[tpg/acess2.git] / Kernel / bin / elf.c

/*\r
 * Acess v0.1\r
 * ELF Executable Loader Code\r
 */\r
#define DEBUG   0\r
#include <acess.h>\r
#include <binary.h>\r
#include "elf.h"\r
\r
#define DEBUG_WARN      1\r
\r
// === PROTOTYPES ===\r
tBinary *Elf_Load(int fp);\r
tBinary *Elf_Load64(int fp, Elf64_Ehdr *hdr);\r
tBinary *Elf_Load32(int fp, Elf32_Ehdr *hdr);\r
 int    Elf_Relocate(void *Base);\r
 int    Elf_Relocate32(void *Base);\r
 int    Elf_GetSymbol(void *Base, const char *Name, Uint *ret);\r
 int    Elf_Int_DoRelocate(Uint r_info, Uint32 *ptr, Uint32 addend, Elf32_Sym *symtab, Uint base);\r
Uint    Elf_Int_HashString(const char *str);\r
\r
// === GLOBALS ===\r
tBinaryType     gELF_Info = {\r
        NULL,\r
        0x464C457F, 0xFFFFFFFF, // '\x7FELF'\r
        "ELF",\r
        Elf_Load, Elf_Relocate, Elf_GetSymbol\r
        };\r
\r
// === CODE ===\r
tBinary *Elf_Load(int fp)\r
{\r
        Elf64_Ehdr      hdr;\r
        \r
        // Read ELF Header\r
        VFS_Read(fp, sizeof(hdr), &hdr);\r
        \r
        // Check the file type\r
        if(hdr.e_ident[0] != 0x7F || hdr.e_ident[1] != 'E' || hdr.e_ident[2] != 'L' || hdr.e_ident[3] != 'F') {\r
                Log_Warning("ELF", "Non-ELF File was passed to the ELF loader");\r
                return NULL;\r
        }\r
\r
        switch(hdr.e_ident[4])  // EI_CLASS\r
        {\r
        case ELFCLASS32:\r
                return Elf_Load32(fp, (Elf32_Ehdr*)&hdr);\r
        case ELFCLASS64:\r
                return Elf_Load64(fp, &hdr);\r
        default:\r
                Log_Warning("ELF", "Unknown EI_CLASS value %i", hdr.e_ident[4]);\r
                return NULL;\r
        }\r
}\r
\r
tBinary *Elf_Load64(int FD, Elf64_Ehdr *Header)\r
{\r
        tBinary *ret;\r
        Elf64_Phdr      phtab[Header->e_phnum];\r
         int    nLoadSegments;\r
         int    i, j;\r
        \r
        // Sanity check\r
        if( Header->e_phoff == 0 )\r
        {\r
                Log_Warning("ELF", "No program header, panic!");\r
                return NULL;\r
        }\r
        if( Header->e_shentsize != sizeof(Elf64_Shdr) ) {\r
                Log_Warning("ELF", "Header gives shentsize as %i, my type is %i",\r
                        Header->e_shentsize, sizeof(Elf64_Shdr) );\r
        }\r
        if( Header->e_phentsize != sizeof(Elf64_Phdr) ) {\r
                Log_Warning("ELF", "Header gives phentsize as %i, my type is %i",\r
                        Header->e_phentsize, sizeof(Elf64_Phdr) );\r
        }\r
\r
        LOG("Header = {");\r
        LOG("  e_ident = %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x %02x",\r
                Header->e_ident[0], Header->e_ident[1], Header->e_ident[2], Header->e_ident[3],\r
                Header->e_ident[4], Header->e_ident[5], Header->e_ident[6], Header->e_ident[7],\r
                Header->e_ident[8], Header->e_ident[9], Header->e_ident[10], Header->e_ident[11],\r
                Header->e_ident[12], Header->e_ident[13], Header->e_ident[14], Header->e_ident[15]\r
                );\r
        LOG("  e_type = %i", Header->e_type);\r
        LOG("  e_machine = %i", Header->e_machine);\r
        LOG("  e_version = %i", Header->e_version);\r
        LOG("  e_entry   = 0x%llx", Header->e_entry);\r
        LOG("  e_phoff   = 0x%llx", Header->e_phoff);\r
        LOG("  e_shoff   = 0x%llx", Header->e_shoff);\r
        LOG("  e_flags   = 0x%x", Header->e_flags);\r
        LOG("  e_ehsize  = %i", Header->e_ehsize);\r
        LOG("  e_phentsize = %i", Header->e_phentsize);\r
        LOG("  e_phnum   = %i", Header->e_phnum);\r
        LOG("  e_shentsize = %i", Header->e_shentsize);\r
        LOG("  e_shnum   = %i", Header->e_shnum);\r
        LOG("  e_shstrndx = %i", Header->e_shstrndx);\r
        LOG("}");\r
\r
        // Load Program Header table\r
        VFS_Seek(FD, Header->e_phoff, SEEK_SET);\r
        VFS_Read(FD, sizeof(Elf64_Phdr)*Header->e_phnum, phtab);\r
\r
        // Count load segments\r
        nLoadSegments = 0;\r
        for( i = 0; i < Header->e_phnum; i ++ )\r
        {\r
                if( phtab[i].p_type != PT_LOAD )        continue ;\r
                nLoadSegments ++;\r
        }\r
        \r
        // Allocate Information Structure\r
        ret = malloc( sizeof(tBinary) + sizeof(tBinarySection)*nLoadSegments );\r
        // Fill Info Struct\r
        ret->Entry = Header->e_entry;\r
        ret->Base = -1;         // Set Base to maximum value\r
        ret->NumSections = nLoadSegments;\r
        ret->Interpreter = NULL;\r
\r
        j = 0;  // LoadSections[] index\r
        for( i = 0; i < Header->e_phnum; i ++ )\r
        {\r
                LOG("phtab[%i] = {", i);\r
                LOG("  .p_type   = %i", phtab[i].p_type);\r
                LOG("  .p_flags  = 0x%x", phtab[i].p_flags);\r
                LOG("  .p_offset = 0x%llx", phtab[i].p_offset);\r
                LOG("  .p_vaddr  = 0x%llx", phtab[i].p_vaddr);\r
                LOG("  .p_paddr  = 0x%llx", phtab[i].p_paddr);\r
                LOG("  .p_filesz = 0x%llx", phtab[i].p_filesz);\r
                LOG("  .p_memsz  = 0x%llx", phtab[i].p_memsz);\r
                LOG("  .p_align  = 0x%llx", phtab[i].p_align);\r
                LOG("}");\r
\r
                // Get Interpreter Name\r
                if( phtab[i].p_type == PT_INTERP )\r
                {\r
                        char *tmp;\r
                        if(ret->Interpreter)    continue;\r
                        tmp = malloc(phtab[i].p_filesz);\r
                        VFS_Seek(FD, phtab[i].p_offset, 1);\r
                        VFS_Read(FD, phtab[i].p_filesz, tmp);\r
                        ret->Interpreter = Binary_RegInterp(tmp);\r
                        LOG("Interpreter '%s'", tmp);\r
                        free(tmp);\r
                        continue;\r
                }\r
                \r
                if( phtab[i].p_type != PT_LOAD )        continue ;\r
                \r
                // Find the executable base\r
                if( phtab[i].p_vaddr < ret->Base )      ret->Base = phtab[i].p_vaddr;\r
\r
                ret->LoadSections[j].Offset = phtab[i].p_offset;\r
                ret->LoadSections[j].Virtual = phtab[i].p_vaddr;\r
                ret->LoadSections[j].FileSize = phtab[i].p_filesz;\r
                ret->LoadSections[j].MemSize = phtab[i].p_memsz;\r
                \r
                ret->LoadSections[j].Flags = 0;\r
                if( !(phtab[i].p_flags & PF_W) )\r
                        ret->LoadSections[j].Flags |= BIN_SECTFLAG_RO;\r
                if( phtab[i].p_flags & PF_X )\r
                        ret->LoadSections[j].Flags |= BIN_SECTFLAG_EXEC;\r
                j ++;\r
        }\r
\r
        return ret;\r
}\r
\r
tBinary *Elf_Load32(int FD, Elf32_Ehdr *Header)\r
{\r
        tBinary *ret;\r
        Elf32_Phdr      *phtab;\r
         int    i, j;\r
         int    iLoadCount;\r
\r
        ENTER("xFD", FD);\r
\r
        // Check architecture with current CPU\r
        // - TODO: Support kernel level emulation\r
        #if ARCH_IS_x86\r
        if( Header->machine != EM_386 )\r
        {\r
                Log_Warning("ELF", "Unknown architecure on ELF-32");\r
                LEAVE_RET('n');\r
                return NULL;\r
        }\r
        #endif\r
\r
        // Check for a program header\r
        if(Header->phoff == 0) {\r
                #if DEBUG_WARN\r
                Log_Warning("ELF", "File does not contain a program header (phoff == 0)");\r
                #endif\r
                LEAVE('n');\r
                return NULL;\r
        }\r
        \r
        // Read Program Header Table\r
        phtab = malloc( sizeof(Elf32_Phdr) * Header->phentcount );\r
        if( !phtab ) {\r
                LEAVE('n');\r
                return NULL;\r
        }\r
        LOG("hdr.phoff = 0x%08x", Header->phoff);\r
        VFS_Seek(FD, Header->phoff, SEEK_SET);\r
        VFS_Read(FD, sizeof(Elf32_Phdr)*Header->phentcount, phtab);\r
        \r
        // Count Pages\r
        iLoadCount = 0;\r
        LOG("Header->phentcount = %i", Header->phentcount);\r
        for( i = 0; i < Header->phentcount; i++ )\r
        {\r
                // Ignore Non-LOAD types\r
                if(phtab[i].Type != PT_LOAD)\r
                        continue;\r
                iLoadCount ++;\r
                LOG("phtab[%i] = {VAddr:0x%x, MemSize:0x%x}", i, phtab[i].VAddr, phtab[i].MemSize);\r
        }\r
        \r
        LOG("iLoadCount = %i", iLoadCount);\r
        \r
        // Allocate Information Structure\r
        ret = malloc( sizeof(tBinary) + sizeof(tBinarySection)*iLoadCount );\r
        // Fill Info Struct\r
        ret->Entry = Header->entrypoint;\r
        ret->Base = -1;         // Set Base to maximum value\r
        ret->NumSections = iLoadCount;\r
        ret->Interpreter = NULL;\r
        \r
        // Load Pages\r
        j = 0;\r
        for( i = 0; i < Header->phentcount; i++ )\r
        {\r
                //LOG("phtab[%i].Type = 0x%x", i, phtab[i].Type);\r
                LOG("phtab[%i] = {", i);\r
                LOG(" .Type = 0x%08x", phtab[i].Type);\r
                LOG(" .Offset = 0x%08x", phtab[i].Offset);\r
                LOG(" .VAddr = 0x%08x", phtab[i].VAddr);\r
                LOG(" .PAddr = 0x%08x", phtab[i].PAddr);\r
                LOG(" .FileSize = 0x%08x", phtab[i].FileSize);\r
                LOG(" .MemSize = 0x%08x", phtab[i].MemSize);\r
                LOG(" .Flags = 0x%08x", phtab[i].Flags);\r
                LOG(" .Align = 0x%08x", phtab[i].Align);\r
                LOG(" }");\r
                // Get Interpreter Name\r
                if( phtab[i].Type == PT_INTERP )\r
                {\r
                        char *tmp;\r
                        if(ret->Interpreter)    continue;\r
                        tmp = malloc(phtab[i].FileSize);\r
                        VFS_Seek(FD, phtab[i].Offset, 1);\r
                        VFS_Read(FD, phtab[i].FileSize, tmp);\r
                        ret->Interpreter = Binary_RegInterp(tmp);\r
                        LOG("Interpreter '%s'", tmp);\r
                        free(tmp);\r
                        continue;\r
                }\r
                // Ignore non-LOAD types\r
                if(phtab[i].Type != PT_LOAD)    continue;\r
                \r
                // Find Base\r
                if(phtab[i].VAddr < ret->Base)  ret->Base = phtab[i].VAddr;\r
                \r
                LOG("phtab[%i] = {VAddr:0x%x,Offset:0x%x,FileSize:0x%x}",\r
                        i, phtab[i].VAddr, phtab[i].Offset, phtab[i].FileSize);\r
                \r
                ret->LoadSections[j].Offset = phtab[i].Offset;\r
                ret->LoadSections[j].FileSize = phtab[i].FileSize;\r
                ret->LoadSections[j].Virtual = phtab[i].VAddr;\r
                ret->LoadSections[j].MemSize = phtab[i].MemSize;\r
                ret->LoadSections[j].Flags = 0;\r
                if( !(phtab[i].Flags & PF_W) )\r
                        ret->LoadSections[j].Flags |= BIN_SECTFLAG_RO;\r
                if( phtab[i].Flags & PF_X )\r
                        ret->LoadSections[j].Flags |= BIN_SECTFLAG_EXEC;\r
                j ++;\r
        }\r
        \r
        // Clean Up\r
        free(phtab);\r
        // Return\r
        LEAVE('p', ret);\r
        return ret;\r
}\r
\r
// --- ELF RELOCATION ---\r
int Elf_Relocate(void *Base)\r
{\r
        Elf64_Ehdr      *hdr = Base;\r
        \r
        switch( hdr->e_ident[EI_CLASS] )\r
        {\r
        case ELFCLASS32:\r
                return Elf_Relocate32(Base);\r
        case ELFCLASS64:\r
                return 0;\r
        default:\r
                return 1;\r
        }\r
}\r
\r
\r
/**\r
 * \brief Relocates a loaded ELF Executable\r
 */\r
int Elf_Relocate32(void *Base)\r
{\r
        Elf32_Ehdr      *hdr = Base;\r
        Elf32_Phdr      *phtab;\r
         int    i, j;   // Counters\r
        char    *libPath;\r
        Uint    iRealBase = -1;\r
        Uint    iBaseDiff;\r
         int    iSegmentCount;\r
         int    iSymCount = 0;\r
        Elf32_Rel       *rel = NULL;\r
        Elf32_Rela      *rela = NULL;\r
        Uint32  *pltgot = NULL;\r
        void    *plt = NULL;\r
        Uint32  *ptr;\r
         int    relSz=0, relEntSz=8;\r
         int    relaSz=0, relaEntSz=8;\r
         int    pltSz=0, pltType=0;\r
        Elf32_Dyn       *dynamicTab = NULL;     // Dynamic Table Pointer\r
        char    *dynstrtab = NULL;      // .dynamic String Table\r
        Elf32_Sym       *dynsymtab = NULL;\r
         int    bFailed = 0;\r
        \r
        ENTER("pBase", Base);\r
        \r
        // Parse Program Header to get Dynamic Table\r
        phtab = (void *)( (tVAddr)Base + hdr->phoff );\r
        iSegmentCount = hdr->phentcount;\r
        for(i = 0; i < iSegmentCount; i ++ )\r
        {\r
                // Determine linked base address\r
                if(phtab[i].Type == PT_LOAD && iRealBase > phtab[i].VAddr)\r
                        iRealBase = phtab[i].VAddr;\r
                \r
                // Find Dynamic Section\r
                if(phtab[i].Type == PT_DYNAMIC) {\r
                        if(dynamicTab) {\r
                                Log_Warning("ELF", "Elf_Relocate - Multiple PT_DYNAMIC segments\n");\r
                                continue;\r
                        }\r
                        dynamicTab = (void *) (tVAddr) phtab[i].VAddr;\r
                        j = i;  // Save Dynamic Table ID\r
                        break;\r
                }\r
        }\r
        \r
        // Check if a PT_DYNAMIC segement was found\r
        if(!dynamicTab) {\r
                Log_Warning("ELF", "Elf_Relocate: No PT_DYNAMIC segment in image, returning\n");\r
                LEAVE('x', 0);\r
                return 0;\r
        }\r
        \r
        // Page Align real base\r
        iRealBase &= ~0xFFF;\r
        \r
        // Adjust "Real" Base\r
        iBaseDiff = (Uint)Base - iRealBase;\r
        // Adjust Dynamic Table\r
        dynamicTab = (void *) ((Uint)dynamicTab + iBaseDiff);\r
        \r
        // === Get Symbol table and String Table ===\r
        for( j = 0; dynamicTab[j].d_tag != DT_NULL; j++)\r
        {\r
                switch(dynamicTab[j].d_tag)\r
                {\r
                // --- Symbol Table ---\r
                case DT_SYMTAB:\r
                        dynamicTab[j].d_val += iBaseDiff;\r
                        dynsymtab = (void*) (tVAddr) dynamicTab[j].d_val;\r
                        hdr->misc.SymTable = dynamicTab[j].d_val;       // Saved in unused bytes of ident\r
                        break;\r
                \r
                // --- String Table ---\r
                case DT_STRTAB:\r
                        dynamicTab[j].d_val += iBaseDiff;\r
                        dynstrtab = (void*) (tVAddr) dynamicTab[j].d_val;\r
                        break;\r
                \r
                // --- Hash Table --\r
                case DT_HASH:\r
                        dynamicTab[j].d_val += iBaseDiff;\r
                        iSymCount = ((Uint*)((tVAddr)dynamicTab[j].d_val))[1];\r
                        hdr->misc.HashTable = dynamicTab[j].d_val;      // Saved in unused bytes of ident\r
                        break;\r
                }\r
        }\r
\r
        if( !dynsymtab && iSymCount > 0 ) {\r
                Log_Warning("ELF", "Elf_Relocate: No Dynamic symbol table, but count >0");\r
                return 0;\r
        }\r
\r
        // Alter Symbols to true base\r
        for(i = 0; i < iSymCount; i ++)\r
        {\r
                dynsymtab[i].value += iBaseDiff;\r
                dynsymtab[i].nameOfs += (Uint)dynstrtab;\r
                //LOG("Sym '%s' = 0x%x (relocated)\n", dynsymtab[i].name, dynsymtab[i].value);\r
        }\r
        \r
        // === Add to loaded list (can be imported now) ===\r
        //Binary_AddLoaded( (Uint)Base );\r
\r
        // === Parse Relocation Data ===\r
        for( j = 0; dynamicTab[j].d_tag != DT_NULL; j++)\r
        {\r
                switch(dynamicTab[j].d_tag)\r
                {\r
                // --- Shared Library Name ---\r
                case DT_SONAME:\r
                        LOG(".so Name '%s'\n", dynstrtab+dynamicTab[j].d_val);\r
                        break;\r
                // --- Needed Library ---\r
                case DT_NEEDED:\r
                        libPath = dynstrtab + dynamicTab[j].d_val;\r
                        Log_Notice("ELF", "%p - Required Library '%s' (Ignored in kernel mode)\n", Base, libPath);\r
                        break;\r
                // --- PLT/GOT ---\r
                case DT_PLTGOT: pltgot = (void*)(iBaseDiff+dynamicTab[j].d_val);        break;\r
                case DT_JMPREL: plt = (void*)(iBaseDiff+dynamicTab[j].d_val);   break;\r
                case DT_PLTREL: pltType = dynamicTab[j].d_val;  break;\r
                case DT_PLTRELSZ:       pltSz = dynamicTab[j].d_val;    break;\r
                \r
                // --- Relocation ---\r
                case DT_REL:    rel = (void*)(iBaseDiff + dynamicTab[j].d_val); break;\r
                case DT_RELSZ:  relSz = dynamicTab[j].d_val;    break;\r
                case DT_RELENT: relEntSz = dynamicTab[j].d_val; break;\r
                \r
                case DT_RELA:   rela = (void*)(iBaseDiff + dynamicTab[j].d_val);        break;\r
                case DT_RELASZ: relaSz = dynamicTab[j].d_val;   break;\r
                case DT_RELAENT:        relaEntSz = dynamicTab[j].d_val;        break;\r
                }\r
        }\r
        \r
        // Parse Relocation Entries\r
        if(rel && relSz)\r
        {\r
                j = relSz / relEntSz;\r
                for( i = 0; i < j; i++ )\r
                {\r
                        ptr = (void*)(iBaseDiff + rel[i].r_offset);\r
                        if( !Elf_Int_DoRelocate(rel[i].r_info, ptr, *ptr, dynsymtab, (Uint)Base) ) {\r
                                bFailed = 1;\r
                        }\r
                }\r
        }\r
        // Parse Relocation Entries\r
        if(rela && relaSz)\r
        {\r
                j = relaSz / relaEntSz;\r
                for( i = 0; i < j; i++ )\r
                {\r
                        ptr = (void*)(iBaseDiff + rela[i].r_offset);\r
                        if( !Elf_Int_DoRelocate(rela[i].r_info, ptr, rela[i].r_addend, dynsymtab, (Uint)Base) ) {\r
                                bFailed = 1;\r
                        }\r
                }\r
        }\r
        \r
        // === Process PLT (Procedure Linkage Table) ===\r
        if(plt && pltSz)\r
        {\r
                if(pltType == DT_REL)\r
                {\r
                        Elf32_Rel       *pltRel = plt;\r
                        j = pltSz / sizeof(Elf32_Rel);\r
                        LOG("PLT Rel - plt = %p, pltSz = %i (%i ents)", plt, pltSz, j);\r
                        for(i = 0; i < j; i++)\r
                        {\r
                                ptr = (void*)(iBaseDiff + pltRel[i].r_offset);\r
                                if( !Elf_Int_DoRelocate(pltRel[i].r_info, ptr, *ptr, dynsymtab, (Uint)Base) ) {\r
                                        bFailed = 1;\r
                                }\r
                        }\r
                }\r
                else\r
                {\r
                        Elf32_Rela      *pltRela = plt;\r
                        j = pltSz / sizeof(Elf32_Rela);\r
                        LOG("PLT RelA - plt = %p, pltSz = %i (%i ents)", plt, pltSz, j);\r
                        for(i=0;i<j;i++)\r
                        {\r
                                ptr = (void*)(iBaseDiff + pltRela[i].r_offset);\r
                                if( !Elf_Int_DoRelocate(pltRela[i].r_info, ptr, pltRela[i].r_addend, dynsymtab, (Uint)Base) ) {\r
                                        bFailed = 1;\r
                                }\r
                        }\r
                }\r
        }\r
        \r
        if(bFailed) {\r
                LEAVE('i', 0);\r
                return 0;\r
        }\r
        \r
        LEAVE('x', 1);\r
        return 1;\r
}\r
\r
/**\r
 * \fn void Elf_Int_DoRelocate(Uint r_info, Uint32 *ptr, Uint32 addend, Elf32_Sym *symtab, Uint base)\r
 * \brief Performs a relocation\r
 * \param r_info        Field from relocation entry\r
 * \param ptr   Pointer to location of relocation\r
 * \param addend        Value to add to symbol\r
 * \param symtab        Symbol Table\r
 * \param base  Base of loaded binary\r
 */\r
int Elf_Int_DoRelocate(Uint r_info, Uint32 *ptr, Uint32 addend, Elf32_Sym *symtab, Uint base)\r
{\r
        Uint    val;\r
         int    type = ELF32_R_TYPE(r_info);\r
         int    sym = ELF32_R_SYM(r_info);\r
        char    *sSymName = symtab[sym].name;\r
        \r
        //LogF("Elf_Int_DoRelocate: (r_info=0x%x, ptr=0x%x, addend=0x%x, .., base=0x%x)\n",\r
        //      r_info, ptr, addend, base);\r
        \r
        switch( type )\r
        {\r
        // Standard 32 Bit Relocation (S+A)\r
        case R_386_32:\r
                if( !Elf_GetSymbol((void*)base, sSymName, &val) )       // Search this binary first\r
                        if( !Binary_GetSymbol( sSymName, &val ) )\r
                                return 0;\r
                LOG("%08x R_386_32 *0x%x += 0x%x('%s')", r_info, ptr, val, sSymName);\r
                *ptr = val + addend;\r
                break;\r
                \r
        // 32 Bit Relocation wrt. Offset (S+A-P)\r
        case R_386_PC32:\r
                if( !Elf_GetSymbol( (void*)base, sSymName, &val ) )\r
                        if( !Binary_GetSymbol( sSymName, &val ) )\r
                                return 0;\r
                LOG("%08x R_386_PC32 *0x%x = 0x%x + 0x%x('%s') - 0x%x", r_info, ptr, *ptr, val, sSymName, (Uint)ptr );\r
                // TODO: Check if it needs the true value of ptr or the compiled value\r
                // NOTE: Testing using true value\r
                *ptr = val + addend - (Uint)ptr;\r
                break;\r
\r
        // Absolute Value of a symbol (S)\r
        case R_386_GLOB_DAT:\r
                if( !Elf_GetSymbol( (void*)base, sSymName, &val ) )\r
                        if( !Binary_GetSymbol( sSymName, &val ) )\r
                                return 0;\r
                LOG("%08x R_386_GLOB_DAT *0x%x = 0x%x (%s)", r_info, ptr, val, sSymName);\r
                *ptr = val;\r
                break;\r
        \r
        // Absolute Value of a symbol (S)\r
        case R_386_JMP_SLOT:\r
                if( !Elf_GetSymbol( (void*)base, sSymName, &val ) )\r
                        if( !Binary_GetSymbol( sSymName, &val ) )\r
                                return 0;\r
                LOG("%08x R_386_JMP_SLOT *0x%x = 0x%x (%s)", r_info, ptr, val, sSymName);\r
                *ptr = val;\r
                break;\r
\r
        // Base Address (B+A)\r
        case R_386_RELATIVE:\r
                LOG("%08x R_386_RELATIVE *0x%x = 0x%x + 0x%x", r_info, ptr, base, addend);\r
                *ptr = base + addend;\r
                break;\r
                \r
        default:\r
                LOG("Rel 0x%x: 0x%x,%i", ptr, sym, type);\r
                break;\r
        }\r
        return 1;\r
}\r
\r
/**\r
 * \fn int Elf_GetSymbol(void *Base, const char *name, Uint *ret)\r
 * \brief Get a symbol from the loaded binary\r
 */\r
int Elf_GetSymbol(void *Base, const char *Name, Uint *ret)\r
{\r
        Elf32_Ehdr      *hdr = (void*)Base;\r
        Elf32_Sym       *symtab;\r
         int    nbuckets = 0;\r
         int    iSymCount = 0;\r
         int    i;\r
        Uint    *pBuckets;\r
        Uint    *pChains;\r
        Uint    iNameHash;\r
\r
        if(!Base)       return 0;\r
\r
        pBuckets = (void *) hdr->misc.HashTable;\r
        symtab = (void *) hdr->misc.SymTable;\r
        \r
        nbuckets = pBuckets[0];\r
        iSymCount = pBuckets[1];\r
        pBuckets = &pBuckets[2];\r
        pChains = &pBuckets[ nbuckets ];\r
        \r
        // Get hash\r
        iNameHash = Elf_Int_HashString(Name);\r
        iNameHash %= nbuckets;\r
\r
        // Check Bucket\r
        i = pBuckets[ iNameHash ];\r
        if(symtab[i].shndx != SHN_UNDEF && strcmp(symtab[i].name, Name) == 0) {\r
                if(ret) *ret = symtab[ i ].value;\r
                return 1;\r
        }\r
        \r
        // Walk Chain\r
        while(pChains[i] != STN_UNDEF)\r
        {\r
                i = pChains[i];\r
                if(symtab[i].shndx != SHN_UNDEF && strcmp(symtab[ i ].name, Name) == 0) {\r
                        if(ret) *ret = symtab[ i ].value;\r
                        return 1;\r
                }\r
        }\r
        return 0;\r
}\r
\r
/**\r
 * \fn Uint Elf_Int_HashString(char *str)\r
 * \brief Hash a string in the ELF format\r
 * \param str   String to hash\r
 * \return Hash value\r
 */\r
Uint Elf_Int_HashString(const char *str)\r
{\r
        Uint    h = 0, g;\r
        while(*str)\r
        {\r
                h = (h << 4) + *str++;\r
                if( (g = h & 0xf0000000) )\r
                        h ^= g >> 24;\r
                h &= ~g;\r
        }\r
        return h;\r
}\r