forked from OSchip/llvm-project
483 lines
15 KiB
C++
483 lines
15 KiB
C++
//===-- xray_interface.cpp --------------------------------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file is a part of XRay, a dynamic runtime instrumentation system.
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//
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// Implementation of the API functions.
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//
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//===----------------------------------------------------------------------===//
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#include "xray_interface_internal.h"
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#include <cstdint>
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#include <cstdio>
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#include <errno.h>
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#include <limits>
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#include <string.h>
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#include <sys/mman.h>
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#if SANITIZER_FUCHSIA
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#include <zircon/process.h>
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#include <zircon/sanitizer.h>
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#include <zircon/status.h>
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#include <zircon/syscalls.h>
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#endif
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#include "sanitizer_common/sanitizer_addrhashmap.h"
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#include "sanitizer_common/sanitizer_common.h"
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#include "xray_defs.h"
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#include "xray_flags.h"
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extern __sanitizer::SpinMutex XRayInstrMapMutex;
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extern __sanitizer::atomic_uint8_t XRayInitialized;
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extern __xray::XRaySledMap XRayInstrMap;
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namespace __xray {
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#if defined(__x86_64__)
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static const int16_t cSledLength = 12;
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#elif defined(__aarch64__)
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static const int16_t cSledLength = 32;
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#elif defined(__arm__)
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static const int16_t cSledLength = 28;
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#elif SANITIZER_MIPS32
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static const int16_t cSledLength = 48;
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#elif SANITIZER_MIPS64
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static const int16_t cSledLength = 64;
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#elif defined(__powerpc64__)
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static const int16_t cSledLength = 8;
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#else
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#error "Unsupported CPU Architecture"
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#endif /* CPU architecture */
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// This is the function to call when we encounter the entry or exit sleds.
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atomic_uintptr_t XRayPatchedFunction{0};
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// This is the function to call from the arg1-enabled sleds/trampolines.
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atomic_uintptr_t XRayArgLogger{0};
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// This is the function to call when we encounter a custom event log call.
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atomic_uintptr_t XRayPatchedCustomEvent{0};
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// This is the function to call when we encounter a typed event log call.
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atomic_uintptr_t XRayPatchedTypedEvent{0};
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// This is the global status to determine whether we are currently
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// patching/unpatching.
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atomic_uint8_t XRayPatching{0};
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struct TypeDescription {
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uint32_t type_id;
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std::size_t description_string_length;
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};
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using TypeDescriptorMapType = AddrHashMap<TypeDescription, 11>;
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// An address map from immutable descriptors to type ids.
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TypeDescriptorMapType TypeDescriptorAddressMap{};
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atomic_uint32_t TypeEventDescriptorCounter{0};
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// MProtectHelper is an RAII wrapper for calls to mprotect(...) that will
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// undo any successful mprotect(...) changes. This is used to make a page
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// writeable and executable, and upon destruction if it was successful in
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// doing so returns the page into a read-only and executable page.
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//
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// This is only used specifically for runtime-patching of the XRay
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// instrumentation points. This assumes that the executable pages are
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// originally read-and-execute only.
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class MProtectHelper {
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void *PageAlignedAddr;
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std::size_t MProtectLen;
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bool MustCleanup;
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public:
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explicit MProtectHelper(void *PageAlignedAddr,
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std::size_t MProtectLen,
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std::size_t PageSize) XRAY_NEVER_INSTRUMENT
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: PageAlignedAddr(PageAlignedAddr),
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MProtectLen(MProtectLen),
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MustCleanup(false) {
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#if SANITIZER_FUCHSIA
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MProtectLen = RoundUpTo(MProtectLen, PageSize);
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#endif
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}
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int MakeWriteable() XRAY_NEVER_INSTRUMENT {
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#if SANITIZER_FUCHSIA
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auto R = __sanitizer_change_code_protection(
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reinterpret_cast<uintptr_t>(PageAlignedAddr), MProtectLen, true);
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if (R != ZX_OK) {
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Report("XRay: cannot change code protection: %s\n",
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_zx_status_get_string(R));
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return -1;
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}
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MustCleanup = true;
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return 0;
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#else
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auto R = mprotect(PageAlignedAddr, MProtectLen,
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PROT_READ | PROT_WRITE | PROT_EXEC);
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if (R != -1)
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MustCleanup = true;
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return R;
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#endif
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}
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~MProtectHelper() XRAY_NEVER_INSTRUMENT {
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if (MustCleanup) {
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#if SANITIZER_FUCHSIA
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auto R = __sanitizer_change_code_protection(
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reinterpret_cast<uintptr_t>(PageAlignedAddr), MProtectLen, false);
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if (R != ZX_OK) {
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Report("XRay: cannot change code protection: %s\n",
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_zx_status_get_string(R));
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}
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#else
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mprotect(PageAlignedAddr, MProtectLen, PROT_READ | PROT_EXEC);
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#endif
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}
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}
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};
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namespace {
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bool patchSled(const XRaySledEntry &Sled, bool Enable,
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int32_t FuncId) XRAY_NEVER_INSTRUMENT {
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bool Success = false;
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switch (Sled.Kind) {
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case XRayEntryType::ENTRY:
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Success = patchFunctionEntry(Enable, FuncId, Sled, __xray_FunctionEntry);
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break;
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case XRayEntryType::EXIT:
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Success = patchFunctionExit(Enable, FuncId, Sled);
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break;
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case XRayEntryType::TAIL:
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Success = patchFunctionTailExit(Enable, FuncId, Sled);
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break;
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case XRayEntryType::LOG_ARGS_ENTRY:
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Success = patchFunctionEntry(Enable, FuncId, Sled, __xray_ArgLoggerEntry);
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break;
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case XRayEntryType::CUSTOM_EVENT:
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Success = patchCustomEvent(Enable, FuncId, Sled);
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break;
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case XRayEntryType::TYPED_EVENT:
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Success = patchTypedEvent(Enable, FuncId, Sled);
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break;
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default:
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Report("Unsupported sled kind '%d' @%04x\n", Sled.Address, int(Sled.Kind));
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return false;
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}
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return Success;
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}
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XRayPatchingStatus patchFunction(int32_t FuncId,
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bool Enable) XRAY_NEVER_INSTRUMENT {
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if (!atomic_load(&XRayInitialized,
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memory_order_acquire))
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return XRayPatchingStatus::NOT_INITIALIZED; // Not initialized.
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uint8_t NotPatching = false;
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if (!atomic_compare_exchange_strong(
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&XRayPatching, &NotPatching, true, memory_order_acq_rel))
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return XRayPatchingStatus::ONGOING; // Already patching.
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// Next, we look for the function index.
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XRaySledMap InstrMap;
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{
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SpinMutexLock Guard(&XRayInstrMapMutex);
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InstrMap = XRayInstrMap;
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}
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// If we don't have an index, we can't patch individual functions.
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if (InstrMap.Functions == 0)
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return XRayPatchingStatus::NOT_INITIALIZED;
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// FuncId must be a positive number, less than the number of functions
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// instrumented.
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if (FuncId <= 0 || static_cast<size_t>(FuncId) > InstrMap.Functions) {
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Report("Invalid function id provided: %d\n", FuncId);
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return XRayPatchingStatus::FAILED;
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}
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// Now we patch ths sleds for this specific function.
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auto SledRange = InstrMap.SledsIndex[FuncId - 1];
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auto *f = SledRange.Begin;
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auto *e = SledRange.End;
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bool SucceedOnce = false;
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while (f != e)
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SucceedOnce |= patchSled(*f++, Enable, FuncId);
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atomic_store(&XRayPatching, false,
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memory_order_release);
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if (!SucceedOnce) {
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Report("Failed patching any sled for function '%d'.", FuncId);
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return XRayPatchingStatus::FAILED;
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}
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return XRayPatchingStatus::SUCCESS;
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}
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// controlPatching implements the common internals of the patching/unpatching
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// implementation. |Enable| defines whether we're enabling or disabling the
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// runtime XRay instrumentation.
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XRayPatchingStatus controlPatching(bool Enable) XRAY_NEVER_INSTRUMENT {
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if (!atomic_load(&XRayInitialized,
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memory_order_acquire))
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return XRayPatchingStatus::NOT_INITIALIZED; // Not initialized.
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uint8_t NotPatching = false;
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if (!atomic_compare_exchange_strong(
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&XRayPatching, &NotPatching, true, memory_order_acq_rel))
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return XRayPatchingStatus::ONGOING; // Already patching.
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uint8_t PatchingSuccess = false;
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auto XRayPatchingStatusResetter =
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at_scope_exit([&PatchingSuccess] {
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if (!PatchingSuccess)
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atomic_store(&XRayPatching, false,
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memory_order_release);
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});
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XRaySledMap InstrMap;
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{
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SpinMutexLock Guard(&XRayInstrMapMutex);
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InstrMap = XRayInstrMap;
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}
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if (InstrMap.Entries == 0)
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return XRayPatchingStatus::NOT_INITIALIZED;
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uint32_t FuncId = 1;
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uint64_t CurFun = 0;
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// First we want to find the bounds for which we have instrumentation points,
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// and try to get as few calls to mprotect(...) as possible. We're assuming
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// that all the sleds for the instrumentation map are contiguous as a single
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// set of pages. When we do support dynamic shared object instrumentation,
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// we'll need to do this for each set of page load offsets per DSO loaded. For
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// now we're assuming we can mprotect the whole section of text between the
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// minimum sled address and the maximum sled address (+ the largest sled
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// size).
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auto *MinSled = &InstrMap.Sleds[0];
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auto *MaxSled = &InstrMap.Sleds[InstrMap.Entries - 1];
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for (std::size_t I = 0; I < InstrMap.Entries; I++) {
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const auto &Sled = InstrMap.Sleds[I];
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if (Sled.address() < MinSled->address())
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MinSled = &Sled;
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if (Sled.address() > MaxSled->address())
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MaxSled = &Sled;
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}
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const size_t PageSize = flags()->xray_page_size_override > 0
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? flags()->xray_page_size_override
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: GetPageSizeCached();
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if ((PageSize == 0) || ((PageSize & (PageSize - 1)) != 0)) {
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Report("System page size is not a power of two: %lld\n", PageSize);
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return XRayPatchingStatus::FAILED;
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}
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void *PageAlignedAddr =
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reinterpret_cast<void *>(MinSled->address() & ~(PageSize - 1));
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size_t MProtectLen =
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(MaxSled->address() - reinterpret_cast<uptr>(PageAlignedAddr)) +
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cSledLength;
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MProtectHelper Protector(PageAlignedAddr, MProtectLen, PageSize);
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if (Protector.MakeWriteable() == -1) {
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Report("Failed mprotect: %d\n", errno);
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return XRayPatchingStatus::FAILED;
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}
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for (std::size_t I = 0; I < InstrMap.Entries; ++I) {
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auto &Sled = InstrMap.Sleds[I];
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auto F = Sled.function();
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if (CurFun == 0)
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CurFun = F;
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if (F != CurFun) {
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++FuncId;
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CurFun = F;
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}
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patchSled(Sled, Enable, FuncId);
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}
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atomic_store(&XRayPatching, false,
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memory_order_release);
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PatchingSuccess = true;
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return XRayPatchingStatus::SUCCESS;
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}
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XRayPatchingStatus mprotectAndPatchFunction(int32_t FuncId,
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bool Enable) XRAY_NEVER_INSTRUMENT {
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XRaySledMap InstrMap;
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{
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SpinMutexLock Guard(&XRayInstrMapMutex);
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InstrMap = XRayInstrMap;
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}
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// FuncId must be a positive number, less than the number of functions
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// instrumented.
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if (FuncId <= 0 || static_cast<size_t>(FuncId) > InstrMap.Functions) {
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Report("Invalid function id provided: %d\n", FuncId);
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return XRayPatchingStatus::FAILED;
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}
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const size_t PageSize = flags()->xray_page_size_override > 0
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? flags()->xray_page_size_override
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: GetPageSizeCached();
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if ((PageSize == 0) || ((PageSize & (PageSize - 1)) != 0)) {
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Report("Provided page size is not a power of two: %lld\n", PageSize);
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return XRayPatchingStatus::FAILED;
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}
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// Here we compute the minumum sled and maximum sled associated with a
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// particular function ID.
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auto SledRange = InstrMap.SledsIndex[FuncId - 1];
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auto *f = SledRange.Begin;
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auto *e = SledRange.End;
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auto *MinSled = f;
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auto *MaxSled = (SledRange.End - 1);
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while (f != e) {
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if (f->address() < MinSled->address())
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MinSled = f;
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if (f->address() > MaxSled->address())
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MaxSled = f;
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++f;
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}
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void *PageAlignedAddr =
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reinterpret_cast<void *>(MinSled->address() & ~(PageSize - 1));
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size_t MProtectLen =
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(MaxSled->address() - reinterpret_cast<uptr>(PageAlignedAddr)) +
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cSledLength;
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MProtectHelper Protector(PageAlignedAddr, MProtectLen, PageSize);
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if (Protector.MakeWriteable() == -1) {
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Report("Failed mprotect: %d\n", errno);
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return XRayPatchingStatus::FAILED;
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}
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return patchFunction(FuncId, Enable);
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}
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} // namespace
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} // namespace __xray
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using namespace __xray;
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// The following functions are declared `extern "C" {...}` in the header, hence
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// they're defined in the global namespace.
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int __xray_set_handler(void (*entry)(int32_t,
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XRayEntryType)) XRAY_NEVER_INSTRUMENT {
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if (atomic_load(&XRayInitialized,
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memory_order_acquire)) {
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atomic_store(&__xray::XRayPatchedFunction,
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reinterpret_cast<uintptr_t>(entry),
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memory_order_release);
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return 1;
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}
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return 0;
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}
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int __xray_set_customevent_handler(void (*entry)(void *, size_t))
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XRAY_NEVER_INSTRUMENT {
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if (atomic_load(&XRayInitialized,
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memory_order_acquire)) {
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atomic_store(&__xray::XRayPatchedCustomEvent,
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reinterpret_cast<uintptr_t>(entry),
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memory_order_release);
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return 1;
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}
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return 0;
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}
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int __xray_set_typedevent_handler(void (*entry)(
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uint16_t, const void *, size_t)) XRAY_NEVER_INSTRUMENT {
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if (atomic_load(&XRayInitialized,
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memory_order_acquire)) {
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atomic_store(&__xray::XRayPatchedTypedEvent,
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reinterpret_cast<uintptr_t>(entry),
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memory_order_release);
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return 1;
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}
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return 0;
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}
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int __xray_remove_handler() XRAY_NEVER_INSTRUMENT {
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return __xray_set_handler(nullptr);
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}
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int __xray_remove_customevent_handler() XRAY_NEVER_INSTRUMENT {
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return __xray_set_customevent_handler(nullptr);
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}
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int __xray_remove_typedevent_handler() XRAY_NEVER_INSTRUMENT {
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return __xray_set_typedevent_handler(nullptr);
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}
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uint16_t __xray_register_event_type(
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const char *const event_type) XRAY_NEVER_INSTRUMENT {
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TypeDescriptorMapType::Handle h(&TypeDescriptorAddressMap, (uptr)event_type);
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if (h.created()) {
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h->type_id = atomic_fetch_add(
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&TypeEventDescriptorCounter, 1, memory_order_acq_rel);
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h->description_string_length = strnlen(event_type, 1024);
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}
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return h->type_id;
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}
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XRayPatchingStatus __xray_patch() XRAY_NEVER_INSTRUMENT {
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return controlPatching(true);
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}
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XRayPatchingStatus __xray_unpatch() XRAY_NEVER_INSTRUMENT {
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return controlPatching(false);
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}
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XRayPatchingStatus __xray_patch_function(int32_t FuncId) XRAY_NEVER_INSTRUMENT {
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return mprotectAndPatchFunction(FuncId, true);
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}
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XRayPatchingStatus
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__xray_unpatch_function(int32_t FuncId) XRAY_NEVER_INSTRUMENT {
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return mprotectAndPatchFunction(FuncId, false);
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}
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int __xray_set_handler_arg1(void (*entry)(int32_t, XRayEntryType, uint64_t)) {
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if (!atomic_load(&XRayInitialized,
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memory_order_acquire))
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return 0;
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// A relaxed write might not be visible even if the current thread gets
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// scheduled on a different CPU/NUMA node. We need to wait for everyone to
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// have this handler installed for consistency of collected data across CPUs.
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atomic_store(&XRayArgLogger, reinterpret_cast<uint64_t>(entry),
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memory_order_release);
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return 1;
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}
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int __xray_remove_handler_arg1() { return __xray_set_handler_arg1(nullptr); }
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uintptr_t __xray_function_address(int32_t FuncId) XRAY_NEVER_INSTRUMENT {
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SpinMutexLock Guard(&XRayInstrMapMutex);
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if (FuncId <= 0 || static_cast<size_t>(FuncId) > XRayInstrMap.Functions)
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return 0;
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return XRayInstrMap.SledsIndex[FuncId - 1].Begin->function()
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// On PPC, function entries are always aligned to 16 bytes. The beginning of a
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// sled might be a local entry, which is always +8 based on the global entry.
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// Always return the global entry.
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#ifdef __PPC__
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& ~0xf
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#endif
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;
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}
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size_t __xray_max_function_id() XRAY_NEVER_INSTRUMENT {
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SpinMutexLock Guard(&XRayInstrMapMutex);
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return XRayInstrMap.Functions;
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}
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