third_party/llvm-project/compiler-rt/lib/esan/working_set_posix.cpp - cobalt - Git at Google

 //===-- working_set_posix.cpp -----------------------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of EfficiencySanitizer, a family of performance tuners.
 //
 // POSIX-specific working set tool code.
 //===----------------------------------------------------------------------===//

 #include "working_set.h"
 #include "esan_flags.h"
 #include "esan_shadow.h"
 #include "sanitizer_common/sanitizer_common.h"
 #include "sanitizer_common/sanitizer_linux.h"
 #include <signal.h>
 #include <sys/mman.h>

 namespace __esan {

 // We only support regular POSIX threads with a single signal handler
 // for the whole process == thread group.
 // Thus we only need to store one app signal handler.
 // FIXME: Store and use any alternate stack and signal flags set by
 // the app.  For now we just call the app handler from our handler.
 static __sanitizer_sigaction AppSigAct;

 bool processWorkingSetSignal(int SigNum, void (*Handler)(int),
                              void (**Result)(int)) {
   VPrintf(2, "%s: %d\n", __FUNCTION__, SigNum);
   if (SigNum == SIGSEGV) {
     *Result = AppSigAct.handler;
     AppSigAct.sigaction = (decltype(AppSigAct.sigaction))Handler;
     return false; // Skip real call.
   }
   return true;
 }

 bool processWorkingSetSigaction(int SigNum, const void *ActVoid,
                                 void *OldActVoid) {
   VPrintf(2, "%s: %d\n", __FUNCTION__, SigNum);
   if (SigNum == SIGSEGV) {
     const struct sigaction *Act = (const struct sigaction *) ActVoid;
     struct sigaction *OldAct = (struct sigaction *) OldActVoid;
     if (OldAct)
       internal_memcpy(OldAct, &AppSigAct, sizeof(OldAct));
     if (Act)
       internal_memcpy(&AppSigAct, Act, sizeof(AppSigAct));
     return false; // Skip real call.
   }
   return true;
 }

 bool processWorkingSetSigprocmask(int How, void *Set, void *OldSet) {
   VPrintf(2, "%s\n", __FUNCTION__);
   // All we need to do is ensure that SIGSEGV is not blocked.
   // FIXME: we are not fully transparent as we do not pretend that
   // SIGSEGV is still blocked on app queries: that would require
   // per-thread mask tracking.
   if (Set && (How == SIG_BLOCK || How == SIG_SETMASK)) {
     if (internal_sigismember((__sanitizer_sigset_t *)Set, SIGSEGV)) {
       VPrintf(1, "%s: removing SIGSEGV from the blocked set\n", __FUNCTION__);
       internal_sigdelset((__sanitizer_sigset_t *)Set, SIGSEGV);
     }
   }
   return true;
 }

 static void reinstateDefaultHandler(int SigNum) {
   __sanitizer_sigaction SigAct;
   internal_memset(&SigAct, 0, sizeof(SigAct));
   SigAct.sigaction = (decltype(SigAct.sigaction))SIG_DFL;
   int Res = internal_sigaction(SigNum, &SigAct, nullptr);
   CHECK(Res == 0);
   VPrintf(1, "Unregistered for %d handler\n", SigNum);
 }

 // If this is a shadow fault, we handle it here; otherwise, we pass it to the
 // app to handle it just as the app would do without our tool in place.
 static void handleMemoryFault(int SigNum, __sanitizer_siginfo *Info,
                               void *Ctx) {
   if (SigNum == SIGSEGV) {
     // We rely on si_addr being filled in (thus we do not support old kernels).
     siginfo_t *SigInfo = (siginfo_t *)Info;
     uptr Addr = (uptr)SigInfo->si_addr;
     if (isShadowMem(Addr)) {
       VPrintf(3, "Shadow fault @%p\n", Addr);
       uptr PageSize = GetPageSizeCached();
       int Res = internal_mprotect((void *)RoundDownTo(Addr, PageSize),
                                   PageSize, PROT_READ|PROT_WRITE);
       CHECK(Res == 0);
     } else if (AppSigAct.sigaction) {
       // FIXME: For simplicity we ignore app options including its signal stack
       // (we just use ours) and all the delivery flags.
       AppSigAct.sigaction(SigNum, Info, Ctx);
     } else {
       // Crash instead of spinning with infinite faults.
       reinstateDefaultHandler(SigNum);
     }
   } else
     UNREACHABLE("signal not registered");
 }

 void registerMemoryFaultHandler() {
   // We do not use an alternate signal stack, as doing so would require
   // setting it up for each app thread.
   // FIXME: This could result in problems with emulating the app's signal
   // handling if the app relies on an alternate stack for SIGSEGV.

   // We require that SIGSEGV is not blocked.  We use a sigprocmask
   // interceptor to ensure that in the future.  Here we ensure it for
   // the current thread.  We assume there are no other threads at this
   // point during initialization, or that at least they do not block
   // SIGSEGV.
   __sanitizer_sigset_t SigSet;
   internal_sigemptyset(&SigSet);
   internal_sigprocmask(SIG_BLOCK, &SigSet, nullptr);

   __sanitizer_sigaction SigAct;
   internal_memset(&SigAct, 0, sizeof(SigAct));
   SigAct.sigaction = handleMemoryFault;
   // We want to handle nested signals b/c we need to handle a
   // shadow fault in an app signal handler.
   SigAct.sa_flags = SA_SIGINFO | SA_NODEFER;
   int Res = internal_sigaction(SIGSEGV, &SigAct, &AppSigAct);
   CHECK(Res == 0);
   VPrintf(1, "Registered for SIGSEGV handler\n");
 }

 } // namespace __esan
	//===-- working_set_posix.cpp ------------------------------------ C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of EfficiencySanitizer, a family of performance tuners.
	//
	// POSIX-specific working set tool code.
	//===----------------------------------------------------------------------===//

	#include "working_set.h"
	#include "esan_flags.h"
	#include "esan_shadow.h"
	#include "sanitizer_common/sanitizer_common.h"
	#include "sanitizer_common/sanitizer_linux.h"
	#include <signal.h>
	#include <sys/mman.h>

	namespace __esan {

	// We only support regular POSIX threads with a single signal handler
	// for the whole process == thread group.
	// Thus we only need to store one app signal handler.
	// FIXME: Store and use any alternate stack and signal flags set by
	// the app. For now we just call the app handler from our handler.
	static __sanitizer_sigaction AppSigAct;

	bool processWorkingSetSignal(int SigNum, void (*Handler)(int),
	void (**Result)(int)) {
	VPrintf(2, "%s: %d\n", __FUNCTION__, SigNum);
	if (SigNum == SIGSEGV) {
	*Result = AppSigAct.handler;
	AppSigAct.sigaction = (decltype(AppSigAct.sigaction))Handler;
	return false; // Skip real call.
	}
	return true;
	}

	bool processWorkingSetSigaction(int SigNum, const void *ActVoid,
	void *OldActVoid) {
	VPrintf(2, "%s: %d\n", __FUNCTION__, SigNum);
	if (SigNum == SIGSEGV) {
	const struct sigaction Act = (const struct sigaction ) ActVoid;
	struct sigaction OldAct = (struct sigaction ) OldActVoid;
	if (OldAct)
	internal_memcpy(OldAct, &AppSigAct, sizeof(OldAct));
	if (Act)
	internal_memcpy(&AppSigAct, Act, sizeof(AppSigAct));
	return false; // Skip real call.
	}
	return true;
	}

	bool processWorkingSetSigprocmask(int How, void Set, void OldSet) {
	VPrintf(2, "%s\n", __FUNCTION__);
	// All we need to do is ensure that SIGSEGV is not blocked.
	// FIXME: we are not fully transparent as we do not pretend that
	// SIGSEGV is still blocked on app queries: that would require
	// per-thread mask tracking.
	if (Set && (How == SIG_BLOCK \|\| How == SIG_SETMASK)) {
	if (internal_sigismember((__sanitizer_sigset_t *)Set, SIGSEGV)) {
	VPrintf(1, "%s: removing SIGSEGV from the blocked set\n", __FUNCTION__);
	internal_sigdelset((__sanitizer_sigset_t *)Set, SIGSEGV);
	}
	}
	return true;
	}

	static void reinstateDefaultHandler(int SigNum) {
	__sanitizer_sigaction SigAct;
	internal_memset(&SigAct, 0, sizeof(SigAct));
	SigAct.sigaction = (decltype(SigAct.sigaction))SIG_DFL;
	int Res = internal_sigaction(SigNum, &SigAct, nullptr);
	CHECK(Res == 0);
	VPrintf(1, "Unregistered for %d handler\n", SigNum);
	}

	// If this is a shadow fault, we handle it here; otherwise, we pass it to the
	// app to handle it just as the app would do without our tool in place.
	static void handleMemoryFault(int SigNum, __sanitizer_siginfo *Info,
	void *Ctx) {
	if (SigNum == SIGSEGV) {
	// We rely on si_addr being filled in (thus we do not support old kernels).
	siginfo_t SigInfo = (siginfo_t )Info;
	uptr Addr = (uptr)SigInfo->si_addr;
	if (isShadowMem(Addr)) {
	VPrintf(3, "Shadow fault @%p\n", Addr);
	uptr PageSize = GetPageSizeCached();
	int Res = internal_mprotect((void *)RoundDownTo(Addr, PageSize),
	PageSize, PROT_READ\|PROT_WRITE);
	CHECK(Res == 0);
	} else if (AppSigAct.sigaction) {
	// FIXME: For simplicity we ignore app options including its signal stack
	// (we just use ours) and all the delivery flags.
	AppSigAct.sigaction(SigNum, Info, Ctx);
	} else {
	// Crash instead of spinning with infinite faults.
	reinstateDefaultHandler(SigNum);
	}
	} else
	UNREACHABLE("signal not registered");
	}

	void registerMemoryFaultHandler() {
	// We do not use an alternate signal stack, as doing so would require
	// setting it up for each app thread.
	// FIXME: This could result in problems with emulating the app's signal
	// handling if the app relies on an alternate stack for SIGSEGV.

	// We require that SIGSEGV is not blocked. We use a sigprocmask
	// interceptor to ensure that in the future. Here we ensure it for
	// the current thread. We assume there are no other threads at this
	// point during initialization, or that at least they do not block
	// SIGSEGV.
	__sanitizer_sigset_t SigSet;
	internal_sigemptyset(&SigSet);
	internal_sigprocmask(SIG_BLOCK, &SigSet, nullptr);

	__sanitizer_sigaction SigAct;
	internal_memset(&SigAct, 0, sizeof(SigAct));
	SigAct.sigaction = handleMemoryFault;
	// We want to handle nested signals b/c we need to handle a
	// shadow fault in an app signal handler.
	SigAct.sa_flags = SA_SIGINFO \| SA_NODEFER;
	int Res = internal_sigaction(SIGSEGV, &SigAct, &AppSigAct);
	CHECK(Res == 0);
	VPrintf(1, "Registered for SIGSEGV handler\n");
	}

	} // namespace __esan