kc3-lang/harfbuzz/src/hb-vector.hh

Branch - branch -main

• Show log

  Commit

• Hash : e1fd2bee
  Author :
  Date : 2025-09-18T11:18:09
  

  [alloc-pool] Reduce memory usage by reclaiming some discards
  

Download

• src/hb-vector.hh

• /*
   * Copyright © 2017,2018  Google, Inc.
   *
   *  This is part of HarfBuzz, a text shaping library.
   *
   * Permission is hereby granted, without written agreement and without
   * license or royalty fees, to use, copy, modify, and distribute this
   * software and its documentation for any purpose, provided that the
   * above copyright notice and the following two paragraphs appear in
   * all copies of this software.
   *
   * IN NO EVENT SHALL THE COPYRIGHT HOLDER BE LIABLE TO ANY PARTY FOR
   * DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES
   * ARISING OUT OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN
   * IF THE COPYRIGHT HOLDER HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH
   * DAMAGE.
   *
   * THE COPYRIGHT HOLDER SPECIFICALLY DISCLAIMS ANY WARRANTIES, INCLUDING,
   * BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND
   * FITNESS FOR A PARTICULAR PURPOSE.  THE SOFTWARE PROVIDED HEREUNDER IS
   * ON AN "AS IS" BASIS, AND THE COPYRIGHT HOLDER HAS NO OBLIGATION TO
   * PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
   *
   * Google Author(s): Behdad Esfahbod
   */
  
  #ifndef HB_VECTOR_HH
  #define HB_VECTOR_HH
  
  #include "hb.hh"
  #include "hb-array.hh"
  #include "hb-meta.hh"
  #include "hb-null.hh"
  
  // Change to 1 to force inline vector allocs, to see callsite in malloc-stats tool.
  #if 0
  #define HB_ALWAYS_INLINE_VECTOR_ALLOCS HB_ALWAYS_INLINE
  #else
  #define HB_ALWAYS_INLINE_VECTOR_ALLOCS
  #endif
  
  template <typename Type,
  	  bool sorted=false>
  struct hb_vector_t
  {
    static constexpr bool realloc_move = true;
  
    typedef Type item_t;
    static constexpr unsigned item_size = hb_static_size (Type);
    using array_t = typename std::conditional<sorted, hb_sorted_array_t<Type>, hb_array_t<Type>>::type;
    using c_array_t = typename std::conditional<sorted, hb_sorted_array_t<const Type>, hb_array_t<const Type>>::type;
  
    hb_vector_t () = default;
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    hb_vector_t (std::initializer_list<Type> lst) : hb_vector_t ()
    {
      alloc (lst.size (), true);
      for (auto&& item : lst)
        push (item);
    }
    template <typename Iterable,
  	    hb_requires (hb_is_iterable (Iterable))>
    explicit hb_vector_t (const Iterable &o) : hb_vector_t ()
    {
      extend (o);
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    hb_vector_t (const hb_vector_t &o) : hb_vector_t ()
    {
      alloc_exact (o.length);
      if (unlikely (in_error ())) return;
      copy_array (o.as_array ());
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    hb_vector_t (array_t o) : hb_vector_t ()
    {
      alloc_exact (o.length);
      if (unlikely (in_error ())) return;
      copy_array (o);
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    hb_vector_t (c_array_t o) : hb_vector_t ()
    {
      alloc_exact (o.length);
      if (unlikely (in_error ())) return;
      copy_array (o);
    }
    hb_vector_t (hb_vector_t &&o) noexcept
    {
      allocated = o.allocated;
      length = o.length;
      arrayZ = o.arrayZ;
      o.init ();
    }
    ~hb_vector_t () { fini (); }
  
    template <unsigned n>
    void
    set_storage (Type (&array)[n])
    { set_storage (array, n); }
    void
    set_storage (hb_array_t<Type> array)
    { set_storage (array.arrayZ, array.length); }
    template <typename T = Type,
  	    hb_enable_if (hb_is_trivially_constructible(T) &&
  			  hb_is_trivially_destructible(T))>
    void
    set_storage (Type *array, unsigned n)
    {
      assert (allocated == 0);
      assert (length == 0);
  
      arrayZ = array;
      length = n;
    }
  
    template <typename Iterable,
  	    hb_requires (hb_is_iterable (Iterable))>
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    void extend (const Iterable &o)
    {
      auto iter = hb_iter (o);
      if (iter.is_random_access_iterator || iter.has_fast_len)
      {
        if (unlikely (!alloc (hb_len (iter), true)))
  	return;
        unsigned count = hb_len (iter);
        for (unsigned i = 0; i < count; i++)
  	push_has_room (*iter++);
      }
      while (iter)
      {
        if (unlikely (!alloc (length + 1)))
          return;
        unsigned room = allocated - length;
        for (unsigned i = 0; i < room && iter; i++)
  	push_has_room (*iter++);
      }
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    void extend (array_t o)
    {
      alloc (length + o.length);
      if (unlikely (in_error ())) return;
      copy_array (o);
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    void extend (c_array_t o)
    {
      alloc (length + o.length);
      if (unlikely (in_error ())) return;
      copy_array (o);
    }
  
    public:
    int allocated = 0; /* < 0 means allocation failed. */
    unsigned int length = 0;
    public:
    Type *arrayZ = nullptr;
  
    void init ()
    {
      allocated = length = 0;
      arrayZ = nullptr;
    }
    void init0 ()
    {
    }
  
    void fini ()
    {
      if (is_owned ())
      {
        shrink_vector (0);
        hb_free (arrayZ);
      }
      init ();
    }
  
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    hb_vector_t &reset ()
    {
      if (unlikely (in_error ()))
        reset_error ();
      resize (0);
      return *this;
    }
  
    friend void swap (hb_vector_t& a, hb_vector_t& b) noexcept
    {
      hb_swap (a.allocated, b.allocated);
      hb_swap (a.length, b.length);
      hb_swap (a.arrayZ, b.arrayZ);
    }
  
    hb_vector_t& operator = (const hb_vector_t &o)
    {
      reset ();
      alloc_exact (o.length);
      if (unlikely (in_error ())) return *this;
  
      length = 0;
      copy_array (o.as_array ());
  
      return *this;
    }
    hb_vector_t& operator = (hb_vector_t &&o) noexcept
    {
      hb_swap (*this, o);
      return *this;
    }
  
    hb_bytes_t as_bytes () const
    { return hb_bytes_t ((const char *) arrayZ, get_size ()); }
  
    bool operator == (const hb_vector_t &o) const { return as_array () == o.as_array (); }
    bool operator != (const hb_vector_t &o) const { return !(*this == o); }
    uint32_t hash () const { return as_array ().hash (); }
  
    Type& operator [] (int i_)
    {
      unsigned int i = (unsigned int) i_;
      if (unlikely (i >= length))
        return Crap (Type);
      return arrayZ[i];
    }
    const Type& operator [] (int i_) const
    {
      unsigned int i = (unsigned int) i_;
      if (unlikely (i >= length))
        return Null (Type);
      return arrayZ[i];
    }
  
    Type& tail () { return (*this)[length - 1]; }
    const Type& tail () const { return (*this)[length - 1]; }
  
    explicit operator bool () const { return length; }
    unsigned get_size () const { return length * item_size; }
  
    /* Sink interface. */
    template <typename T>
    hb_vector_t& operator << (T&& v) { push (std::forward<T> (v)); return *this; }
  
    array_t   as_array ()       { return hb_array (arrayZ, length); }
    c_array_t as_array () const { return hb_array (arrayZ, length); }
  
    /* Iterator. */
    typedef c_array_t   iter_t;
    typedef array_t   writer_t;
      iter_t   iter () const { return as_array (); }
    writer_t writer ()       { return as_array (); }
    operator   iter_t () const { return   iter (); }
    operator writer_t ()       { return writer (); }
  
    /* Faster range-based for loop. */
    Type *begin () const { return arrayZ; }
    Type *end () const { return arrayZ + length; }
  
  
    hb_sorted_array_t<Type> as_sorted_array ()
    { return hb_sorted_array (arrayZ, length); }
    hb_sorted_array_t<const Type> as_sorted_array () const
    { return hb_sorted_array (arrayZ, length); }
  
    template <typename T> explicit operator T * () { return arrayZ; }
    template <typename T> explicit operator const T * () const { return arrayZ; }
  
    Type * operator  + (unsigned int i) { return arrayZ + i; }
    const Type * operator  + (unsigned int i) const { return arrayZ + i; }
  
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    Type *push ()
    {
      if (unlikely (!resize (length + 1)))
        return std::addressof (Crap (Type));
      return std::addressof (arrayZ[length - 1]);
    }
    template <typename... Args>
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    Type *push (Args&&... args)
    {
      if (unlikely ((int) length >= allocated && !alloc (length + 1)))
        // If push failed to allocate then don't copy v, since this may cause
        // the created copy to leak memory since we won't have stored a
        // reference to it.
        return std::addressof (Crap (Type));
  
      return push_has_room (std::forward<Args> (args)...);
    }
    template <typename... Args>
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    Type *push_has_room (Args&&... args)
    {
      /* Emplace. */
      Type *p = std::addressof (arrayZ[length++]);
      return new (p) Type (std::forward<Args> (args)...);
    }
  
    bool is_owned () const
    {
      return allocated != 0 && allocated != -1;
    }
  
    bool in_error () const { return allocated < 0; }
    void set_error ()
    {
      assert (allocated >= 0);
      allocated = -allocated - 1;
    }
    void reset_error ()
    {
      assert (allocated < 0);
      allocated = -(allocated + 1);
    }
  
    Type *
    _realloc (unsigned new_allocated)
    {
      if (!new_allocated)
      {
        if (is_owned ())
  	hb_free (arrayZ);
        return nullptr;
      }
      if (!allocated && arrayZ)
      {
        /* If we have a non-null arrayZ but allocated is 0, then we are
         * reallocating from a foreign array. */
        Type *new_array = (Type *) hb_malloc (new_allocated * sizeof (Type));
        if (unlikely (!new_array))
  	return nullptr;
        hb_memcpy ((void *) new_array, (const void *) arrayZ, length * sizeof (Type));
        return new_array;
      }
      return (Type *) hb_realloc (arrayZ, new_allocated * sizeof (Type));
    }
    Type *
    _malloc_move (unsigned new_allocated)
    {
      if (!new_allocated)
      {
        if (is_owned ())
  	hb_free (arrayZ);
        return nullptr;
      }
      Type *new_array = (Type *) hb_malloc (new_allocated * sizeof (Type));
      if (likely (new_array))
      {
        for (unsigned i = 0; i < length; i++)
        {
  	new (std::addressof (new_array[i])) Type ();
  	new_array[i] = std::move (arrayZ[i]);
  	arrayZ[i].~Type ();
        }
        if (is_owned ())
  	hb_free (arrayZ);
      }
      return new_array;
    }
  
    template <typename T = Type,
  	    hb_enable_if (hb_is_trivially_copy_assignable(T))>
    Type *
    realloc_vector (unsigned new_allocated, hb_priority<0>)
    {
      return _realloc (new_allocated);
    }
    template <typename T = Type,
  	    hb_enable_if (!hb_is_trivially_copy_assignable(T))>
    Type *
    realloc_vector (unsigned new_allocated, hb_priority<0>)
    {
      return _malloc_move (new_allocated);
    }
    /* Specialization for types that can be moved using realloc(). */
    template <typename T = Type,
  	    hb_enable_if (T::realloc_move)>
    Type *
    realloc_vector (unsigned new_allocated, hb_priority<1>)
    {
      return _realloc (new_allocated);
    }
  
    template <typename T = Type,
  	    hb_enable_if (hb_is_trivially_constructible(T))>
    void
    grow_vector (unsigned size, hb_priority<0>)
    {
      hb_memset (arrayZ + length, 0, (size - length) * sizeof (*arrayZ));
      length = size;
    }
    template <typename T = Type,
  	    hb_enable_if (!hb_is_trivially_constructible(T))>
    void
    grow_vector (unsigned size, hb_priority<0>)
    {
      for (; length < size; length++)
        new (std::addressof (arrayZ[length])) Type ();
    }
    /* Specialization for hb_vector_t<hb_{vector,array}_t<U>> to speed up. */
    template <typename T = Type,
  	    hb_enable_if (hb_is_same (T, hb_vector_t<typename T::item_t>) ||
  			  hb_is_same (T, hb_array_t <typename T::item_t>))>
    void
    grow_vector (unsigned size, hb_priority<1>)
    {
      hb_memset (arrayZ + length, 0, (size - length) * sizeof (*arrayZ));
      length = size;
    }
  
    template <typename T = Type,
  	    hb_enable_if (hb_is_trivially_copyable (T))>
    void
    copy_array (hb_array_t<Type> other)
    {
      hb_memcpy ((void *) (arrayZ + length), (const void *) other.arrayZ, other.length * item_size);
      length += other.length;
    }
    template <typename T = Type,
  	    hb_enable_if (hb_is_trivially_copyable (T))>
    void
    copy_array (hb_array_t<const Type> other)
    {
      hb_memcpy ((void *) (arrayZ + length), (const void *) other.arrayZ, other.length * item_size);
      length += other.length;
    }
    template <typename T = Type,
  	    hb_enable_if (!hb_is_trivially_copyable (T) &&
  			   std::is_copy_constructible<T>::value)>
    void
    copy_array (hb_array_t<const Type> other)
    {
      for (unsigned i = 0; i < other.length; i++)
        new (std::addressof (arrayZ[length + i])) Type (other.arrayZ[i]);
      length += other.length;
    }
    template <typename T = Type,
  	    hb_enable_if (!hb_is_trivially_copyable (T) &&
  			  !std::is_copy_constructible<T>::value &&
  			  std::is_default_constructible<T>::value &&
  			  std::is_copy_assignable<T>::value)>
    void
    copy_array (hb_array_t<const Type> other)
    {
      for (unsigned i = 0; i < other.length; i++)
      {
        new (std::addressof (arrayZ[length + i])) Type ();
        arrayZ[length + i] = other.arrayZ[i];
      }
      length += other.length;
    }
  
    void
    shrink_vector (unsigned size)
    {
      assert (size <= length);
      if (!hb_is_trivially_destructible(Type))
      {
        unsigned count = length - size;
        Type *p = arrayZ + length;
        while (count--)
          (--p)->~Type ();
      }
      length = size;
    }
  
    void
    shift_down_vector (unsigned i)
    {
      for (; i < length; i++)
        arrayZ[i - 1] = std::move (arrayZ[i]);
    }
  
    /* Allocate for size but don't adjust length. */
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool alloc (unsigned int size, bool exact=false)
    {
      if (unlikely (in_error ()))
        return false;
  
      unsigned int new_allocated;
      if (exact)
      {
        /* If exact was specified, we allow shrinking the storage. */
        size = hb_max (size, length);
        if (size <= (unsigned) allocated &&
  	  size >= (unsigned) allocated >> 2)
  	return true;
  
        new_allocated = size;
      }
      else
      {
        if (likely (size <= (unsigned) allocated))
  	return true;
  
        new_allocated = allocated;
        while (size > new_allocated)
  	new_allocated += (new_allocated >> 1) + 8;
      }
  
      /* Reallocate */
  
      bool overflows =
        (int) in_error () ||
        (new_allocated < size) ||
        hb_unsigned_mul_overflows (new_allocated, sizeof (Type));
  
      if (unlikely (overflows))
      {
        set_error ();
        return false;
      }
  
      Type *new_array = realloc_vector (new_allocated, hb_prioritize);
  
      if (unlikely (new_allocated && !new_array))
      {
        if (new_allocated <= (unsigned) allocated)
          return true; // shrinking failed; it's okay; happens in our fuzzer
  
        set_error ();
        return false;
      }
  
      arrayZ = new_array;
      allocated = new_allocated;
  
      return true;
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool alloc_exact (unsigned int size)
    {
      return alloc (size, true);
    }
  
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    void clear ()
    {
      resize (0);
    }
  
    template <typename allocator_t>
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool allocate_from_pool (allocator_t *allocator, unsigned size, unsigned int initialize = true)
    {
      if (allocator)
      {
        assert (!length && !allocated);
        arrayZ = (Type *) allocator->alloc (size * sizeof (Type), alignof (Type));
        if (unlikely (!arrayZ))
        {
  	set_error ();
  	return false;
        }
        if (initialize)
  	grow_vector (size, hb_prioritize);
        else
  	length = size;
        return true;
      }
      return resize_full ((int) size, initialize, true);
    }
  
    template <typename allocator_t>
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool allocate_from_pool (allocator_t *allocator, const hb_vector_t &other)
    {
      if (unlikely (!allocate_from_pool (allocator, other.length, false)))
        return false;
      length = 0;
      copy_array (other.as_array ());
      return true;
    }
  
    template <typename allocator_t>
    void shrink_back_to_pool (allocator_t *allocator, int size)
    {
      unsigned orig_length = length;
  
      shrink (size, false);
  
      if (allocator && !is_owned ())
        allocator->discard (arrayZ + length, (orig_length - length) * sizeof (Type));
    }
  
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool resize_full (int size_, bool initialize, bool exact)
    {
      unsigned int size = size_ < 0 ? 0u : (unsigned int) size_;
      if (!alloc (size, exact))
        return false;
  
      if (size > length)
      {
        if (initialize)
  	grow_vector (size, hb_prioritize);
      }
      else if (size < length)
      {
        if (initialize)
  	shrink_vector (size);
      }
  
      length = size;
      return true;
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool resize (int size_)
    {
      return resize_full (size_, true, false);
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool resize_dirty (int size_)
    {
      return resize_full (size_, false, false);
    }
    HB_ALWAYS_INLINE_VECTOR_ALLOCS
    bool resize_exact (int size_)
    {
      return resize_full (size_, true, true);
    }
  
    Type pop ()
    {
      if (!length) return Null (Type);
      Type v (std::move (arrayZ[length - 1]));
      arrayZ[length - 1].~Type ();
      length--;
      return v;
    }
  
    void remove_ordered (unsigned int i)
    {
      if (unlikely (i >= length))
        return;
      shift_down_vector (i + 1);
      arrayZ[length - 1].~Type ();
      length--;
    }
  
    template <bool Sorted = sorted,
  	    hb_enable_if (!Sorted)>
    void remove_unordered (unsigned int i)
    {
      if (unlikely (i >= length))
        return;
      if (i != length - 1)
        arrayZ[i] = std::move (arrayZ[length - 1]);
      arrayZ[length - 1].~Type ();
      length--;
    }
  
    void shrink (int size_, bool shrink_memory = true)
    {
      unsigned int size = size_ < 0 ? 0u : (unsigned int) size_;
      if (size >= length)
        return;
  
      shrink_vector (size);
  
      if (is_owned () && shrink_memory)
        alloc_exact (size); /* To force shrinking memory if needed. */
    }
  
  
    /* Sorting API. */
    void qsort (int (*cmp)(const void*, const void*) = Type::cmp)
    { as_array ().qsort (cmp); }
  
    /* Unsorted search API. */
    template <typename T>
    Type *lsearch (const T &x, Type *not_found = nullptr)
    { return as_array ().lsearch (x, not_found); }
    template <typename T>
    const Type *lsearch (const T &x, const Type *not_found = nullptr) const
    { return as_array ().lsearch (x, not_found); }
    template <typename T>
    bool lfind (const T &x, unsigned *pos = nullptr) const
    { return as_array ().lfind (x, pos); }
  
    /* Sorted search API. */
    template <typename T,
  	    bool Sorted=sorted, hb_enable_if (Sorted)>
    Type *bsearch (const T &x, Type *not_found = nullptr)
    { return as_array ().bsearch (x, not_found); }
    template <typename T,
  	    bool Sorted=sorted, hb_enable_if (Sorted)>
    const Type *bsearch (const T &x, const Type *not_found = nullptr) const
    { return as_array ().bsearch (x, not_found); }
    template <typename T,
  	    bool Sorted=sorted, hb_enable_if (Sorted)>
    bool bfind (const T &x, unsigned int *i = nullptr,
  	      hb_not_found_t not_found = HB_NOT_FOUND_DONT_STORE,
  	      unsigned int to_store = (unsigned int) -1) const
    { return as_array ().bfind (x, i, not_found, to_store); }
  };
  
  template <typename Type>
  using hb_sorted_vector_t = hb_vector_t<Type, true>;
  
  #endif /* HB_VECTOR_HH */
  

Download