//===-- xray_init.cpp -------------------------------------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file is a part of XRay, a dynamic runtime instrumentation system. // // XRay initialisation logic. //===----------------------------------------------------------------------===// #include #include #include #include "sanitizer_common/sanitizer_common.h" #include "xray/xray_interface.h" #include "xray_allocator.h" #include "xray_defs.h" #include "xray_flags.h" #include "xray_interface_internal.h" extern "C" { void __xray_init(); extern const XRaySledEntry __start_xray_instr_map[] __attribute__((weak)); extern const XRaySledEntry __stop_xray_instr_map[] __attribute__((weak)); extern const XRayFunctionSledIndex __start_xray_fn_idx[] __attribute__((weak)); extern const XRayFunctionSledIndex __stop_xray_fn_idx[] __attribute__((weak)); #if SANITIZER_APPLE // HACK: This is a temporary workaround to make XRay build on // Darwin, but it will probably not work at runtime. const XRaySledEntry __start_xray_instr_map[] = {}; extern const XRaySledEntry __stop_xray_instr_map[] = {}; extern const XRayFunctionSledIndex __start_xray_fn_idx[] = {}; extern const XRayFunctionSledIndex __stop_xray_fn_idx[] = {}; #endif } using namespace __xray; // When set to 'true' this means the XRay runtime has been initialised. We use // the weak symbols defined above (__start_xray_inst_map and // __stop_xray_instr_map) to initialise the instrumentation map that XRay uses // for runtime patching/unpatching of instrumentation points. atomic_uint8_t XRayInitialized{0}; // This should always be updated before XRayInitialized is updated. SpinMutex XRayInstrMapMutex; // Contains maps for the main executable as well as DSOs. XRaySledMap *XRayInstrMaps; // Number of binary objects registered. atomic_uint32_t XRayNumObjects{0}; // Global flag to determine whether the flags have been initialized. atomic_uint8_t XRayFlagsInitialized{0}; // A mutex to allow only one thread to initialize the XRay data structures. SpinMutex XRayInitMutex; // Registers XRay sleds and trampolines coming from the main executable or one // of the linked DSOs. // Returns the object ID if registration is successful, -1 otherwise. int32_t __xray_register_sleds(const XRaySledEntry *SledsBegin, const XRaySledEntry *SledsEnd, const XRayFunctionSledIndex *FnIndexBegin, const XRayFunctionSledIndex *FnIndexEnd, bool FromDSO, XRayTrampolines Trampolines) XRAY_NEVER_INSTRUMENT { if (!SledsBegin || !SledsEnd) { Report("Invalid XRay sleds.\n"); return -1; } XRaySledMap SledMap; SledMap.FromDSO = FromDSO; SledMap.Loaded = true; SledMap.Trampolines = Trampolines; SledMap.Sleds = SledsBegin; SledMap.Entries = SledsEnd - SledsBegin; if (FnIndexBegin != nullptr) { SledMap.SledsIndex = FnIndexBegin; SledMap.Functions = FnIndexEnd - FnIndexBegin; } else { size_t CountFunctions = 0; uint64_t LastFnAddr = 0; for (std::size_t I = 0; I < SledMap.Entries; I++) { const auto &Sled = SledMap.Sleds[I]; const auto Function = Sled.function(); if (Function != LastFnAddr) { CountFunctions++; LastFnAddr = Function; } } SledMap.SledsIndex = nullptr; SledMap.Functions = CountFunctions; } if (SledMap.Functions >= XRayMaxFunctions) { Report("Too many functions! Maximum is %ld\n", XRayMaxFunctions); return -1; } if (Verbosity()) Report("Registering %d new functions!\n", SledMap.Functions); { SpinMutexLock Guard(&XRayInstrMapMutex); auto Idx = atomic_fetch_add(&XRayNumObjects, 1, memory_order_acq_rel); if (Idx >= XRayMaxObjects) { Report("Too many objects registered! Maximum is %ld\n", XRayMaxObjects); return -1; } XRayInstrMaps[Idx] = std::move(SledMap); return Idx; } } // __xray_init() will do the actual loading of the current process' memory map // and then proceed to look for the .xray_instr_map section/segment. void __xray_init() XRAY_NEVER_INSTRUMENT { SpinMutexLock Guard(&XRayInitMutex); // Short-circuit if we've already initialized XRay before. if (atomic_load(&XRayInitialized, memory_order_acquire)) return; // XRAY is not compatible with PaX MPROTECT CheckMPROTECT(); if (!atomic_load(&XRayFlagsInitialized, memory_order_acquire)) { initializeFlags(); atomic_store(&XRayFlagsInitialized, true, memory_order_release); } if (__start_xray_instr_map == nullptr) { if (Verbosity()) Report("XRay instrumentation map missing. Not initializing XRay.\n"); return; } atomic_store(&XRayNumObjects, 0, memory_order_release); // Pre-allocation takes up approx. 5kB for XRayMaxObjects=64. XRayInstrMaps = allocateBuffer(XRayMaxObjects); int MainBinaryId = __xray_register_sleds(__start_xray_instr_map, __stop_xray_instr_map, __start_xray_fn_idx, __stop_xray_fn_idx, false, {}); // The executable should always get ID 0. if (MainBinaryId != 0) { Report("Registering XRay sleds failed.\n"); return; } atomic_store(&XRayInitialized, true, memory_order_release); #ifndef XRAY_NO_PREINIT if (flags()->patch_premain) __xray_patch(); #endif } // Registers XRay sleds and trampolines of an instrumented DSO. // Returns the object ID if registration is successful, -1 otherwise. // // Default visibility is hidden, so we have to explicitly make it visible to // DSO. SANITIZER_INTERFACE_ATTRIBUTE int32_t __xray_register_dso( const XRaySledEntry *SledsBegin, const XRaySledEntry *SledsEnd, const XRayFunctionSledIndex *FnIndexBegin, const XRayFunctionSledIndex *FnIndexEnd, XRayTrampolines Trampolines) XRAY_NEVER_INSTRUMENT { // Make sure XRay has been initialized in the main executable. __xray_init(); if (__xray_num_objects() == 0) { if (Verbosity()) Report("No XRay instrumentation map in main executable. Not initializing " "XRay for DSO.\n"); return -1; } // Register sleds in global map. int ObjId = __xray_register_sleds(SledsBegin, SledsEnd, FnIndexBegin, FnIndexEnd, true, Trampolines); #ifndef XRAY_NO_PREINIT if (ObjId >= 0 && flags()->patch_premain) __xray_patch_object(ObjId); #endif return ObjId; } // Deregisters a DSO from the main XRay runtime. // Called from the DSO-local runtime when the library is unloaded (e.g. if // dlclose is called). // Returns true if the object ID is valid and the DSO was successfully // deregistered. SANITIZER_INTERFACE_ATTRIBUTE bool __xray_deregister_dso(int32_t ObjId) XRAY_NEVER_INSTRUMENT { if (!atomic_load(&XRayInitialized, memory_order_acquire)) { if (Verbosity()) Report("XRay has not been initialized. Cannot deregister DSO.\n"); return false; } if (ObjId <= 0 || static_cast(ObjId) >= __xray_num_objects()) { if (Verbosity()) Report("Can't deregister object with ID %d: ID is invalid.\n", ObjId); return false; } { SpinMutexLock Guard(&XRayInstrMapMutex); auto &Entry = XRayInstrMaps[ObjId]; if (!Entry.FromDSO) { if (Verbosity()) Report("Can't deregister object with ID %d: object does not correspond " "to a shared library.\n", ObjId); return false; } if (!Entry.Loaded) { if (Verbosity()) Report("Can't deregister object with ID %d: object is not loaded.\n", ObjId); return true; } // Mark DSO as unloaded. No need to unpatch. Entry.Loaded = false; } if (Verbosity()) Report("Deregistered object with ID %d.\n", ObjId); return true; } // FIXME: Make check-xray tests work on FreeBSD without // SANITIZER_CAN_USE_PREINIT_ARRAY. // See sanitizer_internal_defs.h where the macro is defined. // Calling unresolved PLT functions in .preinit_array can lead to deadlock on // FreeBSD but here it seems benign. #if !defined(XRAY_NO_PREINIT) && \ (SANITIZER_CAN_USE_PREINIT_ARRAY || SANITIZER_FREEBSD) // Only add the preinit array initialization if the sanitizers can. __attribute__((section(".preinit_array"), used)) void (*__local_xray_preinit)(void) = __xray_init; #else // If we cannot use the .preinit_array section, we should instead use dynamic // initialisation. __attribute__ ((constructor (0))) static void __local_xray_dyninit() { __xray_init(); } #endif