", |
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type, addr, string_symbols + str_index); */ |
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|
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if (type != 0 && addr != 0) |
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add_symbol_name(&m->symbol_context, |
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addr, 0, string_symbols + str_index, 0, -1); |
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i++; |
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} |
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|
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free(string_symbols); |
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free(syms); |
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} |
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|
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fclose(f); |
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|
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*entrypointp = (int32_t)entry; |
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|
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if (encoding == ELFDATA2LSB) |
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*byte_orderp = EMUL_LITTLE_ENDIAN; |
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else |
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*byte_orderp = EMUL_BIG_ENDIAN; |
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|
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n_executables_loaded ++; |
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} |
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|
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|
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/* |
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* file_load_macho(): |
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* |
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* Loads a Mach-O binary image into the emulated memory. The entry point |
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* is stored in the specified CPU's registers. |
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* |
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* TODO: |
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* |
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* o) Almost everything. |
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* |
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* o) I haven't had time to look into whether Apple's open source |
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* license is BSD-compatible or not. Perhaps it would be possible |
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* to use a header file containing symbolic names, and not use |
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* hardcoded values. |
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*/ |
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static void file_load_macho(struct machine *m, struct memory *mem, |
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char *filename, uint64_t *entrypointp, int arch, int *byte_orderp, |
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int is_64bit, int is_reversed) |
341 |
{ |
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FILE *f; |
343 |
uint64_t entry = 0; |
344 |
int entry_set = 0; |
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int encoding = ELFDATA2MSB; |
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unsigned char buf[65536]; |
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char *symbols, *strings; |
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uint32_t cputype, cpusubtype, filetype, ncmds, sizeofcmds, flags; |
349 |
uint64_t vmaddr, vmsize, fileoff, filesize; |
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int cmd_type, cmd_len, i, flavor; |
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int32_t symoff, nsyms, stroff, strsize; |
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size_t len, pos; |
353 |
|
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if (m->cpus[0]->byte_order == EMUL_BIG_ENDIAN) |
355 |
encoding = ELFDATA2MSB; |
356 |
|
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f = fopen(filename, "r"); |
358 |
if (f == NULL) { |
359 |
perror(filename); |
360 |
exit(1); |
361 |
} |
362 |
|
363 |
if (is_64bit) { |
364 |
fatal("TODO: 64-bit Mach-O. Not supported yet.\n"); |
365 |
exit(1); |
366 |
} |
367 |
if (is_reversed) { |
368 |
fatal("TODO: Reversed-endianness. Not supported yet.\n"); |
369 |
exit(1); |
370 |
} |
371 |
|
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len = fread(buf, 1, sizeof(buf), f); |
373 |
if (len < 100) { |
374 |
fatal("Bad Mach-O file?\n"); |
375 |
exit(1); |
376 |
} |
377 |
|
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unencode(cputype, &buf[4], uint32_t); |
379 |
unencode(cpusubtype, &buf[8], uint32_t); |
380 |
unencode(filetype, &buf[12], uint32_t); |
381 |
unencode(ncmds, &buf[16], uint32_t); |
382 |
unencode(sizeofcmds, &buf[20], uint32_t); |
383 |
unencode(flags, &buf[24], uint32_t); |
384 |
|
385 |
/* debug("cputype=0x%x cpusubtype=0x%x filetype=0x%x\n", |
386 |
cputype, cpusubtype, filetype); |
387 |
debug("ncmds=%i sizeofcmds=0x%08x flags=0x%08x\n", |
388 |
ncmds, sizeofcmds, flags); */ |
389 |
|
390 |
/* |
391 |
* Compare to "normal" values. |
392 |
* NOTE/TODO: These were for a Darwin (Macintosh PPC) kernel. |
393 |
*/ |
394 |
if (cputype != 0x12) { |
395 |
fatal("Error: Unimplemented cputype 0x%x\n", cputype); |
396 |
exit(1); |
397 |
} |
398 |
if (cpusubtype != 0) { |
399 |
fatal("Error: Unimplemented cpusubtype 0x%x\n", cpusubtype); |
400 |
exit(1); |
401 |
} |
402 |
/* Filetype 2 means an executable image. */ |
403 |
if (filetype != 2) { |
404 |
fatal("Error: Unimplemented filetype 0x%x\n", filetype); |
405 |
exit(1); |
406 |
} |
407 |
if (!(flags & 1)) { |
408 |
fatal("Error: File has 'undefined references'. Cannot" |
409 |
" be executed.\n", flags); |
410 |
exit(1); |
411 |
} |
412 |
|
413 |
/* I've only encountered flags == 1 so far. */ |
414 |
if (flags != 1) { |
415 |
fatal("Error: Unimplemented flags 0x%x\n", flags); |
416 |
exit(1); |
417 |
} |
418 |
|
419 |
/* |
420 |
* Read all load commands: |
421 |
*/ |
422 |
pos = is_64bit? 32 : 28; |
423 |
cmd_type = 0; |
424 |
do { |
425 |
/* Read command type and length: */ |
426 |
unencode(cmd_type, &buf[pos], uint32_t); |
427 |
unencode(cmd_len, &buf[pos+4], uint32_t); |
428 |
|
429 |
#if 0 |
430 |
debug("cmd %i, len=%i\n", cmd_type, cmd_len); |
431 |
for (i=8; i<cmd_len; i++) { |
432 |
unsigned char ch = buf[pos+i]; |
433 |
if (ch >= ' ' && ch < 127) |
434 |
debug("%c", ch); |
435 |
else |
436 |
debug("."); |
437 |
} |
438 |
#endif |
439 |
switch (cmd_type) { |
440 |
case 1: /* LC_SEGMENT */ |
441 |
debug("seg "); |
442 |
for (i=0; i<16; i++) { |
443 |
if (buf[pos + 8 + i] == 0) |
444 |
break; |
445 |
debug("%c", buf[pos + 8 + i]); |
446 |
} |
447 |
unencode(vmaddr, &buf[pos+8+16+0], uint32_t); |
448 |
unencode(vmsize, &buf[pos+8+16+4], uint32_t); |
449 |
unencode(fileoff, &buf[pos+8+16+8], uint32_t); |
450 |
unencode(filesize, &buf[pos+8+16+12], uint32_t); |
451 |
debug(": vmaddr=0x%x size=0x%x fileoff=0x%x", |
452 |
(int)vmaddr, (int)vmsize, (int)fileoff); |
453 |
|
454 |
if (filesize == 0) { |
455 |
debug("\n"); |
456 |
break; |
457 |
} |
458 |
|
459 |
fseek(f, fileoff, SEEK_SET); |
460 |
|
461 |
/* Load data from the file: */ |
462 |
while (filesize != 0) { |
463 |
unsigned char buf[32768]; |
464 |
ssize_t len = filesize > sizeof(buf) ? |
465 |
sizeof(buf) : filesize; |
466 |
len = fread(buf, 1, len, f); |
467 |
|
468 |
/* printf("fread len=%i vmaddr=%x buf[0..]=" |
469 |
"%02x %02x %02x\n", (int)len, (int)vmaddr, |
470 |
buf[0], buf[1], buf[2]); */ |
471 |
|
472 |
if (len > 0) { |
473 |
int len2 = 0; |
474 |
uint64_t vaddr1 = vmaddr & |
475 |
((1 << BITS_PER_MEMBLOCK) - 1); |
476 |
uint64_t vaddr2 = (vmaddr + |
477 |
len) & ((1 << BITS_PER_MEMBLOCK)-1); |
478 |
if (vaddr2 < vaddr1) { |
479 |
len2 = len - vaddr2; |
480 |
m->cpus[0]->memory_rw(m->cpus[ |
481 |
0], mem, vmaddr, &buf[0], |
482 |
len2, MEM_WRITE, |
483 |
NO_EXCEPTIONS); |
484 |
} |
485 |
m->cpus[0]->memory_rw(m->cpus[0], mem, |
486 |
vmaddr + len2, &buf[len2], len-len2, |
487 |
MEM_WRITE, NO_EXCEPTIONS); |
488 |
} else { |
489 |
fprintf(stderr, "error reading\n"); |
490 |
exit(1); |
491 |
} |
492 |
|
493 |
vmaddr += len; |
494 |
filesize -= len; |
495 |
} |
496 |
|
497 |
debug("\n"); |
498 |
break; |
499 |
|
500 |
case 2: /* LC_SYMTAB */ |
501 |
unencode(symoff, &buf[pos+8], uint32_t); |
502 |
unencode(nsyms, &buf[pos+12], uint32_t); |
503 |
unencode(stroff, &buf[pos+16], uint32_t); |
504 |
unencode(strsize, &buf[pos+20], uint32_t); |
505 |
debug("symtable: %i symbols @ 0x%x (strings at " |
506 |
"0x%x)\n", nsyms, symoff, stroff); |
507 |
|
508 |
symbols = malloc(12 * nsyms); |
509 |
if (symbols == NULL) { |
510 |
fprintf(stderr, "out of memory\n"); |
511 |
exit(1); |
512 |
} |
513 |
fseek(f, symoff, SEEK_SET); |
514 |
fread(symbols, 1, 12 * nsyms, f); |
515 |
|
516 |
strings = malloc(strsize); |
517 |
if (strings == NULL) { |
518 |
fprintf(stderr, "out of memory\n"); |
519 |
exit(1); |
520 |
} |
521 |
fseek(f, stroff, SEEK_SET); |
522 |
fread(strings, 1, strsize, f); |
523 |
|
524 |
for (i=0; i<nsyms; i++) { |
525 |
int n_strx, n_type, n_sect, n_desc; |
526 |
uint32_t n_value; |
527 |
unencode(n_strx, &symbols[i*12+0], int32_t); |
528 |
unencode(n_type, &symbols[i*12+4], uint8_t); |
529 |
unencode(n_sect, &symbols[i*12+5], uint8_t); |
530 |
unencode(n_desc, &symbols[i*12+6], int16_t); |
531 |
unencode(n_value, &symbols[i*12+8], uint32_t); |
532 |
/* debug("%i: strx=%i type=%i sect=%i desc=%i" |
533 |
" value=0x%x\n", i, n_strx, n_type, |
534 |
n_sect, n_desc, n_value); */ |
535 |
add_symbol_name(&m->symbol_context, |
536 |
n_value, 0, strings + n_strx, 0, -1); |
537 |
} |
538 |
|
539 |
free(symbols); |
540 |
free(strings); |
541 |
break; |
542 |
|
543 |
case 5: debug("unix thread context: "); |
544 |
/* See http://cvs.sf.net/viewcvs.py/hte/ |
545 |
HT%20Editor/machostruc.h or similar for details |
546 |
on the thread struct. */ |
547 |
unencode(flavor, &buf[pos+8], uint32_t); |
548 |
if (flavor != 1) { |
549 |
fatal("unimplemented flavor %i\n", flavor); |
550 |
exit(1); |
551 |
} |
552 |
|
553 |
if (arch != ARCH_PPC) { |
554 |
fatal("non-PPC arch? TODO\n"); |
555 |
exit(1); |
556 |
} |
557 |
|
558 |
unencode(entry, &buf[pos+16], uint32_t); |
559 |
entry_set = 1; |
560 |
debug("pc=0x%x\n", (int)entry); |
561 |
|
562 |
for (i=1; i<40; i++) { |
563 |
uint32_t x; |
564 |
unencode(x, &buf[pos+16+i*4], uint32_t); |
565 |
if (x != 0) { |
566 |
fatal("Entry nr %i in the Mach-O" |
567 |
" thread struct is non-zero" |
568 |
" (0x%x). This is not supported" |
569 |
" yet. TODO\n", i, x); |
570 |
exit(1); |
571 |
} |
572 |
} |
573 |
break; |
574 |
|
575 |
default:fatal("WARNING! Unimplemented load command %i!\n", |
576 |
cmd_type); |
577 |
} |
578 |
|
579 |
pos += cmd_len; |
580 |
} while (pos < sizeofcmds && cmd_type != 0); |
581 |
|
582 |
fclose(f); |
583 |
|
584 |
if (!entry_set) { |
585 |
fatal("No entry point? Aborting.\n"); |
586 |
exit(1); |
587 |
} |
588 |
|
589 |
*entrypointp = entry; |
590 |
|
591 |
if (encoding == ELFDATA2LSB) |
592 |
*byte_orderp = EMUL_LITTLE_ENDIAN; |
593 |
else |
594 |
*byte_orderp = EMUL_BIG_ENDIAN; |
595 |
|
596 |
n_executables_loaded ++; |
597 |
} |
598 |
|
599 |
|
600 |
/* |
601 |
* file_load_ecoff(): |
602 |
* |
603 |
* Loads an ecoff binary image into the emulated memory. The entry point |
604 |
* (read from the ecoff header) is stored in the specified CPU's registers. |
605 |
*/ |
606 |
static void file_load_ecoff(struct machine *m, struct memory *mem, |
607 |
char *filename, uint64_t *entrypointp, |
608 |
int arch, uint64_t *gpp, int *byte_orderp) |
609 |
{ |
610 |
struct ecoff_exechdr exechdr; |
611 |
int f_magic, f_nscns, f_nsyms; |
612 |
int a_magic; |
613 |
off_t f_symptr, a_tsize, a_dsize, a_bsize; |
614 |
uint64_t a_entry, a_tstart, a_dstart, a_bstart, a_gp, end_addr=0; |
615 |
char *format_name; |
616 |
struct ecoff_scnhdr scnhdr; |
617 |
FILE *f; |
618 |
int len, secn, total_len, chunk_size; |
619 |
int encoding = ELFDATA2LSB; /* Assume little-endian. See below */ |
620 |
int program_byte_order = -1; |
621 |
unsigned char buf[8192]; |
622 |
|
623 |
f = fopen(filename, "r"); |
624 |
if (f == NULL) { |
625 |
perror(filename); |
626 |
exit(1); |
627 |
} |
628 |
|
629 |
len = fread(&exechdr, 1, sizeof(exechdr), f); |
630 |
if (len != sizeof(exechdr)) { |
631 |
fprintf(stderr, " not a complete ecoff image\n"); |
632 |
exit(1); |
633 |
} |
634 |
|
635 |
/* |
636 |
* The following code looks a bit ugly, but it should work. The ECOFF |
637 |
* 16-bit magic value seems to be stored in MSB byte order for |
638 |
* big-endian binaries, and LSB byte order for little-endian binaries. |
639 |
* |
640 |
* The unencode() assumes little-endianness by default. |
641 |
*/ |
642 |
unencode(f_magic, &exechdr.f.f_magic, uint16_t); |
643 |
switch (f_magic) { |
644 |
case ((ECOFF_MAGIC_MIPSEB & 0xff) << 8) + |
645 |
((ECOFF_MAGIC_MIPSEB >> 8) & 0xff): |
646 |
format_name = "MIPS1 BE"; |
647 |
encoding = ELFDATA2MSB; |
648 |
break; |
649 |
case ECOFF_MAGIC_MIPSEB: |
650 |
/* NOTE: Big-endian header, little-endian code! */ |
651 |
format_name = "MIPS1 BE-LE"; |
652 |
encoding = ELFDATA2MSB; |
653 |
program_byte_order = ELFDATA2LSB; |
654 |
break; |
655 |
case ECOFF_MAGIC_MIPSEL: |
656 |
format_name = "MIPS1 LE"; |
657 |
encoding = ELFDATA2LSB; |
658 |
break; |
659 |
case ((ECOFF_MAGIC_MIPSEB2 & 0xff) << 8) + |
660 |
((ECOFF_MAGIC_MIPSEB2 >> 8) & 0xff): |
661 |
format_name = "MIPS2 BE"; |
662 |
encoding = ELFDATA2MSB; |
663 |
break; |
664 |
case ECOFF_MAGIC_MIPSEL2: |
665 |
format_name = "MIPS2 LE"; |
666 |
encoding = ELFDATA2LSB; |
667 |
break; |
668 |
case ((ECOFF_MAGIC_MIPSEB3 & 0xff) << 8) + |
669 |
((ECOFF_MAGIC_MIPSEB3 >> 8) & 0xff): |
670 |
format_name = "MIPS3 BE"; |
671 |
encoding = ELFDATA2MSB; |
672 |
break; |
673 |
case ECOFF_MAGIC_MIPSEL3: |
674 |
format_name = "MIPS3 LE"; |
675 |
encoding = ELFDATA2LSB; |
676 |
break; |
677 |
default: |
678 |
fprintf(stderr, "%s: unimplemented ECOFF format, magic = " |
679 |
"0x%04x\n", filename, (int)f_magic); |
680 |
exit(1); |
681 |
} |
682 |
|
683 |
/* Read various header information: */ |
684 |
unencode(f_nscns, &exechdr.f.f_nscns, uint16_t); |
685 |
unencode(f_symptr, &exechdr.f.f_symptr, uint32_t); |
686 |
unencode(f_nsyms, &exechdr.f.f_nsyms, uint32_t); |
687 |
debug("ECOFF, %s, %i sections, %i symbols @ 0x%lx\n", |
688 |
format_name, f_nscns, f_nsyms, (long)f_symptr); |
689 |
|
690 |
unencode(a_magic, &exechdr.a.magic, uint16_t); |
691 |
unencode(a_tsize, &exechdr.a.tsize, uint32_t); |
692 |
unencode(a_dsize, &exechdr.a.dsize, uint32_t); |
693 |
unencode(a_bsize, &exechdr.a.bsize, uint32_t); |
694 |
debug("magic 0x%04x, tsize 0x%x, dsize 0x%x, bsize 0x%x\n", |
695 |
a_magic, (int)a_tsize, (int)a_dsize, (int)a_bsize); |
696 |
|
697 |
unencode(a_tstart, &exechdr.a.text_start, uint32_t); |
698 |
unencode(a_dstart, &exechdr.a.data_start, uint32_t); |
699 |
unencode(a_bstart, &exechdr.a.bss_start, uint32_t); |
700 |
debug("text @ 0x%08x, data @ 0x%08x, bss @ 0x%08x\n", |
701 |
(int)a_tstart, (int)a_dstart, (int)a_bstart); |
702 |
|
703 |
unencode(a_entry, &exechdr.a.entry, uint32_t); |
704 |
unencode(a_gp, &exechdr.a.gp_value, uint32_t); |
705 |
debug("entrypoint 0x%08x, gp = 0x%08x\n", |
706 |
(int)a_entry, (int)a_gp); |
707 |
|
708 |
/* |
709 |
* Special hack for a MACH/pmax kernel, I don't know how applicable |
710 |
* this is for other files: |
711 |
* there are no sections (!), and a_magic = 0x0108 instead of |
712 |
* 0x0107 as it is on most other (E)COFF files I've seen. |
713 |
* |
714 |
* Then load everything after the header to the text start address. |
715 |
*/ |
716 |
if (f_nscns == 0 && a_magic == 0x108) { |
717 |
uint64_t where = a_tstart; |
718 |
total_len = 0; |
719 |
fseek(f, 0x50, SEEK_SET); |
720 |
while (!feof(f)) { |
721 |
chunk_size = 256; |
722 |
len = fread(buf, 1, chunk_size, f); |
723 |
|
724 |
if (len > 0) |
725 |
m->cpus[0]->memory_rw(m->cpus[0], mem, where, |
726 |
&buf[0], len, MEM_WRITE, NO_EXCEPTIONS); |
727 |
where += len; |
728 |
total_len += len; |
729 |
} |
730 |
debug("MACH/pmax hack (!), read 0x%x bytes\n", total_len); |
731 |
} |
732 |
|
733 |
/* Go through all the section headers: */ |
734 |
for (secn=0; secn<f_nscns; secn++) { |
735 |
off_t s_scnptr, s_relptr, s_lnnoptr, oldpos; |
736 |
int s_nreloc, s_nlnno, s_flags; |
737 |
int s_size; |
738 |
unsigned int i; |
739 |
uint64_t s_paddr, s_vaddr; |
740 |
|
741 |
/* Read a section header: */ |
742 |
len = fread(&scnhdr, 1, sizeof(scnhdr), f); |
743 |
if (len != sizeof(scnhdr)) { |
744 |
fprintf(stderr, "%s: incomplete section " |
745 |
"header %i\n", filename, secn); |
746 |
exit(1); |
747 |
} |
748 |
|
749 |
/* Show the section name: */ |
750 |
debug("section "); |
751 |
for (i=0; i<sizeof(scnhdr.s_name); i++) |
752 |
if (scnhdr.s_name[i] >= 32 && scnhdr.s_name[i] < 127) |
753 |
debug("%c", scnhdr.s_name[i]); |
754 |
else |
755 |
break; |
756 |
debug(" ("); |
757 |
|
758 |
unencode(s_paddr, &scnhdr.s_paddr, uint32_t); |
759 |
unencode(s_vaddr, &scnhdr.s_vaddr, uint32_t); |
760 |
unencode(s_size, &scnhdr.s_size, uint32_t); |
761 |
unencode(s_scnptr, &scnhdr.s_scnptr, uint32_t); |
762 |
unencode(s_relptr, &scnhdr.s_relptr, uint32_t); |
763 |
unencode(s_lnnoptr, &scnhdr.s_lnnoptr, uint32_t); |
764 |
unencode(s_nreloc, &scnhdr.s_nreloc, uint16_t); |
765 |
unencode(s_nlnno, &scnhdr.s_nlnno, uint16_t); |
766 |
unencode(s_flags, &scnhdr.s_flags, uint32_t); |
767 |
|
768 |
debug("0x%x @ 0x%08x, offset 0x%lx, flags 0x%x)\n", |
769 |
(int)s_size, (int)s_vaddr, (long)s_scnptr, (int)s_flags); |
770 |
|
771 |
end_addr = s_vaddr + s_size; |
772 |
|
773 |
if (s_relptr != 0) { |
774 |
/* |
775 |
* TODO: Read this url, or similar: |
776 |
* http://www.iecc.com/linker/linker07.html |
777 |
*/ |
778 |
fprintf(stderr, "%s: relocatable code/data in " |
779 |
"section nr %i: not yet implemented\n", |
780 |
filename, secn); |
781 |
exit(1); |
782 |
} |
783 |
|
784 |
/* Loadable? Then load the section: */ |
785 |
if (s_scnptr != 0 && s_size != 0 && |
786 |
s_vaddr != 0 && !(s_flags & 0x02)) { |
787 |
/* Remember the current file offset: */ |
788 |
oldpos = ftello(f); |
789 |
|
790 |
/* Load the section into emulated memory: */ |
791 |
fseek(f, s_scnptr, SEEK_SET); |
792 |
total_len = 0; |
793 |
chunk_size = 1; |
794 |
if ((s_vaddr & 0xf) == 0) chunk_size = 0x10; |
795 |
if ((s_vaddr & 0xff) == 0) chunk_size = 0x100; |
796 |
if ((s_vaddr & 0xfff) == 0) chunk_size = 0x1000; |
797 |
while (total_len < s_size) { |
798 |
len = chunk_size; |
799 |
if (total_len + len > s_size) |
800 |
len = s_size - total_len; |
801 |
len = fread(buf, 1, chunk_size, f); |
802 |
if (len == 0) { |
803 |
debug("!!! total_len = %i, " |
804 |
"chunk_size = %i, len = %i\n", |
805 |
total_len, chunk_size, len); |
806 |
break; |
807 |
} |
808 |
|
809 |
m->cpus[0]->memory_rw(m->cpus[0], mem, s_vaddr, |
810 |
&buf[0], len, MEM_WRITE, NO_EXCEPTIONS); |
811 |
s_vaddr += len; |
812 |
total_len += len; |
813 |
} |
814 |
|
815 |
/* Return to position inside the section headers: */ |
816 |
fseek(f, oldpos, SEEK_SET); |
817 |
} |
818 |
} |
819 |
|
820 |
if (f_symptr != 0 && f_nsyms != 0) { |
821 |
struct ecoff_symhdr symhdr; |
822 |
int sym_magic, iextMax, issExtMax, issMax, crfd; |
823 |
off_t cbRfdOffset, cbExtOffset, cbSsExtOffset, cbSsOffset; |
824 |
char *symbol_data; |
825 |
struct ecoff_extsym *extsyms; |
826 |
int nsymbols, sym_nr; |
827 |
|
828 |
fseek(f, f_symptr, SEEK_SET); |
829 |
|
830 |
len = fread(&symhdr, 1, sizeof(symhdr), f); |
831 |
if (len != sizeof(symhdr)) { |
832 |
fprintf(stderr, "%s: not a complete " |
833 |
"ecoff image: symhdr broken\n", filename); |
834 |
exit(1); |
835 |
} |
836 |
|
837 |
unencode(sym_magic, &symhdr.magic, uint16_t); |
838 |
unencode(crfd, &symhdr.crfd, uint32_t); |
839 |
unencode(cbRfdOffset, &symhdr.cbRfdOffset, uint32_t); |
840 |
unencode(issMax, &symhdr.issMax, uint32_t); |
841 |
unencode(cbSsOffset, &symhdr.cbSsOffset, uint32_t); |
842 |
unencode(issExtMax, &symhdr.issExtMax, uint32_t); |
843 |
unencode(cbSsExtOffset, &symhdr.cbSsExtOffset, uint32_t); |
844 |
unencode(iextMax, &symhdr.iextMax, uint32_t); |
845 |
unencode(cbExtOffset, &symhdr.cbExtOffset, uint32_t); |
846 |
|
847 |
if (sym_magic != MIPS_MAGIC_SYM) { |
848 |
unsigned char *ms_sym_buf; |
849 |
struct ms_sym *sym; |
850 |
int n_real_symbols = 0; |
851 |
|
852 |
debug("bad symbol magic, assuming Microsoft format: "); |
853 |
|
854 |
/* |
855 |
* See http://www.lisoleg.net/lisoleg/elfandlib/ |
856 |
* Microsoft%20Portable%20Executable%20COFF%20For |
857 |
* mat%20Specification.txt |
858 |
* for more details. |
859 |
*/ |
860 |
ms_sym_buf = malloc(sizeof(struct ms_sym) * f_nsyms); |
861 |
if (ms_sym_buf == NULL) { |
862 |
fprintf(stderr, "out of memory\n"); |
863 |
exit(1); |
864 |
} |
865 |
fseek(f, f_symptr, SEEK_SET); |
866 |
len = fread(ms_sym_buf, 1, |
867 |
sizeof(struct ms_sym) * f_nsyms, f); |
868 |
sym = (struct ms_sym *) ms_sym_buf; |
869 |
for (sym_nr=0; sym_nr<f_nsyms; sym_nr++) { |
870 |
char name[300]; |
871 |
uint32_t v, t, altname; |
872 |
/* debug("sym %5i: '", sym_nr); |
873 |
for (i=0; i<8 && sym->name[i]; i++) |
874 |
debug("%c", sym->name[i]); */ |
875 |
v = sym->value[0] + (sym->value[1] << 8) |
876 |
+ (sym->value[2] << 16) |
877 |
+ ((uint64_t)sym->value[3] << 24); |
878 |
altname = sym->name[4] + (sym->name[5] << 8) |
879 |
+ (sym->name[6] << 16) |
880 |
+ ((uint64_t)sym->name[3] << 24); |
881 |
t = (sym->type[1] << 8) + sym->type[0]; |
882 |
/* TODO: big endian COFF? */ |
883 |
/* debug("' value=0x%x type=0x%04x", v, t); */ |
884 |
|
885 |
if (t == 0x20 && sym->name[0]) { |
886 |
memcpy(name, sym->name, 8); |
887 |
name[8] = '\0'; |
888 |
add_symbol_name(&m->symbol_context, |
889 |
v, 0, name, 0, -1); |
890 |
n_real_symbols ++; |
891 |
} else if (t == 0x20 && !sym->name[0]) { |
892 |
off_t ofs; |
893 |
ofs = f_symptr + altname + |
894 |
sizeof(struct ms_sym) * f_nsyms; |
895 |
fseek(f, ofs, SEEK_SET); |
896 |
fread(name, 1, sizeof(name), f); |
897 |
name[sizeof(name)-1] = '\0'; |
898 |
/* debug(" [altname=0x%x '%s']", |
899 |
altname, name); */ |
900 |
add_symbol_name(&m->symbol_context, |
901 |
v, 0, name, 0, -1); |
902 |
n_real_symbols ++; |
903 |
} |
904 |
|
905 |
|
906 |
if (sym->n_aux_syms) { |
907 |
int n = sym->n_aux_syms; |
908 |
/* debug(" aux='"); */ |
909 |
while (n-- > 0) { |
910 |
sym ++; sym_nr ++; |
911 |
/* for (i=0; i<8 && |
912 |
sym->name[i]; i++) |
913 |
debug("%c", |
914 |
sym->name[i]); */ |
915 |
} |
916 |
/* debug("'"); */ |
917 |
} |
918 |
/* debug("\n"); */ |
919 |
sym ++; |
920 |
} |
921 |
|
922 |
debug("%i symbols\n", n_real_symbols); |
923 |
free(ms_sym_buf); |
924 |
|
925 |
goto skip_normal_coff_symbols; |
926 |
} |
927 |
|
928 |
debug("symbol header: magic = 0x%x\n", sym_magic); |
929 |
|
930 |
debug("%i symbols @ 0x%08x (strings @ 0x%08x)\n", |
931 |
iextMax, cbExtOffset, cbSsExtOffset); |
932 |
|
933 |
symbol_data = malloc(issExtMax + 2); |
934 |
if (symbol_data == NULL) { |
935 |
fprintf(stderr, "out of memory\n"); |
936 |
exit(1); |
937 |
} |
938 |
memset(symbol_data, 0, issExtMax + 2); |
939 |
fseek(f, cbSsExtOffset, SEEK_SET); |
940 |
fread(symbol_data, 1, issExtMax + 1, f); |
941 |
|
942 |
nsymbols = iextMax; |
943 |
|
944 |
extsyms = malloc(iextMax * sizeof(struct ecoff_extsym)); |
945 |
if (extsyms == NULL) { |
946 |
fprintf(stderr, "out of memory\n"); |
947 |
exit(1); |
948 |
} |
949 |
memset(extsyms, 0, iextMax * sizeof(struct ecoff_extsym)); |
950 |
fseek(f, cbExtOffset, SEEK_SET); |
951 |
fread(extsyms, 1, iextMax * sizeof(struct ecoff_extsym), f); |
952 |
|
953 |
/* Unencode the strindex and value first: */ |
954 |
for (sym_nr=0; sym_nr<nsymbols; sym_nr++) { |
955 |
uint64_t value, strindex; |
956 |
|
957 |
unencode(strindex, &extsyms[sym_nr].es_strindex, |
958 |
uint32_t); |
959 |
unencode(value, &extsyms[sym_nr].es_value, uint32_t); |
960 |
|
961 |
extsyms[sym_nr].es_strindex = strindex; |
962 |
extsyms[sym_nr].es_value = value; |
963 |
} |
964 |
|
965 |
for (sym_nr=0; sym_nr<nsymbols; sym_nr++) { |
966 |
/* debug("symbol%6i: 0x%08x = %s\n", |
967 |
sym_nr, (int)extsyms[sym_nr].es_value, |
968 |
symbol_data + extsyms[sym_nr].es_strindex); */ |
969 |
|
970 |
add_symbol_name(&m->symbol_context, |
971 |
extsyms[sym_nr].es_value, 0, |
972 |
symbol_data + extsyms[sym_nr].es_strindex, 0, -1); |
973 |
} |
974 |
|
975 |
free(extsyms); |
976 |
free(symbol_data); |
977 |
|
978 |
skip_normal_coff_symbols: |
979 |
; |
980 |
} |
981 |
|
982 |
fclose(f); |
983 |
|
984 |
*entrypointp = a_entry; |
985 |
*gpp = a_gp; |
986 |
m->file_loaded_end_addr = end_addr; |
987 |
|
988 |
if (program_byte_order != -1) |
989 |
encoding = program_byte_order; |
990 |
|
991 |
if (encoding == ELFDATA2LSB) |
992 |
*byte_orderp = EMUL_LITTLE_ENDIAN; |
993 |
else |
994 |
*byte_orderp = EMUL_BIG_ENDIAN; |
995 |
|
996 |
n_executables_loaded ++; |
997 |
} |
998 |
|
999 |
|
1000 |
/* |
1001 |
* file_load_srec(): |
1002 |
* |
1003 |
* Loads a Motorola SREC file into emulated memory. Description of the SREC |
1004 |
* file format can be found at here: |
1005 |
* |
1006 |
* http://www.ndsu.nodak.edu/instruct/tareski/373f98/notes/srecord.htm |
1007 |
* or http://www.amelek.gda.pl/avr/uisp/srecord.htm |
1008 |
*/ |
1009 |
static void file_load_srec(struct machine *m, struct memory *mem, |
1010 |
char *filename, uint64_t *entrypointp) |
1011 |
{ |
1012 |
FILE *f; |
1013 |
unsigned char buf[516]; |
1014 |
unsigned char bytes[270]; |
1015 |
uint64_t entry = 0, vaddr = 0; |
1016 |
int i, j, count; |
1017 |
char ch; |
1018 |
int buf_len, data_start = 0; |
1019 |
int entry_set = 0; |
1020 |
int warning = 0; |
1021 |
int warning_len = 0; |
1022 |
int total_bytes_loaded = 0; |
1023 |
|
1024 |
f = fopen(filename, "r"); |
1025 |
if (f == NULL) { |
1026 |
perror(filename); |
1027 |
exit(1); |
1028 |
} |
1029 |
|
1030 |
/* Load file contents: */ |
1031 |
while (!feof(f)) { |
1032 |
memset(buf, 0, sizeof(buf)); |
1033 |
fgets((char *)buf, sizeof(buf)-1, f); |
1034 |
|
1035 |
if (buf[0] == 0 || buf[0]=='\r' || buf[0]=='\n') |
1036 |
continue; |
1037 |
|
1038 |
if (buf[0] != 'S') { |
1039 |
if (!warning) |
1040 |
debug("WARNING! non-S-record found\n"); |
1041 |
warning = 1; |
1042 |
continue; |
1043 |
} |
1044 |
|
1045 |
buf_len = strlen((char *)buf); |
1046 |
|
1047 |
if (buf_len < 10) { |
1048 |
if (!warning_len) |
1049 |
debug("WARNING! invalid S-record found\n"); |
1050 |
warning_len = 1; |
1051 |
continue; |
1052 |
} |
1053 |
|
1054 |
/* |
1055 |
* Stype count address data checksum |
1056 |
* 01 23 4.. .. (last 2 bytes) |
1057 |
* |
1058 |
* TODO: actually check the checksum |
1059 |
*/ |
1060 |
|
1061 |
j = 0; |
1062 |
for (i=1; i<buf_len; i++) { |
1063 |
if (buf[i]>='a' && buf[i]<='f') |
1064 |
buf[i] += 10 - 'a'; |
1065 |
else if (buf[i] >= 'A' && buf[i] <= 'F') |
1066 |
buf[i] += 10 - 'A'; |
1067 |
else if (buf[i] >= '0' && buf[i] <= '9') |
1068 |
buf[i] -= '0'; |
1069 |
else if (buf[i] == '\r' || buf[i] == '\n') { |
1070 |
} else |
1071 |
fatal("invalid characters '%c' in S-record\n", |
1072 |
buf[i]); |
1073 |
|
1074 |
if (i >= 4) { |
1075 |
if (i & 1) |
1076 |
bytes[j++] += buf[i]; |
1077 |
else |
1078 |
bytes[j] = buf[i] * 16; |
1079 |
} |
1080 |
} |
1081 |
|
1082 |
count = buf[2] * 16 + buf[3]; |
1083 |
/* debug("count=%i j=%i\n", count, j); */ |
1084 |
/* count is j - 1. */ |
1085 |
|
1086 |
switch (buf[1]) { |
1087 |
case 0: |
1088 |
debug("SREC \""); |
1089 |
for (i=2; i<count-1; i++) { |
1090 |
ch = bytes[i]; |
1091 |
if (ch >= ' ' && ch < 127) |
1092 |
debug("%c", ch); |
1093 |
else |
1094 |
debug("?"); |
1095 |
} |
1096 |
debug("\"\n"); |
1097 |
break; |
1098 |
case 1: |
1099 |
case 2: |
1100 |
case 3: |
1101 |
/* switch again, to get the load address: */ |
1102 |
switch (buf[1]) { |
1103 |
case 1: data_start = 2; |
1104 |
vaddr = (bytes[0] << 8) + bytes[1]; |
1105 |
break; |
1106 |
case 2: data_start = 3; |
1107 |
vaddr = (bytes[0] << 16) + (bytes[1] << 8) + |
1108 |
bytes[2]; |
1109 |
break; |
1110 |
case 3: data_start = 4; |
1111 |
vaddr = ((uint64_t)bytes[0] << 24) + |
1112 |
(bytes[1] << 16) + (bytes[2]<<8) + bytes[3]; |
1113 |
} |
1114 |
m->cpus[0]->memory_rw(m->cpus[0], mem, vaddr, |
1115 |
&bytes[data_start], count - 1 - data_start, |
1116 |
MEM_WRITE, NO_EXCEPTIONS); |
1117 |
total_bytes_loaded += count - 1 - data_start; |
1118 |
break; |
1119 |
case 7: |
1120 |
case 8: |
1121 |
case 9: |
1122 |
/* switch again, to get the entry point: */ |
1123 |
switch (buf[1]) { |
1124 |
case 7: entry = ((uint64_t)bytes[0] << 24) + |
1125 |
(bytes[1] << 16) + (bytes[2]<<8) + bytes[3]; |
1126 |
break; |
1127 |
case 8: entry = (bytes[0] << 16) + (bytes[1] << 8) + |
1128 |
bytes[2]; |
1129 |
break; |
1130 |
case 9: entry = (bytes[0] << 8) + bytes[1]; |
1131 |
break; |
1132 |
} |
1133 |
entry_set = 1; |
1134 |
debug("entry point 0x%08x\n", (unsigned int)entry); |
1135 |
break; |
1136 |
default: |
1137 |
debug("unimplemented S-record type %i\n", buf[1]); |
1138 |
} |
1139 |
} |
1140 |
|
1141 |
debug("0x%x bytes loaded\n", total_bytes_loaded); |
1142 |
|
1143 |
fclose(f); |
1144 |
|
1145 |
if (!entry_set) |
1146 |
debug("WARNING! no entrypoint found!\n"); |
1147 |
else |
1148 |
*entrypointp = entry; |
1149 |
|
1150 |
n_executables_loaded ++; |
1151 |
} |
1152 |
|
1153 |
|
1154 |
/* |
1155 |
* file_load_raw(): |
1156 |
* |
1157 |
* Loads a raw binary into emulated memory. The filename should be |
1158 |
* of the following form: loadaddress:filename |
1159 |
* or loadaddress:skiplen:filename |
1160 |
* or loadaddress:skiplen:pc:filename |
1161 |
*/ |
1162 |
static void file_load_raw(struct machine *m, struct memory *mem, |
1163 |
char *filename, uint64_t *entrypointp) |
1164 |
{ |
1165 |
FILE *f; |
1166 |
int len, sign3264; |
1167 |
unsigned char buf[16384]; |
1168 |
uint64_t entry, loadaddr, vaddr, skip = 0; |
1169 |
char *p, *p2; |
1170 |
|
1171 |
/* Special case for 32-bit MIPS: */ |
1172 |
sign3264 = 0; |
1173 |
if (m->arch == ARCH_MIPS && m->cpus[0]->is_32bit) |
1174 |
sign3264 = 1; |
1175 |
|
1176 |
p = strchr(filename, ':'); |
1177 |
if (p == NULL) { |
1178 |
fprintf(stderr, "\n"); |
1179 |
perror(filename); |
1180 |
exit(1); |
1181 |
} |
1182 |
|
1183 |
loadaddr = vaddr = entry = strtoull(filename, NULL, 0); |
1184 |
p2 = p+1; |
1185 |
|
1186 |
/* A second value? That's the optional skip value */ |
1187 |
p = strchr(p2, ':'); |
1188 |
if (p != NULL) { |
1189 |
skip = strtoull(p2, NULL, 0); |
1190 |
p = p+1; |
1191 |
/* A third value? That's the initial pc: */ |
1192 |
if (strchr(p, ':') != NULL) { |
1193 |
entry = strtoull(p, NULL, 0); |
1194 |
p = strchr(p, ':') + 1; |
1195 |
} |
1196 |
} else |
1197 |
p = p2; |
1198 |
|
1199 |
if (sign3264) { |
1200 |
loadaddr = (int64_t)(int32_t)loadaddr; |
1201 |
entry = (int64_t)(int32_t)entry; |
1202 |
vaddr = (int64_t)(int32_t)vaddr; |
1203 |
skip = (int64_t)(int32_t)skip; |
1204 |
} |
1205 |
|
1206 |
f = fopen(strrchr(filename, ':')+1, "r"); |
1207 |
if (f == NULL) { |
1208 |
perror(p); |
1209 |
exit(1); |
1210 |
} |
1211 |
|
1212 |
fseek(f, skip, SEEK_SET); |
1213 |
|
1214 |
/* Load file contents: */ |
1215 |
while (!feof(f)) { |
1216 |
size_t to_read = sizeof(buf); |
1217 |
|
1218 |
/* If vaddr isn't buf-size aligned, then start with a |
1219 |
smaller buffer: */ |
1220 |
if (vaddr & (sizeof(buf) - 1)) |
1221 |
to_read = sizeof(buf) - (vaddr & (sizeof(buf)-1)); |
1222 |
|
1223 |
len = fread(buf, 1, to_read, f); |
1224 |
|
1225 |
if (len > 0) |
1226 |
m->cpus[0]->memory_rw(m->cpus[0], mem, vaddr, &buf[0], |
1227 |
len, MEM_WRITE, NO_EXCEPTIONS); |
1228 |
|
1229 |
vaddr += len; |
1230 |
} |
1231 |
|
1232 |
debug("RAW: 0x%"PRIx64" bytes @ 0x%08"PRIx64, |
1233 |
(uint64_t) (ftello(f) - skip), (uint64_t) loadaddr); |
1234 |
|
1235 |
if (skip != 0) |
1236 |
debug(" (0x%"PRIx64" bytes of header skipped)", |
1237 |
(uint64_t) skip); |
1238 |
|
1239 |
debug("\n"); |
1240 |
|
1241 |
fclose(f); |
1242 |
|
1243 |
*entrypointp = entry; |
1244 |
|
1245 |
n_executables_loaded ++; |
1246 |
} |
1247 |
|
1248 |
|
1249 |
/* |
1250 |
* file_load_elf(): |
1251 |
* |
1252 |
* Loads an ELF image into the emulated memory. The entry point (read from |
1253 |
* the ELF header) and the initial value of the gp register (read from the |
1254 |
* ELF symbol table) are stored in the specified CPU's registers. |
1255 |
* |
1256 |
* This is pretty heavy stuff, but is needed because of the heaviness of |
1257 |
* ELF files. :-/ Hopefully it will be able to recognize most valid ELFs. |
1258 |
*/ |
1259 |
static void file_load_elf(struct machine *m, struct memory *mem, |
1260 |
char *filename, uint64_t *entrypointp, int arch, uint64_t *gpp, |
1261 |
int *byte_order, uint64_t *tocp) |
1262 |
{ |
1263 |
Elf32_Ehdr hdr32; |
1264 |
Elf64_Ehdr hdr64; |
1265 |
FILE *f; |
1266 |
uint64_t eentry; |
1267 |
int len, i, ok; |
1268 |
int elf64, encoding, eflags; |
1269 |
int etype, emachine; |
1270 |
int ephnum, ephentsize, eshnum, eshentsize; |
1271 |
off_t ephoff, eshoff; |
1272 |
Elf32_Phdr phdr32; |
1273 |
Elf64_Phdr phdr64; |
1274 |
Elf32_Shdr shdr32; |
1275 |
Elf64_Shdr shdr64; |
1276 |
Elf32_Sym sym32; |
1277 |
Elf64_Sym sym64; |
1278 |
int ofs; |
1279 |
int chunk_len = 1024, align_len; |
1280 |
char *symbol_strings = NULL; size_t symbol_length = 0; |
1281 |
char *s; |
1282 |
Elf32_Sym *symbols_sym32 = NULL; int n_symbols = 0; |
1283 |
Elf64_Sym *symbols_sym64 = NULL; |
1284 |
|
1285 |
f = fopen(filename, "r"); |
1286 |
if (f == NULL) { |
1287 |
perror(filename); |
1288 |
exit(1); |
1289 |
} |
1290 |
|
1291 |
len = fread(&hdr32, 1, sizeof(Elf32_Ehdr), f); |
1292 |
if (len < (signed int)sizeof(Elf32_Ehdr)) { |
1293 |
fprintf(stderr, "%s: not an ELF file image\n", filename); |
1294 |
exit(1); |
1295 |
} |
1296 |
|
1297 |
if (memcmp(&hdr32.e_ident[EI_MAG0], ELFMAG, SELFMAG) != 0) { |
1298 |
fprintf(stderr, "%s: not an ELF file image\n", filename); |
1299 |
exit(1); |
1300 |
} |
1301 |
|
1302 |
switch (hdr32.e_ident[EI_CLASS]) { |
1303 |
case ELFCLASS32: |
1304 |
elf64 = 0; |
1305 |
break; |
1306 |
case ELFCLASS64: |
1307 |
elf64 = 1; |
1308 |
fseek(f, 0, SEEK_SET); |
1309 |
len = fread(&hdr64, 1, sizeof(Elf64_Ehdr), f); |
1310 |
if (len < (signed int)sizeof(Elf64_Ehdr)) { |
1311 |
fprintf(stderr, "%s: not an ELF64 file image\n", |
1312 |
filename); |
1313 |
exit(1); |
1314 |
} |
1315 |
break; |
1316 |
default: |
1317 |
fprintf(stderr, "%s: unknown ELF class '%i'\n", |
1318 |
filename, hdr32.e_ident[EI_CLASS]); |
1319 |
exit(1); |
1320 |
} |
1321 |
|
1322 |
encoding = hdr32.e_ident[EI_DATA]; |
1323 |
if (encoding != ELFDATA2LSB && encoding != ELFDATA2MSB) { |
1324 |
fprintf(stderr, "%s: unknown data encoding '%i'\n", |
1325 |
filename, hdr32.e_ident[EI_DATA]); |
1326 |
exit(1); |
1327 |
} |
1328 |
|
1329 |
if (elf64) { |
1330 |
unencode(etype, &hdr64.e_type, Elf64_Quarter); |
1331 |
unencode(eflags, &hdr64.e_flags, Elf64_Half); |
1332 |
unencode(emachine, &hdr64.e_machine, Elf64_Quarter); |
1333 |
unencode(eentry, &hdr64.e_entry, Elf64_Addr); |
1334 |
unencode(ephnum, &hdr64.e_phnum, Elf64_Quarter); |
1335 |
unencode(ephentsize, &hdr64.e_phentsize, Elf64_Quarter); |
1336 |
unencode(ephoff, &hdr64.e_phoff, Elf64_Off); |
1337 |
unencode(eshnum, &hdr64.e_shnum, Elf64_Quarter); |
1338 |
unencode(eshentsize, &hdr64.e_shentsize, Elf64_Quarter); |
1339 |
unencode(eshoff, &hdr64.e_shoff, Elf64_Off); |
1340 |
if (ephentsize != sizeof(Elf64_Phdr)) { |
1341 |
fprintf(stderr, "%s: incorrect phentsize? %i, should " |
1342 |
"be %i\nPerhaps this is a dynamically linked " |
1343 |
"binary (which isn't supported yet).\n", filename, |
1344 |
(int)ephentsize, (int)sizeof(Elf64_Phdr)); |
1345 |
exit(1); |
1346 |
} |
1347 |
if (eshentsize != sizeof(Elf64_Shdr)) { |
1348 |
fprintf(stderr, "%s: incorrect shentsize? %i, should " |
1349 |
"be %i\nPerhaps this is a dynamically linked " |
1350 |
"binary (which isn't supported yet).\n", filename, |
1351 |
(int)eshentsize, (int)sizeof(Elf64_Shdr)); |
1352 |
exit(1); |
1353 |
} |
1354 |
} else { |
1355 |
unencode(etype, &hdr32.e_type, Elf32_Half); |
1356 |
unencode(eflags, &hdr32.e_flags, Elf32_Word); |
1357 |
unencode(emachine, &hdr32.e_machine, Elf32_Half); |
1358 |
unencode(eentry, &hdr32.e_entry, Elf32_Addr); |
1359 |
unencode(ephnum, &hdr32.e_phnum, Elf32_Half); |
1360 |
unencode(ephentsize, &hdr32.e_phentsize, Elf32_Half); |
1361 |
unencode(ephoff, &hdr32.e_phoff, Elf32_Off); |
1362 |
unencode(eshnum, &hdr32.e_shnum, Elf32_Half); |
1363 |
unencode(eshentsize, &hdr32.e_shentsize, Elf32_Half); |
1364 |
unencode(eshoff, &hdr32.e_shoff, Elf32_Off); |
1365 |
if (ephentsize != sizeof(Elf32_Phdr)) { |
1366 |
fprintf(stderr, "%s: incorrect phentsize? %i, should " |
1367 |
"be %i\nPerhaps this is a dynamically linked " |
1368 |
"binary (which isn't supported yet).\n", filename, |
1369 |
(int)ephentsize, (int)sizeof(Elf32_Phdr)); |
1370 |
exit(1); |
1371 |
} |
1372 |
if (eshentsize != sizeof(Elf32_Shdr)) { |
1373 |
fprintf(stderr, "%s: incorrect shentsize? %i, should " |
1374 |
"be %i\nPerhaps this is a dynamically linked " |
1375 |
"binary (which isn't supported yet).\n", filename, |
1376 |
(int)eshentsize, (int)sizeof(Elf32_Shdr)); |
1377 |
exit(1); |
1378 |
} |
1379 |
} |
1380 |
|
1381 |
if ( etype != ET_EXEC ) { |
1382 |
fprintf(stderr, "%s is not an ELF Executable file, type = %i\n", |
1383 |
filename, etype); |
1384 |
exit(1); |
1385 |
} |
1386 |
|
1387 |
ok = 0; |
1388 |
switch (arch) { |
1389 |
case ARCH_ALPHA: |
1390 |
switch (emachine) { |
1391 |
case EM_ALPHA: |
1392 |
case -28634: |
1393 |
ok = 1; |
1394 |
} |
1395 |
break; |
1396 |
case ARCH_ARM: |
1397 |
switch (emachine) { |
1398 |
case EM_ARM: |
1399 |
ok = 1; |
1400 |
} |
1401 |
break; |
1402 |
case ARCH_AVR: |
1403 |
switch (emachine) { |
1404 |
case EM_AVR: |
1405 |
ok = 1; |
1406 |
} |
1407 |
break; |
1408 |
/* case ARCH_AVR32: |
1409 |
switch (emachine) { |
1410 |
case 6317: |
1411 |
ok = 1; |
1412 |
} |
1413 |
break; |
1414 |
case ARCH_HPPA: |
1415 |
switch (emachine) { |
1416 |
case EM_PARISC: |
1417 |
ok = 1; |
1418 |
} |
1419 |
break; |
1420 |
case ARCH_I960: |
1421 |
switch (emachine) { |
1422 |
case EM_960: |
1423 |
ok = 1; |
1424 |
} |
1425 |
break; |
1426 |
case ARCH_IA64: |
1427 |
switch (emachine) { |
1428 |
case EM_IA_64: |
1429 |
ok = 1; |
1430 |
} |
1431 |
break; */ |
1432 |
case ARCH_M68K: |
1433 |
switch (emachine) { |
1434 |
case EM_68K: |
1435 |
ok = 1; |
1436 |
} |
1437 |
break; |
1438 |
case ARCH_MIPS: |
1439 |
switch (emachine) { |
1440 |
case EM_MIPS: |
1441 |
case EM_MIPS_RS3_LE: |
1442 |
ok = 1; |
1443 |
} |
1444 |
break; |
1445 |
case ARCH_PPC: |
1446 |
switch (emachine) { |
1447 |
case EM_PPC: |
1448 |
case EM_PPC64: |
1449 |
ok = 1; |
1450 |
} |
1451 |
break; |
1452 |
case ARCH_SH: |
1453 |
switch (emachine) { |
1454 |
case EM_SH: |
1455 |
ok = 1; |
1456 |
} |
1457 |
break; |
1458 |
case ARCH_SPARC: |
1459 |
switch (emachine) { |
1460 |
case EM_SPARC: |
1461 |
case EM_SPARCV9: |
1462 |
ok = 1; |
1463 |
} |
1464 |
break; |
1465 |
/* case ARCH_X86: |
1466 |
switch (emachine) { |
1467 |
case EM_386: |
1468 |
case EM_486: |
1469 |
*tocp = 1; |
1470 |
ok = 1; |
1471 |
break; |
1472 |
case EM_AMD64: |
1473 |
*tocp = 2; |
1474 |
ok = 1; |
1475 |
break; |
1476 |
} |
1477 |
break; */ |
1478 |
default: |
1479 |
fatal("file.c: INTERNAL ERROR: Unimplemented arch!\n"); |
1480 |
} |
1481 |
if (!ok) { |
1482 |
fprintf(stderr, "%s: this is a ", filename); |
1483 |
if (emachine >= 0 && emachine < N_ELF_MACHINE_TYPES) |
1484 |
fprintf(stderr, elf_machine_type[emachine]); |
1485 |
else |
1486 |
fprintf(stderr, "machine type '%i'", emachine); |
1487 |
fprintf(stderr, " ELF binary!\n"); |
1488 |
exit(1); |
1489 |
} |
1490 |
|
1491 |
s = "entry point"; |
1492 |
if (elf64 && arch == ARCH_PPC) |
1493 |
s = "function descriptor at"; |
1494 |
|
1495 |
debug("ELF%i %s, %s 0x", elf64? 64 : 32, |
1496 |
encoding == ELFDATA2LSB? "LSB (LE)" : "MSB (BE)", s); |
1497 |
|
1498 |
if (elf64) |
1499 |
debug("%016"PRIx64"\n", (uint64_t) eentry); |
1500 |
else |
1501 |
debug("%08"PRIx32"\n", (uint32_t) eentry); |
1502 |
|
1503 |
/* |
1504 |
* SH64: 32-bit instruction encoding? |
1505 |
*/ |
1506 |
if (arch == ARCH_SH && (eentry & 1)) { |
1507 |
debug("SH64: 32-bit instruction encoding\n"); |
1508 |
m->cpus[0]->cd.sh.compact = 0; |
1509 |
m->cpus[0]->cd.sh.cpu_type.bits = 64; |
1510 |
} |
1511 |
|
1512 |
/* Read the program headers: */ |
1513 |
|
1514 |
for (i=0; i<ephnum; i++) { |
1515 |
int p_type; |
1516 |
uint64_t p_offset; |
1517 |
uint64_t p_vaddr; |
1518 |
uint64_t p_paddr; |
1519 |
uint64_t p_filesz; |
1520 |
uint64_t p_memsz; |
1521 |
int p_flags; |
1522 |
int p_align; |
1523 |
|
1524 |
fseek(f, ephoff + i * ephentsize, SEEK_SET); |
1525 |
|
1526 |
if (elf64) { |
1527 |
fread(&phdr64, 1, sizeof(Elf64_Phdr), f); |
1528 |
unencode(p_type, &phdr64.p_type, Elf64_Half); |
1529 |
unencode(p_flags, &phdr64.p_flags, Elf64_Half); |
1530 |
unencode(p_offset, &phdr64.p_offset, Elf64_Off); |
1531 |
unencode(p_vaddr, &phdr64.p_vaddr, Elf64_Addr); |
1532 |
unencode(p_paddr, &phdr64.p_paddr, Elf64_Addr); |
1533 |
unencode(p_filesz, &phdr64.p_filesz, Elf64_Xword); |
1534 |
unencode(p_memsz, &phdr64.p_memsz, Elf64_Xword); |
1535 |
unencode(p_align, &phdr64.p_align, Elf64_Xword); |
1536 |
} else { |
1537 |
fread(&phdr32, 1, sizeof(Elf32_Phdr), f); |
1538 |
unencode(p_type, &phdr32.p_type, Elf32_Word); |
1539 |
unencode(p_offset, &phdr32.p_offset, Elf32_Off); |
1540 |
unencode(p_vaddr, &phdr32.p_vaddr, Elf32_Addr); |
1541 |
unencode(p_paddr, &phdr32.p_paddr, Elf32_Addr); |
1542 |
unencode(p_filesz, &phdr32.p_filesz, Elf32_Word); |
1543 |
unencode(p_memsz, &phdr32.p_memsz, Elf32_Word); |
1544 |
unencode(p_flags, &phdr32.p_flags, Elf32_Word); |
1545 |
unencode(p_align, &phdr32.p_align, Elf32_Word); |
1546 |
} |
1547 |
|
1548 |
/* |
1549 |
* Hack for loading PPC kernels that are linked to high |
1550 |
* addresses. (This requires enabling of instruction and |
1551 |
* data virtual address translation.) |
1552 |
*/ |
1553 |
if (arch == ARCH_PPC) { |
1554 |
if ( (elf64 && (p_vaddr >> 60) != 0) || |
1555 |
(!elf64 && (p_vaddr >> 28) != 0) ) |
1556 |
m->cpus[m->bootstrap_cpu]-> |
1557 |
cd.ppc.msr |= PPC_MSR_IR | PPC_MSR_DR; |
1558 |
} |
1559 |
|
1560 |
if (p_memsz != 0 && (p_type == PT_LOAD || |
1561 |
(p_type & PF_MASKPROC) == PT_MIPS_REGINFO)) { |
1562 |
debug("chunk %i (", i); |
1563 |
if (p_type == PT_LOAD) |
1564 |
debug("load"); |
1565 |
else |
1566 |
debug("0x%08"PRIx32, (uint32_t) p_type); |
1567 |
|
1568 |
debug(") @ 0x%"PRIx64", vaddr 0x", (uint64_t) p_offset); |
1569 |
|
1570 |
if (elf64) |
1571 |
debug("%016"PRIx64, (uint64_t) p_vaddr); |
1572 |
else |
1573 |
debug("%08"PRIx32, (uint32_t) p_vaddr); |
1574 |
|
1575 |
debug(" len=0x%"PRIx64"\n", (uint64_t) p_memsz); |
1576 |
|
1577 |
if (p_vaddr != p_paddr) { |
1578 |
if (elf64) |
1579 |
debug("NOTE: vaddr (0x%"PRIx64") and " |
1580 |
"paddr (0x%"PRIx64") differ; using " |
1581 |
"vaddr\n", (uint64_t) p_vaddr, |
1582 |
(uint64_t) p_paddr); |
1583 |
else |
1584 |
debug("NOTE: vaddr (0x%08"PRIx32") and " |
1585 |
"paddr (0x%08"PRIx32") differ; usin" |
1586 |
"g vaddr\n", (uint32_t) p_vaddr, |
1587 |
(uint32_t)p_paddr); |
1588 |
} |
1589 |
|
1590 |
if (p_memsz < p_filesz) { |
1591 |
fprintf(stderr, "%s: memsz < filesz. TODO: how" |
1592 |
" to handle this? memsz=%016"PRIx64 |
1593 |
" filesz=%016"PRIx64"\n", filename, |
1594 |
(uint64_t) p_memsz, (uint64_t) p_filesz); |
1595 |
exit(1); |
1596 |
} |
1597 |
|
1598 |
fseek(f, p_offset, SEEK_SET); |
1599 |
align_len = 1; |
1600 |
if ((p_vaddr & 0xf)==0) align_len = 0x10; |
1601 |
if ((p_vaddr & 0x3f)==0) align_len = 0x40; |
1602 |
if ((p_vaddr & 0xff)==0) align_len = 0x100; |
1603 |
if ((p_vaddr & 0xfff)==0) align_len = 0x1000; |
1604 |
if ((p_vaddr & 0x3fff)==0) align_len = 0x4000; |
1605 |
if ((p_vaddr & 0xffff)==0) align_len = 0x10000; |
1606 |
ofs = 0; len = chunk_len = align_len; |
1607 |
while (ofs < (int64_t)p_filesz && len==chunk_len) { |
1608 |
unsigned char *ch = malloc(chunk_len); |
1609 |
int i = 0; |
1610 |
|
1611 |
/* Switch to larger size, if possible: */ |
1612 |
if (align_len < 0x10000 && |
1613 |
((p_vaddr + ofs) & 0xffff)==0) { |
1614 |
align_len = 0x10000; |
1615 |
len = chunk_len = align_len; |
1616 |
free(ch); |
1617 |
ch = malloc(chunk_len); |
1618 |
} else if (align_len < 0x1000 && |
1619 |
((p_vaddr + ofs) & 0xfff)==0) { |
1620 |
align_len = 0x1000; |
1621 |
len = chunk_len = align_len; |
1622 |
free(ch); |
1623 |
ch = malloc(chunk_len); |
1624 |
} |
1625 |
|
1626 |
if (ch == NULL) { |
1627 |
fprintf(stderr, "out of memory\n"); |
1628 |
exit(1); |
1629 |
} |
1630 |
|
1631 |
len = fread(&ch[0], 1, chunk_len, f); |
1632 |
if (ofs + len > (int64_t)p_filesz) |
1633 |
len = p_filesz - ofs; |
1634 |
|
1635 |
while (i < len) { |
1636 |
size_t len_to_copy; |
1637 |
len_to_copy = (i + align_len) <= len? |
1638 |
align_len : len - i; |
1639 |
m->cpus[0]->memory_rw(m->cpus[0], mem, |
1640 |
p_vaddr + ofs, &ch[i], len_to_copy, |
1641 |
MEM_WRITE, NO_EXCEPTIONS); |
1642 |
ofs += align_len; |
1643 |
i += align_len; |
1644 |
} |
1645 |
|
1646 |
free(ch); |
1647 |
} |
1648 |
} |
1649 |
} |
1650 |
|
1651 |
/* |
1652 |
* Read the section headers to find the address of the _gp |
1653 |
* symbol (for MIPS): |
1654 |
*/ |
1655 |
|
1656 |
for (i=0; i<eshnum; i++) { |
1657 |
int sh_name, sh_type, sh_flags, sh_link, sh_info, sh_entsize; |
1658 |
uint64_t sh_addr, sh_size, sh_addralign; |
1659 |
off_t sh_offset; |
1660 |
int n_entries; /* for reading the symbol / string tables */ |
1661 |
|
1662 |
/* debug("section header %i at %016"PRIx64"\n", i, |
1663 |
(uint64_t) eshoff+i*eshentsize); */ |
1664 |
|
1665 |
fseek(f, eshoff + i * eshentsize, SEEK_SET); |
1666 |
|
1667 |
if (elf64) { |
1668 |
len = fread(&shdr64, 1, sizeof(Elf64_Shdr), f); |
1669 |
if (len != sizeof(Elf64_Shdr)) { |
1670 |
fprintf(stderr, "couldn't read header\n"); |
1671 |
exit(1); |
1672 |
} |
1673 |
unencode(sh_name, &shdr64.sh_name, Elf64_Half); |
1674 |
unencode(sh_type, &shdr64.sh_type, Elf64_Half); |
1675 |
unencode(sh_flags, &shdr64.sh_flags, Elf64_Xword); |
1676 |
unencode(sh_addr, &shdr64.sh_addr, Elf64_Addr); |
1677 |
unencode(sh_offset, &shdr64.sh_offset, Elf64_Off); |
1678 |
unencode(sh_size, &shdr64.sh_size, Elf64_Xword); |
1679 |
unencode(sh_link, &shdr64.sh_link, Elf64_Half); |
1680 |
unencode(sh_info, &shdr64.sh_info, Elf64_Half); |
1681 |
unencode(sh_addralign, &shdr64.sh_addralign, |
1682 |
Elf64_Xword); |
1683 |
unencode(sh_entsize, &shdr64.sh_entsize, Elf64_Xword); |
1684 |
} else { |
1685 |
len = fread(&shdr32, 1, sizeof(Elf32_Shdr), f); |
1686 |
if (len != sizeof(Elf32_Shdr)) { |
1687 |
fprintf(stderr, "couldn't read header\n"); |
1688 |
exit(1); |
1689 |
} |
1690 |
unencode(sh_name, &shdr32.sh_name, Elf32_Word); |
1691 |
unencode(sh_type, &shdr32.sh_type, Elf32_Word); |
1692 |
unencode(sh_flags, &shdr32.sh_flags, Elf32_Word); |
1693 |
unencode(sh_addr, &shdr32.sh_addr, Elf32_Addr); |
1694 |
unencode(sh_offset, &shdr32.sh_offset, Elf32_Off); |
1695 |
unencode(sh_size, &shdr32.sh_size, Elf32_Word); |
1696 |
unencode(sh_link, &shdr32.sh_link, Elf32_Word); |
1697 |
unencode(sh_info, &shdr32.sh_info, Elf32_Word); |
1698 |
unencode(sh_addralign, &shdr32.sh_addralign,Elf32_Word); |
1699 |
unencode(sh_entsize, &shdr32.sh_entsize, Elf32_Word); |
1700 |
} |
1701 |
|
1702 |
/* debug("sh_name=%04lx, sh_type=%08lx, sh_flags=%08lx" |
1703 |
" sh_size=%06lx sh_entsize=%03lx\n", |
1704 |
(long)sh_name, (long)sh_type, (long)sh_flags, |
1705 |
(long)sh_size, (long)sh_entsize); */ |
1706 |
|
1707 |
/* Perhaps it is bad to reuse sh_entsize like this? TODO */ |
1708 |
if (elf64) |
1709 |
sh_entsize = sizeof(Elf64_Sym); |
1710 |
else |
1711 |
sh_entsize = sizeof(Elf32_Sym); |
1712 |
|
1713 |
if (sh_type == SHT_SYMTAB) { |
1714 |
size_t len; |
1715 |
n_entries = sh_size / sh_entsize; |
1716 |
|
1717 |
fseek(f, sh_offset, SEEK_SET); |
1718 |
|
1719 |
if (elf64) { |
1720 |
if (symbols_sym64 != NULL) |
1721 |
free(symbols_sym64); |
1722 |
symbols_sym64 = malloc(sh_size); |
1723 |
if (symbols_sym64 == NULL) { |
1724 |
fprintf(stderr, "out of memory\n"); |
1725 |
exit(1); |
1726 |
} |
1727 |
|
1728 |
len = fread(symbols_sym64, 1, sh_entsize * |
1729 |
n_entries, f); |
1730 |
} else { |
1731 |
if (symbols_sym32 != NULL) |
1732 |
free(symbols_sym32); |
1733 |
symbols_sym32 = malloc(sh_size); |
1734 |
if (symbols_sym32 == NULL) { |
1735 |
fprintf(stderr, "out of memory\n"); |
1736 |
exit(1); |
1737 |
} |
1738 |
|
1739 |
len = fread(symbols_sym32, 1, |
1740 |
sh_entsize * n_entries, f); |
1741 |
} |
1742 |
|
1743 |
if (len != sh_size) { |
1744 |
fprintf(stderr, "could not read symbols from " |
1745 |
"%s\n", filename); |
1746 |
exit(1); |
1747 |
} |
1748 |
|
1749 |
debug("%i symbol entries at 0x%"PRIx64"\n", |
1750 |
(int) n_entries, (uint64_t) sh_offset); |
1751 |
|
1752 |
n_symbols = n_entries; |
1753 |
} |
1754 |
|
1755 |
/* |
1756 |
* TODO: This is incorrect, there may be several strtab |
1757 |
* sections. |
1758 |
* |
1759 |
* For now, the simple/stupid guess that the largest string |
1760 |
* table is the one to use seems to be good enough. |
1761 |
*/ |
1762 |
|
1763 |
if (sh_type == SHT_STRTAB && sh_size > symbol_length) { |
1764 |
size_t len; |
1765 |
|
1766 |
if (symbol_strings != NULL) |
1767 |
free(symbol_strings); |
1768 |
|
1769 |
symbol_strings = malloc(sh_size + 1); |
1770 |
if (symbol_strings == NULL) { |
1771 |
fprintf(stderr, "out of memory\n"); |
1772 |
exit(1); |
1773 |
} |
1774 |
|
1775 |
fseek(f, sh_offset, SEEK_SET); |
1776 |
len = fread(symbol_strings, 1, sh_size, f); |
1777 |
if (len != sh_size) { |
1778 |
fprintf(stderr, "could not read symbols from " |
1779 |
"%s\n", filename); |
1780 |
exit(1); |
1781 |
} |
1782 |
|
1783 |
debug("%i bytes of symbol strings at 0x%"PRIx64"\n", |
1784 |
(int) sh_size, (uint64_t) sh_offset); |
1785 |
|
1786 |
symbol_strings[sh_size] = '\0'; |
1787 |
symbol_length = sh_size; |
1788 |
} |
1789 |
} |
1790 |
|
1791 |
fclose(f); |
1792 |
|
1793 |
/* Decode symbols: */ |
1794 |
if (symbol_strings != NULL) { |
1795 |
for (i=0; i<n_symbols; i++) { |
1796 |
uint64_t st_name, addr, size; |
1797 |
int st_info; |
1798 |
|
1799 |
if (elf64) { |
1800 |
sym64 = symbols_sym64[i]; |
1801 |
unencode(st_name, &sym64.st_name, Elf64_Half); |
1802 |
unencode(st_info, &sym64.st_info, Elf_Byte); |
1803 |
unencode(addr, &sym64.st_value, Elf64_Addr); |
1804 |
unencode(size, &sym64.st_size, Elf64_Xword); |
1805 |
} else { |
1806 |
sym32 = symbols_sym32[i]; |
1807 |
unencode(st_name, &sym32.st_name, Elf32_Word); |
1808 |
unencode(st_info, &sym32.st_info, Elf_Byte); |
1809 |
unencode(addr, &sym32.st_value, Elf32_Word); |
1810 |
unencode(size, &sym32.st_size, Elf32_Word); |
1811 |
} |
1812 |
|
1813 |
/* debug("symbol info=0x%02x addr=0x%016"PRIx64 |
1814 |
" (%i) '%s'\n", st_info, (uint64_t) addr, |
1815 |
st_name, symbol_strings + st_name); */ |
1816 |
|
1817 |
if (size == 0) |
1818 |
size ++; |
1819 |
|
1820 |
if (addr != 0) /* && ((st_info >> 4) & 0xf) |
1821 |
>= STB_GLOBAL) */ { |
1822 |
/* debug("symbol info=0x%02x addr=0x%016"PRIx64 |
1823 |
" '%s'\n", st_info, (uint64_t) addr, |
1824 |
symbol_strings + st_name); */ |
1825 |
add_symbol_name(&m->symbol_context, |
1826 |
addr, size, symbol_strings + st_name, |
1827 |
0, -1); |
1828 |
} |
1829 |
|
1830 |
if (strcmp(symbol_strings + st_name, "_gp") == 0) { |
1831 |
debug("found _gp address: 0x"); |
1832 |
if (elf64) |
1833 |
debug("%016"PRIx64"\n", (uint64_t)addr); |
1834 |
else |
1835 |
debug("%08"PRIx32"\n", (uint32_t)addr); |
1836 |
*gpp = addr; |
1837 |
} |
1838 |
} |
1839 |
} |
1840 |
|
1841 |
*entrypointp = eentry; |
1842 |
|
1843 |
if (encoding == ELFDATA2LSB) |
1844 |
*byte_order = EMUL_LITTLE_ENDIAN; |
1845 |
else |
1846 |
*byte_order = EMUL_BIG_ENDIAN; |
1847 |
|
1848 |
if (elf64 && arch == ARCH_PPC) { |
1849 |
/* |
1850 |
* Special case for 64-bit PPC ELFs: |
1851 |
* |
1852 |
* The ELF starting symbol points to a ".opd" section |
1853 |
* which contains a function descriptor: |
1854 |
* |
1855 |
* uint64_t start; |
1856 |
* uint64_t toc_base; |
1857 |
* uint64_t something_else; (?) |
1858 |
*/ |
1859 |
int res; |
1860 |
unsigned char b[sizeof(uint64_t)]; |
1861 |
uint64_t toc_base; |
1862 |
|
1863 |
debug("PPC64: "); |
1864 |
|
1865 |
res = m->cpus[0]->memory_rw(m->cpus[0], mem, eentry, b, |
1866 |
sizeof(b), MEM_READ, NO_EXCEPTIONS); |
1867 |
if (!res) |
1868 |
debug(" [WARNING: could not read memory?] "); |
1869 |
|
1870 |
/* PPC are always big-endian: */ |
1871 |
*entrypointp = ((uint64_t)b[0] << 56) + |
1872 |
((uint64_t)b[1] << 48) + ((uint64_t)b[2] << 40) + |
1873 |
((uint64_t)b[3] << 32) + ((uint64_t)b[4] << 24) + |
1874 |
((uint64_t)b[5] << 16) + ((uint64_t)b[6] << 8) + |
1875 |
(uint64_t)b[7]; |
1876 |
|
1877 |
res = m->cpus[0]->memory_rw(m->cpus[0], mem, eentry + 8, |
1878 |
b, sizeof(b), MEM_READ, NO_EXCEPTIONS); |
1879 |
if (!res) |
1880 |
fatal(" [WARNING: could not read memory?] "); |
1881 |
|
1882 |
toc_base = ((uint64_t)b[0] << 56) + |
1883 |
((uint64_t)b[1] << 48) + ((uint64_t)b[2] << 40) + |
1884 |
((uint64_t)b[3] << 32) + ((uint64_t)b[4] << 24) + |
1885 |
((uint64_t)b[5] << 16) + ((uint64_t)b[6] << 8) + |
1886 |
(uint64_t)b[7]; |
1887 |
|
1888 |
debug("entrypoint 0x%016"PRIx64", toc_base 0x%016"PRIx64"\n", |
1889 |
(uint64_t) *entrypointp, (uint64_t) toc_base); |
1890 |
if (tocp != NULL) |
1891 |
*tocp = toc_base; |
1892 |
} |
1893 |
|
1894 |
n_executables_loaded ++; |
1895 |
} |
1896 |
|
1897 |
|
1898 |
/* |
1899 |
* file_n_executables_loaded(): |
1900 |
* |
1901 |
* Returns the number of executable files loaded into emulated memory. |
1902 |
*/ |
1903 |
int file_n_executables_loaded(void) |
1904 |
{ |
1905 |
return n_executables_loaded; |
1906 |
} |
1907 |
|
1908 |
|
1909 |
/* |
1910 |
* file_load(): |
1911 |
* |
1912 |
* Sense the file format of a file (ELF, a.out, ecoff), and call the |
1913 |
* right file_load_XXX() function. If the file isn't of a recognized |
1914 |
* binary format, assume that it contains symbol definitions. |
1915 |
* |
1916 |
* If the filename doesn't exist, try to treat the name as |
1917 |
* "address:filename" and load the file as a raw binary. |
1918 |
*/ |
1919 |
void file_load(struct machine *machine, struct memory *mem, |
1920 |
char *filename, uint64_t *entrypointp, |
1921 |
int arch, uint64_t *gpp, int *byte_orderp, uint64_t *tocp) |
1922 |
{ |
1923 |
int iadd = DEBUG_INDENTATION, old_quiet_mode; |
1924 |
FILE *f; |
1925 |
unsigned char buf[12]; |
1926 |
unsigned char buf2[2]; |
1927 |
size_t len, len2, i; |
1928 |
off_t size; |
1929 |
|
1930 |
if (byte_orderp == NULL) { |
1931 |
fprintf(stderr, "file_load(): byte_order == NULL\n"); |
1932 |
exit(1); |
1933 |
} |
1934 |
|
1935 |
if (arch == ARCH_NOARCH) { |
1936 |
fprintf(stderr, "file_load(): FATAL ERROR: no arch?\n"); |
1937 |
exit(1); |
1938 |
} |
1939 |
|
1940 |
if (mem == NULL || filename == NULL) { |
1941 |
fprintf(stderr, "file_load(): mem or filename is NULL\n"); |
1942 |
exit(1); |
1943 |
} |
1944 |
|
1945 |
/* Skip configuration files: */ |
1946 |
if (filename[0] == '@') |
1947 |
return; |
1948 |
|
1949 |
debug("loading %s%s\n", filename, verbose >= 2? ":" : ""); |
1950 |
debug_indentation(iadd); |
1951 |
|
1952 |
old_quiet_mode = quiet_mode; |
1953 |
if (verbose < 2) |
1954 |
quiet_mode = 1; |
1955 |
|
1956 |
f = fopen(filename, "r"); |
1957 |
if (f == NULL) { |
1958 |
file_load_raw(machine, mem, filename, entrypointp); |
1959 |
goto ret; |
1960 |
} |
1961 |
|
1962 |
fseek(f, 0, SEEK_END); |
1963 |
size = ftello(f); |
1964 |
fseek(f, 0, SEEK_SET); |
1965 |
|
1966 |
memset(buf, 0, sizeof(buf)); |
1967 |
len = fread(buf, 1, sizeof(buf), f); |
1968 |
fseek(f, 510, SEEK_SET); |
1969 |
len2 = fread(buf2, 1, sizeof(buf2), f); |
1970 |
fclose(f); |
1971 |
|
1972 |
if (len < (signed int)sizeof(buf)) { |
1973 |
fprintf(stderr, "\nThis file is too small to contain " |
1974 |
"anything useful\n"); |
1975 |
exit(1); |
1976 |
} |
1977 |
|
1978 |
/* Is it an ELF? */ |
1979 |
if (buf[0] == 0x7f && buf[1]=='E' && buf[2]=='L' && buf[3]=='F') { |
1980 |
file_load_elf(machine, mem, filename, |
1981 |
entrypointp, arch, gpp, byte_orderp, tocp); |
1982 |
goto ret; |
1983 |
} |
1984 |
|
1985 |
/* Is it an a.out? */ |
1986 |
if (buf[0]==0x00 && buf[1]==0x8b && buf[2]==0x01 && buf[3]==0x07) { |
1987 |
/* MIPS a.out */ |
1988 |
file_load_aout(machine, mem, filename, 0, |
1989 |
entrypointp, arch, byte_orderp); |
1990 |
goto ret; |
1991 |
} |
1992 |
if (buf[0]==0x00 && buf[1]==0x87 && buf[2]==0x01 && buf[3]==0x08) { |
1993 |
/* M68K a.out */ |
1994 |
file_load_aout(machine, mem, filename, |
1995 |
AOUT_FLAG_VADDR_ZERO_HACK /* for OpenBSD/mac68k */, |
1996 |
entrypointp, arch, byte_orderp); |
1997 |
goto ret; |
1998 |
} |
1999 |
if (buf[0]==0x00 && buf[1]==0x8f && buf[2]==0x01 && buf[3]==0x0b) { |
2000 |
/* ARM a.out */ |
2001 |
file_load_aout(machine, mem, filename, AOUT_FLAG_FROM_BEGINNING, |
2002 |
entrypointp, arch, byte_orderp); |
2003 |
goto ret; |
2004 |
} |
2005 |
if (buf[0]==0x00 && buf[1]==0x86 && buf[2]==0x01 && buf[3]==0x0b) { |
2006 |
/* i386 a.out (old OpenBSD and NetBSD etc) */ |
2007 |
file_load_aout(machine, mem, filename, AOUT_FLAG_FROM_BEGINNING, |
2008 |
entrypointp, arch, byte_orderp); |
2009 |
goto ret; |
2010 |
} |
2011 |
if (buf[0]==0x01 && buf[1]==0x03 && buf[2]==0x01 && buf[3]==0x07) { |
2012 |
/* SPARC a.out (old 32-bit NetBSD etc) */ |
2013 |
file_load_aout(machine, mem, filename, AOUT_FLAG_NO_SIZES, |
2014 |
entrypointp, arch, byte_orderp); |
2015 |
goto ret; |
2016 |
} |
2017 |
if (buf[0]==0x00 && buf[2]==0x00 && buf[8]==0x7a && buf[9]==0x75) { |
2018 |
/* DEC OSF1 on MIPS: */ |
2019 |
file_load_aout(machine, mem, filename, AOUT_FLAG_DECOSF1, |
2020 |
entrypointp, arch, byte_orderp); |
2021 |
goto ret; |
2022 |
} |
2023 |
|
2024 |
/* |
2025 |
* Is it a Mach-O file? |
2026 |
*/ |
2027 |
if (buf[0] == 0xfe && buf[1] == 0xed && buf[2] == 0xfa && |
2028 |
(buf[3] == 0xce || buf[3] == 0xcf)) { |
2029 |
file_load_macho(machine, mem, filename, entrypointp, |
2030 |
arch, byte_orderp, buf[3] == 0xcf, 0); |
2031 |
goto ret; |
2032 |
} |
2033 |
if ((buf[0] == 0xce || buf[0] == 0xcf) && buf[1] == 0xfa && |
2034 |
buf[2] == 0xed && buf[3] == 0xfe) { |
2035 |
file_load_macho(machine, mem, filename, entrypointp, |
2036 |
arch, byte_orderp, buf[0] == 0xcf, 1); |
2037 |
goto ret; |
2038 |
} |
2039 |
|
2040 |
/* |
2041 |
* Is it an ecoff? |
2042 |
* |
2043 |
* TODO: What's the deal with the magic value's byte order? Sometimes |
2044 |
* it seems to be reversed for BE when compared to LE, but not always? |
2045 |
*/ |
2046 |
if (buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEB || |
2047 |
buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEL || |
2048 |
buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEB2 || |
2049 |
buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEL2 || |
2050 |
buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEB3 || |
2051 |
buf[0]+256*buf[1] == ECOFF_MAGIC_MIPSEL3 || |
2052 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEB || |
2053 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEL || |
2054 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEB2 || |
2055 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEL2 || |
2056 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEB3 || |
2057 |
buf[1]+256*buf[0] == ECOFF_MAGIC_MIPSEL3) { |
2058 |
file_load_ecoff(machine, mem, filename, entrypointp, |
2059 |
arch, gpp, byte_orderp); |
2060 |
goto ret; |
2061 |
} |
2062 |
|
2063 |
/* Is it a Motorola SREC file? */ |
2064 |
if ((buf[0]=='S' && buf[1]>='0' && buf[1]<='9')) { |
2065 |
file_load_srec(machine, mem, filename, entrypointp); |
2066 |
goto ret; |
2067 |
} |
2068 |
|
2069 |
/* gzipped files are not supported: */ |
2070 |
if (buf[0]==0x1f && buf[1]==0x8b) { |
2071 |
fprintf(stderr, "\nYou need to gunzip the file before you" |
2072 |
" try to use it.\n"); |
2073 |
exit(1); |
2074 |
} |
2075 |
|
2076 |
if (size > 24000000) { |
2077 |
fprintf(stderr, "\nThis file is very large (%lli bytes)\n", |
2078 |
(long long)size); |
2079 |
fprintf(stderr, "Are you sure it is a kernel and not a disk " |
2080 |
"image? (Use the -d option.)\n"); |
2081 |
exit(1); |
2082 |
} |
2083 |
|
2084 |
if (size == 1474560) |
2085 |
fprintf(stderr, "Hm... this file is the size of a 1.44 MB " |
2086 |
"floppy image. Maybe you forgot the\n-d switch?\n"); |
2087 |
|
2088 |
/* |
2089 |
* Ugly hack for Dreamcast: When booting from a Dreamcast CDROM |
2090 |
* image, a temporary file is extracted into /tmp/gxemul.*, but this |
2091 |
* is a "scrambled" raw binary. This code unscrambles it, and loads |
2092 |
* it as a raw binary. |
2093 |
*/ |
2094 |
if (machine->machine_type == MACHINE_DREAMCAST && |
2095 |
strncmp(filename, "/tmp/gxemul.", 12) == 0) { |
2096 |
char *tmp_filename = malloc(strlen(filename) + 100); |
2097 |
snprintf(tmp_filename, strlen(filename) + 100, |
2098 |
"%s.descrambled", filename); |
2099 |
debug("descrambling into %s\n", tmp_filename); |
2100 |
dreamcast_descramble(filename, tmp_filename); |
2101 |
|
2102 |
snprintf(tmp_filename, strlen(filename) + 100, |
2103 |
"0x8c010000:%s.descrambled", filename); |
2104 |
debug("loading descrambled Dreamcast binary\n"); |
2105 |
file_load_raw(machine, mem, tmp_filename, entrypointp); |
2106 |
free(tmp_filename); |
2107 |
|
2108 |
/* Hack: Start a "boot from CDROM" sequence: */ |
2109 |
*entrypointp = 0x8c000080; |
2110 |
goto ret; |
2111 |
} |
2112 |
|
2113 |
/* |
2114 |
* Last resort: symbol definitions from nm (or nm -S): |
2115 |
* |
2116 |
* If the buf contains typical 'binary' characters, then print |
2117 |
* an error message and quit instead of assuming that it is a |
2118 |
* symbol file. |
2119 |
*/ |
2120 |
for (i=0; i<(signed)sizeof(buf); i++) |
2121 |
if (buf[i] < 32 && buf[i] != '\t' && |
2122 |
buf[i] != '\n' && buf[i] != '\r' && |
2123 |
buf[i] != '\f') { |
2124 |
fprintf(stderr, "\nThe file format of '%s' is " |
2125 |
"unknown.\n\n ", filename); |
2126 |
for (i=0; i<(signed)sizeof(buf); i++) |
2127 |
fprintf(stderr, " %02x", buf[i]); |
2128 |
|
2129 |
if (len2 == 2 && buf2[0] == 0x55 && buf2[1] == 0xaa) |
2130 |
fprintf(stderr, "\n\nIt has a PC-style " |
2131 |
"bootsector marker."); |
2132 |
|
2133 |
fprintf(stderr, "\n\nPossible explanations:\n\n" |
2134 |
" o) If this is a disk image, you forgot '-d' " |
2135 |
"on the command line.\n" |
2136 |
" o) This is an unsupported binary format.\n\n"); |
2137 |
exit(1); |
2138 |
} |
2139 |
|
2140 |
symbol_readfile(&machine->symbol_context, filename); |
2141 |
|
2142 |
ret: |
2143 |
debug_indentation(-iadd); |
2144 |
quiet_mode = old_quiet_mode; |
2145 |
} |
2146 |
|