diff options
Diffstat (limited to 'lib/mlibc/options/rtdl/generic/main.cpp')
-rw-r--r-- | lib/mlibc/options/rtdl/generic/main.cpp | 844 |
1 files changed, 844 insertions, 0 deletions
diff --git a/lib/mlibc/options/rtdl/generic/main.cpp b/lib/mlibc/options/rtdl/generic/main.cpp new file mode 100644 index 0000000..3cff1e4 --- /dev/null +++ b/lib/mlibc/options/rtdl/generic/main.cpp @@ -0,0 +1,844 @@ + +#include <elf.h> +#include <link.h> + +#include <frg/manual_box.hpp> +#include <frg/small_vector.hpp> + +#include <abi-bits/auxv.h> +#include <mlibc/debug.hpp> +#include <mlibc/rtdl-sysdeps.hpp> +#include <mlibc/rtdl-config.hpp> +#include <mlibc/rtdl-abi.hpp> +#include <mlibc/stack_protector.hpp> +#include <internal-config.h> +#include <abi-bits/auxv.h> + +#include "elf.hpp" +#include "linker.hpp" + +#if __MLIBC_POSIX_OPTION +#include <dlfcn.h> +#endif + +#define HIDDEN __attribute__((__visibility__("hidden"))) +#define EXPORT __attribute__((__visibility__("default"))) + +static constexpr bool logEntryExit = false; +static constexpr bool logStartup = false; +static constexpr bool logDlCalls = false; + +#ifndef MLIBC_STATIC_BUILD +extern HIDDEN void *_GLOBAL_OFFSET_TABLE_[]; +extern HIDDEN elf_dyn _DYNAMIC[]; +#endif + +namespace mlibc { + // Declared in options/internal/mlibc/tcb.hpp. + bool tcb_available_flag = false; +} + +mlibc::RtdlConfig rtdlConfig; + +bool ldShowAuxv = false; + +uintptr_t *entryStack; +frg::manual_box<ObjectRepository> initialRepository; +frg::manual_box<Scope> globalScope; + +frg::manual_box<RuntimeTlsMap> runtimeTlsMap; + +// We use a small vector of size 4 to avoid memory allocation for the default library paths +frg::manual_box<frg::small_vector<frg::string_view, 4, MemoryAllocator>> libraryPaths; + +frg::manual_box<frg::vector<frg::string_view, MemoryAllocator>> preloads; + +static SharedObject *executableSO; +extern HIDDEN char __ehdr_start[]; + +// Global debug interface variable +DebugInterface globalDebugInterface; + +#ifndef MLIBC_STATIC_BUILD + +// Use a PC-relative instruction sequence to find our runtime load address. +uintptr_t getLdsoBase() { +#if defined(__x86_64__) || defined(__i386__) || defined(__aarch64__) + // On x86_64, the first GOT entry holds the link-time address of _DYNAMIC. + // TODO: This isn't guaranteed on AArch64, so this might fail with some linkers. + auto linktime_dynamic = reinterpret_cast<uintptr_t>(_GLOBAL_OFFSET_TABLE_[0]); + auto runtime_dynamic = reinterpret_cast<uintptr_t>(_DYNAMIC); + return runtime_dynamic - linktime_dynamic; +#elif defined(__riscv) + return reinterpret_cast<uintptr_t>(&__ehdr_start); +#endif +} + +// Relocates the dynamic linker (i.e. this DSO) itself. +// Assumptions: +// - There are no references to external symbols. +// Note that this code is fragile in the sense that it must not contain relocations itself. +// TODO: Use tooling to verify this at compile time. +extern "C" void relocateSelf() { + size_t rela_offset = 0; + size_t rela_size = 0; + size_t rel_offset = 0; + size_t rel_size = 0; + size_t relr_offset = 0; + size_t relr_size = 0; + for(size_t i = 0; _DYNAMIC[i].d_tag != DT_NULL; i++) { + auto ent = &_DYNAMIC[i]; + switch(ent->d_tag) { + case DT_REL: rel_offset = ent->d_un.d_ptr; break; + case DT_RELSZ: rel_size = ent->d_un.d_val; break; + case DT_RELA: rela_offset = ent->d_un.d_ptr; break; + case DT_RELASZ: rela_size = ent->d_un.d_val; break; + case DT_RELR: relr_offset = ent->d_un.d_ptr; break; + case DT_RELRSZ: relr_size = ent->d_un.d_val; break; + } + } + + auto ldso_base = getLdsoBase(); + + __ensure((rel_offset != 0) ^ (rela_offset != 0)); + + for(size_t disp = 0; disp < rela_size; disp += sizeof(elf_rela)) { + auto reloc = reinterpret_cast<elf_rela *>(ldso_base + rela_offset + disp); + + auto type = ELF_R_TYPE(reloc->r_info); + if(ELF_R_SYM(reloc->r_info)) + __builtin_trap(); + + auto p = reinterpret_cast<uint64_t *>(ldso_base + reloc->r_offset); + switch(type) { + case R_RELATIVE: + *p = ldso_base + reloc->r_addend; + break; + default: + __builtin_trap(); + } + } + + for(size_t disp = 0; disp < rel_size; disp += sizeof(elf_rel)) { + auto reloc = reinterpret_cast<elf_rel *>(ldso_base + rel_offset + disp); + + auto type = ELF_R_TYPE(reloc->r_info); + if(ELF_R_SYM(reloc->r_info)) + __builtin_trap(); + + auto p = reinterpret_cast<uint64_t *>(ldso_base + reloc->r_offset); + switch(type) { + case R_RELATIVE: + *p += ldso_base; + break; + default: + __builtin_trap(); + } + } + + elf_addr *addr = nullptr; + for(size_t disp = 0; disp < relr_size; disp += sizeof(elf_relr)) { + auto entry = *(elf_relr *)(ldso_base + relr_offset + disp); + + // Even entry indicates the beginning address. + if(!(entry & 1)) { + addr = (elf_addr *)(ldso_base + entry); + __ensure(addr); + *addr++ += ldso_base; + }else { + // Odd entry indicates entry is a bitmap of the subsequent locations to be relocated. + for(int i = 0; entry; ++i) { + if(entry & 1) { + addr[i] += ldso_base; + } + entry >>= 1; + } + + // Each entry describes at max 63 (on 64bit) or 31 (on 32bit) subsequent locations. + addr += CHAR_BIT * sizeof(elf_relr) - 1; + } + } +} +#endif + +extern "C" void *lazyRelocate(SharedObject *object, unsigned int rel_index) { + __ensure(object->lazyExplicitAddend); + auto reloc = (elf_rela *)(object->baseAddress + object->lazyRelocTableOffset + + rel_index * sizeof(elf_rela)); + auto type = ELF_R_TYPE(reloc->r_info); + auto symbol_index = ELF_R_SYM(reloc->r_info); + + __ensure(type == R_X86_64_JUMP_SLOT); + __ensure(ELF_CLASS == ELFCLASS64); + + auto symbol = (elf_sym *)(object->baseAddress + object->symbolTableOffset + + symbol_index * sizeof(elf_sym)); + ObjectSymbol r(object, symbol); + auto p = Scope::resolveGlobalOrLocal(*globalScope, object->localScope, r.getString(), object->objectRts, 0); + if(!p) + mlibc::panicLogger() << "Unresolved JUMP_SLOT symbol" << frg::endlog; + + //mlibc::infoLogger() << "Lazy relocation to " << symbol_str + // << " resolved to " << pointer << frg::endlog; + + *(uint64_t *)(object->baseAddress + reloc->r_offset) = p->virtualAddress(); + return (void *)p->virtualAddress(); +} + +extern "C" [[ gnu::visibility("default") ]] void *__rtdl_allocateTcb() { + auto tcb = allocateTcb(); + initTlsObjects(tcb, globalScope->_objects, false); + return tcb; +} + +extern "C" { + [[ gnu::visibility("hidden") ]] void dl_debug_state() { + // This function is used to signal changes in the debugging link map, + // GDB just sets a breakpoint on this function and we can call it + // everytime we update the link map. We don't need to implement + // anything besides defining and calling it. + } +} + +extern "C" [[gnu::alias("dl_debug_state"), gnu::visibility("default")]] void _dl_debug_state() noexcept; + +// This symbol can be used by GDB to find the global interface structure +[[ gnu::visibility("default") ]] DebugInterface *_dl_debug_addr = &globalDebugInterface; + +static frg::vector<frg::string_view, MemoryAllocator> parseList(frg::string_view paths, frg::string_view separators) { + frg::vector<frg::string_view, MemoryAllocator> list{getAllocator()}; + + size_t p = 0; + while(p < paths.size()) { + size_t s; // Offset of next colon or end of string. + if(size_t cs = paths.find_first_of(separators, p); cs != size_t(-1)) { + s = cs; + }else{ + s = paths.size(); + } + + auto path = paths.sub_string(p, s - p); + p = s + 1; + + if(path.size() == 0) + continue; + + if(path.ends_with("/")) { + size_t i = path.size() - 1; + while(i > 0 && path[i] == '/') + i--; + path = path.sub_string(0, i + 1); + } + + if(path == "/") + path = ""; + + list.push_back(path); + } + + return list; +} + +extern "C" void *interpreterMain(uintptr_t *entry_stack) { + if(logEntryExit) + mlibc::infoLogger() << "Entering ld.so" << frg::endlog; + entryStack = entry_stack; + runtimeTlsMap.initialize(); + libraryPaths.initialize(getAllocator()); + preloads.initialize(getAllocator()); + + void *phdr_pointer = 0; + size_t phdr_entry_size = 0; + size_t phdr_count = 0; + void *entry_pointer = 0; + void *stack_entropy = nullptr; + + const char *execfn = "(executable)"; + +#ifndef MLIBC_STATIC_BUILD + using ctor_fn = void(*)(void); + + ctor_fn *ldso_ctors = nullptr; + size_t num_ldso_ctors = 0; + + auto ldso_base = getLdsoBase(); + if(logStartup) { + mlibc::infoLogger() << "ldso: Own base address is: 0x" + << frg::hex_fmt(ldso_base) << frg::endlog; + mlibc::infoLogger() << "ldso: Own dynamic section is at: " << _DYNAMIC << frg::endlog; + } + +#ifdef __x86_64__ + // These entries are reserved on x86_64. + // TODO: Use a fake PLT stub that reports an error message? + _GLOBAL_OFFSET_TABLE_[1] = 0; + _GLOBAL_OFFSET_TABLE_[2] = 0; +#endif + + // Validate our own dynamic section. + // Here, we make sure that the dynamic linker does not need relocations itself. + uintptr_t strtab_offset = 0; + uintptr_t soname_str = 0; + for(size_t i = 0; _DYNAMIC[i].d_tag != DT_NULL; i++) { + auto ent = &_DYNAMIC[i]; + switch(ent->d_tag) { + case DT_STRTAB: strtab_offset = ent->d_un.d_ptr; break; + case DT_SONAME: soname_str = ent->d_un.d_val; break; + case DT_INIT_ARRAY: ldso_ctors = reinterpret_cast<ctor_fn *>(ent->d_un.d_ptr + ldso_base); break; + case DT_INIT_ARRAYSZ: num_ldso_ctors = ent->d_un.d_val / sizeof(ctor_fn); break; + case DT_HASH: + case DT_GNU_HASH: + case DT_STRSZ: + case DT_SYMTAB: + case DT_SYMENT: + case DT_RELA: + case DT_RELASZ: + case DT_RELAENT: + case DT_RELACOUNT: + case DT_DEBUG: + case DT_REL: + case DT_RELSZ: + case DT_RELENT: + case DT_RELCOUNT: + case DT_RELR: + case DT_RELRSZ: + case DT_RELRENT: + continue; + default: + __ensure(!"Unexpected dynamic entry in program interpreter"); + } + } + __ensure(strtab_offset); + __ensure(soname_str); + + // Find the auxiliary vector by skipping args and environment. + auto aux = entryStack; + aux += *aux + 1; // First, we skip argc and all args. + __ensure(!*aux); + aux++; + while(*aux) { // Loop through the environment. + auto env = reinterpret_cast<char *>(*aux); + frg::string_view view{env}; + size_t s = view.find_first('='); + + if(s == size_t(-1)) + mlibc::panicLogger() << "rtdl: environment '" << env << "' is missing a '='" << frg::endlog; + + auto name = view.sub_string(0, s); + auto value = const_cast<char *>(view.data() + s + 1); + + if(name == "LD_SHOW_AUXV" && *value && *value != '0') { + ldShowAuxv = true; + }else if(name == "LD_LIBRARY_PATH" && *value) { + for(auto path : parseList(value, ":;")) + libraryPaths->push_back(path); + }else if(name == "LD_PRELOAD" && *value) { + *preloads = parseList(value, " :"); + } + + aux++; + } + aux++; + + // Add default library paths + libraryPaths->push_back("/lib"); + libraryPaths->push_back("/lib64"); + libraryPaths->push_back("/usr/lib"); + libraryPaths->push_back("/usr/lib64"); + + // Parse the actual vector. + while(true) { + auto value = aux + 1; + if(!(*aux)) + break; + + if(ldShowAuxv) { + switch(*aux) { + case AT_PHDR: mlibc::infoLogger() << "AT_PHDR: 0x" << frg::hex_fmt{*value} << frg::endlog; break; + case AT_PHENT: mlibc::infoLogger() << "AT_PHENT: " << *value << frg::endlog; break; + case AT_PHNUM: mlibc::infoLogger() << "AT_PHNUM: " << *value << frg::endlog; break; + case AT_ENTRY: mlibc::infoLogger() << "AT_ENTRY: 0x" << frg::hex_fmt{*value} << frg::endlog; break; + case AT_PAGESZ: mlibc::infoLogger() << "AT_PAGESZ: " << *value << frg::endlog; break; + case AT_BASE: mlibc::infoLogger() << "AT_BASE: 0x" << frg::hex_fmt{*value} << frg::endlog; break; + case AT_FLAGS: mlibc::infoLogger() << "AT_FLAGS: 0x" << frg::hex_fmt{*value} << frg::endlog; break; + case AT_NOTELF: mlibc::infoLogger() << "AT_NOTELF: " << frg::hex_fmt{*value} << frg::endlog; break; + case AT_UID: mlibc::infoLogger() << "AT_UID: " << *value << frg::endlog; break; + case AT_EUID: mlibc::infoLogger() << "AT_EUID: " << *value << frg::endlog; break; + case AT_GID: mlibc::infoLogger() << "AT_GID: " << *value << frg::endlog; break; + case AT_EGID: mlibc::infoLogger() << "AT_EGID: " << *value << frg::endlog; break; +#ifdef AT_PLATFORM + case AT_PLATFORM: mlibc::infoLogger() << "AT_PLATFORM: " << reinterpret_cast<const char *>(*value) << frg::endlog; break; +#endif +#ifdef AT_HWCAP + case AT_HWCAP: mlibc::infoLogger() << "AT_HWCAP: " << frg::hex_fmt{*value} << frg::endlog; break; +#endif +#ifdef AT_CLKTCK + case AT_CLKTCK: mlibc::infoLogger() << "AT_CLKTCK: " << *value << frg::endlog; break; +#endif +#ifdef AT_FPUCW + case AT_FPUCW: mlibc::infoLogger() << "AT_FPUCW: " << frg::hex_fmt{*value} << frg::endlog; break; +#endif +#ifdef AT_SECURE + case AT_SECURE: mlibc::infoLogger() << "AT_SECURE: " << *value << frg::endlog; break; +#endif +#ifdef AT_RANDOM + case AT_RANDOM: mlibc::infoLogger() << "AT_RANDOM: 0x" << frg::hex_fmt{*value} << frg::endlog; break; +#endif +#ifdef AT_EXECFN + case AT_EXECFN: mlibc::infoLogger() << "AT_EXECFN: " << reinterpret_cast<const char *>(*value) << frg::endlog; break; +#endif +#ifdef AT_SYSINFO_EHDR + case AT_SYSINFO_EHDR: mlibc::infoLogger() << "AT_SYSINFO_EHDR: 0x" << frg::hex_fmt{*value} << frg::endlog; break; +#endif + } + } + + // TODO: Whitelist auxiliary vector entries here? + switch(*aux) { + case AT_PHDR: phdr_pointer = reinterpret_cast<void *>(*value); break; + case AT_PHENT: phdr_entry_size = *value; break; + case AT_PHNUM: phdr_count = *value; break; + case AT_ENTRY: entry_pointer = reinterpret_cast<void *>(*value); break; + case AT_EXECFN: execfn = reinterpret_cast<const char *>(*value); break; + case AT_RANDOM: stack_entropy = reinterpret_cast<void*>(*value); break; + case AT_SECURE: rtdlConfig.secureRequired = reinterpret_cast<uintptr_t>(*value); break; + } + + aux += 2; + } + globalDebugInterface.base = reinterpret_cast<void*>(ldso_base); + +// This is here because libgcc will add a global constructor on glibc Linux +// (which is what it believes we are due to the aarch64-linux-gnu toolchain) +// in order to check if LSE atomics are supported. +// +// This is not necessary on a custom Linux toolchain and is purely an artifact of +// using the host toolchain. +#if defined(__aarch64__) && defined(__gnu_linux__) + for (size_t i = 0; i < num_ldso_ctors; i++) { + if(logStartup) + mlibc::infoLogger() << "ldso: Running own constructor at " + << reinterpret_cast<void *>(ldso_ctors[i]) + << frg::endlog; + ldso_ctors[i](); + } +#else + if (num_ldso_ctors > 0) { + mlibc::panicLogger() << "ldso: Found unexpected own global constructor(s), init_array starts at: " + << ldso_ctors + << frg::endlog; + } +#endif + +#else + auto ehdr = reinterpret_cast<elf_ehdr*>(__ehdr_start); + phdr_pointer = reinterpret_cast<void*>((uintptr_t)ehdr->e_phoff + (uintptr_t)ehdr); + phdr_entry_size = ehdr->e_phentsize; + phdr_count = ehdr->e_phnum; + entry_pointer = reinterpret_cast<void*>(ehdr->e_entry); +#endif + __ensure(phdr_pointer); + __ensure(entry_pointer); + + if(logStartup) + mlibc::infoLogger() << "ldso: Executable PHDRs are at " << phdr_pointer + << frg::endlog; + + // perform the initial dynamic linking + initialRepository.initialize(); + + globalScope.initialize(true); + + // Add the dynamic linker, as well as the exectuable to the repository. +#ifndef MLIBC_STATIC_BUILD + auto ldso_soname = reinterpret_cast<const char *>(ldso_base + strtab_offset + soname_str); + auto ldso = initialRepository->injectObjectFromDts(ldso_soname, + frg::string<MemoryAllocator> { getAllocator() }, + ldso_base, _DYNAMIC, 1); + ldso->phdrPointer = phdr_pointer; + ldso->phdrCount = phdr_count; + ldso->phdrEntrySize = phdr_entry_size; + + // TODO: support non-zero base addresses? + executableSO = initialRepository->injectObjectFromPhdrs(execfn, + frg::string<MemoryAllocator> { execfn, getAllocator() }, + phdr_pointer, phdr_entry_size, phdr_count, entry_pointer, 1); + + // We can't initialise the ldso object after the executable SO, + // so we have to set the ldso path after loading both. + ldso->path = executableSO->interpreterPath; + +#else + executableSO = initialRepository->injectStaticObject(execfn, + frg::string<MemoryAllocator>{ execfn, getAllocator() }, + phdr_pointer, phdr_entry_size, phdr_count, entry_pointer, 1); + globalDebugInterface.base = (void*)executableSO->baseAddress; +#endif + + globalDebugInterface.head = &executableSO->linkMap; + executableSO->inLinkMap = true; + Loader linker{globalScope.get(), executableSO, true, 1}; + linker.linkObjects(executableSO); + + mlibc::initStackGuard(stack_entropy); + + auto tcb = allocateTcb(); + if(mlibc::sys_tcb_set(tcb)) + __ensure(!"sys_tcb_set() failed"); + tcb->tid = mlibc::this_tid(); + mlibc::tcb_available_flag = true; + + globalDebugInterface.ver = 1; + globalDebugInterface.brk = &dl_debug_state; + globalDebugInterface.state = 0; + dl_debug_state(); + + linker.initObjects(); + + if(logEntryExit) + mlibc::infoLogger() << "Leaving ld.so, jump to " + << (void *)executableSO->entry << frg::endlog; + return executableSO->entry; +} + +const char *lastError; + +extern "C" [[ gnu::visibility("default") ]] uintptr_t *__dlapi_entrystack() { + return entryStack; +} + +extern "C" [[ gnu::visibility("default") ]] +const char *__dlapi_error() { + auto error = lastError; + lastError = nullptr; + return error; +} + +extern "C" [[ gnu::visibility("default") ]] +void *__dlapi_get_tls(struct __abi_tls_entry *entry) { + return reinterpret_cast<char *>(accessDtv(entry->object)) + entry->offset; +} + +extern "C" [[ gnu::visibility("default") ]] +const mlibc::RtdlConfig &__dlapi_get_config() { + return rtdlConfig; +} + +#if __MLIBC_POSIX_OPTION + +extern "C" [[ gnu::visibility("default") ]] +void *__dlapi_open(const char *file, int flags, void *returnAddress) { + if (logDlCalls) + mlibc::infoLogger() << "rtdl: __dlapi_open(" << (file ? file : "nullptr") << ")" << frg::endlog; + + if (flags & RTLD_DEEPBIND) + mlibc::infoLogger() << "rtdl: dlopen(RTLD_DEEPBIND) is unsupported" << frg::endlog; + + if(!file) + return executableSO; + + // TODO: Thread-safety! + auto rts = rtsCounter++; + + SharedObject *object; + if (flags & RTLD_NOLOAD) { + object = initialRepository->findLoadedObject(file); + if (object && object->globalRts == 0 && (flags & RTLD_GLOBAL)) { + // The object was opened with RTLD_LOCAL, but we are called with RTLD_NOLOAD | RTLD_GLOBAL. + // According to the man page, we should promote to the global scope here. + object->globalRts = rts; + globalScope->appendObject(object); + } + } else { + bool isGlobal = flags & RTLD_GLOBAL; + Scope *newScope = isGlobal ? globalScope.get() : nullptr; + + frg::expected<LinkerError, SharedObject *> objectResult; + if (frg::string_view{file}.find_first('/') == size_t(-1)) { + // In order to know which RUNPATH / RPATH to process, we must find the calling object. + SharedObject *origin = initialRepository->findCaller(returnAddress); + if (!origin) { + mlibc::panicLogger() << "rtdl: unable to determine calling object of dlopen " + << "(ra = " << returnAddress << ")" << frg::endlog; + } + + objectResult = initialRepository->requestObjectWithName(file, origin, newScope, !isGlobal, rts); + } else { + objectResult = initialRepository->requestObjectAtPath(file, newScope, !isGlobal, rts); + } + + if(!objectResult) { + switch (objectResult.error()) { + case LinkerError::success: + __builtin_unreachable(); + case LinkerError::notFound: + lastError = "Cannot locate requested DSO"; + break; + case LinkerError::fileTooShort: + lastError = "File too short"; + break; + case LinkerError::notElf: + lastError = "File is not an ELF file"; + break; + case LinkerError::wrongElfType: + lastError = "File has wrong ELF type"; + break; + case LinkerError::outOfMemory: + lastError = "Out of memory"; + break; + case LinkerError::invalidProgramHeader: + lastError = "File has invalid program header"; + break; + } + return nullptr; + } + object = objectResult.value(); + + Loader linker{object->localScope, nullptr, false, rts}; + linker.linkObjects(object); + linker.initObjects(); + } + + dl_debug_state(); + + return object; +} + +extern "C" [[ gnu::visibility("default") ]] +void *__dlapi_resolve(void *handle, const char *string, void *returnAddress) { + if (logDlCalls) { + const char *name; + bool quote = false; + if (handle == RTLD_DEFAULT) { + name = "RTLD_DEFAULT"; + } else if (handle == RTLD_NEXT) { + name = "RTLD_NEXT"; + } else { + name = ((SharedObject *)handle)->name.data(); + quote = true; + } + + mlibc::infoLogger() << "rtdl: __dlapi_resolve(" << (quote ? "\"" : "") << name + << (quote ? "\"" : "") << ", \"" << string << "\")" << frg::endlog; + } + + frg::optional<ObjectSymbol> target; + + if (handle == RTLD_DEFAULT) { + target = globalScope->resolveSymbol(string, 0, 0); + } else if (handle == RTLD_NEXT) { + SharedObject *origin = initialRepository->findCaller(returnAddress); + if (!origin) { + mlibc::panicLogger() << "rtdl: unable to determine calling object of dlsym " + << "(ra = " << returnAddress << ")" << frg::endlog; + } + + target = Scope::resolveGlobalOrLocalNext(*globalScope, origin->localScope, string, origin); + } else { + // POSIX does not unambiguously state how dlsym() is supposed to work; it just + // states that "The symbol resolution algorithm used shall be dependency order + // as described in dlopen()". + // + // Linux libc's lookup the symbol in the given DSO and all of its dependencies + // in breadth-first order. That is also what we implement here. + // + // Note that this *differs* from the algorithm that is used for relocations + // (since the algorithm used for relocations takes (i) the global scope, + // and (ii) the local scope of the DSO into account (which can contain more objects + // than just the dependencies of the DSO, if the DSO was loaded as a dependency + // of a dlopen()ed DSO). + + frg::vector<SharedObject *, MemoryAllocator> queue{getAllocator()}; + + struct Token { }; + frg::hash_map< + SharedObject *, Token, + frg::hash<SharedObject *>, MemoryAllocator + > visited{frg::hash<SharedObject *>{}, getAllocator()}; + + auto root = reinterpret_cast<SharedObject *>(handle); + visited.insert(root, Token{}); + queue.push_back(root); + + for(size_t i = 0; i < queue.size(); i++) { + auto current = queue[i]; + + target = resolveInObject(current, string); + if(target) + break; + + for(auto dep : current->dependencies) { + if(visited.get(dep)) + continue; + visited.insert(dep, Token{}); + queue.push_back(dep); + } + } + } + + if (!target) { + if (logDlCalls) + mlibc::infoLogger() << "rtdl: could not resolve \"" << string << "\"" << frg::endlog; + + lastError = "Cannot resolve requested symbol"; + return nullptr; + } + return reinterpret_cast<void *>(target->virtualAddress()); +} + +struct __dlapi_symbol { + const char *file; + void *base; + const char *symbol; + void *address; +}; + +extern "C" [[ gnu::visibility("default") ]] +int __dlapi_reverse(const void *ptr, __dlapi_symbol *info) { + if (logDlCalls) + mlibc::infoLogger() << "rtdl: __dlapi_reverse(" << ptr << ")" << frg::endlog; + + for(size_t i = 0; i < initialRepository->loadedObjects.size(); i++) { + auto object = initialRepository->loadedObjects[i]; + + auto eligible = [&] (ObjectSymbol cand) { + if(cand.symbol()->st_shndx == SHN_UNDEF) + return false; + + auto bind = ELF_ST_BIND(cand.symbol()->st_info); + if(bind != STB_GLOBAL && bind != STB_WEAK) + return false; + + return true; + }; + + auto hash_table = (Elf64_Word *)(object->baseAddress + object->hashTableOffset); + auto num_symbols = hash_table[1]; + for(size_t i = 0; i < num_symbols; i++) { + ObjectSymbol cand{object, (elf_sym *)(object->baseAddress + + object->symbolTableOffset + i * sizeof(elf_sym))}; + if(eligible(cand) && cand.virtualAddress() == reinterpret_cast<uintptr_t>(ptr)) { + if (logDlCalls) + mlibc::infoLogger() << "rtdl: Found symbol " << cand.getString() << " in object " + << object->path << frg::endlog; + + info->file = object->path.data(); + info->base = reinterpret_cast<void *>(object->baseAddress); + info->symbol = cand.getString(); + info->address = reinterpret_cast<void *>(cand.virtualAddress()); + return 0; + } + } + } + + // Not found, find the DSO it should be in. + for(size_t i = 0; i < initialRepository->loadedObjects.size(); i++) { + auto object = initialRepository->loadedObjects[i]; + + for(size_t j = 0; j < object->phdrCount; j++) { + auto phdr = (elf_phdr *)((uintptr_t)object->phdrPointer + j * object->phdrEntrySize); + if(phdr->p_type != PT_LOAD) { + continue; + } + uintptr_t start = object->baseAddress + phdr->p_vaddr; + uintptr_t end = start + phdr->p_memsz; + if(reinterpret_cast<uintptr_t>(ptr) >= start && reinterpret_cast<uintptr_t>(ptr) < end) { + mlibc::infoLogger() << "rtdl: Found DSO " << object->path << frg::endlog; + info->file = object->path.data(); + info->base = reinterpret_cast<void *>(object->baseAddress); + info->symbol = nullptr; + info->address = 0; + return 0; + } + } + } + + if (logDlCalls) + mlibc::infoLogger() << "rtdl: Could not find symbol in __dlapi_reverse()" << frg::endlog; + + return -1; +} + +extern "C" [[ gnu::visibility("default") ]] +int __dlapi_close(void *) { + if (logDlCalls) + mlibc::infoLogger() << "mlibc: dlclose() is a no-op" << frg::endlog; + return 0; +} + +#endif + +extern "C" [[ gnu::visibility("default") ]] +int __dlapi_iterate_phdr(int (*callback)(struct dl_phdr_info *, size_t, void*), void *data) { + int last_return = 0; + for (auto object : initialRepository->loadedObjects) { + struct dl_phdr_info info; + info.dlpi_addr = object->baseAddress; + info.dlpi_name = object->name.data(); + + if(object->isMainObject) { + info.dlpi_name = ""; + } else { + info.dlpi_name = object->name.data(); + } + info.dlpi_phdr = static_cast<ElfW(Phdr)*>(object->phdrPointer); + info.dlpi_phnum = object->phdrCount; + info.dlpi_adds = rtsCounter; + info.dlpi_subs = 0; // TODO(geert): implement dlclose(). + if (object->tlsModel != TlsModel::null) + info.dlpi_tls_modid = object->tlsIndex; + else + info.dlpi_tls_modid = 0; + info.dlpi_tls_data = tryAccessDtv(object); + + last_return = callback(&info, sizeof(struct dl_phdr_info), data); + if(last_return) + return last_return; + } + + return last_return; +} + +extern "C" [[ gnu::visibility("default") ]] +void __dlapi_enter(uintptr_t *entry_stack) { +#if MLIBC_STATIC_BUILD + interpreterMain(entry_stack); +#else + (void)entry_stack; +#endif +} + +// XXX(qookie): +// This is here because libgcc will call into __getauxval on glibc Linux +// (which is what it believes we are due to the aarch64-linux-gnu toolchain) +// in order to find AT_HWCAP to discover if LSE atomics are supported. +// +// This is not necessary on a custom Linux toolchain and is purely an artifact of +// using the host toolchain. + +// __gnu_linux__ is the define checked by libgcc +#if defined(__aarch64__) && defined(__gnu_linux__) && !defined(MLIBC_STATIC_BUILD) + +extern "C" unsigned long __getauxval(unsigned long type) { + // Find the auxiliary vector by skipping args and environment. + auto aux = entryStack; + aux += *aux + 1; // Skip argc and all arguments + __ensure(!*aux); + aux++; + while(*aux) // Now, we skip the environment. + aux++; + aux++; + + // Parse the auxiliary vector. + while(true) { + auto value = aux + 1; + if(*aux == AT_NULL) { + return 0; + }else if(*aux == type) { + return *value; + } + aux += 2; + } +} + +#endif |