compiler-rt/lib/tsan/rtl/tsan_sync.cc - nest-cam/4320010/compiler-rt - Git at Google

 //===-- tsan_sync.cc ------------------------------------------------------===//
 //
 //                     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 ThreadSanitizer (TSan), a race detector.
 //
 //===----------------------------------------------------------------------===//
 #include "sanitizer_common/sanitizer_placement_new.h"
 #include "tsan_sync.h"
 #include "tsan_rtl.h"
 #include "tsan_mman.h"

 namespace __tsan {

 void DDMutexInit(ThreadState *thr, uptr pc, SyncVar *s);

 SyncVar::SyncVar()
     : mtx(MutexTypeSyncVar, StatMtxSyncVar) {
   Reset(0);
 }

 void SyncVar::Init(ThreadState *thr, uptr pc, uptr addr, u64 uid) {
   this->addr = addr;
   this->uid = uid;
   this->next = 0;

   creation_stack_id = 0;
   if (kCppMode)  // Go does not use them
     creation_stack_id = CurrentStackId(thr, pc);
   if (common_flags()->detect_deadlocks)
     DDMutexInit(thr, pc, this);
 }

 void SyncVar::Reset(ThreadState *thr) {
   uid = 0;
   creation_stack_id = 0;
   owner_tid = kInvalidTid;
   last_lock = 0;
   recursion = 0;
   is_rw = 0;
   is_recursive = 0;
   is_broken = 0;
   is_linker_init = 0;

   if (thr == 0) {
     CHECK_EQ(clock.size(), 0);
     CHECK_EQ(read_clock.size(), 0);
   } else {
     clock.Reset(&thr->clock_cache);
     read_clock.Reset(&thr->clock_cache);
   }
 }

 MetaMap::MetaMap() {
   atomic_store(&uid_gen_, 0, memory_order_relaxed);
 }

 void MetaMap::AllocBlock(ThreadState *thr, uptr pc, uptr p, uptr sz) {
   u32 idx = block_alloc_.Alloc(&thr->block_cache);
   MBlock *b = block_alloc_.Map(idx);
   b->siz = sz;
   b->tid = thr->tid;
   b->stk = CurrentStackId(thr, pc);
   u32 *meta = MemToMeta(p);
   DCHECK_EQ(*meta, 0);
   *meta = idx | kFlagBlock;
 }

 uptr MetaMap::FreeBlock(ThreadState *thr, uptr pc, uptr p) {
   MBlock* b = GetBlock(p);
   if (b == 0)
     return 0;
   uptr sz = RoundUpTo(b->siz, kMetaShadowCell);
   FreeRange(thr, pc, p, sz);
   return sz;
 }

 bool MetaMap::FreeRange(ThreadState *thr, uptr pc, uptr p, uptr sz) {
   bool has_something = false;
   u32 *meta = MemToMeta(p);
   u32 *end = MemToMeta(p + sz);
   if (end == meta)
     end++;
   for (; meta < end; meta++) {
     u32 idx = *meta;
     if (idx == 0) {
       // Note: don't write to meta in this case -- the block can be huge.
       continue;
     }
     *meta = 0;
     has_something = true;
     while (idx != 0) {
       if (idx & kFlagBlock) {
         block_alloc_.Free(&thr->block_cache, idx & ~kFlagMask);
         break;
       } else if (idx & kFlagSync) {
         DCHECK(idx & kFlagSync);
         SyncVar *s = sync_alloc_.Map(idx & ~kFlagMask);
         u32 next = s->next;
         s->Reset(thr);
         sync_alloc_.Free(&thr->sync_cache, idx & ~kFlagMask);
         idx = next;
       } else {
         CHECK(0);
       }
     }
   }
   return has_something;
 }

 // ResetRange removes all meta objects from the range.
 // It is called for large mmap-ed regions. The function is best-effort wrt
 // freeing of meta objects, because we don't want to page in the whole range
 // which can be huge. The function probes pages one-by-one until it finds a page
 // without meta objects, at this point it stops freeing meta objects. Because
 // thread stacks grow top-down, we do the same starting from end as well.
 void MetaMap::ResetRange(ThreadState *thr, uptr pc, uptr p, uptr sz) {
   const uptr kMetaRatio = kMetaShadowCell / kMetaShadowSize;
   const uptr kPageSize = GetPageSizeCached() * kMetaRatio;
   if (sz <= 4 * kPageSize) {
     // If the range is small, just do the normal free procedure.
     FreeRange(thr, pc, p, sz);
     return;
   }
   // First, round both ends of the range to page size.
   uptr diff = RoundUp(p, kPageSize) - p;
   if (diff != 0) {
     FreeRange(thr, pc, p, diff);
     p += diff;
     sz -= diff;
   }
   diff = p + sz - RoundDown(p + sz, kPageSize);
   if (diff != 0) {
     FreeRange(thr, pc, p + sz - diff, diff);
     sz -= diff;
   }
   // Now we must have a non-empty page-aligned range.
   CHECK_GT(sz, 0);
   CHECK_EQ(p, RoundUp(p, kPageSize));
   CHECK_EQ(sz, RoundUp(sz, kPageSize));
   const uptr p0 = p;
   const uptr sz0 = sz;
   // Probe start of the range.
   while (sz > 0) {
     bool has_something = FreeRange(thr, pc, p, kPageSize);
     p += kPageSize;
     sz -= kPageSize;
     if (!has_something)
       break;
   }
   // Probe end of the range.
   while (sz > 0) {
     bool has_something = FreeRange(thr, pc, p - kPageSize, kPageSize);
     sz -= kPageSize;
     if (!has_something)
       break;
   }
   // Finally, page out the whole range (including the parts that we've just
   // freed). Note: we can't simply madvise, because we need to leave a zeroed
   // range (otherwise __tsan_java_move can crash if it encounters a left-over
   // meta objects in java heap).
   uptr metap = (uptr)MemToMeta(p0);
   uptr metasz = sz0 / kMetaRatio;
   UnmapOrDie((void*)metap, metasz);
   MmapFixedNoReserve(metap, metasz);
 }

 MBlock* MetaMap::GetBlock(uptr p) {
   u32 *meta = MemToMeta(p);
   u32 idx = *meta;
   for (;;) {
     if (idx == 0)
       return 0;
     if (idx & kFlagBlock)
       return block_alloc_.Map(idx & ~kFlagMask);
     DCHECK(idx & kFlagSync);
     SyncVar * s = sync_alloc_.Map(idx & ~kFlagMask);
     idx = s->next;
   }
 }

 SyncVar* MetaMap::GetOrCreateAndLock(ThreadState *thr, uptr pc,
                               uptr addr, bool write_lock) {
   return GetAndLock(thr, pc, addr, write_lock, true);
 }

 SyncVar* MetaMap::GetIfExistsAndLock(uptr addr) {
   return GetAndLock(0, 0, addr, true, false);
 }

 SyncVar* MetaMap::GetAndLock(ThreadState *thr, uptr pc,
                              uptr addr, bool write_lock, bool create) {
   u32 *meta = MemToMeta(addr);
   u32 idx0 = *meta;
   u32 myidx = 0;
   SyncVar *mys = 0;
   for (;;) {
     u32 idx = idx0;
     for (;;) {
       if (idx == 0)
         break;
       if (idx & kFlagBlock)
         break;
       DCHECK(idx & kFlagSync);
       SyncVar * s = sync_alloc_.Map(idx & ~kFlagMask);
       if (s->addr == addr) {
         if (myidx != 0) {
           mys->Reset(thr);
           sync_alloc_.Free(&thr->sync_cache, myidx);
         }
         if (write_lock)
           s->mtx.Lock();
         else
           s->mtx.ReadLock();
         return s;
       }
       idx = s->next;
     }
     if (!create)
       return 0;
     if (*meta != idx0) {
       idx0 = *meta;
       continue;
     }

     if (myidx == 0) {
       const u64 uid = atomic_fetch_add(&uid_gen_, 1, memory_order_relaxed);
       myidx = sync_alloc_.Alloc(&thr->sync_cache);
       mys = sync_alloc_.Map(myidx);
       mys->Init(thr, pc, addr, uid);
     }
     mys->next = idx0;
     if (atomic_compare_exchange_strong((atomic_uint32_t*)meta, &idx0,
         myidx | kFlagSync, memory_order_release)) {
       if (write_lock)
         mys->mtx.Lock();
       else
         mys->mtx.ReadLock();
       return mys;
     }
   }
 }

 void MetaMap::MoveMemory(uptr src, uptr dst, uptr sz) {
   // src and dst can overlap,
   // there are no concurrent accesses to the regions (e.g. stop-the-world).
   CHECK_NE(src, dst);
   CHECK_NE(sz, 0);
   uptr diff = dst - src;
   u32 *src_meta = MemToMeta(src);
   u32 *dst_meta = MemToMeta(dst);
   u32 *src_meta_end = MemToMeta(src + sz);
   uptr inc = 1;
   if (dst > src) {
     src_meta = MemToMeta(src + sz) - 1;
     dst_meta = MemToMeta(dst + sz) - 1;
     src_meta_end = MemToMeta(src) - 1;
     inc = -1;
   }
   for (; src_meta != src_meta_end; src_meta += inc, dst_meta += inc) {
     CHECK_EQ(*dst_meta, 0);
     u32 idx = *src_meta;
     *src_meta = 0;
     *dst_meta = idx;
     // Patch the addresses in sync objects.
     while (idx != 0) {
       if (idx & kFlagBlock)
         break;
       CHECK(idx & kFlagSync);
       SyncVar *s = sync_alloc_.Map(idx & ~kFlagMask);
       s->addr += diff;
       idx = s->next;
     }
   }
 }

 void MetaMap::OnThreadIdle(ThreadState *thr) {
   block_alloc_.FlushCache(&thr->block_cache);
   sync_alloc_.FlushCache(&thr->sync_cache);
 }

 }  // namespace __tsan
	//===-- tsan_sync.cc ------------------------------------------------------===//
	//
	// 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 ThreadSanitizer (TSan), a race detector.
	//
	//===----------------------------------------------------------------------===//
	#include "sanitizer_common/sanitizer_placement_new.h"
	#include "tsan_sync.h"
	#include "tsan_rtl.h"
	#include "tsan_mman.h"

	namespace __tsan {

	void DDMutexInit(ThreadState thr, uptr pc, SyncVar s);

	SyncVar::SyncVar()
	: mtx(MutexTypeSyncVar, StatMtxSyncVar) {
	Reset(0);
	}

	void SyncVar::Init(ThreadState *thr, uptr pc, uptr addr, u64 uid) {
	this->addr = addr;
	this->uid = uid;
	this->next = 0;

	creation_stack_id = 0;
	if (kCppMode) // Go does not use them
	creation_stack_id = CurrentStackId(thr, pc);
	if (common_flags()->detect_deadlocks)
	DDMutexInit(thr, pc, this);
	}

	void SyncVar::Reset(ThreadState *thr) {
	uid = 0;
	creation_stack_id = 0;
	owner_tid = kInvalidTid;
	last_lock = 0;
	recursion = 0;
	is_rw = 0;
	is_recursive = 0;
	is_broken = 0;
	is_linker_init = 0;

	if (thr == 0) {
	CHECK_EQ(clock.size(), 0);
	CHECK_EQ(read_clock.size(), 0);
	} else {
	clock.Reset(&thr->clock_cache);
	read_clock.Reset(&thr->clock_cache);
	}
	}

	MetaMap::MetaMap() {
	atomic_store(&uid_gen_, 0, memory_order_relaxed);
	}

	void MetaMap::AllocBlock(ThreadState *thr, uptr pc, uptr p, uptr sz) {
	u32 idx = block_alloc_.Alloc(&thr->block_cache);
	MBlock *b = block_alloc_.Map(idx);
	b->siz = sz;
	b->tid = thr->tid;
	b->stk = CurrentStackId(thr, pc);
	u32 *meta = MemToMeta(p);
	DCHECK_EQ(*meta, 0);
	*meta = idx \| kFlagBlock;
	}

	uptr MetaMap::FreeBlock(ThreadState *thr, uptr pc, uptr p) {
	MBlock* b = GetBlock(p);
	if (b == 0)
	return 0;
	uptr sz = RoundUpTo(b->siz, kMetaShadowCell);
	FreeRange(thr, pc, p, sz);
	return sz;
	}

	bool MetaMap::FreeRange(ThreadState *thr, uptr pc, uptr p, uptr sz) {
	bool has_something = false;
	u32 *meta = MemToMeta(p);
	u32 *end = MemToMeta(p + sz);
	if (end == meta)
	end++;
	for (; meta < end; meta++) {
	u32 idx = *meta;
	if (idx == 0) {
	// Note: don't write to meta in this case -- the block can be huge.
	continue;
	}
	*meta = 0;
	has_something = true;
	while (idx != 0) {
	if (idx & kFlagBlock) {
	block_alloc_.Free(&thr->block_cache, idx & ~kFlagMask);
	break;
	} else if (idx & kFlagSync) {
	DCHECK(idx & kFlagSync);
	SyncVar *s = sync_alloc_.Map(idx & ~kFlagMask);
	u32 next = s->next;
	s->Reset(thr);
	sync_alloc_.Free(&thr->sync_cache, idx & ~kFlagMask);
	idx = next;
	} else {
	CHECK(0);
	}
	}
	}
	return has_something;
	}

	// ResetRange removes all meta objects from the range.
	// It is called for large mmap-ed regions. The function is best-effort wrt
	// freeing of meta objects, because we don't want to page in the whole range
	// which can be huge. The function probes pages one-by-one until it finds a page
	// without meta objects, at this point it stops freeing meta objects. Because
	// thread stacks grow top-down, we do the same starting from end as well.
	void MetaMap::ResetRange(ThreadState *thr, uptr pc, uptr p, uptr sz) {
	const uptr kMetaRatio = kMetaShadowCell / kMetaShadowSize;
	const uptr kPageSize = GetPageSizeCached() * kMetaRatio;
	if (sz <= 4 * kPageSize) {
	// If the range is small, just do the normal free procedure.
	FreeRange(thr, pc, p, sz);
	return;
	}
	// First, round both ends of the range to page size.
	uptr diff = RoundUp(p, kPageSize) - p;
	if (diff != 0) {
	FreeRange(thr, pc, p, diff);
	p += diff;
	sz -= diff;
	}
	diff = p + sz - RoundDown(p + sz, kPageSize);
	if (diff != 0) {
	FreeRange(thr, pc, p + sz - diff, diff);
	sz -= diff;
	}
	// Now we must have a non-empty page-aligned range.
	CHECK_GT(sz, 0);
	CHECK_EQ(p, RoundUp(p, kPageSize));
	CHECK_EQ(sz, RoundUp(sz, kPageSize));
	const uptr p0 = p;
	const uptr sz0 = sz;
	// Probe start of the range.
	while (sz > 0) {
	bool has_something = FreeRange(thr, pc, p, kPageSize);
	p += kPageSize;
	sz -= kPageSize;
	if (!has_something)
	break;
	}
	// Probe end of the range.
	while (sz > 0) {
	bool has_something = FreeRange(thr, pc, p - kPageSize, kPageSize);
	sz -= kPageSize;
	if (!has_something)
	break;
	}
	// Finally, page out the whole range (including the parts that we've just
	// freed). Note: we can't simply madvise, because we need to leave a zeroed
	// range (otherwise __tsan_java_move can crash if it encounters a left-over
	// meta objects in java heap).
	uptr metap = (uptr)MemToMeta(p0);
	uptr metasz = sz0 / kMetaRatio;
	UnmapOrDie((void*)metap, metasz);
	MmapFixedNoReserve(metap, metasz);
	}

	MBlock* MetaMap::GetBlock(uptr p) {
	u32 *meta = MemToMeta(p);
	u32 idx = *meta;
	for (;;) {
	if (idx == 0)
	return 0;
	if (idx & kFlagBlock)
	return block_alloc_.Map(idx & ~kFlagMask);
	DCHECK(idx & kFlagSync);
	SyncVar * s = sync_alloc_.Map(idx & ~kFlagMask);
	idx = s->next;
	}
	}

	SyncVar* MetaMap::GetOrCreateAndLock(ThreadState *thr, uptr pc,
	uptr addr, bool write_lock) {
	return GetAndLock(thr, pc, addr, write_lock, true);
	}

	SyncVar* MetaMap::GetIfExistsAndLock(uptr addr) {
	return GetAndLock(0, 0, addr, true, false);
	}

	SyncVar* MetaMap::GetAndLock(ThreadState *thr, uptr pc,
	uptr addr, bool write_lock, bool create) {
	u32 *meta = MemToMeta(addr);
	u32 idx0 = *meta;
	u32 myidx = 0;
	SyncVar *mys = 0;
	for (;;) {
	u32 idx = idx0;
	for (;;) {
	if (idx == 0)
	break;
	if (idx & kFlagBlock)
	break;
	DCHECK(idx & kFlagSync);
	SyncVar * s = sync_alloc_.Map(idx & ~kFlagMask);
	if (s->addr == addr) {
	if (myidx != 0) {
	mys->Reset(thr);
	sync_alloc_.Free(&thr->sync_cache, myidx);
	}
	if (write_lock)
	s->mtx.Lock();
	else
	s->mtx.ReadLock();
	return s;
	}
	idx = s->next;
	}
	if (!create)
	return 0;
	if (*meta != idx0) {
	idx0 = *meta;
	continue;
	}

	if (myidx == 0) {
	const u64 uid = atomic_fetch_add(&uid_gen_, 1, memory_order_relaxed);
	myidx = sync_alloc_.Alloc(&thr->sync_cache);
	mys = sync_alloc_.Map(myidx);
	mys->Init(thr, pc, addr, uid);
	}
	mys->next = idx0;
	if (atomic_compare_exchange_strong((atomic_uint32_t*)meta, &idx0,
	myidx \| kFlagSync, memory_order_release)) {
	if (write_lock)
	mys->mtx.Lock();
	else
	mys->mtx.ReadLock();
	return mys;
	}
	}
	}

	void MetaMap::MoveMemory(uptr src, uptr dst, uptr sz) {
	// src and dst can overlap,
	// there are no concurrent accesses to the regions (e.g. stop-the-world).
	CHECK_NE(src, dst);
	CHECK_NE(sz, 0);
	uptr diff = dst - src;
	u32 *src_meta = MemToMeta(src);
	u32 *dst_meta = MemToMeta(dst);
	u32 *src_meta_end = MemToMeta(src + sz);
	uptr inc = 1;
	if (dst > src) {
	src_meta = MemToMeta(src + sz) - 1;
	dst_meta = MemToMeta(dst + sz) - 1;
	src_meta_end = MemToMeta(src) - 1;
	inc = -1;
	}
	for (; src_meta != src_meta_end; src_meta += inc, dst_meta += inc) {
	CHECK_EQ(*dst_meta, 0);
	u32 idx = *src_meta;
	*src_meta = 0;
	*dst_meta = idx;
	// Patch the addresses in sync objects.
	while (idx != 0) {
	if (idx & kFlagBlock)
	break;
	CHECK(idx & kFlagSync);
	SyncVar *s = sync_alloc_.Map(idx & ~kFlagMask);
	s->addr += diff;
	idx = s->next;
	}
	}
	}

	void MetaMap::OnThreadIdle(ThreadState *thr) {
	block_alloc_.FlushCache(&thr->block_cache);
	sync_alloc_.FlushCache(&thr->sync_cache);
	}

	} // namespace __tsan