lib/scudo/standalone/common.h - compiler-rt - Git at Google

 //===-- common.h ------------------------------------------------*- 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
 //
 //===----------------------------------------------------------------------===//

 #ifndef SCUDO_COMMON_H_
 #define SCUDO_COMMON_H_

 #include "internal_defs.h"

 #include "fuchsia.h"
 #include "linux.h"

 #include <stddef.h>
 #include <string.h>

 namespace scudo {

 template <class Dest, class Source> INLINE Dest bit_cast(const Source &S) {
   COMPILER_CHECK(sizeof(Dest) == sizeof(Source));
   Dest D;
   memcpy(&D, &S, sizeof(D));
   return D;
 }

 INLINE constexpr uptr roundUpTo(uptr X, uptr Boundary) {
   return (X + Boundary - 1) & ~(Boundary - 1);
 }

 INLINE constexpr uptr roundDownTo(uptr X, uptr Boundary) {
   return X & ~(Boundary - 1);
 }

 INLINE constexpr bool isAligned(uptr X, uptr Alignment) {
   return (X & (Alignment - 1)) == 0;
 }

 template <class T> constexpr T Min(T A, T B) { return A < B ? A : B; }

 template <class T> constexpr T Max(T A, T B) { return A > B ? A : B; }

 template <class T> void Swap(T &A, T &B) {
   T Tmp = A;
   A = B;
   B = Tmp;
 }

 INLINE bool isPowerOfTwo(uptr X) { return (X & (X - 1)) == 0; }

 INLINE uptr getMostSignificantSetBitIndex(uptr X) {
   DCHECK_NE(X, 0U);
   return SCUDO_WORDSIZE - 1U - static_cast<uptr>(__builtin_clzl(X));
 }

 INLINE uptr roundUpToPowerOfTwo(uptr Size) {
   DCHECK(Size);
   if (isPowerOfTwo(Size))
     return Size;
   const uptr Up = getMostSignificantSetBitIndex(Size);
   DCHECK_LT(Size, (1UL << (Up + 1)));
   DCHECK_GT(Size, (1UL << Up));
   return 1UL << (Up + 1);
 }

 INLINE uptr getLeastSignificantSetBitIndex(uptr X) {
   DCHECK_NE(X, 0U);
   return static_cast<uptr>(__builtin_ctzl(X));
 }

 INLINE uptr getLog2(uptr X) {
   DCHECK(isPowerOfTwo(X));
   return getLeastSignificantSetBitIndex(X);
 }

 INLINE u32 getRandomU32(u32 *State) {
   // ANSI C linear congruential PRNG (16-bit output).
   // return (*State = *State * 1103515245 + 12345) >> 16;
   // XorShift (32-bit output).
   *State ^= *State << 13;
   *State ^= *State >> 17;
   *State ^= *State << 5;
   return *State;
 }

 INLINE u32 getRandomModN(u32 *State, u32 N) {
   return getRandomU32(State) % N; // [0, N)
 }

 template <typename T> INLINE void shuffle(T *A, u32 N, u32 *RandState) {
   if (N <= 1)
     return;
   u32 State = *RandState;
   for (u32 I = N - 1; I > 0; I--)
     Swap(A[I], A[getRandomModN(&State, I + 1)]);
   *RandState = State;
 }

 // Hardware specific inlinable functions.

 INLINE void yieldProcessor(u8 Count) {
 #if defined(__i386__) || defined(__x86_64__)
   __asm__ __volatile__("" ::: "memory");
   for (u8 I = 0; I < Count; I++)
     __asm__ __volatile__("pause");
 #elif defined(__aarch64__) || defined(__arm__)
   __asm__ __volatile__("" ::: "memory");
   for (u8 I = 0; I < Count; I++)
     __asm__ __volatile__("yield");
 #endif
   __asm__ __volatile__("" ::: "memory");
 }

 // Platform specific functions.

 extern uptr PageSizeCached;
 uptr getPageSizeSlow();
 INLINE uptr getPageSizeCached() {
   // Bionic uses a hardcoded value.
   if (SCUDO_ANDROID)
     return 4096U;
   if (LIKELY(PageSizeCached))
     return PageSizeCached;
   return getPageSizeSlow();
 }

 u32 getNumberOfCPUs();

 const char *getEnv(const char *Name);

 u64 getMonotonicTime();

 // Our randomness gathering function is limited to 256 bytes to ensure we get
 // as many bytes as requested, and avoid interruptions (on Linux).
 constexpr uptr MaxRandomLength = 256U;
 bool getRandom(void *Buffer, uptr Length, bool Blocking = false);

 // Platform memory mapping functions.

 #define MAP_ALLOWNOMEM (1U << 0)
 #define MAP_NOACCESS (1U << 1)
 #define MAP_RESIZABLE (1U << 2)

 // Our platform memory mapping use is restricted to 3 scenarios:
 // - reserve memory at a random address (MAP_NOACCESS);
 // - commit memory in a previously reserved space;
 // - commit memory at a random address.
 // As such, only a subset of parameters combinations is valid, which is checked
 // by the function implementation. The Data parameter allows to pass opaque
 // platform specific data to the function.
 // Returns nullptr on error or dies if MAP_ALLOWNOMEM is not specified.
 void *map(void *Addr, uptr Size, const char *Name, uptr Flags = 0,
           MapPlatformData *Data = nullptr);

 // Indicates that we are getting rid of the whole mapping, which might have
 // further consequences on Data, depending on the platform.
 #define UNMAP_ALL (1U << 0)

 void unmap(void *Addr, uptr Size, uptr Flags = 0,
            MapPlatformData *Data = nullptr);

 void releasePagesToOS(uptr BaseAddress, uptr Offset, uptr Size,
                       MapPlatformData *Data = nullptr);

 // Internal map & unmap fatal error. This must not call map().
 void NORETURN dieOnMapUnmapError(bool OutOfMemory = false);

 // Logging related functions.

 void setAbortMessage(const char *Message);

 } // namespace scudo

 #endif // SCUDO_COMMON_H_
	//===-- common.h ------------------------------------------------- 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
	//
	//===----------------------------------------------------------------------===//

	#ifndef SCUDO_COMMON_H_
	#define SCUDO_COMMON_H_

	#include "internal_defs.h"

	#include "fuchsia.h"
	#include "linux.h"

	#include <stddef.h>
	#include <string.h>

	namespace scudo {

	template <class Dest, class Source> INLINE Dest bit_cast(const Source &S) {
	COMPILER_CHECK(sizeof(Dest) == sizeof(Source));
	Dest D;
	memcpy(&D, &S, sizeof(D));
	return D;
	}

	INLINE constexpr uptr roundUpTo(uptr X, uptr Boundary) {
	return (X + Boundary - 1) & ~(Boundary - 1);
	}

	INLINE constexpr uptr roundDownTo(uptr X, uptr Boundary) {
	return X & ~(Boundary - 1);
	}

	INLINE constexpr bool isAligned(uptr X, uptr Alignment) {
	return (X & (Alignment - 1)) == 0;
	}

	template <class T> constexpr T Min(T A, T B) { return A < B ? A : B; }

	template <class T> constexpr T Max(T A, T B) { return A > B ? A : B; }

	template <class T> void Swap(T &A, T &B) {
	T Tmp = A;
	A = B;
	B = Tmp;
	}

	INLINE bool isPowerOfTwo(uptr X) { return (X & (X - 1)) == 0; }

	INLINE uptr getMostSignificantSetBitIndex(uptr X) {
	DCHECK_NE(X, 0U);
	return SCUDO_WORDSIZE - 1U - static_cast<uptr>(__builtin_clzl(X));
	}

	INLINE uptr roundUpToPowerOfTwo(uptr Size) {
	DCHECK(Size);
	if (isPowerOfTwo(Size))
	return Size;
	const uptr Up = getMostSignificantSetBitIndex(Size);
	DCHECK_LT(Size, (1UL << (Up + 1)));
	DCHECK_GT(Size, (1UL << Up));
	return 1UL << (Up + 1);
	}

	INLINE uptr getLeastSignificantSetBitIndex(uptr X) {
	DCHECK_NE(X, 0U);
	return static_cast<uptr>(__builtin_ctzl(X));
	}

	INLINE uptr getLog2(uptr X) {
	DCHECK(isPowerOfTwo(X));
	return getLeastSignificantSetBitIndex(X);
	}

	INLINE u32 getRandomU32(u32 *State) {
	// ANSI C linear congruential PRNG (16-bit output).
	// return (State = State * 1103515245 + 12345) >> 16;
	// XorShift (32-bit output).
	State ^= State << 13;
	State ^= State >> 17;
	State ^= State << 5;
	return *State;
	}

	INLINE u32 getRandomModN(u32 *State, u32 N) {
	return getRandomU32(State) % N; // [0, N)
	}

	template <typename T> INLINE void shuffle(T A, u32 N, u32 RandState) {
	if (N <= 1)
	return;
	u32 State = *RandState;
	for (u32 I = N - 1; I > 0; I--)
	Swap(A[I], A[getRandomModN(&State, I + 1)]);
	*RandState = State;
	}

	// Hardware specific inlinable functions.

	INLINE void yieldProcessor(u8 Count) {
	#if defined(__i386__) \|\| defined(__x86_64__)
	__asm__ __volatile__("" ::: "memory");
	for (u8 I = 0; I < Count; I++)
	__asm__ __volatile__("pause");
	#elif defined(__aarch64__) \|\| defined(__arm__)
	__asm__ __volatile__("" ::: "memory");
	for (u8 I = 0; I < Count; I++)
	__asm__ __volatile__("yield");
	#endif
	__asm__ __volatile__("" ::: "memory");
	}

	// Platform specific functions.

	extern uptr PageSizeCached;
	uptr getPageSizeSlow();
	INLINE uptr getPageSizeCached() {
	// Bionic uses a hardcoded value.
	if (SCUDO_ANDROID)
	return 4096U;
	if (LIKELY(PageSizeCached))
	return PageSizeCached;
	return getPageSizeSlow();
	}

	u32 getNumberOfCPUs();

	const char getEnv(const char Name);

	u64 getMonotonicTime();

	// Our randomness gathering function is limited to 256 bytes to ensure we get
	// as many bytes as requested, and avoid interruptions (on Linux).
	constexpr uptr MaxRandomLength = 256U;
	bool getRandom(void *Buffer, uptr Length, bool Blocking = false);

	// Platform memory mapping functions.

	#define MAP_ALLOWNOMEM (1U << 0)
	#define MAP_NOACCESS (1U << 1)
	#define MAP_RESIZABLE (1U << 2)

	// Our platform memory mapping use is restricted to 3 scenarios:
	// - reserve memory at a random address (MAP_NOACCESS);
	// - commit memory in a previously reserved space;
	// - commit memory at a random address.
	// As such, only a subset of parameters combinations is valid, which is checked
	// by the function implementation. The Data parameter allows to pass opaque
	// platform specific data to the function.
	// Returns nullptr on error or dies if MAP_ALLOWNOMEM is not specified.
	void map(void Addr, uptr Size, const char *Name, uptr Flags = 0,
	MapPlatformData *Data = nullptr);

	// Indicates that we are getting rid of the whole mapping, which might have
	// further consequences on Data, depending on the platform.
	#define UNMAP_ALL (1U << 0)

	void unmap(void *Addr, uptr Size, uptr Flags = 0,
	MapPlatformData *Data = nullptr);

	void releasePagesToOS(uptr BaseAddress, uptr Offset, uptr Size,
	MapPlatformData *Data = nullptr);

	// Internal map & unmap fatal error. This must not call map().
	void NORETURN dieOnMapUnmapError(bool OutOfMemory = false);

	// Logging related functions.

	void setAbortMessage(const char *Message);

	} // namespace scudo

	#endif // SCUDO_COMMON_H_