/* Transformation functions for ELF data types. Copyright (C) 1998,1999,2000,2002,2004,2005,2006,2007,2015 Red Hat, Inc. This file is part of elfutils. Written by Ulrich Drepper , 1998. This file is free software; you can redistribute it and/or modify it under the terms of either * the GNU Lesser General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version or * the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version or both in parallel, as here. elfutils 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 copies of the GNU General Public License and the GNU Lesser General Public License along with this program. If not, see . */ #ifdef HAVE_CONFIG_H # include #endif #include #include #include #include #include "libelfP.h" #ifndef LIBELFBITS # define LIBELFBITS 32 #endif /* Well, what shall I say. Nothing to do here. */ #define elf_cvt_Byte(dest, src, n) \ (__builtin_constant_p (n) && (n) == 1 \ ? (void) (*((char *) (dest)) = *((char *) (src))) \ : Elf32_cvt_Byte (dest, src, n)) static void (elf_cvt_Byte) (void *dest, const void *src, size_t n, int encode __attribute__ ((unused))) { if (n != 0) memmove (dest, src, n); } /* We'll optimize the definition of the conversion functions here a bit. We need only functions for 16, 32, and 64 bits. The functions referenced in the table will be aliases for one of these functions. Which one is decided by the ELFxx_FSZ_type. */ #if ALLOW_UNALIGNED #define FETCH(Bits, ptr) (*(const uint##Bits##_t *) ptr) #define STORE(Bits, ptr, val) (*(uint##Bits##_t *) ptr = val) #else union unaligned { uint16_t u16; uint32_t u32; uint64_t u64; } attribute_packed; #define FETCH(Bits, ptr) (((const union unaligned *) ptr)->u##Bits) #define STORE(Bits, ptr, val) (((union unaligned *) ptr)->u##Bits = val) #endif /* Now define the conversion functions for the basic types. We use here the fact that file and memory types are the same and that we have the ELFxx_FSZ_* macros. At the same time we define inline functions which we will use to convert the complex types. */ #define FUNDAMENTAL(NAME, Name, Bits) \ INLINE2 (ELFW2(Bits,FSZ_##NAME), ElfW2(Bits,cvt_##Name), ElfW2(Bits,Name)) #define INLINE2(Bytes, FName, TName) \ INLINE3 (Bytes, FName, TName) #define INLINE3(Bytes, FName, TName) \ static inline void FName##1 (void *dest, const void *ptr) \ { \ switch (Bytes) \ { \ case 2: STORE (16, dest, bswap_16 (FETCH (16, ptr))); break; \ case 4: STORE (32, dest, bswap_32 (FETCH (32, ptr))); break; \ case 8: STORE (64, dest, bswap_64 (FETCH (64, ptr))); break; \ default: \ abort (); \ } \ } \ \ static void FName (void *dest, const void *ptr, size_t len, \ int encode __attribute__ ((unused))) \ { \ size_t n = len / sizeof (TName); \ if (dest < ptr) \ while (n-- > 0) \ { \ FName##1 (dest, ptr); \ dest += Bytes; \ ptr += Bytes; \ } \ else \ { \ dest += len; \ ptr += len; \ while (n-- > 0) \ { \ ptr -= Bytes; \ dest -= Bytes; \ FName##1 (dest, ptr); \ } \ } \ } /* Now the tricky part: define the transformation functions for the complex types. We will use the definitions of the types in abstract.h. */ #define START(Bits, Name, EName) \ static void \ ElfW2 (Bits, cvt_##Name) (void *dest, const void *src, size_t len, \ int encode __attribute__ ((unused))) \ { ElfW2(Bits, Name) *tdest = (ElfW2(Bits, Name) *) dest; \ ElfW2(Bits, Name) *tsrc = (ElfW2(Bits, Name) *) src; \ size_t n; \ for (n = len / sizeof (ElfW2(Bits, Name)); n > 0; ++tdest, ++tsrc, --n) { #define END(Bits, Name) } } #define TYPE_EXTRA(Code) #define TYPE_XLATE(Code) Code #define TYPE_NAME(Type, Name) TYPE_NAME2 (Type, Name) #define TYPE_NAME2(Type, Name) Type##1 (&tdest->Name, &tsrc->Name); #define TYPE(Name, Bits) TYPE2 (Name, Bits) #define TYPE2(Name, Bits) TYPE3 (Name##Bits) #define TYPE3(Name) Name (cvt_) /* Signal that we are generating conversion functions. */ #define GENERATE_CONVERSION /* First generate the 32-bit conversion functions. */ #define LIBELFBITS 32 #include "gelf_xlate.h" /* Now generate the 64-bit conversion functions. */ #define LIBELFBITS 64 #include "gelf_xlate.h" /* We have a few functions which we must create by hand since the sections do not contain records of only one type. */ #include "version_xlate.h" #include "gnuhash_xlate.h" #include "note_xlate.h" #include "chdr_xlate.h" /* Now the externally visible table with the function pointers. */ const xfct_t __elf_xfctstom[ELFCLASSNUM - 1][ELF_T_NUM] = { [ELFCLASS32 - 1] = { #define define_xfcts(Bits) \ [ELF_T_BYTE] = elf_cvt_Byte, \ [ELF_T_ADDR] = ElfW2(Bits, cvt_Addr), \ [ELF_T_DYN] = ElfW2(Bits, cvt_Dyn), \ [ELF_T_EHDR] = ElfW2(Bits, cvt_Ehdr), \ [ELF_T_HALF] = ElfW2(Bits, cvt_Half), \ [ELF_T_OFF] = ElfW2(Bits, cvt_Off), \ [ELF_T_PHDR] = ElfW2(Bits, cvt_Phdr), \ [ELF_T_RELA] = ElfW2(Bits, cvt_Rela), \ [ELF_T_REL] = ElfW2(Bits, cvt_Rel), \ [ELF_T_SHDR] = ElfW2(Bits, cvt_Shdr), \ [ELF_T_SWORD] = ElfW2(Bits, cvt_Sword), \ [ELF_T_SYM] = ElfW2(Bits, cvt_Sym), \ [ELF_T_WORD] = ElfW2(Bits, cvt_Word), \ [ELF_T_XWORD] = ElfW2(Bits, cvt_Xword), \ [ELF_T_SXWORD] = ElfW2(Bits, cvt_Sxword), \ [ELF_T_VDEF] = elf_cvt_Verdef, \ [ELF_T_VDAUX] = elf_cvt_Verdef, \ [ELF_T_VNEED] = elf_cvt_Verneed, \ [ELF_T_VNAUX] = elf_cvt_Verneed, \ [ELF_T_NHDR] = elf_cvt_note4, \ [ELF_T_NHDR8] = elf_cvt_note8, \ [ELF_T_SYMINFO] = ElfW2(Bits, cvt_Syminfo), \ [ELF_T_MOVE] = ElfW2(Bits, cvt_Move), \ [ELF_T_LIB] = ElfW2(Bits, cvt_Lib), \ [ELF_T_AUXV] = ElfW2(Bits, cvt_auxv_t), \ [ELF_T_CHDR] = ElfW2(Bits, cvt_chdr) define_xfcts (32), [ELF_T_GNUHASH] = Elf32_cvt_Word }, [ELFCLASS64 - 1] = { define_xfcts (64), [ELF_T_GNUHASH] = elf_cvt_gnuhash } };