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I have a C++ project, run rightly compiled by gcc-4.1.2-46 and gcc-4.4.5-6

But it has an abnormal dead loop while compiled by gcc-4.4.6-3 using -O2.

I use gdb to attach it when the process running, and find the thread is running but the stack does not change.

objdump the program, find that it has 3 instruction jmp to self, like this:

   432f6c:       48 89 c7                mov    %rax,%rdi 
   432f6f:       90                      nop 
   432f70:       e8 b3 e4 fd ff          callq  411428 <_Unwind_Resume@plt> 
   432f75:       eb fe                   jmp    432f75 <_ZN9oceanbase12updateserver11QueryEngine3getERKNS0_5TEKeyE+0x4d5> 
   432f77:       48 8d 7c 24 70          lea    0x70(%rsp),%rdi 
   432f7c:       48 89 c3                mov    %rax,%rbx 
   432f7f:       e8 9c 32 00 00          callq  436220 <_ZN9oceanbase12updateserver12BitLockGuardD1Ev>

I have not used "goto" in code.

When the code is compiled by gcc-4.4.6-3 using -O0,

the jmp to self instruction disappeared

So I doubt it is a bug of gcc-4.4.6.3.

The code is a simple multi-thread Hashmap using BitLock to protect the buckets:

      #define ATOMIC_CAS(val, cmpv, newv) __sync_val_compare_and_swap((val), (cmpv), (newv))
      #define ATOMIC_ADD(val, addv) __sync_add_and_fetch((val), (addv))
      #define ATOMIC_SUB(val, subv) __sync_sub_and_fetch((val), (subv))

      template <typename Key,
                typename Value,
                typename BucketAllocator,
                typename NodeAllocator>
      class LightyHashMap
      {
        struct Node
        {
          Key key;
          Value value;
          union
          {
            Node *next;
            int64_t flag;
          };
        };
        static const int64_t EMPTY_FLAG = 0xffffffffffffffff;
        static const int64_t INIT_UNIT_SIZE = (64L * 1024L / sizeof(Node)) * sizeof(Node);
        typedef Hash<Key> HashFunc;
        typedef Equal<Key> EqualFunc;
        public:
          LightyHashMap(BucketAllocator &bucket_allocator, NodeAllocator &node_allocator);
          ~LightyHashMap();
        private:
          DISALLOW_COPY_AND_ASSIGN(LightyHashMap);
        public:
          int create(const int64_t bucket_num);
          void destroy();
          int clear();
        public:
          inline int insert(const Key &key, const Value &value);
          inline int get(const Key &key, Value &value);
          inline int erase(const Key &key, Value *value = NULL);
          inline int64_t uninit_unit_num() const;
          inline int64_t bucket_using() const;
          inline int64_t size() const;
        private:
          void init_bucket_unit_(const int64_t bucket_pos);
        private:
          BucketAllocator &bucket_allocator_;
          NodeAllocator &node_allocator_;
          int64_t bucket_num_;
          Node *buckets_;
          volatile int64_t uninit_unit_num_;
          uint8_t *init_units_;
          BitLock bit_lock_;
          int64_t bucket_using_;
          int64_t size_;
          HashFunc hash_func_;
          EqualFunc equal_func_;
      };

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::LightyHashMap(
        BucketAllocator &bucket_allocator,
        NodeAllocator &node_allocator) : bucket_allocator_(bucket_allocator),
                                         node_allocator_(node_allocator),
                                         bucket_num_(0),
                                         buckets_(NULL),
                                         uninit_unit_num_(0),
                                         init_units_(NULL),
                                         bucket_using_(0),
                                         size_(0),
                                         hash_func_(),
                                         equal_func_()
      {
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::~LightyHashMap()
      {
        destroy();
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::create(const int64_t bucket_num)
      {
        int ret = common::OB_SUCCESS;
        int64_t uninit_unit_num = (bucket_num * sizeof(Node) / INIT_UNIT_SIZE) \
                                  + ((0 == (bucket_num * sizeof(Node) % INIT_UNIT_SIZE)) ? 0 : 1);
        if (NULL != buckets_)
        {
          ret = common::OB_INIT_TWICE;
        }
        else if (0 >= bucket_num)
        {
          ret = common::OB_INVALID_ARGUMENT;
        }
        else if (NULL == (buckets_ = (Node*)bucket_allocator_.alloc(bucket_num * sizeof(Node))))
        {
          ret = common::OB_MEM_OVERFLOW;
        }
        else if (NULL == (init_units_ = (uint8_t*)bucket_allocator_.alloc(uninit_unit_num * sizeof(uint8_t))))
        {
          ret = common::OB_MEM_OVERFLOW;
        }
        else if (OB_SUCCESS != (ret = bit_lock_.init(bucket_num)))
        {
          // init bit lock fail
        }
        else
        {
          bucket_num_ = bucket_num;
          uninit_unit_num_ = uninit_unit_num;
          memset(init_units_, 0, uninit_unit_num_ * sizeof(uint8_t));
          bucket_using_ = 0;
          size_ = 0;
        }
        if (common::OB_SUCCESS != ret)
        {
          destroy();
        }
        return ret;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      void LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::destroy()
      {
        if (NULL != buckets_)
        {
          if (NULL != init_units_)
          {
            for (int64_t i = 0; i < bucket_num_; i++)
            {
              int64_t unit_pos = i * sizeof(Node) / INIT_UNIT_SIZE;
              uint8_t ov = init_units_[unit_pos];
              if (0 == (ov & 0x80))
              {
                continue;
              }
              Node *iter = buckets_[i].next;
              while (EMPTY_FLAG != buckets_[i].flag
                    && NULL != iter)
              {
                Node *tmp = iter;
                iter = iter->next;
                node_allocator_.free(tmp);
              }
              buckets_[i].flag = EMPTY_FLAG;
            }
          }
          bucket_allocator_.free(buckets_);
          buckets_ = NULL;
        }
        if (NULL != init_units_)
        {
          bucket_allocator_.free(init_units_);
          init_units_ = NULL;
        }
        bit_lock_.destroy();
        bucket_num_ = 0;
        uninit_unit_num_ = 0;
        bucket_using_ = 0;
        size_ = 0;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::clear()
      {
        int ret = common::OB_SUCCESS;
        if (NULL == buckets_
            || NULL == init_units_)
        {
          ret = common::OB_NOT_INIT;
        }
        else
        {
          for (int64_t i = 0; i < bucket_num_; i++)
          {
            int64_t unit_pos = i * sizeof(Node) / INIT_UNIT_SIZE;
            uint8_t ov = init_units_[unit_pos];
            if (0 == (ov & 0x80))
            {
              continue;
            }
            BitLockGuard guard(bit_lock_, i);
            Node *iter = buckets_[i].next;
            while (EMPTY_FLAG != buckets_[i].flag
                  && NULL != iter)
            {
              Node *tmp = iter;
              iter = iter->next;
              node_allocator_.free(tmp);
            }
            buckets_[i].flag = EMPTY_FLAG;
          }
          uninit_unit_num_ = (bucket_num_ * sizeof(Node) / INIT_UNIT_SIZE) \
                              + ((0 == (bucket_num_ * sizeof(Node) % INIT_UNIT_SIZE)) ? 0 : 1);
          memset(init_units_, 0, uninit_unit_num_ * sizeof(Node));
          bucket_using_ = 0;
          size_ = 0;
        }
        return ret;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::insert(const Key &key, const Value &value)
      {
        int ret = common::OB_SUCCESS;
        if (NULL == buckets_
            || NULL == init_units_)
        {
          ret = common::OB_NOT_INIT;
        }
        else
        {
          int64_t hash_value = hash_func_(key);
          int64_t bucket_pos = hash_value % bucket_num_;
          init_bucket_unit_(bucket_pos);
          BitLockGuard guard(bit_lock_, bucket_pos);
          if (EMPTY_FLAG == buckets_[bucket_pos].flag)
          {
            buckets_[bucket_pos].key = key;
            buckets_[bucket_pos].value = value;
            buckets_[bucket_pos].next = NULL;
            common::atomic_inc((uint64_t*)&bucket_using_);
            common::atomic_inc((uint64_t*)&size_);
          }
          else
          {
            Node *iter = &(buckets_[bucket_pos]);
            while (true)
            {
              if (equal_func_(iter->key, key))
              {
                ret = common::OB_ENTRY_EXIST;
                break;
              }
              if (NULL != iter->next)
              {
                iter = iter->next;
              }
              else
              {
                break;
              }
            }
            if (common::OB_SUCCESS == ret)
            {
              Node *node = (Node*)node_allocator_.alloc(sizeof(Node));
              if(NULL == node)
              {
                ret = common::OB_MEM_OVERFLOW;
              }
              else
              {
                node->key = key;
                node->value = value;
                node->next = NULL;
                iter->next = node;
                common::atomic_inc((uint64_t*)&size_);
              }
            }
          }
        }
        return ret;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::get(const Key &key, Value &value)
      {
        int ret = common::OB_SUCCESS;
        if (NULL == buckets_
            || NULL == init_units_)
        {
          ret = common::OB_NOT_INIT;
        }
        else
        {
          int64_t hash_value = hash_func_(key);
          int64_t bucket_pos = hash_value % bucket_num_;
          init_bucket_unit_(bucket_pos);
          BitLockGuard guard(bit_lock_, bucket_pos);
          ret = common::OB_ENTRY_NOT_EXIST;
          if (EMPTY_FLAG != buckets_[bucket_pos].flag)
          {
            Node *iter = &(buckets_[bucket_pos]);
            while (NULL != iter)
            {
              if (equal_func_(iter->key, key))
              {
                value = iter->value;
                ret = common::OB_SUCCESS;
                break;
              }
              iter = iter->next;
            }
          }
        }
        return ret;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::erase(const Key &key, Value *value)
      {
        int ret = common::OB_SUCCESS;
        if (NULL == buckets_
            || NULL == init_units_)
        {
          ret = common::OB_NOT_INIT;
        }
        else
        {
          int64_t hash_value = hash_func_(key);
          int64_t bucket_pos = hash_value % bucket_num_;
          init_bucket_unit_(bucket_pos);
          BitLockGuard guard(bit_lock_, bucket_pos);
          ret = common::OB_ENTRY_NOT_EXIST;
          if (EMPTY_FLAG != buckets_[bucket_pos].flag)
          {
            Node *iter = &(buckets_[bucket_pos]);
            Node *prev = NULL;
            while (NULL != iter)
            {
              if (equal_func_(iter->key, key))
              {
                if (NULL != value)
                {
                  *value = iter->value;
                }
                if (NULL == prev)
                {
                  buckets_[bucket_pos].flag = EMPTY_FLAG;
                }
                else
                {
                  // do not free deleted node
                  prev->next = iter->next;
                }
                ret = common::OB_SUCCESS;
                break;
              }
              prev = iter;
              iter = iter->next;
            }
          }
        }
        return ret;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int64_t LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::uninit_unit_num() const
      {
        return uninit_unit_num_;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int64_t LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::bucket_using() const
      {
        return bucket_using_;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      int64_t LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::size() const
      {
        return size_;
      }

      template <typename Key, typename Value, typename BucketAllocator, typename NodeAllocator>
      void LightyHashMap<Key, Value, BucketAllocator, NodeAllocator>::init_bucket_unit_(const int64_t bucket_pos)
      {
        while (0 < uninit_unit_num_)
        {
          int64_t unit_pos = bucket_pos * sizeof(Node) / INIT_UNIT_SIZE;
          uint8_t ov = init_units_[unit_pos];
          if (ov & 0x80)
          {
            break;
          }
          ov = 0;
          uint8_t nv = ov | 0x01;
          if (ov == ATOMIC_CAS(&(init_units_[unit_pos]), ov, nv))
          {
            int64_t ms_size = std::min((bucket_num_ - bucket_pos) * sizeof(Node), (uint64_t)INIT_UNIT_SIZE);
            memset((char*)buckets_ + unit_pos * INIT_UNIT_SIZE, -1, ms_size);
            ATOMIC_SUB(&uninit_unit_num_, 1);
            init_units_[unit_pos] = 0x80;
            break;
          }
        }
      }

//////////////////////////////////////////////////////////////////////////////////////////

static const uint8_t BIT_MASKS[8] = {0x01, 0x02, 0x04, 0x08, 0x10, 0x20, 0x40, 0x80};

class BitLock
{
  public:
    BitLock() : size_(0),
                bits_(NULL)
    {
    };
    ~BitLock()
    {
      destroy();
    };
  public:
    inline int init(const int64_t size);
    inline void destroy();
    inline int lock(const int64_t index);
    inline int unlock(const int64_t index);
  private:
    int64_t size_;
    uint8_t *bits_;
};

class BitLockGuard
{
  public:
    BitLockGuard(BitLock &lock, const int64_t index) : lock_(lock),
                                                       index_(index)
    {
      lock_.lock(index_);
    };
    ~BitLockGuard()
    {
      lock_.unlock(index_);
    };
  private:
    BitLock &lock_;
    const int64_t index_;
};

int BitLock::init(const int64_t size)
{
  int ret = common::OB_SUCCESS;
  if (0 < size_
      || NULL != bits_)
  {
    ret = common::OB_INIT_TWICE;
  }
  else if (0 >= size)
  {
    ret = common::OB_INVALID_ARGUMENT;
  }
  else
  {
    int64_t byte_size = common::upper_align(size, 8) / 8;
    if (NULL == (bits_ = (uint8_t*)common::ob_malloc(byte_size)))
    {
      ret = common::OB_MEM_OVERFLOW;
    }
    else
    {
      memset(bits_, 0, byte_size);
      size_ = size;
    }
  }
  return ret;
}

void BitLock::destroy()
{
  if (NULL != bits_)
  {
    common::ob_free(bits_);
    bits_ = NULL;
  }
  size_ = 0;
}

int BitLock::lock(const int64_t index)
{
  int ret = common::OB_SUCCESS;
  if (0 >= size_
      || NULL == bits_)
  {
    ret = common::OB_NOT_INIT;
  }
  else if (index >= size_)
  {
    ret = common::OB_INVALID_ARGUMENT;
  }
  else
  {
    int64_t byte_index = index / 8;
    int64_t bit_index = index % 8;
    while (true)
    {
      uint8_t ov = bits_[byte_index];
      if (ov & BIT_MASKS[bit_index])
      {
        continue;
      }
      if (ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov | BIT_MASKS[bit_index]))
      {
        break;
      }
    }
  }
  return ret;
}

int BitLock::unlock(const int64_t index)
{
  int ret = common::OB_SUCCESS;
  if (0 >= size_
      || NULL == bits_)
  {
    ret = common::OB_NOT_INIT;
  }
  else if (index >= size_)
  {
    ret = common::OB_INVALID_ARGUMENT;
  }
  else
  {
    int64_t byte_index = index / 8;
    int64_t bit_index = index % 8;
    while (true)
    {
      uint8_t ov = bits_[byte_index];
      if (!(ov & BIT_MASKS[bit_index]))
      {
        // have not locked
        break;
      }
      if (ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov & ~BIT_MASKS[bit_index]))
      {
        break;
      }
    }
  }
  return ret;
}
share|improve this question
4  
With no code, noone can help you. Try to create a SSCCE that demonstrates the problem. –  Chris Dodd Mar 16 '13 at 5:08
    
It's not only goto that can cause your application to go into a loop. –  Mark Garcia Mar 16 '13 at 5:11
    
You possibly could be looking at some form of inlining of a function where the compiler decides to simply jump to the code block rather than making an actual call. It's hard to say without seeing the original code. –  Jason Mar 16 '13 at 5:44

2 Answers 2

up vote 2 down vote accepted

I suspect the problem is in your loop in BitLock::lock:

    while (true)
    {
      uint8_t ov = bits_[byte_index];
      if (ov & BIT_MASKS[bit_index])
      {
        continue;
      }
      if (ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov | BIT_MASKS[bit_index]))
      {
        break;
      }
    }

The __sync_val_compare_and_swap in your ATOMIC_CAS macro will act as memory barrier, preventing the compiler/processor from speculating loads across it, but it won't do anything about loads before it, so the condition ov & BIT_MASKS[bit_index] could be optimized based on the value of bits_[byte_index] before the __sync_val_compare_and_swap call and thus resulting in an infinite loop.

Try the following, instead:

    while (true)
    {
      uint8_t ov = bits_[byte_index];
      if (ov & BIT_MASKS[bit_index])
      {
        __sync_synchronize();  // or define ATOMIC_SYNC if you prefer
        continue;
      }
      if (ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov | BIT_MASKS[bit_index]))
      {
        break;
      }
    }

The __sync_synchronize memory barrier will prevent the loop from degenerating into a trivial one.

share|improve this answer
    
Yes, it does not generate a infinite loop when I add the __sync_synchronize() or asm("pause") or modify the code like: if (!(ov & BIT_MASKS[bit_index]) && ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov | BIT_MASKS[bit_index])) –  user2176204 Mar 17 '13 at 1:58
    
OK, good to know...also, just to caution, I'm pretty sure that even if (!(ov & BIT_MASKS[bit_index]) && ov == ATOMIC_CAS(&(bits_[byte_index]), ov, ov | BIT_MASKS[bit_index])) might happen to work, I don't think it's reliable; if the former condition is false, there's nothing stopping the compiler from doing the exact same optimization as in your original code, and it very well might in a later version of GCC. So you should put an explicit memory barrier, because that's what you need for the semantics to be correct. –  Stephen Lin Mar 17 '13 at 6:19
    
Also, your solutions other might work to prevent the compiler from reordering loads, but it does nothing to stop a sufficiently smart processor from doing the same. –  Stephen Lin Mar 17 '13 at 6:20
    
Yes, I found that use "volatile" to declare the "bits_", also making the compiler generate correct instructions; But I think that using __sync_synchronize() can make both the compiler and the processor to work correctly –  user2176204 Mar 17 '13 at 8:14
    
@user2176204 to be honest (although I think you should put one anyway) you might technically be OK with just volatile and without a memory fence here, since a processor (unlike a compiler) will presumably not loop indefinitely based on a cached load, but I'm not 100% sure if it's guaranteed or not. I'm going to post a new question about this, because I'm curious. –  Stephen Lin Mar 17 '13 at 21:08

Update:

The _Unwind_Resume function will

Resume the unwind process, called at the end of cleanup code that didn't return to the normal thread of execution (ie, not a catch).

See The Secret Life of C++: Day 3: Exceptions

which according to this

It's needed for pthread_cancel. It resumes unwinding after a cleanup.

So it seems there is an exception in a thread for which there is no catch... given that the behavior is different with different versions of gcc and different optimization levels I would venture that you are using threads and have a race condition.

share|improve this answer

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