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|
/* $Id: ldrELFRelocatable.cpp.h $ */
/** @file
* IPRT - Binary Image Loader, Template for ELF Relocatable Images.
*/
/*
* Copyright (C) 2006-2020 Oracle Corporation
*
* This file is part of VirtualBox Open Source Edition (OSE), as
* available from http://www.virtualbox.org. This file is free software;
* you can redistribute it and/or modify it under the terms of the GNU
* General Public License (GPL) as published by the Free Software
* Foundation, in version 2 as it comes in the "COPYING" file of the
* VirtualBox OSE distribution. VirtualBox OSE is distributed in the
* hope that it will be useful, but WITHOUT ANY WARRANTY of any kind.
*
* The contents of this file may alternatively be used under the terms
* of the Common Development and Distribution License Version 1.0
* (CDDL) only, as it comes in the "COPYING.CDDL" file of the
* VirtualBox OSE distribution, in which case the provisions of the
* CDDL are applicable instead of those of the GPL.
*
* You may elect to license modified versions of this file under the
* terms and conditions of either the GPL or the CDDL or both.
*/
/*******************************************************************************
* Defined Constants And Macros *
*******************************************************************************/
#if ELF_MODE == 32
# define RTLDRELF_NAME(name) rtldrELF32##name
# define RTLDRELF_SUFF(name) name##32
# define RTLDRELF_MID(pre,suff) pre##32##suff
# define FMT_ELF_ADDR "%08RX32"
# define FMT_ELF_ADDR7 "%07RX32"
# define FMT_ELF_HALF "%04RX16"
# define FMT_ELF_OFF "%08RX32"
# define FMT_ELF_SIZE "%08RX32"
# define FMT_ELF_SWORD "%RI32"
# define FMT_ELF_WORD "%08RX32"
# define FMT_ELF_XWORD "%08RX32"
# define FMT_ELF_SXWORD "%RI32"
# define Elf_Xword Elf32_Word
# define Elf_Sxword Elf32_Sword
#elif ELF_MODE == 64
# define RTLDRELF_NAME(name) rtldrELF64##name
# define RTLDRELF_SUFF(name) name##64
# define RTLDRELF_MID(pre,suff) pre##64##suff
# define FMT_ELF_ADDR "%016RX64"
# define FMT_ELF_ADDR7 "%08RX64"
# define FMT_ELF_HALF "%04RX16"
# define FMT_ELF_SHALF "%RI16"
# define FMT_ELF_OFF "%016RX64"
# define FMT_ELF_SIZE "%016RX64"
# define FMT_ELF_SWORD "%RI32"
# define FMT_ELF_WORD "%08RX32"
# define FMT_ELF_XWORD "%016RX64"
# define FMT_ELF_SXWORD "%RI64"
# define Elf_Xword Elf64_Xword
# define Elf_Sxword Elf64_Sxword
#endif
#define Elf_Ehdr RTLDRELF_MID(Elf,_Ehdr)
#define Elf_Phdr RTLDRELF_MID(Elf,_Phdr)
#define Elf_Shdr RTLDRELF_MID(Elf,_Shdr)
#define Elf_Sym RTLDRELF_MID(Elf,_Sym)
#define Elf_Rel RTLDRELF_MID(Elf,_Rel)
#define Elf_Rela RTLDRELF_MID(Elf,_Rela)
#define Elf_Nhdr RTLDRELF_MID(Elf,_Nhdr)
#define Elf_Dyn RTLDRELF_MID(Elf,_Dyn)
#define Elf_Addr RTLDRELF_MID(Elf,_Addr)
#define Elf_Half RTLDRELF_MID(Elf,_Half)
#define Elf_Off RTLDRELF_MID(Elf,_Off)
#define Elf_Size RTLDRELF_MID(Elf,_Size)
#define Elf_Sword RTLDRELF_MID(Elf,_Sword)
#define Elf_Word RTLDRELF_MID(Elf,_Word)
#define RTLDRMODELF RTLDRELF_MID(RTLDRMODELF,RT_NOTHING)
#define PRTLDRMODELF RTLDRELF_MID(PRTLDRMODELF,RT_NOTHING)
#define RTLDRMODELFSHX RTLDRELF_MID(RTLDRMODELFSHX,RT_NOTHING)
#define PRTLDRMODELFSHX RTLDRELF_MID(PRTLDRMODELFSHX,RT_NOTHING)
#define ELF_R_SYM(info) RTLDRELF_MID(ELF,_R_SYM)(info)
#define ELF_R_TYPE(info) RTLDRELF_MID(ELF,_R_TYPE)(info)
#define ELF_R_INFO(sym, type) RTLDRELF_MID(ELF,_R_INFO)(sym, type)
#define ELF_ST_BIND(info) RTLDRELF_MID(ELF,_ST_BIND)(info)
/*******************************************************************************
* Structures and Typedefs *
*******************************************************************************/
/**
* Extra section info.
*/
typedef struct RTLDRMODELFSHX
{
/** The corresponding program header. */
uint16_t idxPhdr;
/** The corresponding dynamic section entry (address). */
uint16_t idxDt;
/** The DT tag. */
uint32_t uDtTag;
} RTLDRMODELFSHX;
typedef RTLDRMODELFSHX *PRTLDRMODELFSHX;
/**
* The ELF loader structure.
*/
typedef struct RTLDRMODELF
{
/** Core module structure. */
RTLDRMODINTERNAL Core;
/** Pointer to readonly mapping of the image bits.
* This mapping is provided by the pReader. */
const void *pvBits;
/** The ELF header. */
Elf_Ehdr Ehdr;
/** Pointer to our copy of the section headers with sh_addr as RVAs.
* The virtual addresses in this array is the 0 based assignments we've given the image.
* Not valid if the image is DONE. */
Elf_Shdr *paShdrs;
/** Unmodified section headers (allocated after paShdrs, so no need to free).
* Not valid if the image is DONE. */
Elf_Shdr const *paOrgShdrs;
/** Runs parallel to paShdrs and is part of the same allocation. */
PRTLDRMODELFSHX paShdrExtras;
/** Base section number, either 1 or zero depending on whether we've
* re-used the NULL entry for .elf.headers in ET_EXEC/ET_DYN. */
unsigned iFirstSect;
/** Set if the SHF_ALLOC section headers are in order of sh_addr. */
bool fShdrInOrder;
/** The size of the loaded image. */
size_t cbImage;
/** The image base address if it's an EXEC or DYN image. */
Elf_Addr LinkAddress;
struct
{
/** The symbol section index. */
unsigned iSymSh;
/** Number of symbols in the table. */
unsigned cSyms;
/** Pointer to symbol table within RTLDRMODELF::pvBits. */
const Elf_Sym *paSyms;
/** The string section index. */
unsigned iStrSh;
/** Size of the string table. */
unsigned cbStr;
/** Pointer to string table within RTLDRMODELF::pvBits. */
const char *pStr;
} Rel /**< Regular symbols and strings. */
, Dyn /**< Dynamic symbols and strings. */;
/** Pointer to section header string table within RTLDRMODELF::pvBits. */
const char *pShStr;
/** Size of the section header string table. */
unsigned cbShStr;
/** The '.eh_frame' section index. Zero if not searched for, ~0U if not found. */
unsigned iShEhFrame;
/** The '.eh_frame_hdr' section index. Zero if not searched for, ~0U if not found. */
unsigned iShEhFrameHdr;
/** The '.dynamic' / SHT_DYNAMIC section index. ~0U if not present. */
unsigned iShDynamic;
/** Number of entries in paDynamic. */
unsigned cDynamic;
/** The dynamic section (NULL for ET_REL). */
Elf_Dyn *paDynamic;
/** Program headers (NULL for ET_REL). */
Elf_Phdr *paPhdrs;
/** Info extracted from PT_DYNAMIC and the program headers. */
struct
{
/** DT_RELA/DT_REL. */
Elf_Addr uPtrRelocs;
/** DT_RELASZ/DT_RELSZ. */
Elf_Xword cbRelocs;
/** Non-zero if we've seen DT_RELAENT/DT_RELENT. */
unsigned cbRelocEntry;
/** DT_RELA or DT_REL. */
unsigned uRelocType;
/** The index of the section header matching DT_RELA/DT_REL. */
unsigned idxShRelocs;
/** DT_JMPREL. */
Elf_Addr uPtrJmpRelocs;
/** DT_PLTRELSZ. */
Elf_Xword cbJmpRelocs;
/** DT_RELA or DT_REL (if we've seen DT_PLTREL). */
unsigned uJmpRelocType;
/** The index of the section header matching DT_JMPREL. */
unsigned idxShJmpRelocs;
} DynInfo;
} RTLDRMODELF;
/** Pointer to an ELF module instance. */
typedef RTLDRMODELF *PRTLDRMODELF;
/**
* Maps the image bits into memory and resolve pointers into it.
*
* @returns iprt status code.
* @param pModElf The ELF loader module instance data.
* @param fNeedsBits Set if we actually need the pvBits member.
* If we don't, we can simply read the string and symbol sections, thus saving memory.
*/
static int RTLDRELF_NAME(MapBits)(PRTLDRMODELF pModElf, bool fNeedsBits)
{
NOREF(fNeedsBits);
if (pModElf->pvBits)
return VINF_SUCCESS;
int rc = pModElf->Core.pReader->pfnMap(pModElf->Core.pReader, &pModElf->pvBits);
if (RT_SUCCESS(rc))
{
const uint8_t *pu8 = (const uint8_t *)pModElf->pvBits;
if (pModElf->Rel.iSymSh != ~0U)
pModElf->Rel.paSyms = (const Elf_Sym *)(pu8 + pModElf->paShdrs[pModElf->Rel.iSymSh].sh_offset);
if (pModElf->Rel.iStrSh != ~0U)
pModElf->Rel.pStr = (const char *)(pu8 + pModElf->paShdrs[pModElf->Rel.iStrSh].sh_offset);
if (pModElf->Dyn.iSymSh != ~0U)
pModElf->Dyn.paSyms = (const Elf_Sym *)(pu8 + pModElf->paShdrs[pModElf->Dyn.iSymSh].sh_offset);
if (pModElf->Dyn.iStrSh != ~0U)
pModElf->Dyn.pStr = (const char *)(pu8 + pModElf->paShdrs[pModElf->Dyn.iStrSh].sh_offset);
pModElf->pShStr = (const char *)(pu8 + pModElf->paShdrs[pModElf->Ehdr.e_shstrndx].sh_offset);
/*
* Verify that the ends of the string tables have a zero terminator
* (this avoids duplicating the appropriate checks later in the code accessing the string tables).
*
* sh_offset and sh_size were verfied in RTLDRELF_NAME(ValidateSectionHeader)() already so they
* are safe to use.
*/
AssertMsgStmt( pModElf->Rel.iStrSh == ~0U
|| pModElf->Rel.pStr[pModElf->paShdrs[pModElf->Rel.iStrSh].sh_size - 1] == '\0',
("The string table is not zero terminated!\n"),
rc = VERR_LDRELF_UNTERMINATED_STRING_TAB);
AssertMsgStmt( pModElf->Dyn.iStrSh == ~0U
|| pModElf->Dyn.pStr[pModElf->paShdrs[pModElf->Dyn.iStrSh].sh_size - 1] == '\0',
("The string table is not zero terminated!\n"),
rc = VERR_LDRELF_UNTERMINATED_STRING_TAB);
AssertMsgStmt(pModElf->pShStr[pModElf->paShdrs[pModElf->Ehdr.e_shstrndx].sh_size - 1] == '\0',
("The section header string table is not zero terminated!\n"),
rc = VERR_LDRELF_UNTERMINATED_STRING_TAB);
if (RT_FAILURE(rc))
{
/* Unmap. */
int rc2 = pModElf->Core.pReader->pfnUnmap(pModElf->Core.pReader, pModElf->pvBits);
AssertRC(rc2);
pModElf->pvBits = NULL;
pModElf->Rel.paSyms = NULL;
pModElf->Rel.pStr = NULL;
pModElf->Dyn.paSyms = NULL;
pModElf->Dyn.pStr = NULL;
pModElf->pShStr = NULL;
}
}
return rc;
}
/*
*
* EXEC & DYN.
* EXEC & DYN.
* EXEC & DYN.
* EXEC & DYN.
* EXEC & DYN.
*
*/
/**
* Get the symbol and symbol value.
*
* @returns iprt status code.
* @param pModElf The ELF loader module instance data.
* @param BaseAddr The base address which the module is being fixedup to.
* @param pfnGetImport The callback function to use to resolve imports (aka unresolved externals).
* @param pvUser User argument to pass to the callback.
* @param iSym The symbol to get.
* @param ppSym Where to store the symbol pointer on success. (read only)
* @param pSymValue Where to store the symbol value on success.
*/
static int RTLDRELF_NAME(SymbolExecDyn)(PRTLDRMODELF pModElf, Elf_Addr BaseAddr, PFNRTLDRIMPORT pfnGetImport, void *pvUser,
Elf_Size iSym, const Elf_Sym **ppSym, Elf_Addr *pSymValue)
{
/*
* Validate and find the symbol.
*/
AssertMsgReturn(iSym < pModElf->Dyn.cSyms, ("iSym=%d is an invalid symbol index!\n", iSym), VERR_LDRELF_INVALID_SYMBOL_INDEX);
const Elf_Sym *pSym = &pModElf->Dyn.paSyms[iSym];
*ppSym = pSym;
AssertMsgReturn(pSym->st_name < pModElf->Dyn.cbStr,
("iSym=%d st_name=%d str sh_size=%d\n", iSym, pSym->st_name, pModElf->Dyn.cbStr),
VERR_LDRELF_INVALID_SYMBOL_NAME_OFFSET);
const char * const pszName = pModElf->Dyn.pStr + pSym->st_name;
/*
* Determine the symbol value.
*
* Symbols needs different treatment depending on which section their are in.
* Undefined and absolute symbols goes into special non-existing sections.
*/
switch (pSym->st_shndx)
{
/*
* Undefined symbol, needs resolving.
*
* Since ELF has no generic concept of importing from specific module (the OS/2 ELF format
* has but that's an OS extension and only applies to programs and dlls), we'll have to ask
* the resolver callback to do a global search.
*/
case SHN_UNDEF:
{
/* Try to resolve the symbol. */
RTUINTPTR Value;
int rc = pfnGetImport(&pModElf->Core, "", pszName, ~0U, &Value, pvUser);
AssertMsgRCReturn(rc, ("Failed to resolve '%s' (iSym=" FMT_ELF_SIZE " rc=%Rrc\n", pszName, iSym, rc), rc);
*pSymValue = (Elf_Addr)Value;
AssertMsgReturn((RTUINTPTR)*pSymValue == Value,
("Symbol value overflowed! '%s' (iSym=" FMT_ELF_SIZE "\n", pszName, iSym), VERR_SYMBOL_VALUE_TOO_BIG);
Log2(("rtldrELF: #%-3d - UNDEF " FMT_ELF_ADDR " '%s'\n", iSym, *pSymValue, pszName));
break;
}
/*
* Absolute symbols needs no fixing since they are, well, absolute.
*/
case SHN_ABS:
*pSymValue = pSym->st_value;
Log2(("rtldrELF: #%-3d - ABS " FMT_ELF_ADDR " '%s'\n", iSym, *pSymValue, pszName));
break;
/*
* All other symbols are addressed relative the image base in DYN and EXEC binaries.
*/
default:
AssertMsgReturn(pSym->st_shndx < pModElf->Ehdr.e_shnum,
("iSym=%d st_shndx=%d e_shnum=%d pszName=%s\n", iSym, pSym->st_shndx, pModElf->Ehdr.e_shnum, pszName),
VERR_BAD_EXE_FORMAT);
*pSymValue = pSym->st_value + BaseAddr;
Log2(("rtldrELF: #%-3d - %5d " FMT_ELF_ADDR " '%s'\n", iSym, pSym->st_shndx, *pSymValue, pszName));
break;
}
return VINF_SUCCESS;
}
#if ELF_MODE == 32
/** Helper for RelocateSectionExecDyn. */
DECLINLINE(const Elf_Shdr *) RTLDRELF_NAME(RvaToSectionHeader)(PRTLDRMODELF pModElf, Elf_Addr uRva)
{
const Elf_Shdr * const pShdrFirst = pModElf->paShdrs;
const Elf_Shdr *pShdr = pShdrFirst + pModElf->Ehdr.e_shnum;
while (--pShdr != pShdrFirst)
if (uRva - pShdr->sh_addr /*rva*/ < pShdr->sh_size)
return pShdr;
AssertFailed();
return pShdr;
}
#endif
/**
* Applies the fixups for a section in an executable image.
*
* @returns iprt status code.
* @param pModElf The ELF loader module instance data.
* @param BaseAddr The base address which the module is being fixedup to.
* @param pfnGetImport The callback function to use to resolve imports (aka unresolved externals).
* @param pvUser User argument to pass to the callback.
* @param SecAddr The section address. This is the address the relocations are relative to.
* @param cbSec The section size. The relocations must be inside this.
* @param pu8SecBaseR Where we read section bits from.
* @param pu8SecBaseW Where we write section bits to.
* @param pvRelocs Pointer to where we read the relocations from.
* @param cbRelocs Size of the relocations.
*/
static int RTLDRELF_NAME(RelocateSectionExecDyn)(PRTLDRMODELF pModElf, Elf_Addr BaseAddr,
PFNRTLDRIMPORT pfnGetImport, void *pvUser,
const Elf_Addr SecAddr, Elf_Size cbSec,
const uint8_t *pu8SecBaseR, uint8_t *pu8SecBaseW,
const void *pvRelocs, Elf_Size cbRelocs)
{
#if ELF_MODE != 32
NOREF(pu8SecBaseR);
#endif
/*
* Iterate the relocations.
* The relocations are stored in an array of Elf32_Rel records and covers the entire relocation section.
*/
#if ELF_MODE == 32
const Elf_Shdr *pShdr = pModElf->paShdrs;
const Elf_Addr offDelta = BaseAddr - pModElf->LinkAddress;
#endif
const Elf_Reloc *paRels = (const Elf_Reloc *)pvRelocs;
const unsigned iRelMax = (unsigned)(cbRelocs / sizeof(paRels[0]));
AssertMsgReturn(iRelMax == cbRelocs / sizeof(paRels[0]), (FMT_ELF_SIZE "\n", cbRelocs / sizeof(paRels[0])),
VERR_IMAGE_TOO_BIG);
for (unsigned iRel = 0; iRel < iRelMax; iRel++)
{
/*
* Apply fixups not taking a symbol (will 'continue' rather than 'break').
*/
AssertMsgReturn(paRels[iRel].r_offset < cbSec, (FMT_ELF_ADDR " " FMT_ELF_SIZE "\n", paRels[iRel].r_offset, cbSec),
VERR_LDRELF_INVALID_RELOCATION_OFFSET);
#if ELF_MODE == 32
if (paRels[iRel].r_offset - pShdr->sh_addr /*rva*/ >= pShdr->sh_size)
pShdr = RTLDRELF_NAME(RvaToSectionHeader)(pModElf, paRels[iRel].r_offset);
static const Elf_Addr s_uZero = 0;
const Elf_Addr *pAddrR = RT_LIKELY(pShdr->sh_type != SHT_NOBITS) /* Where to read the addend. */
? (const Elf_Addr *)(pu8SecBaseR + paRels[iRel].r_offset - pShdr->sh_addr /*rva*/
+ pShdr->sh_offset)
: &s_uZero;
#endif
Elf_Addr *pAddrW = (Elf_Addr *)(pu8SecBaseW + paRels[iRel].r_offset); /* Where to write the fixup. */
switch (ELF_R_TYPE(paRels[iRel].r_info))
{
/*
* Image relative (addend + base).
*/
#if ELF_MODE == 32
case R_386_RELATIVE:
{
const Elf_Addr Value = *pAddrR + BaseAddr;
*(uint32_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_386_RELATIVE Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value));
AssertCompile(sizeof(Value) == sizeof(uint32_t));
continue;
}
#elif ELF_MODE == 64
case R_X86_64_RELATIVE:
{
const Elf_Addr Value = paRels[iRel].r_addend + BaseAddr;
*(uint64_t *)pAddrW = (uint64_t)Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_RELATIVE Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value));
AssertCompile(sizeof(Value) == sizeof(uint64_t));
continue;
}
#endif
/*
* R_XXX_NONE.
*/
#if ELF_MODE == 32
case R_386_NONE:
#elif ELF_MODE == 64
case R_X86_64_NONE:
#endif
continue;
}
/*
* Validate and find the symbol, resolve undefined ones.
*/
const Elf_Sym *pSym = NULL; /* shut up gcc */
Elf_Addr SymValue = 0; /* shut up gcc-4 */
int rc = RTLDRELF_NAME(SymbolExecDyn)(pModElf, BaseAddr, pfnGetImport, pvUser, ELF_R_SYM(paRels[iRel].r_info), &pSym, &SymValue);
if (RT_FAILURE(rc))
return rc;
/*
* Apply the fixup.
*/
switch (ELF_R_TYPE(paRels[iRel].r_info))
{
#if ELF_MODE == 32
/*
* GOT/PLT.
*/
case R_386_GLOB_DAT:
{
*(uint32_t *)pAddrW = (uint32_t)SymValue;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_386_GLOB_DAT Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, SymValue));
AssertCompile(sizeof(SymValue) == sizeof(uint32_t));
break;
}
case R_386_JMP_SLOT:
{
*(uint32_t *)pAddrW = (uint32_t)SymValue;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_386_JMP_SLOT Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, SymValue));
AssertCompile(sizeof(SymValue) == sizeof(uint32_t));
break;
}
/*
* Absolute addressing.
*/
case R_386_32:
{
Elf_Addr Value;
if (pSym->st_shndx < pModElf->Ehdr.e_shnum)
Value = *pAddrR + offDelta; /* Simplified. */
else if (pSym->st_shndx == SHN_ABS)
continue; /* Internal fixup, no need to apply it. */
else if (pSym->st_shndx == SHN_UNDEF)
Value = SymValue + *pAddrR;
else
AssertFailedReturn(VERR_LDR_GENERAL_FAILURE); /** @todo SHN_COMMON */
*(uint32_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_386_32 Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value));
break;
}
/*
* PC relative addressing.
*/
case R_386_PC32:
{
Elf_Addr Value;
if (pSym->st_shndx < pModElf->Ehdr.e_shnum)
continue; /* Internal fixup, no need to apply it. */
else if (pSym->st_shndx == SHN_ABS)
Value = *pAddrR + offDelta; /* Simplified. */
else if (pSym->st_shndx == SHN_UNDEF)
{
const Elf_Addr SourceAddr = SecAddr + paRels[iRel].r_offset + BaseAddr; /* Where the source really is. */
Value = SymValue + *(uint32_t *)pAddrR - SourceAddr;
*(uint32_t *)pAddrW = Value;
}
else
AssertFailedReturn(VERR_LDR_GENERAL_FAILURE); /** @todo SHN_COMMON */
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_386_PC32 Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value));
break;
}
#elif ELF_MODE == 64
/*
* GOT/PLT.
*/
case R_X86_64_GLOB_DAT:
{
*(uint64_t *)pAddrW = (uint64_t)SymValue;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_GLOB_DAT Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, SymValue));
AssertCompile(sizeof(SymValue) == sizeof(uint64_t));
break;
}
case R_X86_64_JMP_SLOT:
{
*(uint64_t *)pAddrW = (uint64_t)SymValue;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_JMP_SLOT Value=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, SymValue));
AssertCompile(sizeof(SymValue) == sizeof(uint64_t));
break;
}
/*
* Absolute addressing.
*/
case R_X86_64_64:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(uint64_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_64 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value, SymValue));
break;
}
/*
* Truncated 32-bit value (zero-extendedable to the 64-bit value).
*/
case R_X86_64_32:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(uint32_t *)pAddrW = (uint32_t)Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(uint32_t *)pAddrW == SymValue, ("Value=" FMT_ELF_ADDR "\n", SymValue),
VERR_SYMBOL_VALUE_TOO_BIG);
break;
}
/*
* Truncated 32-bit value (sign-extendedable to the 64-bit value).
*/
case R_X86_64_32S:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(int32_t *)pAddrW = (int32_t)Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_32S Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, paRels[iRel].r_offset, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(int32_t *)pAddrW == Value, ("Value=" FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG); /** @todo check the sign-extending here. */
break;
}
/*
* PC relative addressing.
*/
case R_X86_64_PC32:
{
const Elf_Addr SourceAddr = SecAddr + paRels[iRel].r_offset + BaseAddr; /* Where the source really is. */
const Elf_Addr Value = SymValue + paRels[iRel].r_addend - SourceAddr;
*(int32_t *)pAddrW = (int32_t)Value;
Log4((FMT_ELF_ADDR "/" FMT_ELF_ADDR7 ": R_X86_64_PC32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SourceAddr, paRels[iRel].r_offset, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(int32_t *)pAddrW == Value, ("Value=" FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG); /** @todo check the sign-extending here. */
break;
}
#endif
default:
AssertMsgFailed(("Unknown relocation type: %d (iRel=%d iRelMax=%d)\n",
ELF_R_TYPE(paRels[iRel].r_info), iRel, iRelMax));
return VERR_LDRELF_RELOCATION_NOT_SUPPORTED;
}
}
return VINF_SUCCESS;
}
/*
*
* REL
* REL
* REL
* REL
* REL
*
*/
/**
* Get the symbol and symbol value.
*
* @returns iprt status code.
* @param pModElf The ELF loader module instance data.
* @param BaseAddr The base address which the module is being fixedup to.
* @param pfnGetImport The callback function to use to resolve imports (aka unresolved externals).
* @param pvUser User argument to pass to the callback.
* @param iSym The symbol to get.
* @param ppSym Where to store the symbol pointer on success. (read only)
* @param pSymValue Where to store the symbol value on success.
*/
static int RTLDRELF_NAME(Symbol)(PRTLDRMODELF pModElf, Elf_Addr BaseAddr, PFNRTLDRIMPORT pfnGetImport, void *pvUser,
Elf_Size iSym, const Elf_Sym **ppSym, Elf_Addr *pSymValue)
{
/*
* Validate and find the symbol.
*/
AssertMsgReturn(iSym < pModElf->Rel.cSyms, ("iSym=%d is an invalid symbol index!\n", iSym), VERR_LDRELF_INVALID_SYMBOL_INDEX);
const Elf_Sym *pSym = &pModElf->Rel.paSyms[iSym];
*ppSym = pSym;
AssertMsgReturn(pSym->st_name < pModElf->Rel.cbStr,
("iSym=%d st_name=%d str sh_size=%d\n", iSym, pSym->st_name, pModElf->Rel.cbStr),
VERR_LDRELF_INVALID_SYMBOL_NAME_OFFSET);
const char *pszName = ELF_STR(pModElf, pSym->st_name);
/*
* Determine the symbol value.
*
* Symbols needs different treatment depending on which section their are in.
* Undefined and absolute symbols goes into special non-existing sections.
*/
switch (pSym->st_shndx)
{
/*
* Undefined symbol, needs resolving.
*
* Since ELF has no generic concept of importing from specific module (the OS/2 ELF format
* has but that's an OS extension and only applies to programs and dlls), we'll have to ask
* the resolver callback to do a global search.
*/
case SHN_UNDEF:
{
/* Try to resolve the symbol. */
RTUINTPTR Value;
int rc = pfnGetImport(&pModElf->Core, "", pszName, ~0U, &Value, pvUser);
AssertMsgRCReturn(rc, ("Failed to resolve '%s' (iSym=" FMT_ELF_SIZE " rc=%Rrc\n", pszName, iSym, rc), rc);
*pSymValue = (Elf_Addr)Value;
AssertMsgReturn((RTUINTPTR)*pSymValue == Value,
("Symbol value overflowed! '%s' (iSym=" FMT_ELF_SIZE ")\n", pszName, iSym),
VERR_SYMBOL_VALUE_TOO_BIG);
Log2(("rtldrELF: #%-3d - UNDEF " FMT_ELF_ADDR " '%s'\n", iSym, *pSymValue, pszName));
break;
}
/*
* Absolute symbols needs no fixing since they are, well, absolute.
*/
case SHN_ABS:
*pSymValue = pSym->st_value;
Log2(("rtldrELF: #%-3d - ABS " FMT_ELF_ADDR " '%s'\n", iSym, *pSymValue, pszName));
break;
/*
* All other symbols are addressed relative to their section and need to be fixed up.
*/
default:
if (pSym->st_shndx >= pModElf->Ehdr.e_shnum)
{
/* what about common symbols? */
AssertMsg(pSym->st_shndx < pModElf->Ehdr.e_shnum,
("iSym=%d st_shndx=%d e_shnum=%d pszName=%s\n", iSym, pSym->st_shndx, pModElf->Ehdr.e_shnum, pszName));
return VERR_BAD_EXE_FORMAT;
}
*pSymValue = pSym->st_value + pModElf->paShdrs[pSym->st_shndx].sh_addr + BaseAddr;
Log2(("rtldrELF: #%-3d - %5d " FMT_ELF_ADDR " '%s'\n", iSym, pSym->st_shndx, *pSymValue, pszName));
break;
}
return VINF_SUCCESS;
}
/**
* Applies the fixups for a sections.
*
* @returns iprt status code.
* @param pModElf The ELF loader module instance data.
* @param BaseAddr The base address which the module is being fixedup to.
* @param pfnGetImport The callback function to use to resolve imports (aka unresolved externals).
* @param pvUser User argument to pass to the callback.
* @param SecAddr The section address. This is the address the relocations are relative to.
* @param cbSec The section size. The relocations must be inside this.
* @param pu8SecBaseR Where we read section bits from.
* @param pu8SecBaseW Where we write section bits to.
* @param pvRelocs Pointer to where we read the relocations from.
* @param cbRelocs Size of the relocations.
*/
static int RTLDRELF_NAME(RelocateSectionRel)(PRTLDRMODELF pModElf, Elf_Addr BaseAddr, PFNRTLDRIMPORT pfnGetImport, void *pvUser,
const Elf_Addr SecAddr, Elf_Size cbSec, const uint8_t *pu8SecBaseR,
uint8_t *pu8SecBaseW, const void *pvRelocs, Elf_Size cbRelocs)
{
#if ELF_MODE != 32
NOREF(pu8SecBaseR);
#endif
/*
* Iterate the relocations.
* The relocations are stored in an array of Elf32_Rel records and covers the entire relocation section.
*/
const Elf_Reloc *paRels = (const Elf_Reloc *)pvRelocs;
const unsigned iRelMax = (unsigned)(cbRelocs / sizeof(paRels[0]));
AssertMsgReturn(iRelMax == cbRelocs / sizeof(paRels[0]), (FMT_ELF_SIZE "\n", cbRelocs / sizeof(paRels[0])), VERR_IMAGE_TOO_BIG);
for (unsigned iRel = 0; iRel < iRelMax; iRel++)
{
/*
* Skip R_XXX_NONE entries early to avoid confusion in the symbol
* getter code.
*/
#if ELF_MODE == 32
if (ELF_R_TYPE(paRels[iRel].r_info) == R_386_NONE)
continue;
#elif ELF_MODE == 64
if (ELF_R_TYPE(paRels[iRel].r_info) == R_X86_64_NONE)
continue;
#endif
/*
* Get the symbol.
*/
const Elf_Sym *pSym = NULL; /* shut up gcc */
Elf_Addr SymValue = 0; /* shut up gcc-4 */
int rc = RTLDRELF_NAME(Symbol)(pModElf, BaseAddr, pfnGetImport, pvUser, ELF_R_SYM(paRels[iRel].r_info), &pSym, &SymValue);
if (RT_FAILURE(rc))
return rc;
Log3(("rtldrELF: " FMT_ELF_ADDR " %02x %06x - " FMT_ELF_ADDR " %3d %02x %s\n",
paRels[iRel].r_offset, ELF_R_TYPE(paRels[iRel].r_info), (unsigned)ELF_R_SYM(paRels[iRel].r_info),
SymValue, (unsigned)pSym->st_shndx, pSym->st_info, ELF_STR(pModElf, pSym->st_name)));
/*
* Apply the fixup.
*/
AssertMsgReturn(paRels[iRel].r_offset < cbSec, (FMT_ELF_ADDR " " FMT_ELF_SIZE "\n", paRels[iRel].r_offset, cbSec), VERR_LDRELF_INVALID_RELOCATION_OFFSET);
#if ELF_MODE == 32
const Elf_Addr *pAddrR = (const Elf_Addr *)(pu8SecBaseR + paRels[iRel].r_offset); /* Where to read the addend. */
#endif
Elf_Addr *pAddrW = (Elf_Addr *)(pu8SecBaseW + paRels[iRel].r_offset); /* Where to write the fixup. */
switch (ELF_R_TYPE(paRels[iRel].r_info))
{
#if ELF_MODE == 32
/*
* Absolute addressing.
*/
case R_386_32:
{
const Elf_Addr Value = SymValue + *pAddrR;
*(uint32_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR": R_386_32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, Value, SymValue));
break;
}
/*
* PC relative addressing.
*/
case R_386_PC32:
{
const Elf_Addr SourceAddr = SecAddr + paRels[iRel].r_offset + BaseAddr; /* Where the source really is. */
const Elf_Addr Value = SymValue + *(uint32_t *)pAddrR - SourceAddr;
*(uint32_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR": R_386_PC32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SourceAddr, Value, SymValue));
break;
}
/* ignore */
case R_386_NONE:
break;
#elif ELF_MODE == 64
/*
* Absolute addressing
*/
case R_X86_64_64:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(uint64_t *)pAddrW = Value;
Log4((FMT_ELF_ADDR": R_X86_64_64 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, Value, SymValue));
break;
}
/*
* Truncated 32-bit value (zero-extendedable to the 64-bit value).
*/
case R_X86_64_32:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(uint32_t *)pAddrW = (uint32_t)Value;
Log4((FMT_ELF_ADDR": R_X86_64_32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(uint32_t *)pAddrW == Value, ("Value=" FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG);
break;
}
/*
* Truncated 32-bit value (sign-extendedable to the 64-bit value).
*/
case R_X86_64_32S:
{
const Elf_Addr Value = SymValue + paRels[iRel].r_addend;
*(int32_t *)pAddrW = (int32_t)Value;
Log4((FMT_ELF_ADDR": R_X86_64_32S Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SecAddr + paRels[iRel].r_offset + BaseAddr, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(int32_t *)pAddrW == Value, ("Value=" FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG); /** @todo check the sign-extending here. */
break;
}
/*
* PC relative addressing.
*/
case R_X86_64_PC32:
case R_X86_64_PLT32: /* binutils commit 451875b4f976a527395e9303224c7881b65e12ed feature/regression. */
{
const Elf_Addr SourceAddr = SecAddr + paRels[iRel].r_offset + BaseAddr; /* Where the source really is. */
const Elf_Addr Value = SymValue + paRels[iRel].r_addend - SourceAddr;
*(int32_t *)pAddrW = (int32_t)Value;
Log4((FMT_ELF_ADDR": R_X86_64_PC32 Value=" FMT_ELF_ADDR " SymValue=" FMT_ELF_ADDR "\n",
SourceAddr, Value, SymValue));
AssertMsgReturn((Elf_Addr)*(int32_t *)pAddrW == Value, ("Value=" FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG); /** @todo check the sign-extending here. */
break;
}
/* ignore */
case R_X86_64_NONE:
break;
#endif
default:
AssertMsgFailed(("Unknown relocation type: %d (iRel=%d iRelMax=%d)\n",
ELF_R_TYPE(paRels[iRel].r_info), iRel, iRelMax));
return VERR_LDRELF_RELOCATION_NOT_SUPPORTED;
}
}
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::pfnClose */
static DECLCALLBACK(int) RTLDRELF_NAME(Close)(PRTLDRMODINTERNAL pMod)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
if (pModElf->paShdrs)
{
RTMemFree(pModElf->paShdrs);
pModElf->paShdrs = NULL;
}
if (pModElf->paPhdrs)
{
RTMemFree(pModElf->paPhdrs);
pModElf->paPhdrs = NULL;
}
if (pModElf->paDynamic)
{
RTMemFree(pModElf->paDynamic);
pModElf->paDynamic = NULL;
}
if (pModElf->pvBits)
{
pModElf->Core.pReader->pfnUnmap(pModElf->Core.pReader, pModElf->pvBits);
pModElf->pvBits = NULL;
}
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::Done */
static DECLCALLBACK(int) RTLDRELF_NAME(Done)(PRTLDRMODINTERNAL pMod)
{
NOREF(pMod); /*PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;*/
/** @todo Have to think more about this .... */
return -1;
}
/** @copydoc RTLDROPS::pfnEnumSymbols */
static DECLCALLBACK(int) RTLDRELF_NAME(EnumSymbols)(PRTLDRMODINTERNAL pMod, unsigned fFlags, const void *pvBits,
RTUINTPTR BaseAddress, PFNRTLDRENUMSYMS pfnCallback, void *pvUser)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
NOREF(pvBits);
/*
* Validate the input.
*/
Elf_Addr BaseAddr = (Elf_Addr)BaseAddress;
AssertMsgReturn((RTUINTPTR)BaseAddr == BaseAddress, ("%RTptr", BaseAddress), VERR_IMAGE_BASE_TOO_HIGH);
/*
* Make sure we've got the string and symbol tables. (We don't need the pvBits.)
*/
int rc = RTLDRELF_NAME(MapBits)(pModElf, false);
if (RT_FAILURE(rc))
return rc;
/*
* Enumerate the symbol table.
*/
const Elf_Sym *paSyms = pModElf->Rel.paSyms;
unsigned cSyms = pModElf->Rel.cSyms;
const char *pszzStr = pModElf->Rel.pStr;
unsigned cbStr = pModElf->Rel.cbStr;
if ( ( !(fFlags & RTLDR_ENUM_SYMBOL_FLAGS_ALL)
&& pModElf->Dyn.cSyms > 0)
|| cSyms == 0)
{
paSyms = pModElf->Dyn.paSyms;
cSyms = pModElf->Dyn.cSyms;
pszzStr = pModElf->Dyn.pStr;
cbStr = pModElf->Dyn.cbStr;
}
for (unsigned iSym = 1; iSym < cSyms; iSym++)
{
/*
* Skip imports (undefined).
*/
if (paSyms[iSym].st_shndx != SHN_UNDEF)
{
/*
* Calc value and get name.
*/
Elf_Addr Value;
if (paSyms[iSym].st_shndx == SHN_ABS)
/* absolute symbols are not subject to any relocation. */
Value = paSyms[iSym].st_value;
else if (paSyms[iSym].st_shndx < pModElf->Ehdr.e_shnum)
{
if (pModElf->Ehdr.e_type == ET_REL)
/* relative to the section. */
Value = BaseAddr + paSyms[iSym].st_value + pModElf->paShdrs[paSyms[iSym].st_shndx].sh_addr;
else /* Fixed up for link address. */
Value = BaseAddr + paSyms[iSym].st_value - pModElf->LinkAddress;
}
else
{
AssertMsgFailed(("Arg! paSyms[%u].st_shndx=" FMT_ELF_HALF "\n", iSym, paSyms[iSym].st_shndx));
return VERR_BAD_EXE_FORMAT;
}
AssertMsgReturn(paSyms[iSym].st_name < cbStr,
("String outside string table! iSym=%d paSyms[iSym].st_name=%#x\n", iSym, paSyms[iSym].st_name),
VERR_LDRELF_INVALID_SYMBOL_NAME_OFFSET);
const char * const pszName = pszzStr + paSyms[iSym].st_name;
/* String termination was already checked when the string table was mapped. */
if ( *pszName != '\0'
&& ( (fFlags & RTLDR_ENUM_SYMBOL_FLAGS_ALL)
|| ELF_ST_BIND(paSyms[iSym].st_info) == STB_GLOBAL) )
{
/*
* Call back.
*/
AssertMsgReturn(Value == (RTUINTPTR)Value, (FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG);
rc = pfnCallback(pMod, pszName, iSym, (RTUINTPTR)Value, pvUser);
if (rc)
return rc;
}
}
}
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::GetImageSize */
static DECLCALLBACK(size_t) RTLDRELF_NAME(GetImageSize)(PRTLDRMODINTERNAL pMod)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
return pModElf->cbImage;
}
/** @copydoc RTLDROPS::GetBits */
static DECLCALLBACK(int) RTLDRELF_NAME(GetBits)(PRTLDRMODINTERNAL pMod, void *pvBits, RTUINTPTR BaseAddress, PFNRTLDRIMPORT pfnGetImport, void *pvUser)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
/*
* This operation is currently only available on relocatable images.
*/
switch (pModElf->Ehdr.e_type)
{
case ET_REL:
case ET_DYN:
break;
case ET_EXEC:
Log(("RTLdrELF: %s: Executable images are not supported yet!\n", pModElf->Core.pReader->pfnLogName(pModElf->Core.pReader)));
return VERR_LDRELF_EXEC;
default: AssertFailedReturn(VERR_BAD_EXE_FORMAT);
}
/*
* Load the bits into pvBits.
*/
const Elf_Shdr *paShdrs = pModElf->paShdrs;
for (unsigned iShdr = 0; iShdr < pModElf->Ehdr.e_shnum; iShdr++)
{
if (paShdrs[iShdr].sh_flags & SHF_ALLOC)
{
AssertMsgReturn((size_t)paShdrs[iShdr].sh_size == (size_t)paShdrs[iShdr].sh_size, (FMT_ELF_SIZE "\n", paShdrs[iShdr].sh_size), VERR_IMAGE_TOO_BIG);
switch (paShdrs[iShdr].sh_type)
{
case SHT_NOBITS:
memset((uint8_t *)pvBits + paShdrs[iShdr].sh_addr, 0, (size_t)paShdrs[iShdr].sh_size);
break;
case SHT_PROGBITS:
default:
{
int rc = pModElf->Core.pReader->pfnRead(pModElf->Core.pReader, (uint8_t *)pvBits + paShdrs[iShdr].sh_addr,
(size_t)paShdrs[iShdr].sh_size, paShdrs[iShdr].sh_offset);
if (RT_FAILURE(rc))
{
Log(("RTLdrELF: %s: Read error when reading " FMT_ELF_SIZE " bytes at " FMT_ELF_OFF ", iShdr=%d\n",
pModElf->Core.pReader->pfnLogName(pModElf->Core.pReader),
paShdrs[iShdr].sh_size, paShdrs[iShdr].sh_offset, iShdr));
return rc;
}
}
}
}
}
/*
* Relocate the image.
*/
return pModElf->Core.pOps->pfnRelocate(pMod, pvBits, BaseAddress, ~(RTUINTPTR)0, pfnGetImport, pvUser);
}
/** @copydoc RTLDROPS::Relocate */
static DECLCALLBACK(int) RTLDRELF_NAME(Relocate)(PRTLDRMODINTERNAL pMod, void *pvBits, RTUINTPTR NewBaseAddress,
RTUINTPTR OldBaseAddress, PFNRTLDRIMPORT pfnGetImport, void *pvUser)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
#ifdef LOG_ENABLED
const char *pszLogName = pModElf->Core.pReader->pfnLogName(pModElf->Core.pReader);
#endif
NOREF(OldBaseAddress);
/*
* This operation is currently only available on relocatable images.
*/
switch (pModElf->Ehdr.e_type)
{
case ET_REL:
case ET_DYN:
break;
case ET_EXEC:
Log(("RTLdrELF: %s: Executable images are not supported yet!\n", pszLogName));
return VERR_LDRELF_EXEC;
default: AssertFailedReturn(VERR_BAD_EXE_FORMAT);
}
/*
* Validate the input.
*/
Elf_Addr BaseAddr = (Elf_Addr)NewBaseAddress;
AssertMsgReturn((RTUINTPTR)BaseAddr == NewBaseAddress, ("%RTptr", NewBaseAddress), VERR_IMAGE_BASE_TOO_HIGH);
/*
* Map the image bits if not already done and setup pointer into it.
*/
int rc = RTLDRELF_NAME(MapBits)(pModElf, true);
if (RT_FAILURE(rc))
return rc;
/*
* Iterate the sections looking for interesting SHT_REL[A] sections.
*
* In ET_REL files the SHT_REL[A] sections have the section index of
* the section they contain fixups for in the sh_info member.
*/
const Elf_Shdr *paShdrs = pModElf->paShdrs;
Log2(("rtLdrElf: %s: Fixing up image\n", pszLogName));
for (unsigned iShdr = 0; iShdr < pModElf->Ehdr.e_shnum; iShdr++)
{
const Elf_Shdr *pShdrRel = &paShdrs[iShdr];
/*
* Skip sections without interest to us.
*/
#if ELF_MODE == 32
if (pShdrRel->sh_type != SHT_REL)
#else
if (pShdrRel->sh_type != SHT_RELA)
#endif
continue;
if (pModElf->Ehdr.e_type == ET_REL)
{
if (pShdrRel->sh_info >= pModElf->Ehdr.e_shnum)
continue;
const Elf_Shdr *pShdr = &paShdrs[pShdrRel->sh_info]; /* the section to fixup. */
if (!(pShdr->sh_flags & SHF_ALLOC))
continue;
/*
* Relocate the section.
*/
Log2(("rtldrELF: %s: Relocation records for #%d [%s] (sh_info=%d sh_link=%d) found in #%d [%s] (sh_info=%d sh_link=%d)\n",
pszLogName, (int)pShdrRel->sh_info, ELF_SH_STR(pModElf, pShdr->sh_name), (int)pShdr->sh_info, (int)pShdr->sh_link,
iShdr, ELF_SH_STR(pModElf, pShdrRel->sh_name), (int)pShdrRel->sh_info, (int)pShdrRel->sh_link));
rc = RTLDRELF_NAME(RelocateSectionRel)(pModElf, BaseAddr, pfnGetImport, pvUser,
pShdr->sh_addr,
pShdr->sh_size,
(const uint8_t *)pModElf->pvBits + pShdr->sh_offset,
(uint8_t *)pvBits + pShdr->sh_addr,
(const uint8_t *)pModElf->pvBits + pShdrRel->sh_offset,
pShdrRel->sh_size);
}
else
rc = RTLDRELF_NAME(RelocateSectionExecDyn)(pModElf, BaseAddr, pfnGetImport, pvUser,
0, (Elf_Size)pModElf->cbImage,
(const uint8_t *)pModElf->pvBits /** @todo file offset ?? */,
(uint8_t *)pvBits,
(const uint8_t *)pModElf->pvBits + pShdrRel->sh_offset,
pShdrRel->sh_size);
if (RT_FAILURE(rc))
return rc;
}
return VINF_SUCCESS;
}
/**
* Worker for pfnGetSymbolEx.
*/
static int RTLDRELF_NAME(ReturnSymbol)(PRTLDRMODELF pThis, const Elf_Sym *pSym, Elf_Addr uBaseAddr, PRTUINTPTR pValue)
{
Elf_Addr Value;
if (pSym->st_shndx == SHN_ABS)
/* absolute symbols are not subject to any relocation. */
Value = pSym->st_value;
else if (pSym->st_shndx < pThis->Ehdr.e_shnum)
{
if (pThis->Ehdr.e_type == ET_REL)
/* relative to the section. */
Value = uBaseAddr + pSym->st_value + pThis->paShdrs[pSym->st_shndx].sh_addr;
else /* Fixed up for link address. */
Value = uBaseAddr + pSym->st_value - pThis->LinkAddress;
}
else
{
AssertMsgFailed(("Arg! pSym->st_shndx=%d\n", pSym->st_shndx));
return VERR_BAD_EXE_FORMAT;
}
AssertMsgReturn(Value == (RTUINTPTR)Value, (FMT_ELF_ADDR "\n", Value), VERR_SYMBOL_VALUE_TOO_BIG);
*pValue = (RTUINTPTR)Value;
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::pfnGetSymbolEx */
static DECLCALLBACK(int) RTLDRELF_NAME(GetSymbolEx)(PRTLDRMODINTERNAL pMod, const void *pvBits, RTUINTPTR BaseAddress,
uint32_t iOrdinal, const char *pszSymbol, RTUINTPTR *pValue)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
NOREF(pvBits);
/*
* Validate the input.
*/
Elf_Addr uBaseAddr = (Elf_Addr)BaseAddress;
AssertMsgReturn((RTUINTPTR)uBaseAddr == BaseAddress, ("%RTptr", BaseAddress), VERR_IMAGE_BASE_TOO_HIGH);
/*
* Map the image bits if not already done and setup pointer into it.
*/
int rc = RTLDRELF_NAME(MapBits)(pModElf, true);
if (RT_FAILURE(rc))
return rc;
/*
* Calc all kinds of pointers before we start iterating the symbol table.
*/
const Elf_Sym *paSyms = pModElf->Rel.paSyms;
unsigned cSyms = pModElf->Rel.cSyms;
const char *pszzStr = pModElf->Rel.pStr;
unsigned cbStr = pModElf->Rel.cbStr;
if (pModElf->Dyn.cSyms > 0)
{
paSyms = pModElf->Dyn.paSyms;
cSyms = pModElf->Dyn.cSyms;
pszzStr = pModElf->Dyn.pStr;
cbStr = pModElf->Dyn.cbStr;
}
if (iOrdinal == UINT32_MAX)
{
for (unsigned iSym = 1; iSym < cSyms; iSym++)
{
/* Undefined symbols are not exports, they are imports. */
if ( paSyms[iSym].st_shndx != SHN_UNDEF
&& ( ELF_ST_BIND(paSyms[iSym].st_info) == STB_GLOBAL
|| ELF_ST_BIND(paSyms[iSym].st_info) == STB_WEAK))
{
/* Validate the name string and try match with it. */
AssertMsgReturn(paSyms[iSym].st_name < cbStr,
("String outside string table! iSym=%d paSyms[iSym].st_name=%#x\n", iSym, paSyms[iSym].st_name),
VERR_LDRELF_INVALID_SYMBOL_NAME_OFFSET);
if (!strcmp(pszSymbol, pszzStr + paSyms[iSym].st_name))
{
/* matched! */
return RTLDRELF_NAME(ReturnSymbol)(pModElf, &paSyms[iSym], uBaseAddr, pValue);
}
}
}
}
else if (iOrdinal < cSyms)
{
if ( paSyms[iOrdinal].st_shndx != SHN_UNDEF
&& ( ELF_ST_BIND(paSyms[iOrdinal].st_info) == STB_GLOBAL
|| ELF_ST_BIND(paSyms[iOrdinal].st_info) == STB_WEAK))
return RTLDRELF_NAME(ReturnSymbol)(pModElf, &paSyms[iOrdinal], uBaseAddr, pValue);
}
return VERR_SYMBOL_NOT_FOUND;
}
/** @copydoc RTLDROPS::pfnEnumDbgInfo */
static DECLCALLBACK(int) RTLDRELF_NAME(EnumDbgInfo)(PRTLDRMODINTERNAL pMod, const void *pvBits,
PFNRTLDRENUMDBG pfnCallback, void *pvUser)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
RT_NOREF_PV(pvBits);
/*
* Map the image bits if not already done and setup pointer into it.
*/
int rc = RTLDRELF_NAME(MapBits)(pModElf, true);
if (RT_FAILURE(rc))
return rc;
/*
* Do the enumeration.
*/
const Elf_Shdr *paShdrs = pModElf->paOrgShdrs;
for (unsigned iShdr = 0; iShdr < pModElf->Ehdr.e_shnum; iShdr++)
{
/* Debug sections are expected to be PROGBITS and not allocated. */
if (paShdrs[iShdr].sh_type != SHT_PROGBITS)
continue;
if (paShdrs[iShdr].sh_flags & SHF_ALLOC)
continue;
RTLDRDBGINFO DbgInfo;
const char *pszSectName = ELF_SH_STR(pModElf, paShdrs[iShdr].sh_name);
if ( !strncmp(pszSectName, RT_STR_TUPLE(".debug_"))
|| !strcmp(pszSectName, ".WATCOM_references") )
{
RT_ZERO(DbgInfo.u);
DbgInfo.enmType = RTLDRDBGINFOTYPE_DWARF;
DbgInfo.pszExtFile = NULL;
DbgInfo.offFile = paShdrs[iShdr].sh_offset;
DbgInfo.cb = paShdrs[iShdr].sh_size;
DbgInfo.u.Dwarf.pszSection = pszSectName;
}
else if (!strcmp(pszSectName, ".gnu_debuglink"))
{
if ((paShdrs[iShdr].sh_size & 3) || paShdrs[iShdr].sh_size < 8)
return VERR_BAD_EXE_FORMAT;
RT_ZERO(DbgInfo.u);
DbgInfo.enmType = RTLDRDBGINFOTYPE_DWARF_DWO;
DbgInfo.pszExtFile = (const char *)((uintptr_t)pModElf->pvBits + (uintptr_t)paShdrs[iShdr].sh_offset);
if (!RTStrEnd(DbgInfo.pszExtFile, paShdrs[iShdr].sh_size))
return VERR_BAD_EXE_FORMAT;
DbgInfo.u.Dwo.uCrc32 = *(uint32_t *)((uintptr_t)DbgInfo.pszExtFile + (uintptr_t)paShdrs[iShdr].sh_size
- sizeof(uint32_t));
DbgInfo.offFile = -1;
DbgInfo.cb = 0;
}
else
continue;
DbgInfo.LinkAddress = NIL_RTLDRADDR;
DbgInfo.iDbgInfo = iShdr - 1;
rc = pfnCallback(pMod, &DbgInfo, pvUser);
if (rc != VINF_SUCCESS)
return rc;
}
return VINF_SUCCESS;
}
/**
* Locate the next allocated section by RVA (sh_addr).
*
* This is a helper for EnumSegments and SegOffsetToRva.
*
* @returns Pointer to the section header if found, NULL if none.
* @param pModElf The module instance.
* @param iShdrCur The current section header.
*/
static const Elf_Shdr *RTLDRELF_NAME(GetNextAllocatedSection)(PRTLDRMODELF pModElf, unsigned iShdrCur)
{
unsigned const cShdrs = pModElf->Ehdr.e_shnum;
const Elf_Shdr * const paShdrs = pModElf->paShdrs;
if (pModElf->fShdrInOrder)
{
for (unsigned iShdr = iShdrCur + 1; iShdr < cShdrs; iShdr++)
if (paShdrs[iShdr].sh_flags & SHF_ALLOC)
return &paShdrs[iShdr];
}
else
{
Elf_Addr const uEndCur = paShdrs[iShdrCur].sh_addr + paShdrs[iShdrCur].sh_size;
Elf_Addr offBest = ~(Elf_Addr)0;
unsigned iBest = cShdrs;
for (unsigned iShdr = pModElf->iFirstSect; iShdr < cShdrs; iShdr++)
if ((paShdrs[iShdr].sh_flags & SHF_ALLOC) && iShdr != iShdrCur)
{
Elf_Addr const offDelta = paShdrs[iShdr].sh_addr - uEndCur;
if ( offDelta < offBest
&& paShdrs[iShdr].sh_addr >= uEndCur)
{
offBest = offDelta;
iBest = iShdr;
}
}
if (iBest < cShdrs)
return &paShdrs[iBest];
}
return NULL;
}
/** @copydoc RTLDROPS::pfnEnumSegments. */
static DECLCALLBACK(int) RTLDRELF_NAME(EnumSegments)(PRTLDRMODINTERNAL pMod, PFNRTLDRENUMSEGS pfnCallback, void *pvUser)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
/*
* Map the image bits if not already done and setup pointer into it.
*/
int rc = RTLDRELF_NAME(MapBits)(pModElf, true);
if (RT_FAILURE(rc))
return rc;
/*
* Do the enumeration.
*/
char szName[32];
Elf_Addr uPrevMappedRva = 0;
const Elf_Shdr *paShdrs = pModElf->paShdrs;
const Elf_Shdr *paOrgShdrs = pModElf->paOrgShdrs;
for (unsigned iShdr = pModElf->iFirstSect; iShdr < pModElf->Ehdr.e_shnum; iShdr++)
{
RTLDRSEG Seg;
if (iShdr != 0)
{
Seg.pszName = ELF_SH_STR(pModElf, paShdrs[iShdr].sh_name);
Seg.cchName = (uint32_t)strlen(Seg.pszName);
if (Seg.cchName == 0)
{
Seg.pszName = szName;
Seg.cchName = (uint32_t)RTStrPrintf(szName, sizeof(szName), "UnamedSect%02u", iShdr);
}
}
else
{
Seg.pszName = ".elf.headers";
Seg.cchName = 12;
}
Seg.SelFlat = 0;
Seg.Sel16bit = 0;
Seg.fFlags = 0;
Seg.fProt = RTMEM_PROT_READ;
if (paShdrs[iShdr].sh_flags & SHF_WRITE)
Seg.fProt |= RTMEM_PROT_WRITE;
if (paShdrs[iShdr].sh_flags & SHF_EXECINSTR)
Seg.fProt |= RTMEM_PROT_EXEC;
Seg.cb = paShdrs[iShdr].sh_size;
Seg.Alignment = paShdrs[iShdr].sh_addralign;
if (paShdrs[iShdr].sh_flags & SHF_ALLOC)
{
Seg.LinkAddress = paOrgShdrs[iShdr].sh_addr;
Seg.RVA = paShdrs[iShdr].sh_addr;
const Elf_Shdr *pShdr2 = RTLDRELF_NAME(GetNextAllocatedSection)(pModElf, iShdr);
if (pShdr2)
Seg.cbMapped = pShdr2->sh_addr - paShdrs[iShdr].sh_addr;
else
Seg.cbMapped = pModElf->cbImage - paShdrs[iShdr].sh_addr;
uPrevMappedRva = Seg.RVA;
}
else
{
Seg.LinkAddress = NIL_RTLDRADDR;
Seg.RVA = NIL_RTLDRADDR;
Seg.cbMapped = NIL_RTLDRADDR;
}
if (paShdrs[iShdr].sh_type != SHT_NOBITS)
{
Seg.offFile = paShdrs[iShdr].sh_offset;
Seg.cbFile = paShdrs[iShdr].sh_size;
}
else
{
Seg.offFile = -1;
Seg.cbFile = 0;
}
rc = pfnCallback(pMod, &Seg, pvUser);
if (rc != VINF_SUCCESS)
return rc;
}
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::pfnLinkAddressToSegOffset. */
static DECLCALLBACK(int) RTLDRELF_NAME(LinkAddressToSegOffset)(PRTLDRMODINTERNAL pMod, RTLDRADDR LinkAddress,
uint32_t *piSeg, PRTLDRADDR poffSeg)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
const Elf_Shdr *pShdrEnd = NULL;
unsigned cLeft = pModElf->Ehdr.e_shnum - pModElf->iFirstSect;
const Elf_Shdr *pShdr = &pModElf->paOrgShdrs[pModElf->Ehdr.e_shnum];
while (cLeft-- > 0)
{
pShdr--;
if (pShdr->sh_flags & SHF_ALLOC)
{
RTLDRADDR offSeg = LinkAddress - pShdr->sh_addr;
if (offSeg < pShdr->sh_size)
{
*poffSeg = offSeg;
*piSeg = cLeft;
return VINF_SUCCESS;
}
if (offSeg == pShdr->sh_size)
pShdrEnd = pShdr;
}
}
if (pShdrEnd)
{
*poffSeg = pShdrEnd->sh_size;
*piSeg = pShdrEnd - pModElf->paOrgShdrs - pModElf->iFirstSect;
return VINF_SUCCESS;
}
return VERR_LDR_INVALID_LINK_ADDRESS;
}
/** @copydoc RTLDROPS::pfnLinkAddressToRva. */
static DECLCALLBACK(int) RTLDRELF_NAME(LinkAddressToRva)(PRTLDRMODINTERNAL pMod, RTLDRADDR LinkAddress, PRTLDRADDR pRva)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
uint32_t iSeg;
RTLDRADDR offSeg;
int rc = RTLDRELF_NAME(LinkAddressToSegOffset)(pMod, LinkAddress, &iSeg, &offSeg);
if (RT_SUCCESS(rc))
*pRva = pModElf->paShdrs[iSeg + pModElf->iFirstSect].sh_addr + offSeg;
return rc;
}
/** @copydoc RTLDROPS::pfnSegOffsetToRva. */
static DECLCALLBACK(int) RTLDRELF_NAME(SegOffsetToRva)(PRTLDRMODINTERNAL pMod, uint32_t iSeg, RTLDRADDR offSeg,
PRTLDRADDR pRva)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
if (iSeg >= pModElf->Ehdr.e_shnum - pModElf->iFirstSect)
return VERR_LDR_INVALID_SEG_OFFSET;
iSeg += pModElf->iFirstSect; /* skip section 0 if not used */
if (offSeg > pModElf->paShdrs[iSeg].sh_size)
{
const Elf_Shdr *pShdr2 = RTLDRELF_NAME(GetNextAllocatedSection)(pModElf, iSeg);
if ( !pShdr2
|| offSeg > (pShdr2->sh_addr - pModElf->paShdrs[iSeg].sh_addr))
return VERR_LDR_INVALID_SEG_OFFSET;
}
if (!(pModElf->paShdrs[iSeg].sh_flags & SHF_ALLOC))
return VERR_LDR_INVALID_SEG_OFFSET;
*pRva = pModElf->paShdrs[iSeg].sh_addr;
return VINF_SUCCESS;
}
/** @copydoc RTLDROPS::pfnRvaToSegOffset. */
static DECLCALLBACK(int) RTLDRELF_NAME(RvaToSegOffset)(PRTLDRMODINTERNAL pMod, RTLDRADDR Rva,
uint32_t *piSeg, PRTLDRADDR poffSeg)
{
PRTLDRMODELF pModElf = (PRTLDRMODELF)pMod;
Elf_Addr PrevAddr = 0;
unsigned cLeft = pModElf->Ehdr.e_shnum - pModElf->iFirstSect;
const Elf_Shdr *pShdr = &pModElf->paShdrs[pModElf->Ehdr.e_shnum];
while (cLeft-- > 0)
{
pShdr--;
if (pShdr->sh_flags & SHF_ALLOC)
{
Elf_Addr cbSeg = PrevAddr ? PrevAddr - pShdr->sh_addr : pShdr->sh_size;
RTLDRADDR offSeg = Rva - pShdr->sh_addr;
if (offSeg <= cbSeg)
{
*poffSeg = offSeg;
*piSeg = cLeft;
return VINF_SUCCESS;
}
PrevAddr = pShdr->sh_addr;
}
}
return VERR_LDR_INVALID_RVA;
}
/** @callback_method_impl{FNRTLDRIMPORT, Stub used by ReadDbgInfo.} */
static DECLCALLBACK(int) RTLDRELF_NAME(GetImportStubCallback)(RTLDRMOD hLdrMod, const char *pszModule, const char *pszSymbol,
unsigned uSymbol, PRTLDRADDR pValue, void *pvUser)
{
RT_NOREF_PV(hLdrMod); RT_NOREF_PV(pszModule); RT_NOREF_PV(pszSymbol);
RT_NOREF_PV(uSymbol); RT_NOREF_PV(pValue); RT_NOREF_PV(pvUser);
return VERR_SYMBOL_NOT_FOUND;
}
/** @copydoc RTLDROPS::pfnReadDbgInfo. */
static DECLCALLBACK(int) RTLDRELF_NAME(ReadDbgInfo)(PRTLDRMODINTERNAL pMod, uint32_t iDbgInfo, RTFOFF off,
size_t cb, void *pvBuf)
{
PRTLDRMODELF pThis = (PRTLDRMODELF)pMod;
LogFlow(("%s: iDbgInfo=%#x off=%RTfoff cb=%#zu\n", __FUNCTION__, iDbgInfo, off, cb));
/*
* Input validation.
*/
AssertReturn(iDbgInfo < pThis->Ehdr.e_shnum && iDbgInfo + 1 < pThis->Ehdr.e_shnum, VERR_INVALID_PARAMETER);
iDbgInfo++;
AssertReturn(!(pThis->paShdrs[iDbgInfo].sh_flags & SHF_ALLOC), VERR_INVALID_PARAMETER);
AssertReturn(pThis->paShdrs[iDbgInfo].sh_type == SHT_PROGBITS, VERR_INVALID_PARAMETER);
AssertReturn(pThis->paShdrs[iDbgInfo].sh_offset == (uint64_t)off, VERR_INVALID_PARAMETER);
AssertReturn(pThis->paShdrs[iDbgInfo].sh_size == cb, VERR_INVALID_PARAMETER);
uint64_t cbRawImage = pThis->Core.pReader->pfnSize(pThis->Core.pReader);
AssertReturn(off >= 0 && cb <= cbRawImage && (uint64_t)off + cb <= cbRawImage, VERR_INVALID_PARAMETER);
/*
* Read it from the file and look for fixup sections.
*/
int rc;
if (pThis->pvBits)
memcpy(pvBuf, (const uint8_t *)pThis->pvBits + (size_t)off, cb);
else
{
rc = pThis->Core.pReader->pfnRead(pThis->Core.pReader, pvBuf, cb, off);
if (RT_FAILURE(rc))
return rc;
}
uint32_t iRelocs = iDbgInfo + 1;
if ( iRelocs >= pThis->Ehdr.e_shnum
|| pThis->paShdrs[iRelocs].sh_info != iDbgInfo
|| ( pThis->paShdrs[iRelocs].sh_type != SHT_REL
&& pThis->paShdrs[iRelocs].sh_type != SHT_RELA) )
{
iRelocs = 0;
while ( iRelocs < pThis->Ehdr.e_shnum
&& ( pThis->paShdrs[iRelocs].sh_info != iDbgInfo
|| ( pThis->paShdrs[iRelocs].sh_type != SHT_REL
&& pThis->paShdrs[iRelocs].sh_type != SHT_RELA)) )
iRelocs++;
}
if ( iRelocs < pThis->Ehdr.e_shnum
&& pThis->paShdrs[iRelocs].sh_size > 0)
{
/*
* Load the relocations.
*/
uint8_t *pbRelocsBuf = NULL;
const uint8_t *pbRelocs;
if (pThis->pvBits)
pbRelocs = (const uint8_t *)pThis->pvBits + pThis->paShdrs[iRelocs].sh_offset;
else
{
pbRelocs = pbRelocsBuf = (uint8_t *)RTMemTmpAlloc(pThis->paShdrs[iRelocs].sh_size);
if (!pbRelocsBuf)
return VERR_NO_TMP_MEMORY;
rc = pThis->Core.pReader->pfnRead(pThis->Core.pReader, pbRelocsBuf,
pThis->paShdrs[iRelocs].sh_size,
pThis->paShdrs[iRelocs].sh_offset);
if (RT_FAILURE(rc))
{
RTMemTmpFree(pbRelocsBuf);
return rc;
}
}
/*
* Apply the relocations.
*/
if (pThis->Ehdr.e_type == ET_REL)
rc = RTLDRELF_NAME(RelocateSectionRel)(pThis, pThis->LinkAddress,
RTLDRELF_NAME(GetImportStubCallback), NULL /*pvUser*/,
pThis->paShdrs[iDbgInfo].sh_addr,
pThis->paShdrs[iDbgInfo].sh_size,
(const uint8_t *)pvBuf,
(uint8_t *)pvBuf,
pbRelocs,
pThis->paShdrs[iRelocs].sh_size);
else
rc = RTLDRELF_NAME(RelocateSectionExecDyn)(pThis, pThis->LinkAddress,
RTLDRELF_NAME(GetImportStubCallback), NULL /*pvUser*/,
pThis->paShdrs[iDbgInfo].sh_addr,
pThis->paShdrs[iDbgInfo].sh_size,
(const uint8_t *)pvBuf,
(uint8_t *)pvBuf,
pbRelocs,
pThis->paShdrs[iRelocs].sh_size);
RTMemTmpFree(pbRelocsBuf);
}
else
rc = VINF_SUCCESS;
return rc;
}
/**
* @interface_method_impl{RTLDROPS,pfnUnwindFrame}
*/
static DECLCALLBACK(int)
RTLDRELF_NAME(UnwindFrame)(PRTLDRMODINTERNAL pMod, void const *pvBits, uint32_t iSeg, RTUINTPTR off, PRTDBGUNWINDSTATE pState)
{
PRTLDRMODELF pThis = (PRTLDRMODELF)pMod;
LogFlow(("%s: iSeg=%#x off=%RTptr\n", __FUNCTION__, iSeg, off));
/*
* Process the input address, making us both RVA and proper seg:offset out of it.
*/
int rc;
RTLDRADDR uRva = off;
if (iSeg == UINT32_MAX)
rc = RTLDRELF_NAME(RvaToSegOffset)(pMod, uRva, &iSeg, &off);
else
rc = RTLDRELF_NAME(SegOffsetToRva)(pMod, iSeg, off, &uRva);
AssertRCReturn(rc, rc);
/*
* Map the image bits if not already done and setup pointer into it.
*/
RT_NOREF(pvBits); /** @todo Try use passed in pvBits? */
rc = RTLDRELF_NAME(MapBits)(pThis, true);
if (RT_FAILURE(rc))
return rc;
/*
* Do we need to search for .eh_frame and .eh_frame_hdr?
*/
if (pThis->iShEhFrame == 0)
{
pThis->iShEhFrame = ~0U;
pThis->iShEhFrameHdr = ~0U;
unsigned cLeft = 2;
for (unsigned iShdr = 1; iShdr < pThis->Ehdr.e_shnum; iShdr++)
{
const char *pszName = ELF_SH_STR(pThis, pThis->paShdrs[iShdr].sh_name);
if ( pszName[0] == '.'
&& pszName[1] == 'e'
&& pszName[2] == 'h'
&& pszName[3] == '_'
&& pszName[4] == 'f'
&& pszName[5] == 'r'
&& pszName[6] == 'a'
&& pszName[7] == 'm'
&& pszName[8] == 'e')
{
if (pszName[9] == '\0')
pThis->iShEhFrame = iShdr;
else if ( pszName[9] == '_'
&& pszName[10] == 'h'
&& pszName[11] == 'd'
&& pszName[12] == 'r'
&& pszName[13] == '\0')
pThis->iShEhFrameHdr = iShdr;
else
continue;
if (--cLeft == 0)
break;
}
}
}
/*
* Any info present?
*/
unsigned iShdr = pThis->iShEhFrame;
if ( iShdr != ~0U
&& pThis->paShdrs[iShdr].sh_size > 0)
{
if (pThis->paShdrs[iShdr].sh_flags & SHF_ALLOC)
return rtDwarfUnwind_EhData((uint8_t const *)pThis->pvBits + pThis->paShdrs[iShdr].sh_addr,
pThis->paShdrs[iShdr].sh_size, pThis->paShdrs[iShdr].sh_addr,
iSeg, off, uRva, pState, pThis->Core.enmArch);
}
return VERR_DBG_NO_UNWIND_INFO;
}
/**
* The ELF module operations.
*/
static RTLDROPS RTLDRELF_MID(s_rtldrElf,Ops) =
{
#if ELF_MODE == 32
"elf32",
#elif ELF_MODE == 64
"elf64",
#endif
RTLDRELF_NAME(Close),
NULL, /* Get Symbol */
RTLDRELF_NAME(Done),
RTLDRELF_NAME(EnumSymbols),
/* ext: */
RTLDRELF_NAME(GetImageSize),
RTLDRELF_NAME(GetBits),
RTLDRELF_NAME(Relocate),
RTLDRELF_NAME(GetSymbolEx),
NULL /*pfnQueryForwarderInfo*/,
RTLDRELF_NAME(EnumDbgInfo),
RTLDRELF_NAME(EnumSegments),
RTLDRELF_NAME(LinkAddressToSegOffset),
RTLDRELF_NAME(LinkAddressToRva),
RTLDRELF_NAME(SegOffsetToRva),
RTLDRELF_NAME(RvaToSegOffset),
RTLDRELF_NAME(ReadDbgInfo),
NULL /*pfnQueryProp*/,
NULL /*pfnVerifySignature*/,
NULL /*pfnHashImage*/,
RTLDRELF_NAME(UnwindFrame),
42
};
/**
* Validates the ELF header.
*
* @returns iprt status code.
* @param pEhdr Pointer to the ELF header.
* @param cbRawImage The size of the raw image.
* @param pszLogName The log name.
* @param penmArch Where to return the architecture.
* @param pErrInfo Where to return extended error info. Optional.
*/
static int RTLDRELF_NAME(ValidateElfHeader)(const Elf_Ehdr *pEhdr, uint64_t cbRawImage, const char *pszLogName,
PRTLDRARCH penmArch, PRTERRINFO pErrInfo)
{
Log3(("RTLdrELF: e_ident: %.*Rhxs\n"
"RTLdrELF: e_type: " FMT_ELF_HALF "\n"
"RTLdrELF: e_version: " FMT_ELF_HALF "\n"
"RTLdrELF: e_entry: " FMT_ELF_ADDR "\n"
"RTLdrELF: e_phoff: " FMT_ELF_OFF "\n"
"RTLdrELF: e_shoff: " FMT_ELF_OFF "\n"
"RTLdrELF: e_flags: " FMT_ELF_WORD "\n"
"RTLdrELF: e_ehsize: " FMT_ELF_HALF "\n"
"RTLdrELF: e_phentsize: " FMT_ELF_HALF "\n"
"RTLdrELF: e_phnum: " FMT_ELF_HALF "\n"
"RTLdrELF: e_shentsize: " FMT_ELF_HALF "\n"
"RTLdrELF: e_shnum: " FMT_ELF_HALF "\n"
"RTLdrELF: e_shstrndx: " FMT_ELF_HALF "\n",
RT_ELEMENTS(pEhdr->e_ident), &pEhdr->e_ident[0], pEhdr->e_type, pEhdr->e_version,
pEhdr->e_entry, pEhdr->e_phoff, pEhdr->e_shoff,pEhdr->e_flags, pEhdr->e_ehsize, pEhdr->e_phentsize,
pEhdr->e_phnum, pEhdr->e_shentsize, pEhdr->e_shnum, pEhdr->e_shstrndx));
if ( pEhdr->e_ident[EI_MAG0] != ELFMAG0
|| pEhdr->e_ident[EI_MAG1] != ELFMAG1
|| pEhdr->e_ident[EI_MAG2] != ELFMAG2
|| pEhdr->e_ident[EI_MAG3] != ELFMAG3)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Invalid ELF magic (%.*Rhxs)", pszLogName, sizeof(pEhdr->e_ident), pEhdr->e_ident);
if (pEhdr->e_ident[EI_CLASS] != RTLDRELF_SUFF(ELFCLASS))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Invalid ELF class (%.*Rhxs)", pszLogName, sizeof(pEhdr->e_ident), pEhdr->e_ident);
if (pEhdr->e_ident[EI_DATA] != ELFDATA2LSB)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_LDRELF_ODD_ENDIAN,
"%s: ELF endian %x is unsupported", pszLogName, pEhdr->e_ident[EI_DATA]);
if (pEhdr->e_version != EV_CURRENT)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_LDRELF_VERSION,
"%s: ELF version %x is unsupported", pszLogName, pEhdr->e_version);
if (sizeof(Elf_Ehdr) != pEhdr->e_ehsize)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Elf header e_ehsize is %d expected %d!", pszLogName, pEhdr->e_ehsize, sizeof(Elf_Ehdr));
if ( sizeof(Elf_Phdr) != pEhdr->e_phentsize
&& ( pEhdr->e_phnum != 0
|| pEhdr->e_type == ET_DYN
|| pEhdr->e_type == ET_EXEC))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Elf header e_phentsize is %d expected %d!",
pszLogName, pEhdr->e_phentsize, sizeof(Elf_Phdr));
if (sizeof(Elf_Shdr) != pEhdr->e_shentsize)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Elf header e_shentsize is %d expected %d!",
pszLogName, pEhdr->e_shentsize, sizeof(Elf_Shdr));
switch (pEhdr->e_type)
{
case ET_REL:
case ET_EXEC:
case ET_DYN:
break;
default:
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: image type %#x is not supported!",
pszLogName, pEhdr->e_type);
}
switch (pEhdr->e_machine)
{
#if ELF_MODE == 32
case EM_386:
case EM_486:
*penmArch = RTLDRARCH_X86_32;
break;
#elif ELF_MODE == 64
case EM_X86_64:
*penmArch = RTLDRARCH_AMD64;
break;
#endif
default:
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_LDRELF_MACHINE,
"%s: machine type %u is not supported!", pszLogName, pEhdr->e_machine);
}
if ( pEhdr->e_phoff < pEhdr->e_ehsize
&& !(pEhdr->e_phoff && pEhdr->e_phnum)
&& pEhdr->e_phnum)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: The program headers overlap with the ELF header! e_phoff=" FMT_ELF_OFF,
pszLogName, pEhdr->e_phoff);
if ( pEhdr->e_phoff + pEhdr->e_phnum * pEhdr->e_phentsize > cbRawImage
|| pEhdr->e_phoff + pEhdr->e_phnum * pEhdr->e_phentsize < pEhdr->e_phoff)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: The program headers extends beyond the file! e_phoff=" FMT_ELF_OFF " e_phnum=" FMT_ELF_HALF,
pszLogName, pEhdr->e_phoff, pEhdr->e_phnum);
if ( pEhdr->e_shoff < pEhdr->e_ehsize
&& !(pEhdr->e_shoff && pEhdr->e_shnum))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: The section headers overlap with the ELF header! e_shoff=" FMT_ELF_OFF,
pszLogName, pEhdr->e_shoff);
if ( pEhdr->e_shoff + pEhdr->e_shnum * pEhdr->e_shentsize > cbRawImage
|| pEhdr->e_shoff + pEhdr->e_shnum * pEhdr->e_shentsize < pEhdr->e_shoff)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: The section headers extends beyond the file! e_shoff=" FMT_ELF_OFF " e_shnum=" FMT_ELF_HALF,
pszLogName, pEhdr->e_shoff, pEhdr->e_shnum);
if (pEhdr->e_shstrndx == 0 || pEhdr->e_shstrndx > pEhdr->e_shnum)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: The section headers string table is out of bounds! e_shstrndx=" FMT_ELF_HALF " e_shnum=" FMT_ELF_HALF,
pszLogName, pEhdr->e_shstrndx, pEhdr->e_shnum);
return VINF_SUCCESS;
}
/**
* Gets the section header name.
*
* @returns pszName.
* @param pEhdr The elf header.
* @param offName The offset of the section header name.
* @param pszName Where to store the name.
* @param cbName The size of the buffer pointed to by pszName.
*/
const char *RTLDRELF_NAME(GetSHdrName)(PRTLDRMODELF pModElf, Elf_Word offName, char *pszName, size_t cbName)
{
RTFOFF off = pModElf->paShdrs[pModElf->Ehdr.e_shstrndx].sh_offset + offName;
int rc = pModElf->Core.pReader->pfnRead(pModElf->Core.pReader, pszName, cbName - 1, off);
if (RT_FAILURE(rc))
{
/* read by for byte. */
for (unsigned i = 0; i < cbName; i++, off++)
{
rc = pModElf->Core.pReader->pfnRead(pModElf->Core.pReader, pszName + i, 1, off);
if (RT_FAILURE(rc))
{
pszName[i] = '\0';
break;
}
}
}
pszName[cbName - 1] = '\0';
return pszName;
}
/**
* Validates a section header.
*
* @returns iprt status code.
* @param pModElf Pointer to the module structure.
* @param iShdr The index of section header which should be validated.
* The section headers are found in the pModElf->paShdrs array.
* @param cbRawImage The size of the raw image.
* @param pszLogName The log name.
* @param pErrInfo Where to return extended error info. Optional.
*/
static int RTLDRELF_NAME(ValidateSectionHeader)(PRTLDRMODELF pModElf, unsigned iShdr, uint64_t cbRawImage,
const char *pszLogName, PRTERRINFO pErrInfo)
{
const Elf_Shdr *pShdr = &pModElf->paShdrs[iShdr];
char szSectionName[80]; NOREF(szSectionName);
Log3(("RTLdrELF: Section Header #%d:\n"
"RTLdrELF: sh_name: " FMT_ELF_WORD " - %s\n"
"RTLdrELF: sh_type: " FMT_ELF_WORD " (%s)\n"
"RTLdrELF: sh_flags: " FMT_ELF_XWORD "\n"
"RTLdrELF: sh_addr: " FMT_ELF_ADDR "\n"
"RTLdrELF: sh_offset: " FMT_ELF_OFF "\n"
"RTLdrELF: sh_size: " FMT_ELF_XWORD "\n"
"RTLdrELF: sh_link: " FMT_ELF_WORD "\n"
"RTLdrELF: sh_info: " FMT_ELF_WORD "\n"
"RTLdrELF: sh_addralign: " FMT_ELF_XWORD "\n"
"RTLdrELF: sh_entsize: " FMT_ELF_XWORD "\n",
iShdr,
pShdr->sh_name, RTLDRELF_NAME(GetSHdrName)(pModElf, pShdr->sh_name, szSectionName, sizeof(szSectionName)),
pShdr->sh_type, rtldrElfGetShdrType(pShdr->sh_type), pShdr->sh_flags, pShdr->sh_addr,
pShdr->sh_offset, pShdr->sh_size, pShdr->sh_link, pShdr->sh_info, pShdr->sh_addralign,
pShdr->sh_entsize));
if (iShdr == 0)
{
if ( pShdr->sh_name != 0
|| pShdr->sh_type != SHT_NULL
|| pShdr->sh_flags != 0
|| pShdr->sh_addr != 0
|| pShdr->sh_size != 0
|| pShdr->sh_offset != 0
|| pShdr->sh_link != SHN_UNDEF
|| pShdr->sh_addralign != 0
|| pShdr->sh_entsize != 0 )
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Bad #0 section: %.*Rhxs", pszLogName, sizeof(*pShdr), pShdr);
return VINF_SUCCESS;
}
if (pShdr->sh_name >= pModElf->cbShStr)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Shdr #%d: sh_name (%d) is beyond the end of the section header string table (%d)!",
pszLogName, iShdr, pShdr->sh_name, pModElf->cbShStr);
if (pShdr->sh_link >= pModElf->Ehdr.e_shnum)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Shdr #%d: sh_link (%d) is beyond the end of the section table (%d)!",
pszLogName, iShdr, pShdr->sh_link, pModElf->Ehdr.e_shnum);
switch (pShdr->sh_type)
{
/** @todo find specs and check up which sh_info fields indicates section table entries */
case 12301230:
if (pShdr->sh_info >= pModElf->Ehdr.e_shnum)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Shdr #%d: sh_info (%d) is beyond the end of the section table (%d)!",
pszLogName, iShdr, pShdr->sh_link, pModElf->Ehdr.e_shnum);
break;
case SHT_NULL:
break;
case SHT_PROGBITS:
case SHT_SYMTAB:
case SHT_STRTAB:
case SHT_RELA:
case SHT_HASH:
case SHT_DYNAMIC:
case SHT_NOTE:
case SHT_NOBITS:
case SHT_REL:
case SHT_SHLIB:
case SHT_DYNSYM:
/*
* For these types sh_info doesn't have any special meaning, or anything which
* we need/can validate now.
*/
break;
default:
Log(("RTLdrELF: %s: Warning, unknown type %d!\n", pszLogName, pShdr->sh_type));
break;
}
if ( pShdr->sh_type != SHT_NOBITS
&& pShdr->sh_size)
{
uint64_t offEnd = pShdr->sh_offset + pShdr->sh_size;
if ( offEnd > cbRawImage
|| offEnd < (uint64_t)pShdr->sh_offset)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Shdr #%d: sh_offset (" FMT_ELF_OFF ") + sh_size (" FMT_ELF_XWORD " = %RX64) is beyond the end of the file (%RX64)!",
pszLogName, iShdr, pShdr->sh_offset, pShdr->sh_size, offEnd, cbRawImage);
if (pShdr->sh_offset < sizeof(Elf_Ehdr))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Shdr #%d: sh_offset (" FMT_ELF_OFF ") + sh_size (" FMT_ELF_XWORD ") is starting in the ELF header!",
pszLogName, iShdr, pShdr->sh_offset, pShdr->sh_size);
}
return VINF_SUCCESS;
}
/**
* Process the section headers.
*
* @returns iprt status code.
* @param pModElf Pointer to the module structure.
* @param paShdrs The section headers.
* @param cbRawImage The size of the raw image.
* @param pszLogName The log name.
* @param pErrInfo Where to return extended error info. Optional.
*/
static int RTLDRELF_NAME(ValidateAndProcessSectionHeaders)(PRTLDRMODELF pModElf, Elf_Shdr *paShdrs, uint64_t cbRawImage,
const char *pszLogName, PRTERRINFO pErrInfo)
{
Elf_Addr uNextAddr = 0;
for (unsigned i = 0; i < pModElf->Ehdr.e_shnum; i++)
{
int rc = RTLDRELF_NAME(ValidateSectionHeader)(pModElf, i, cbRawImage, pszLogName, pErrInfo);
if (RT_FAILURE(rc))
return rc;
/*
* We're looking for symbol tables.
*/
if (paShdrs[i].sh_type == SHT_SYMTAB)
{
if (pModElf->Rel.iSymSh != ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_LDRELF_MULTIPLE_SYMTABS,
"%s: Multiple symbol tabs! iSymSh=%d i=%d", pszLogName, pModElf->Rel.iSymSh, i);
pModElf->Rel.iSymSh = i;
pModElf->Rel.cSyms = (unsigned)(paShdrs[i].sh_size / sizeof(Elf_Sym));
AssertBreakStmt(pModElf->Rel.cSyms == paShdrs[i].sh_size / sizeof(Elf_Sym), rc = VERR_IMAGE_TOO_BIG);
pModElf->Rel.iStrSh = paShdrs[i].sh_link;
pModElf->Rel.cbStr = (unsigned)paShdrs[pModElf->Rel.iStrSh].sh_size;
AssertBreakStmt(pModElf->Rel.cbStr == paShdrs[pModElf->Rel.iStrSh].sh_size, rc = VERR_IMAGE_TOO_BIG);
}
else if (paShdrs[i].sh_type == SHT_DYNSYM)
{
if (pModElf->Dyn.iSymSh != ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_LDRELF_MULTIPLE_SYMTABS,
"%s: Multiple dynamic symbol tabs! iSymSh=%d i=%d", pszLogName, pModElf->Dyn.iSymSh, i);
if (pModElf->Ehdr.e_type != ET_DYN && pModElf->Ehdr.e_type != ET_EXEC)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Unexpected SHT_DYNSYM (i=%d) for e_type=%d", pszLogName, i, pModElf->Ehdr.e_type);
pModElf->Dyn.iSymSh = i;
pModElf->Dyn.cSyms = (unsigned)(paShdrs[i].sh_size / sizeof(Elf_Sym));
AssertBreakStmt(pModElf->Dyn.cSyms == paShdrs[i].sh_size / sizeof(Elf_Sym), rc = VERR_IMAGE_TOO_BIG);
pModElf->Dyn.iStrSh = paShdrs[i].sh_link;
pModElf->Dyn.cbStr = (unsigned)paShdrs[pModElf->Dyn.iStrSh].sh_size;
AssertBreakStmt(pModElf->Dyn.cbStr == paShdrs[pModElf->Dyn.iStrSh].sh_size, rc = VERR_IMAGE_TOO_BIG);
}
/*
* We're also look for the dynamic section.
*/
else if (paShdrs[i].sh_type == SHT_DYNAMIC)
{
if (pModElf->iShDynamic != ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Multiple dynamic sections! iShDynamic=%d i=%d",
pszLogName, pModElf->iShDynamic, i);
if (pModElf->Ehdr.e_type != ET_DYN && pModElf->Ehdr.e_type != ET_EXEC)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Unexpected SHT_DYNAMIC (i=%d) for e_type=%d", pszLogName, i, pModElf->Ehdr.e_type);
if (paShdrs[i].sh_entsize != sizeof(Elf_Dyn))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: SHT_DYNAMIC (i=%d) sh_entsize=" FMT_ELF_XWORD ", expected %#zx",
pszLogName, i, paShdrs[i].sh_entsize, sizeof(Elf_Dyn));
pModElf->iShDynamic = i;
Elf_Xword const cDynamic = paShdrs[i].sh_size / sizeof(Elf_Dyn);
if (cDynamic > _64K || cDynamic < 2)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: SHT_DYNAMIC (i=%d) sh_size=" FMT_ELF_XWORD " is out of range (2..64K)",
pszLogName, i, paShdrs[i].sh_size);
pModElf->cDynamic = (unsigned)cDynamic;
}
/*
* Special checks for the section string table.
*/
if (i == pModElf->Ehdr.e_shstrndx)
{
if (paShdrs[i].sh_type != SHT_STRTAB)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Section header string table is not a SHT_STRTAB: %#x",
pszLogName, paShdrs[i].sh_type);
if (paShdrs[i].sh_size == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Section header string table is empty", pszLogName);
}
/*
* Kluge for the .data..percpu segment in 64-bit linux kernels.
*/
if (paShdrs[i].sh_flags & SHF_ALLOC)
{
if ( paShdrs[i].sh_addr == 0
&& paShdrs[i].sh_addr < uNextAddr)
{
Elf_Addr uAddr = RT_ALIGN_T(uNextAddr, paShdrs[i].sh_addralign, Elf_Addr);
Log(("RTLdrElf: Out of order section #%d; adjusting sh_addr from " FMT_ELF_ADDR " to " FMT_ELF_ADDR "\n",
i, paShdrs[i].sh_addr, uAddr));
paShdrs[i].sh_addr = uAddr;
}
uNextAddr = paShdrs[i].sh_addr + paShdrs[i].sh_size;
}
} /* for each section header */
return VINF_SUCCESS;
}
/**
* Process the section headers.
*
* @returns iprt status code.
* @param pModElf Pointer to the module structure.
* @param paShdrs The section headers.
* @param cbRawImage The size of the raw image.
* @param pszLogName The log name.
* @param pErrInfo Where to return extended error info. Optional.
*/
static int RTLDRELF_NAME(ValidateAndProcessDynamicInfo)(PRTLDRMODELF pModElf, uint64_t cbRawImage, uint32_t fFlags,
const char *pszLogName, PRTERRINFO pErrInfo)
{
/*
* Check preconditions.
*/
AssertReturn(pModElf->Ehdr.e_type == ET_DYN || pModElf->Ehdr.e_type == ET_EXEC, VERR_INTERNAL_ERROR_2);
if (pModElf->Ehdr.e_phnum <= 1 || pModElf->Ehdr.e_phnum >= _32K)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: e_phnum=%u is out of bounds (2..32K)", pszLogName, pModElf->Ehdr.e_phnum);
if (pModElf->iShDynamic == ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: no .dynamic section", pszLogName);
AssertReturn(pModElf->cDynamic > 1 && pModElf->cDynamic <= _64K, VERR_INTERNAL_ERROR_3);
/* ASSUME that the sections are ordered by address. That simplifies
validation code further down. */
AssertReturn(pModElf->Ehdr.e_shnum >= 2, VERR_INTERNAL_ERROR_4);
Elf_Shdr const *paShdrs = pModElf->paShdrs;
Elf_Addr uPrevEnd = paShdrs[1].sh_addr + paShdrs[1].sh_size;
for (unsigned i = 2; i < pModElf->Ehdr.e_shnum; i++)
if (paShdrs[i].sh_flags & SHF_ALLOC)
{
if (uPrevEnd > paShdrs[i].sh_addr)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: section %u is out of order: uPrevEnd=" FMT_ELF_ADDR " sh_addr=" FMT_ELF_ADDR,
pszLogName, i, uPrevEnd, paShdrs[i].sh_addr);
uPrevEnd = paShdrs[i].sh_addr + paShdrs[i].sh_size;
}
/* Must have string and symbol tables. */
if (pModElf->Dyn.iStrSh == ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: No dynamic string table section", pszLogName);
if (pModElf->Dyn.iSymSh == ~0U)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: No dynamic symbol table section", pszLogName);
/*
* Load the program headers.
*/
size_t const cbPhdrs = sizeof(pModElf->paPhdrs[0]) * pModElf->Ehdr.e_phnum;
Elf_Phdr *paPhdrs = (Elf_Phdr *)RTMemAllocZ(cbPhdrs);
pModElf->paPhdrs = paPhdrs;
AssertReturn(paPhdrs, VERR_NO_MEMORY);
int rc = pModElf->Core.pReader->pfnRead(pModElf->Core.pReader, paPhdrs, cbPhdrs, pModElf->Ehdr.e_phoff);
if (RT_FAILURE(rc))
return RTERRINFO_LOG_SET_F(pErrInfo, rc, "%s: pfnRead(,,%#zx, " FMT_ELF_OFF ") -> %Rrc",
pszLogName, cbPhdrs, pModElf->Ehdr.e_phoff, rc);
/*
* Validate them.
*/
unsigned cbPage = _4K; /** @todo generalize architecture specific stuff using its own code template header. */
switch (pModElf->Core.enmArch)
{
case RTLDRARCH_AMD64:
case RTLDRARCH_X86_32:
break;
default:
AssertFailedBreak(/** @todo page size for got.plt hacks */);
}
unsigned iLoad = 0;
unsigned iLoadShdr = 1; /* ASSUMES ordered (checked above). */
unsigned cDynamic = 0;
Elf_Addr cbImage = 0;
Elf_Addr uLinkAddress = ~(Elf_Addr)0;
for (unsigned i = 0; i < pModElf->Ehdr.e_phnum; i++)
{
const Elf_Phdr * const pPhdr = &paPhdrs[i];
Log3(("RTLdrELF: Program Header #%d:\n"
"RTLdrELF: p_type: " FMT_ELF_WORD " (%s)\n"
"RTLdrELF: p_flags: " FMT_ELF_WORD "\n"
"RTLdrELF: p_offset: " FMT_ELF_OFF "\n"
"RTLdrELF: p_vaddr: " FMT_ELF_ADDR "\n"
"RTLdrELF: p_paddr: " FMT_ELF_ADDR "\n"
"RTLdrELF: p_filesz: " FMT_ELF_XWORD "\n"
"RTLdrELF: p_memsz: " FMT_ELF_XWORD "\n"
"RTLdrELF: p_align: " FMT_ELF_XWORD "\n",
i,
pPhdr->p_type, rtldrElfGetPhdrType(pPhdr->p_type), pPhdr->p_flags, pPhdr->p_offset,
pPhdr->p_vaddr, pPhdr->p_paddr, pPhdr->p_filesz, pPhdr->p_memsz, pPhdr->p_align));
if (pPhdr->p_type == DT_NULL)
continue;
if ( pPhdr->p_filesz != 0
&& ( pPhdr->p_offset >= cbRawImage
|| pPhdr->p_filesz > cbRawImage
|| pPhdr->p_offset + pPhdr->p_filesz > cbRawImage))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u: bogus p_offset=" FMT_ELF_OFF " & p_filesz=" FMT_ELF_XWORD " (file size %#RX64)",
pszLogName, i, pPhdr->p_offset, pPhdr->p_filesz, cbRawImage);
if (pPhdr->p_flags & ~(Elf64_Word)(PF_X | PF_R | PF_W))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Prog Hdr #%u: bogus p_flags=" FMT_ELF_WORD,
pszLogName, i, pPhdr->p_flags);
if (!RT_IS_POWER_OF_TWO(pPhdr->p_align))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Prog Hdr #%u: bogus p_align=" FMT_ELF_XWORD,
pszLogName, i, pPhdr->p_align);
if ( pPhdr->p_align > 1
&& pPhdr->p_memsz > 0
&& pPhdr->p_filesz > 0
&& (pPhdr->p_offset & (pPhdr->p_align - 1)) != (pPhdr->p_vaddr & (pPhdr->p_align - 1)))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u: misaligned p_offset=" FMT_ELF_OFF " p_vaddr=" FMT_ELF_ADDR " p_align=" FMT_ELF_XWORD,
pszLogName, i, pPhdr->p_offset, pPhdr->p_vaddr, pPhdr->p_align);
/* Do some type specfic checks: */
switch (pPhdr->p_type)
{
case PT_LOAD:
{
if (pPhdr->p_memsz < pPhdr->p_filesz)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/LOAD#%u: bogus p_memsz=" FMT_ELF_XWORD " or p_filesz=" FMT_ELF_XWORD,
pszLogName, i, iLoad, pPhdr->p_memsz, pPhdr->p_filesz);
cbImage = pPhdr->p_vaddr + pPhdr->p_memsz;
if (iLoad == 0)
uLinkAddress = pPhdr->p_vaddr;
/* Find the corresponding sections, checking their addresses and
file offsets since the rest of the code is still section based
rather than using program headers as it should... */
Elf_Off off = pPhdr->p_offset;
Elf_Addr uAddr = pPhdr->p_vaddr;
Elf_Xword cbMem = pPhdr->p_memsz;
Elf_Xword cbFile = pPhdr->p_filesz;
while (cbMem > 0)
{
if (iLoadShdr < pModElf->Ehdr.e_shnum)
{ /* likely */ }
else if (iLoadShdr == pModElf->Ehdr.e_shnum)
{
/** @todo anything else to check here? */
iLoadShdr++;
break;
}
else
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/LOAD#%u: Out of sections at " FMT_ELF_ADDR " LB " FMT_ELF_XWORD,
pszLogName, i, iLoad, uAddr, cbMem);
if (!(paShdrs[iLoadShdr].sh_flags & SHF_ALLOC))
{
if ( paShdrs[iLoadShdr].sh_type != SHT_NOBITS
&& paShdrs[iLoadShdr].sh_size > 0
&& off < paShdrs[iLoadShdr].sh_offset + paShdrs[iLoadShdr].sh_size
&& paShdrs[iLoadShdr].sh_offset < off + cbMem)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/LOAD#%u: Overlaps with !SHF_ALLOC section at " FMT_ELF_OFF " LB " FMT_ELF_XWORD,
pszLogName, i, iLoad, paShdrs[iLoadShdr].sh_offset, paShdrs[iLoadShdr].sh_size);
pModElf->paShdrExtras[iLoadShdr].idxPhdr = UINT16_MAX;
iLoadShdr++;
continue;
}
if (uAddr != paShdrs[iLoadShdr].sh_addr)
{
/* Before the first section we expect headers to be loaded, so
that the file is simply mapped from file offset zero. */
if ( iLoadShdr == 1
&& iLoad == 0
&& paShdrs[1].sh_addr == paShdrs[1].sh_offset
&& cbFile >= paShdrs[1].sh_offset
&& cbMem >= paShdrs[1].sh_offset)
{
/* Modify paShdrs[0] to describe the gap. ".elf.headers" */
pModElf->iFirstSect = 0;
pModElf->paShdrs[0].sh_name = 0;
pModElf->paShdrs[0].sh_type = SHT_PROGBITS;
pModElf->paShdrs[0].sh_flags = SHF_ALLOC
| (pPhdr->p_flags & PF_W ? SHF_WRITE : 0)
| (pPhdr->p_flags & PF_X ? SHF_EXECINSTR : 0);
pModElf->paShdrs[0].sh_addr = uAddr;
pModElf->paShdrs[0].sh_offset = off;
pModElf->paShdrs[0].sh_size = paShdrs[1].sh_offset;
pModElf->paShdrs[0].sh_link = 0;
pModElf->paShdrs[0].sh_info = 0;
pModElf->paShdrs[0].sh_addralign = pPhdr->p_align;
pModElf->paShdrs[0].sh_entsize = 0;
*(Elf_Shdr *)pModElf->paOrgShdrs = pModElf->paShdrs[0]; /* (necessary for segment enumeration) */
uAddr += paShdrs[1].sh_offset;
cbMem -= paShdrs[1].sh_offset;
cbFile -= paShdrs[1].sh_offset;
off = paShdrs[1].sh_offset;
}
/* Alignment padding? Allow up to a page size. */
else if ( paShdrs[iLoadShdr].sh_addr > uAddr
&& paShdrs[iLoadShdr].sh_addr - uAddr
< RT_MAX(paShdrs[iLoadShdr].sh_addralign, cbPage /*got.plt hack*/))
{
Elf_Xword cbAlignPadding = paShdrs[iLoadShdr].sh_addr - uAddr;
if (cbAlignPadding >= cbMem)
break;
cbMem -= cbAlignPadding;
uAddr += cbAlignPadding;
if (cbFile > cbAlignPadding)
{
off += cbAlignPadding;
cbFile -= cbAlignPadding;
}
else
{
off += cbFile;
cbFile = 0;
}
}
}
if ( uAddr == paShdrs[iLoadShdr].sh_addr
&& cbMem >= paShdrs[iLoadShdr].sh_size
&& ( paShdrs[iLoadShdr].sh_type != SHT_NOBITS
? off == paShdrs[iLoadShdr].sh_offset
&& cbFile >= paShdrs[iLoadShdr].sh_size /* this might be too strict... */
: cbFile == 0) )
{
if (paShdrs[iLoadShdr].sh_type != SHT_NOBITS)
{
off += paShdrs[iLoadShdr].sh_size;
cbFile -= paShdrs[iLoadShdr].sh_size;
}
uAddr += paShdrs[iLoadShdr].sh_size;
cbMem -= paShdrs[iLoadShdr].sh_size;
}
else
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/LOAD#%u: Mismatch at " FMT_ELF_ADDR " LB " FMT_ELF_XWORD " (file " FMT_ELF_OFF " LB " FMT_ELF_XWORD ") with section #%u " FMT_ELF_ADDR " LB " FMT_ELF_XWORD " (file " FMT_ELF_OFF " sh_type=" FMT_ELF_WORD ")",
pszLogName, i, iLoad, uAddr, cbMem, off, cbFile,
iLoadShdr, paShdrs[iLoadShdr].sh_addr, paShdrs[iLoadShdr].sh_size,
paShdrs[iLoadShdr].sh_offset, paShdrs[iLoadShdr].sh_type);
pModElf->paShdrExtras[iLoadShdr].idxPhdr = iLoad;
iLoadShdr++;
} /* section loop */
iLoad++;
break;
}
case PT_DYNAMIC:
{
const Elf_Shdr *pShdr = &pModElf->paShdrs[pModElf->iShDynamic];
if (pPhdr->p_offset != pShdr->sh_offset)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/DYNAMIC: p_offset=" FMT_ELF_OFF " expected " FMT_ELF_OFF,
pszLogName, i, pPhdr->p_offset, pShdr->sh_offset);
if (RT_MAX(pPhdr->p_memsz, pPhdr->p_filesz) != pShdr->sh_size)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: Prog Hdr #%u/DYNAMIC: expected " FMT_ELF_XWORD " for RT_MAX(p_memsz=" FMT_ELF_XWORD ", p_filesz=" FMT_ELF_XWORD ")",
pszLogName, i, pShdr->sh_size, pPhdr->p_memsz, pPhdr->p_filesz);
cDynamic++;
break;
}
}
}
if (iLoad == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, rc, "%s: No PT_LOAD program headers", pszLogName);
if (cDynamic != 1)
return RTERRINFO_LOG_SET_F(pErrInfo, rc, "%s: No program header for the DYNAMIC section", pszLogName);
cbImage -= uLinkAddress;
pModElf->cbImage = (uint64_t)cbImage;
pModElf->LinkAddress = uLinkAddress;
AssertReturn(pModElf->cbImage == cbImage, VERR_INTERNAL_ERROR_5);
Log3(("RTLdrELF: LinkAddress=" FMT_ELF_ADDR " cbImage=" FMT_ELF_ADDR " (from PT_LOAD)\n", uLinkAddress, cbImage));
for (; iLoadShdr < pModElf->Ehdr.e_shnum; iLoadShdr++)
if ( !(paShdrs[iLoadShdr].sh_flags & SHF_ALLOC)
|| paShdrs[iLoadShdr].sh_size == 0)
pModElf->paShdrExtras[iLoadShdr].idxPhdr = UINT16_MAX;
else
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: No PT_LOAD for section #%u " FMT_ELF_ADDR " LB " FMT_ELF_XWORD " (file " FMT_ELF_OFF " sh_type=" FMT_ELF_WORD ")",
pszLogName, iLoadShdr, paShdrs[iLoadShdr].sh_addr, paShdrs[iLoadShdr].sh_size,
paShdrs[iLoadShdr].sh_offset, paShdrs[iLoadShdr].sh_type);
/*
* Load and validate the dynamic table. We have got / will get most of the
* info we need from the section table, so we must make sure this matches up.
*/
Log3(("RTLdrELF: Dynamic section - %u entries\n", pModElf->cDynamic));
size_t const cbDynamic = pModElf->cDynamic * sizeof(pModElf->paDynamic[0]);
Elf_Dyn * const paDynamic = (Elf_Dyn *)RTMemAlloc(cbDynamic);
AssertReturn(paDynamic, VERR_NO_MEMORY);
pModElf->paDynamic = paDynamic;
rc = pModElf->Core.pReader->pfnRead(pModElf->Core.pReader, paDynamic, cbDynamic, paShdrs[pModElf->iShDynamic].sh_offset);
if (RT_FAILURE(rc))
return RTERRINFO_LOG_SET_F(pErrInfo, rc, "%s: pfnRead(,,%#zx, " FMT_ELF_OFF ") -> %Rrc",
pszLogName, cbDynamic, paShdrs[pModElf->iShDynamic].sh_offset, rc);
for (uint32_t i = 0; i < pModElf->cDynamic; i++)
{
#define LOG_VALIDATE_PTR_RET(szName) do { \
Log3(("RTLdrELF: DT[%u]: %16s " FMT_ELF_ADDR "\n", i, szName, paDynamic[i].d_un.d_ptr)); \
if ((uint64_t)paDynamic[i].d_un.d_ptr - uLinkAddress < cbImage) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" szName ": Invalid address " FMT_ELF_ADDR " (valid range: " FMT_ELF_ADDR " LB " FMT_ELF_ADDR ")", \
pszLogName, i, paDynamic[i].d_un.d_ptr, uLinkAddress, cbImage); \
} while (0)
#define LOG_VALIDATE_PTR_VAL_RET(szName, uExpected) do { \
Log3(("RTLdrELF: DT[%u]: %16s " FMT_ELF_ADDR "\n", i, szName, (uint64_t)paDynamic[i].d_un.d_ptr)); \
if (paDynamic[i].d_un.d_ptr == (Elf_Addr)(uExpected)) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" szName ": " FMT_ELF_ADDR ", expected " FMT_ELF_ADDR, \
pszLogName, i, paDynamic[i].d_un.d_ptr, (Elf_Addr)(uExpected)); \
} while (0)
#define LOG_VALIDATE_STR_RET(szName) do { \
Log3(("RTLdrELF: DT[%u]: %16s %#RX64\n", i, szName, (uint64_t)paDynamic[i].d_un.d_val)); \
if ((uint64_t)paDynamic[i].d_un.d_val < pModElf->Dyn.cbStr) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" szName ": Invalid string table offset %#RX64 (max %#x)", \
pszLogName, i, (uint64_t)paDynamic[i].d_un.d_val, pModElf->Dyn.cbStr); \
} while (0)
#define LOG_VALIDATE_VAL_RET(szName, uExpected) do { \
Log3(("RTLdrELF: DT[%u]: %16s %#RX64\n", i, szName, (uint64_t)paDynamic[i].d_un.d_val)); \
if ((uint64_t)paDynamic[i].d_un.d_val == (uint64_t)(uExpected)) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" szName ": %#RX64, expected %#RX64", \
pszLogName, i, (uint64_t)paDynamic[i].d_un.d_val, (uint64_t)(uExpected)); \
} while (0)
#define SET_RELOC_TYPE_RET(a_szName, a_uType) do { \
if (pModElf->DynInfo.uRelocType == 0 || pModElf->DynInfo.uRelocType == (a_uType)) \
pModElf->DynInfo.uRelocType = (a_uType); \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" a_szName ": Mixing DT_RELA and DT_REL", pszLogName, i); \
} while (0)
#define SET_INFO_FIELD_RET(a_szName, a_Field, a_Value, a_UnsetValue, a_szFmt) do { \
if ((a_Field) == (a_UnsetValue) && (a_Value) != (a_UnsetValue)) \
(a_Field) = (a_Value); /* likely */ \
else if ((a_Field) != (a_UnsetValue)) \
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" a_szName ": Multiple entries (first value " a_szFmt ", second " a_szFmt ")", pszLogName, i, (a_Field), (a_Value)); \
else if ((a_Value) != (a_UnsetValue)) \
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" a_szName ": Unexpected value " a_szFmt, pszLogName, i, (a_Value)); \
} while (0)
#define FIND_MATCHING_SECTION_RET(a_szName, a_ExtraMatchExpr, a_idxShFieldToSet) do { \
unsigned iSh; \
for (iSh = 1; iSh < pModElf->Ehdr.e_shnum; iSh++) \
if ( paShdrs[iSh].sh_addr == paDynamic[i].d_un.d_ptr \
&& (a_ExtraMatchExpr)) \
{ \
(a_idxShFieldToSet) = iSh; \
if (pModElf->paShdrExtras[iSh].idxDt != UINT16_MAX) \
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, \
"%s: DT[%u]/" a_szName ": section #%u (" FMT_ELF_ADDR ") already referenced by DT[%u]", \
pszLogName, i, iSh, paShdrs[iSh].sh_addr, pModElf->paShdrExtras[iSh].idxDt); \
pModElf->paShdrExtras[iSh].idxDt = i; \
pModElf->paShdrExtras[iSh].uDtTag = (uint32_t)paDynamic[i].d_tag; \
break; \
} \
if (iSh < pModElf->Ehdr.e_shnum) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" a_szName ": No matching section for " FMT_ELF_ADDR, pszLogName, i, paDynamic[i].d_un.d_ptr); \
} while (0)
#define ONLY_FOR_DEBUG_OR_VALIDATION_RET(a_szName) do { \
if (fFlags & (RTLDR_O_FOR_DEBUG | RTLDR_O_FOR_VALIDATION)) { /* likely */ } \
else return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/" a_szName ": Not supported (" FMT_ELF_ADDR ")", pszLogName, i, paDynamic[i].d_un.d_ptr); \
} while (0)
#define LOG_NON_VALUE_ENTRY(a_szName) Log3(("RTLdrELF: DT[%u]: %16s (%#RX64)\n", i, a_szName, (uint64_t)paDynamic[i].d_un.d_val))
switch (paDynamic[i].d_tag)
{
case DT_NULL:
LOG_NON_VALUE_ENTRY("DT_NULL");
for (unsigned iNull = i + 1; iNull < pModElf->cDynamic; iNull++)
if (paDynamic[i].d_tag == DT_NULL) /* Not technically a bug, but let's try being extremely strict for now */
LOG_NON_VALUE_ENTRY("DT_NULL");
else if (!(fFlags & (RTLDR_O_FOR_DEBUG | RTLDR_O_FOR_VALIDATION)))
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: DT[%u]/DT_NULL: Dynamic section isn't zero padded (extra #%u of #%u)",
pszLogName, i, iNull - i, pModElf->cDynamic - i);
i = pModElf->cDynamic;
break;
case DT_NEEDED:
LOG_VALIDATE_STR_RET("DT_NEEDED");
break;
case DT_PLTRELSZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_PLTRELSZ", (uint64_t)paDynamic[i].d_un.d_val));
SET_INFO_FIELD_RET("DT_PLTRELSZ", pModElf->DynInfo.cbJmpRelocs, (Elf_Xword)paDynamic[i].d_un.d_val, 0, FMT_ELF_XWORD);
break;
case DT_PLTGOT:
LOG_VALIDATE_PTR_RET("DT_PLTGOT");
break;
case DT_HASH:
LOG_VALIDATE_PTR_RET("DT_HASH");
break;
case DT_STRTAB:
LOG_VALIDATE_PTR_VAL_RET("DT_STRTAB", paShdrs[pModElf->Dyn.iStrSh].sh_addr);
pModElf->paShdrExtras[pModElf->Dyn.iStrSh].idxDt = i;
pModElf->paShdrExtras[pModElf->Dyn.iSymSh].uDtTag = DT_STRTAB;
break;
case DT_SYMTAB:
LOG_VALIDATE_PTR_VAL_RET("DT_SYMTAB", paShdrs[pModElf->Dyn.iSymSh].sh_addr);
pModElf->paShdrExtras[pModElf->Dyn.iSymSh].idxDt = i;
pModElf->paShdrExtras[pModElf->Dyn.iSymSh].uDtTag = DT_SYMTAB;
break;
case DT_RELA:
LOG_VALIDATE_PTR_RET("DT_RELA");
SET_RELOC_TYPE_RET("DT_RELA", DT_RELA);
SET_INFO_FIELD_RET("DT_RELA", pModElf->DynInfo.uPtrRelocs, paDynamic[i].d_un.d_ptr, ~(Elf_Addr)0, FMT_ELF_ADDR);
FIND_MATCHING_SECTION_RET("DT_RELA", paShdrs[iSh].sh_type == SHT_RELA, pModElf->DynInfo.idxShRelocs);
break;
case DT_RELASZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_RELASZ", (uint64_t)paDynamic[i].d_un.d_val));
SET_RELOC_TYPE_RET("DT_RELASZ", DT_RELA);
SET_INFO_FIELD_RET("DT_RELASZ", pModElf->DynInfo.cbRelocs, (Elf_Xword)paDynamic[i].d_un.d_val, 0, FMT_ELF_XWORD);
break;
case DT_RELAENT:
LOG_VALIDATE_VAL_RET("DT_RELAENT", sizeof(Elf_Rela));
SET_RELOC_TYPE_RET("DT_RELAENT", DT_RELA);
SET_INFO_FIELD_RET("DT_RELAENT", pModElf->DynInfo.cbRelocEntry, (unsigned)sizeof(Elf_Rela), 0, "%u");
break;
case DT_STRSZ:
LOG_VALIDATE_VAL_RET("DT_STRSZ", pModElf->Dyn.cbStr);
break;
case DT_SYMENT:
LOG_VALIDATE_VAL_RET("DT_SYMENT", sizeof(Elf_Sym));
break;
case DT_INIT:
LOG_VALIDATE_PTR_RET("DT_INIT");
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_INIT");
break;
case DT_FINI:
LOG_VALIDATE_PTR_RET("DT_FINI");
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_FINI");
break;
case DT_SONAME:
LOG_VALIDATE_STR_RET("DT_SONAME");
break;
case DT_RPATH:
LOG_VALIDATE_STR_RET("DT_RPATH");
break;
case DT_SYMBOLIC:
LOG_NON_VALUE_ENTRY("DT_SYMBOLIC");
break;
case DT_REL:
LOG_VALIDATE_PTR_RET("DT_REL");
SET_RELOC_TYPE_RET("DT_REL", DT_REL);
SET_INFO_FIELD_RET("DT_REL", pModElf->DynInfo.uPtrRelocs, paDynamic[i].d_un.d_ptr, ~(Elf_Addr)0, FMT_ELF_ADDR);
FIND_MATCHING_SECTION_RET("DT_REL", paShdrs[iSh].sh_type == SHT_REL, pModElf->DynInfo.idxShRelocs);
break;
case DT_RELSZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_RELSZ", (uint64_t)paDynamic[i].d_un.d_val));
SET_RELOC_TYPE_RET("DT_RELSZ", DT_REL);
SET_INFO_FIELD_RET("DT_RELSZ", pModElf->DynInfo.cbRelocs, (Elf_Xword)paDynamic[i].d_un.d_val, 0, FMT_ELF_XWORD);
break;
case DT_RELENT:
LOG_VALIDATE_VAL_RET("DT_RELENT", sizeof(Elf_Rel));
SET_RELOC_TYPE_RET("DT_RELENT", DT_REL);
SET_INFO_FIELD_RET("DT_RELENT", pModElf->DynInfo.cbRelocEntry, (unsigned)sizeof(Elf_Rel), 0, "%u");
break;
case DT_PLTREL:
if (paDynamic[i].d_un.d_val != DT_RELA && paDynamic[i].d_un.d_val != DT_REL)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT[%u]/DT_PLTREL: Invalid value %#RX64",
pszLogName, i, (uint64_t)paDynamic[i].d_un.d_val);
Log3(("RTLdrELF: DT[%u]: %16s DT_REL%s\n", i, "DT_PLTREL", paDynamic[i].d_un.d_val == DT_RELA ? "A" : ""));
SET_INFO_FIELD_RET("DT_PLTREL", pModElf->DynInfo.uJmpRelocType, (unsigned)paDynamic[i].d_un.d_val, 0, "%u");
break;
case DT_DEBUG:
LOG_VALIDATE_PTR_RET("DT_DEBUG");
break;
case DT_TEXTREL:
LOG_NON_VALUE_ENTRY("DT_TEXTREL");
break;
case DT_JMPREL:
LOG_VALIDATE_PTR_RET("DT_JMPREL");
SET_INFO_FIELD_RET("DT_JMPREL", pModElf->DynInfo.uPtrJmpRelocs, paDynamic[i].d_un.d_ptr, ~(Elf_Addr)0, FMT_ELF_ADDR);
FIND_MATCHING_SECTION_RET("DT_JMPREL", 1, pModElf->DynInfo.idxShJmpRelocs);
break;
case DT_BIND_NOW:
LOG_NON_VALUE_ENTRY("DT_BIND_NOW");
break;
case DT_INIT_ARRAY:
LOG_VALIDATE_PTR_RET("DT_INIT_ARRAY");
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_INIT_ARRAY");
break;
case DT_FINI_ARRAY:
LOG_VALIDATE_PTR_RET("DT_FINI_ARRAY");
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_FINI_ARRAY");
break;
case DT_INIT_ARRAYSZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_INIT_ARRAYSZ", (uint64_t)paDynamic[i].d_un.d_val));
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_INIT_ARRAYSZ");
break;
case DT_FINI_ARRAYSZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_FINI_ARRAYSZ", (uint64_t)paDynamic[i].d_un.d_val));
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_FINI_ARRAYSZ");
break;
case DT_RUNPATH:
LOG_VALIDATE_STR_RET("DT_RUNPATH");
break;
case DT_FLAGS:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64\n", i, "DT_FLAGS", (uint64_t)paDynamic[i].d_un.d_val));
break;
case DT_PREINIT_ARRAY:
LOG_VALIDATE_PTR_RET("DT_PREINIT_ARRAY");
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_PREINIT_ARRAY");
break;
case DT_PREINIT_ARRAYSZ:
Log3(("RTLdrELF: DT[%u]: %16s %#RX64 bytes\n", i, "DT_PREINIT_ARRAYSZ", (uint64_t)paDynamic[i].d_un.d_val));
ONLY_FOR_DEBUG_OR_VALIDATION_RET("DT_PREINIT_ARRAYSZ");
break;
default:
if ( paDynamic[i].d_un.d_val < DT_ENCODING
|| (paDynamic[i].d_un.d_val & 1))
Log3(("RTLdrELF: DT[%u]: %#010RX64 %#RX64%s\n", i, (uint64_t)paDynamic[i].d_tag,
(uint64_t)paDynamic[i].d_un.d_val, paDynamic[i].d_un.d_val >= DT_ENCODING ? " (val)" : ""));
else
{
Log3(("RTLdrELF: DT[%u]: %#010RX64 " FMT_ELF_ADDR " (addr)\n",
i, (uint64_t)paDynamic[i].d_tag, paDynamic[i].d_un.d_ptr));
if ((uint64_t)paDynamic[i].d_un.d_ptr - uLinkAddress >= cbImage)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: DT[%u]/%#RX64: Invalid address " FMT_ELF_ADDR " (valid range: " FMT_ELF_ADDR " LB " FMT_ELF_ADDR ")",
pszLogName, i, (uint64_t)paDynamic[i].d_tag,
paDynamic[i].d_un.d_ptr, uLinkAddress, cbImage);
}
break;
}
#undef LOG_VALIDATE_VAL_RET
#undef LOG_VALIDATE_STR_RET
#undef LOG_VALIDATE_PTR_VAL_RET
#undef LOG_VALIDATE_PTR_RET
#undef SET_RELOC_TYPE_RET
#undef SET_INFO_FIELD_RET
#undef FIND_MATCHING_SECTION_RET
#undef ONLY_FOR_DEBUG_OR_VALIDATION_RET
}
/*
* Validate the relocation information we've gathered.
*/
Elf_Word uShTypeArch = SHT_RELA; /** @todo generalize architecture specific stuff using its own code template header. */
switch (pModElf->Core.enmArch)
{
case RTLDRARCH_AMD64:
break;
case RTLDRARCH_X86_32:
uShTypeArch = SHT_REL;
break;
default:
AssertFailedBreak(/** @todo page size for got.plt hacks */);
}
if (pModElf->DynInfo.uRelocType != 0)
{
const char * const pszModifier = pModElf->DynInfo.uRelocType == DT_RELA ? "A" : "";
if (pModElf->DynInfo.uPtrRelocs == ~(Elf_Addr)0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_REL%s", pszLogName, pszModifier);
if (pModElf->DynInfo.cbRelocs == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_REL%sSZ", pszLogName, pszModifier);
if (pModElf->DynInfo.cbRelocEntry == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_REL%sENT", pszLogName, pszModifier);
Elf_Shdr const *pShdrRelocs = &paShdrs[pModElf->DynInfo.idxShRelocs];
Elf_Word const uShType = pModElf->DynInfo.uJmpRelocType == DT_RELA ? SHT_RELA : SHT_REL;
if (pShdrRelocs->sh_type != uShType)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_REL%s* does not match section type: %u vs %u",
pszLogName, pszModifier, pShdrRelocs->sh_type, uShType);
if (pShdrRelocs->sh_size != pModElf->DynInfo.cbRelocs)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_REL%sSZ does not match section size: %u vs %u",
pszLogName, pszModifier, pShdrRelocs->sh_size, pModElf->DynInfo.cbRelocs);
if (uShType != uShTypeArch)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_REL%s* does not match architecture: %u, arch wants %u",
pszLogName, pszModifier, uShType, uShTypeArch);
}
if ( pModElf->DynInfo.uPtrJmpRelocs != ~(Elf_Addr)0
|| pModElf->DynInfo.cbJmpRelocs != 0
|| pModElf->DynInfo.uJmpRelocType != 0)
{
if (pModElf->DynInfo.uPtrJmpRelocs == ~(Elf_Addr)0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_JMPREL", pszLogName);
if (pModElf->DynInfo.cbJmpRelocs == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_PLTRELSZ", pszLogName);
if (pModElf->DynInfo.uJmpRelocType == 0)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: Missing DT_PLTREL", pszLogName);
Elf_Shdr const *pShdrRelocs = &paShdrs[pModElf->DynInfo.idxShJmpRelocs];
Elf_Word const uShType = pModElf->DynInfo.uJmpRelocType == DT_RELA ? SHT_RELA : SHT_REL;
if (pShdrRelocs->sh_type != uShType)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_PLTREL does not match section type: %u vs %u",
pszLogName, pShdrRelocs->sh_type, uShType);
if (pShdrRelocs->sh_size != pModElf->DynInfo.cbJmpRelocs)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_PLTRELSZ does not match section size: %u vs %u",
pszLogName, pShdrRelocs->sh_size, pModElf->DynInfo.cbJmpRelocs);
if (uShType != uShTypeArch)
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT, "%s: DT_PLTREL does not match architecture: %u, arch wants %u",
pszLogName, uShType, uShTypeArch);
}
/*
* Check that there aren't any other relocations hiding in the section table.
*/
for (uint32_t i = 1; i < pModElf->Ehdr.e_shnum; i++)
if ( (paShdrs[i].sh_type == SHT_REL || paShdrs[i].sh_type == SHT_RELA)
&& pModElf->paShdrExtras[i].uDtTag != DT_REL
&& pModElf->paShdrExtras[i].uDtTag != DT_RELA
&& pModElf->paShdrExtras[i].uDtTag != DT_JMPREL)
{
char szSecHdrNm[80];
return RTERRINFO_LOG_SET_F(pErrInfo, VERR_BAD_EXE_FORMAT,
"%s: section header #%u (%s type=" FMT_ELF_WORD " size=" FMT_ELF_XWORD ") contains relocations not referenced by the dynamic section",
pszLogName, i,
RTLDRELF_NAME(GetSHdrName)(pModElf, paShdrs[i].sh_name, szSecHdrNm, sizeof(szSecHdrNm)),
paShdrs[i].sh_type, paShdrs[i].sh_size);
}
return VINF_SUCCESS;
}
/**
* Opens an ELF image, fixed bitness.
*
* @returns iprt status code.
* @param pReader The loader reader instance which will provide the raw image bits.
* @param fFlags Reserved, MBZ.
* @param enmArch Architecture specifier.
* @param phLdrMod Where to store the handle.
* @param pErrInfo Where to return extended error info. Optional.
*/
static int RTLDRELF_NAME(Open)(PRTLDRREADER pReader, uint32_t fFlags, RTLDRARCH enmArch, PRTLDRMOD phLdrMod, PRTERRINFO pErrInfo)
{
const char *pszLogName = pReader->pfnLogName(pReader);
uint64_t cbRawImage = pReader->pfnSize(pReader);
RT_NOREF_PV(fFlags);
/*
* Create the loader module instance.
*/
PRTLDRMODELF pModElf = (PRTLDRMODELF)RTMemAllocZ(sizeof(*pModElf));
if (!pModElf)
return VERR_NO_MEMORY;
pModElf->Core.u32Magic = RTLDRMOD_MAGIC;
pModElf->Core.eState = LDR_STATE_INVALID;
pModElf->Core.pReader = pReader;
pModElf->Core.enmFormat = RTLDRFMT_ELF;
pModElf->Core.enmType = RTLDRTYPE_OBJECT;
pModElf->Core.enmEndian = RTLDRENDIAN_LITTLE;
#if ELF_MODE == 32
pModElf->Core.enmArch = RTLDRARCH_X86_32;
#else
pModElf->Core.enmArch = RTLDRARCH_AMD64;
#endif
//pModElf->pvBits = NULL;
//pModElf->Ehdr = {0};
//pModElf->paShdrs = NULL;
//pModElf->Rel.paSyms = NULL;
pModElf->Rel.iSymSh = ~0U;
//pModElf->Rel.cSyms = 0;
pModElf->Rel.iStrSh = ~0U;
//pModElf->Rel.cbStr = 0;
//pModElf->Rel.pStr = NULL;
//pModElf->Dyn.paSyms = NULL;
pModElf->Dyn.iSymSh = ~0U;
//pModElf->Dyn.cSyms = 0;
pModElf->Dyn.iStrSh = ~0U;
//pModElf->Dyn.cbStr = 0;
//pModElf->Dyn.pStr = NULL;
pModElf->iFirstSect = 1;
//pModElf->fShdrInOrder = false;
//pModElf->cbImage = 0;
pModElf->LinkAddress = ~(Elf_Addr)0;
//pModElf->cbShStr = 0;
//pModElf->pShStr = NULL;
//pModElf->iShEhFrame = 0;
//pModElf->iShEhFrameHdr= 0;
pModElf->iShDynamic = ~0U;
//pModElf->cDynamic = 0;
//pModElf->paDynamic = NULL;
//pModElf->paPhdrs = NULL;
pModElf->DynInfo.uPtrRelocs = ~(Elf_Addr)0;
//pModElf->DynInfo.cbRelocs = 0;
//pModElf->DynInfo.cbRelocEntry = 0;
//pModElf->DynInfo.uRelocType = 0;
//pModElf->DynInfo.idxShRelocs = 0;
pModElf->DynInfo.uPtrJmpRelocs = ~(Elf_Addr)0;
//pModElf->DynInfo.cbJmpRelocs = 0;
//pModElf->DynInfo.uJmpRelocType = 0;
//pModElf->DynInfo.idxShJmpRelocs = 0;
/*
* Read and validate the ELF header and match up the CPU architecture.
*/
int rc = pReader->pfnRead(pReader, &pModElf->Ehdr, sizeof(pModElf->Ehdr), 0);
if (RT_SUCCESS(rc))
{
RTLDRARCH enmArchImage = RTLDRARCH_INVALID; /* shut up gcc */
rc = RTLDRELF_NAME(ValidateElfHeader)(&pModElf->Ehdr, cbRawImage, pszLogName, &enmArchImage, pErrInfo);
if (RT_SUCCESS(rc))
{
if ( enmArch != RTLDRARCH_WHATEVER
&& enmArch != enmArchImage)
rc = VERR_LDR_ARCH_MISMATCH;
}
}
if (RT_SUCCESS(rc))
{
/*
* Read the section headers, keeping a prestine copy for the module
* introspection methods.
*/
size_t const cbShdrs = pModElf->Ehdr.e_shnum * sizeof(Elf_Shdr);
Elf_Shdr *paShdrs = (Elf_Shdr *)RTMemAlloc(cbShdrs * 2 + sizeof(RTLDRMODELFSHX) * pModElf->Ehdr.e_shnum);
if (paShdrs)
{
pModElf->paShdrs = paShdrs;
rc = pReader->pfnRead(pReader, paShdrs, cbShdrs, pModElf->Ehdr.e_shoff);
if (RT_SUCCESS(rc))
{
memcpy(&paShdrs[pModElf->Ehdr.e_shnum], paShdrs, cbShdrs);
pModElf->paOrgShdrs = &paShdrs[pModElf->Ehdr.e_shnum];
pModElf->paShdrExtras = (PRTLDRMODELFSHX)&pModElf->paOrgShdrs[pModElf->Ehdr.e_shnum];
memset(pModElf->paShdrExtras, 0xff, sizeof(RTLDRMODELFSHX) * pModElf->Ehdr.e_shnum);
pModElf->cbShStr = paShdrs[pModElf->Ehdr.e_shstrndx].sh_size;
/*
* Validate the section headers and find relevant sections.
*/
rc = RTLDRELF_NAME(ValidateAndProcessSectionHeaders)(pModElf, paShdrs, cbRawImage, pszLogName, pErrInfo);
/*
* Read validate and process program headers if ET_DYN or ET_EXEC.
*/
if (RT_SUCCESS(rc) && (pModElf->Ehdr.e_type == ET_DYN || pModElf->Ehdr.e_type == ET_EXEC))
rc = RTLDRELF_NAME(ValidateAndProcessDynamicInfo)(pModElf, cbRawImage, fFlags, pszLogName, pErrInfo);
/*
* Massage the section headers.
*/
if (RT_SUCCESS(rc))
{
if (pModElf->Ehdr.e_type == ET_REL)
{
/* Do allocations and figure the image size: */
pModElf->LinkAddress = 0;
for (unsigned i = 1; i < pModElf->Ehdr.e_shnum; i++)
if (paShdrs[i].sh_flags & SHF_ALLOC)
{
paShdrs[i].sh_addr = paShdrs[i].sh_addralign
? RT_ALIGN_T(pModElf->cbImage, paShdrs[i].sh_addralign, Elf_Addr)
: (Elf_Addr)pModElf->cbImage;
Elf_Addr EndAddr = paShdrs[i].sh_addr + paShdrs[i].sh_size;
if (pModElf->cbImage < EndAddr)
{
pModElf->cbImage = (size_t)EndAddr;
AssertMsgBreakStmt(pModElf->cbImage == EndAddr, (FMT_ELF_ADDR "\n", EndAddr), rc = VERR_IMAGE_TOO_BIG);
}
Log2(("RTLdrElf: %s: Assigned " FMT_ELF_ADDR " to section #%d\n", pszLogName, paShdrs[i].sh_addr, i));
}
}
else
{
/* Convert sh_addr to RVA: */
Assert(pModElf->LinkAddress != ~(Elf_Addr)0);
for (unsigned i = 0 /*!*/; i < pModElf->Ehdr.e_shnum; i++)
if (paShdrs[i].sh_flags & SHF_ALLOC)
paShdrs[i].sh_addr -= pModElf->LinkAddress;
}
}
/*
* Check if the sections are in order by address, as that will simplify
* enumeration and address translation.
*/
pModElf->fShdrInOrder = true;
Elf_Addr uEndAddr = 0;
for (unsigned i = pModElf->iFirstSect; i < pModElf->Ehdr.e_shnum; i++)
if (paShdrs[i].sh_flags & SHF_ALLOC)
{
if (uEndAddr <= paShdrs[i].sh_addr)
uEndAddr = paShdrs[i].sh_addr + paShdrs[i].sh_size;
else
{
pModElf->fShdrInOrder = false;
break;
}
}
Log2(("RTLdrElf: iSymSh=%u cSyms=%u iStrSh=%u cbStr=%u rc=%Rrc cbImage=%#zx LinkAddress=" FMT_ELF_ADDR " fShdrInOrder=%RTbool\n",
pModElf->Rel.iSymSh, pModElf->Rel.cSyms, pModElf->Rel.iStrSh, pModElf->Rel.cbStr, rc,
pModElf->cbImage, pModElf->LinkAddress, pModElf->fShdrInOrder));
if (RT_SUCCESS(rc))
{
pModElf->Core.pOps = &RTLDRELF_MID(s_rtldrElf,Ops);
pModElf->Core.eState = LDR_STATE_OPENED;
*phLdrMod = &pModElf->Core;
LogFlow(("%s: %s: returns VINF_SUCCESS *phLdrMod=%p\n", __FUNCTION__, pszLogName, *phLdrMod));
return VINF_SUCCESS;
}
}
RTMemFree(paShdrs);
}
else
rc = VERR_NO_MEMORY;
}
RTMemFree(pModElf);
LogFlow(("%s: returns %Rrc\n", __FUNCTION__, rc));
return rc;
}
/*******************************************************************************
* Cleanup Constants And Macros *
*******************************************************************************/
#undef RTLDRELF_NAME
#undef RTLDRELF_SUFF
#undef RTLDRELF_MID
#undef FMT_ELF_ADDR
#undef FMT_ELF_ADDR7
#undef FMT_ELF_HALF
#undef FMT_ELF_SHALF
#undef FMT_ELF_OFF
#undef FMT_ELF_SIZE
#undef FMT_ELF_SWORD
#undef FMT_ELF_WORD
#undef FMT_ELF_XWORD
#undef FMT_ELF_SXWORD
#undef Elf_Ehdr
#undef Elf_Phdr
#undef Elf_Shdr
#undef Elf_Sym
#undef Elf_Rel
#undef Elf_Rela
#undef Elf_Reloc
#undef Elf_Nhdr
#undef Elf_Dyn
#undef Elf_Addr
#undef Elf_Half
#undef Elf_Off
#undef Elf_Size
#undef Elf_Sword
#undef Elf_Word
#undef Elf_Xword
#undef Elf_Sxword
#undef RTLDRMODELF
#undef PRTLDRMODELF
#undef ELF_R_SYM
#undef ELF_R_TYPE
#undef ELF_R_INFO
#undef ELF_ST_BIND
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