compiler-rt/lib/hwasan/hwasan_thread_list.h - llvm-project - Git at Google

 //===-- hwasan_thread_list.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
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of HWAddressSanitizer.
 //
 //===----------------------------------------------------------------------===//

 // HwasanThreadList is a registry for live threads, as well as an allocator for
 // HwasanThread objects and their stack history ring buffers. There are
 // constraints on memory layout of the shadow region and CompactRingBuffer that
 // are part of the ABI contract between compiler-rt and llvm.
 //
 // * Start of the shadow memory region is aligned to 2**kShadowBaseAlignment.
 // * All stack ring buffers are located within (2**kShadowBaseAlignment)
 // sized region below and adjacent to the shadow region.
 // * Each ring buffer has a size of (2**N)*4096 where N is in [0, 8), and is
 // aligned to twice its size. The value of N can be different for each buffer.
 //
 // These constrains guarantee that, given an address A of any element of the
 // ring buffer,
 //     A_next = (A + sizeof(uptr)) & ~((1 << (N + 13)) - 1)
 //   is the address of the next element of that ring buffer (with wrap-around).
 // And, with K = kShadowBaseAlignment,
 //     S = (A | ((1 << K) - 1)) + 1
 //   (align up to kShadowBaseAlignment) is the start of the shadow region.
 //
 // These calculations are used in compiler instrumentation to update the ring
 // buffer and obtain the base address of shadow using only two inputs: address
 // of the current element of the ring buffer, and N (i.e. size of the ring
 // buffer). Since the value of N is very limited, we pack both inputs into a
 // single thread-local word as
 //   (1 << (N + 56)) | A
 // See the implementation of class CompactRingBuffer, which is what is stored in
 // said thread-local word.
 //
 // Note the unusual way of aligning up the address of the shadow:
 //   (A | ((1 << K) - 1)) + 1
 // It is only correct if A is not already equal to the shadow base address, but
 // it saves 2 instructions on AArch64.

 #include "hwasan.h"
 #include "hwasan_allocator.h"
 #include "hwasan_flags.h"
 #include "hwasan_thread.h"

 #include "sanitizer_common/sanitizer_placement_new.h"

 namespace __hwasan {

 static uptr RingBufferSize() {
   uptr desired_bytes = flags()->stack_history_size * sizeof(uptr);
   // FIXME: increase the limit to 8 once this bug is fixed:
   // https://bugs.llvm.org/show_bug.cgi?id=39030
   for (int shift = 1; shift < 7; ++shift) {
     uptr size = 4096 * (1ULL << shift);
     if (size >= desired_bytes)
       return size;
   }
   Printf("stack history size too large: %d\n", flags()->stack_history_size);
   CHECK(0);
   return 0;
 }

 struct ThreadStats {
   uptr n_live_threads;
   uptr total_stack_size;
 };

 class HwasanThreadList {
  public:
   HwasanThreadList(uptr storage, uptr size)
       : free_space_(storage), free_space_end_(storage + size) {
     // [storage, storage + size) is used as a vector of
     // thread_alloc_size_-sized, ring_buffer_size_*2-aligned elements.
     // Each element contains
     // * a ring buffer at offset 0,
     // * a Thread object at offset ring_buffer_size_.
     ring_buffer_size_ = RingBufferSize();
     thread_alloc_size_ =
         RoundUpTo(ring_buffer_size_ + sizeof(Thread), ring_buffer_size_ * 2);
   }

   Thread *CreateCurrentThread(const Thread::InitState *state = nullptr) {
     Thread *t = nullptr;
     {
       SpinMutexLock l(&free_list_mutex_);
       if (!free_list_.empty()) {
         t = free_list_.back();
         free_list_.pop_back();
       }
     }
     if (t) {
       uptr start = (uptr)t - ring_buffer_size_;
       internal_memset((void *)start, 0, ring_buffer_size_ + sizeof(Thread));
     } else {
       t = AllocThread();
     }
     {
       SpinMutexLock l(&live_list_mutex_);
       live_list_.push_back(t);
     }
     t->Init((uptr)t - ring_buffer_size_, ring_buffer_size_, state);
     AddThreadStats(t);
     return t;
   }

   void DontNeedThread(Thread *t) {
     uptr start = (uptr)t - ring_buffer_size_;
     ReleaseMemoryPagesToOS(start, start + thread_alloc_size_);
   }

   void RemoveThreadFromLiveList(Thread *t) {
     SpinMutexLock l(&live_list_mutex_);
     for (Thread *&t2 : live_list_)
       if (t2 == t) {
         // To remove t2, copy the last element of the list in t2's position, and
         // pop_back(). This works even if t2 is itself the last element.
         t2 = live_list_.back();
         live_list_.pop_back();
         return;
       }
     CHECK(0 && "thread not found in live list");
   }

   void ReleaseThread(Thread *t) {
     RemoveThreadStats(t);
     t->Destroy();
     DontNeedThread(t);
     RemoveThreadFromLiveList(t);
     SpinMutexLock l(&free_list_mutex_);
     free_list_.push_back(t);
   }

   Thread *GetThreadByBufferAddress(uptr p) {
     return (Thread *)(RoundDownTo(p, ring_buffer_size_ * 2) +
                       ring_buffer_size_);
   }

   uptr MemoryUsedPerThread() {
     uptr res = sizeof(Thread) + ring_buffer_size_;
     if (auto sz = flags()->heap_history_size)
       res += HeapAllocationsRingBuffer::SizeInBytes(sz);
     return res;
   }

   template <class CB>
   void VisitAllLiveThreads(CB cb) {
     SpinMutexLock l(&live_list_mutex_);
     for (Thread *t : live_list_) cb(t);
   }

   void AddThreadStats(Thread *t) {
     SpinMutexLock l(&stats_mutex_);
     stats_.n_live_threads++;
     stats_.total_stack_size += t->stack_size();
   }

   void RemoveThreadStats(Thread *t) {
     SpinMutexLock l(&stats_mutex_);
     stats_.n_live_threads--;
     stats_.total_stack_size -= t->stack_size();
   }

   ThreadStats GetThreadStats() {
     SpinMutexLock l(&stats_mutex_);
     return stats_;
   }

   uptr GetRingBufferSize() const { return ring_buffer_size_; }

  private:
   Thread *AllocThread() {
     SpinMutexLock l(&free_space_mutex_);
     uptr align = ring_buffer_size_ * 2;
     CHECK(IsAligned(free_space_, align));
     Thread *t = (Thread *)(free_space_ + ring_buffer_size_);
     free_space_ += thread_alloc_size_;
     CHECK(free_space_ <= free_space_end_ && "out of thread memory");
     return t;
   }

   SpinMutex free_space_mutex_;
   uptr free_space_;
   uptr free_space_end_;
   uptr ring_buffer_size_;
   uptr thread_alloc_size_;

   SpinMutex free_list_mutex_;
   InternalMmapVector<Thread *> free_list_;
   SpinMutex live_list_mutex_;
   InternalMmapVector<Thread *> live_list_;

   ThreadStats stats_;
   SpinMutex stats_mutex_;
 };

 void InitThreadList(uptr storage, uptr size);
 HwasanThreadList &hwasanThreadList();

 } // namespace __hwasan
	//===-- hwasan_thread_list.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
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of HWAddressSanitizer.
	//
	//===----------------------------------------------------------------------===//

	// HwasanThreadList is a registry for live threads, as well as an allocator for
	// HwasanThread objects and their stack history ring buffers. There are
	// constraints on memory layout of the shadow region and CompactRingBuffer that
	// are part of the ABI contract between compiler-rt and llvm.
	//
	// * Start of the shadow memory region is aligned to 2**kShadowBaseAlignment.
	// * All stack ring buffers are located within (2**kShadowBaseAlignment)
	// sized region below and adjacent to the shadow region.
	// * Each ring buffer has a size of (2*N)4096 where N is in [0, 8), and is
	// aligned to twice its size. The value of N can be different for each buffer.
	//
	// These constrains guarantee that, given an address A of any element of the
	// ring buffer,
	// A_next = (A + sizeof(uptr)) & ~((1 << (N + 13)) - 1)
	// is the address of the next element of that ring buffer (with wrap-around).
	// And, with K = kShadowBaseAlignment,
	// S = (A \| ((1 << K) - 1)) + 1
	// (align up to kShadowBaseAlignment) is the start of the shadow region.
	//
	// These calculations are used in compiler instrumentation to update the ring
	// buffer and obtain the base address of shadow using only two inputs: address
	// of the current element of the ring buffer, and N (i.e. size of the ring
	// buffer). Since the value of N is very limited, we pack both inputs into a
	// single thread-local word as
	// (1 << (N + 56)) \| A
	// See the implementation of class CompactRingBuffer, which is what is stored in
	// said thread-local word.
	//
	// Note the unusual way of aligning up the address of the shadow:
	// (A \| ((1 << K) - 1)) + 1
	// It is only correct if A is not already equal to the shadow base address, but
	// it saves 2 instructions on AArch64.

	#include "hwasan.h"
	#include "hwasan_allocator.h"
	#include "hwasan_flags.h"
	#include "hwasan_thread.h"

	#include "sanitizer_common/sanitizer_placement_new.h"

	namespace __hwasan {

	static uptr RingBufferSize() {
	uptr desired_bytes = flags()->stack_history_size * sizeof(uptr);
	// FIXME: increase the limit to 8 once this bug is fixed:
	// https://bugs.llvm.org/show_bug.cgi?id=39030
	for (int shift = 1; shift < 7; ++shift) {
	uptr size = 4096 * (1ULL << shift);
	if (size >= desired_bytes)
	return size;
	}
	Printf("stack history size too large: %d\n", flags()->stack_history_size);
	CHECK(0);
	return 0;
	}

	struct ThreadStats {
	uptr n_live_threads;
	uptr total_stack_size;
	};

	class HwasanThreadList {
	public:
	HwasanThreadList(uptr storage, uptr size)
	: free_space_(storage), free_space_end_(storage + size) {
	// [storage, storage + size) is used as a vector of
	// thread_alloc_size_-sized, ring_buffer_size_*2-aligned elements.
	// Each element contains
	// * a ring buffer at offset 0,
	// * a Thread object at offset ring_buffer_size_.
	ring_buffer_size_ = RingBufferSize();
	thread_alloc_size_ =
	RoundUpTo(ring_buffer_size_ + sizeof(Thread), ring_buffer_size_ * 2);
	}

	Thread CreateCurrentThread(const Thread::InitState state = nullptr) {
	Thread *t = nullptr;
	{
	SpinMutexLock l(&free_list_mutex_);
	if (!free_list_.empty()) {
	t = free_list_.back();
	free_list_.pop_back();
	}
	}
	if (t) {
	uptr start = (uptr)t - ring_buffer_size_;
	internal_memset((void *)start, 0, ring_buffer_size_ + sizeof(Thread));
	} else {
	t = AllocThread();
	}
	{
	SpinMutexLock l(&live_list_mutex_);
	live_list_.push_back(t);
	}
	t->Init((uptr)t - ring_buffer_size_, ring_buffer_size_, state);
	AddThreadStats(t);
	return t;
	}

	void DontNeedThread(Thread *t) {
	uptr start = (uptr)t - ring_buffer_size_;
	ReleaseMemoryPagesToOS(start, start + thread_alloc_size_);
	}

	void RemoveThreadFromLiveList(Thread *t) {
	SpinMutexLock l(&live_list_mutex_);
	for (Thread *&t2 : live_list_)
	if (t2 == t) {
	// To remove t2, copy the last element of the list in t2's position, and
	// pop_back(). This works even if t2 is itself the last element.
	t2 = live_list_.back();
	live_list_.pop_back();
	return;
	}
	CHECK(0 && "thread not found in live list");
	}

	void ReleaseThread(Thread *t) {
	RemoveThreadStats(t);
	t->Destroy();
	DontNeedThread(t);
	RemoveThreadFromLiveList(t);
	SpinMutexLock l(&free_list_mutex_);
	free_list_.push_back(t);
	}

	Thread *GetThreadByBufferAddress(uptr p) {
	return (Thread )(RoundDownTo(p, ring_buffer_size_ 2) +
	ring_buffer_size_);
	}

	uptr MemoryUsedPerThread() {
	uptr res = sizeof(Thread) + ring_buffer_size_;
	if (auto sz = flags()->heap_history_size)
	res += HeapAllocationsRingBuffer::SizeInBytes(sz);
	return res;
	}

	template <class CB>
	void VisitAllLiveThreads(CB cb) {
	SpinMutexLock l(&live_list_mutex_);
	for (Thread *t : live_list_) cb(t);
	}

	void AddThreadStats(Thread *t) {
	SpinMutexLock l(&stats_mutex_);
	stats_.n_live_threads++;
	stats_.total_stack_size += t->stack_size();
	}

	void RemoveThreadStats(Thread *t) {
	SpinMutexLock l(&stats_mutex_);
	stats_.n_live_threads--;
	stats_.total_stack_size -= t->stack_size();
	}

	ThreadStats GetThreadStats() {
	SpinMutexLock l(&stats_mutex_);
	return stats_;
	}

	uptr GetRingBufferSize() const { return ring_buffer_size_; }

	private:
	Thread *AllocThread() {
	SpinMutexLock l(&free_space_mutex_);
	uptr align = ring_buffer_size_ * 2;
	CHECK(IsAligned(free_space_, align));
	Thread t = (Thread )(free_space_ + ring_buffer_size_);
	free_space_ += thread_alloc_size_;
	CHECK(free_space_ <= free_space_end_ && "out of thread memory");
	return t;
	}

	SpinMutex free_space_mutex_;
	uptr free_space_;
	uptr free_space_end_;
	uptr ring_buffer_size_;
	uptr thread_alloc_size_;

	SpinMutex free_list_mutex_;
	InternalMmapVector<Thread *> free_list_;
	SpinMutex live_list_mutex_;
	InternalMmapVector<Thread *> live_list_;

	ThreadStats stats_;
	SpinMutex stats_mutex_;
	};

	void InitThreadList(uptr storage, uptr size);
	HwasanThreadList &hwasanThreadList();

	} // namespace __hwasan