libphobos/libdruntime/rt/aaA.d - gcc - Git at Google

 /**
  * Implementation of associative arrays.
  *
  * Copyright: Copyright Digital Mars 2000 - 2015.
  * License:   $(WEB www.boost.org/LICENSE_1_0.txt, Boost License 1.0).
  * Authors:   Martin Nowak
  */
 module rt.aaA;

 /// AA version for debuggers, bump whenever changing the layout
 extern (C) immutable int _aaVersion = 1;

 import core.memory : GC;

 // grow threshold
 private enum GROW_NUM = 4;
 private enum GROW_DEN = 5;
 // shrink threshold
 private enum SHRINK_NUM = 1;
 private enum SHRINK_DEN = 8;
 // grow factor
 private enum GROW_FAC = 4;
 // growing the AA doubles it's size, so the shrink threshold must be
 // smaller than half the grow threshold to have a hysteresis
 static assert(GROW_FAC * SHRINK_NUM * GROW_DEN < GROW_NUM * SHRINK_DEN);
 // initial load factor (for literals), mean of both thresholds
 private enum INIT_NUM = (GROW_DEN * SHRINK_NUM + GROW_NUM * SHRINK_DEN) / 2;
 private enum INIT_DEN = SHRINK_DEN * GROW_DEN;

 private enum INIT_NUM_BUCKETS = 8;
 // magic hash constants to distinguish empty, deleted, and filled buckets
 private enum HASH_EMPTY = 0;
 private enum HASH_DELETED = 0x1;
 private enum HASH_FILLED_MARK = size_t(1) << 8 * size_t.sizeof - 1;

 /// Opaque AA wrapper
 struct AA
 {
     Impl* impl;
     alias impl this;

     private @property bool empty() const pure nothrow @nogc
     {
         return impl is null || !impl.length;
     }
 }

 private struct Impl
 {
 private:
     this(in TypeInfo_AssociativeArray ti, size_t sz = INIT_NUM_BUCKETS)
     {
         keysz = cast(uint) ti.key.tsize;
         valsz = cast(uint) ti.value.tsize;
         buckets = allocBuckets(sz);
         firstUsed = cast(uint) buckets.length;
         entryTI = fakeEntryTI(ti.key, ti.value);
         valoff = cast(uint) talign(keysz, ti.value.talign);

         import rt.lifetime : hasPostblit, unqualify;

         if (hasPostblit(unqualify(ti.key)))
             flags |= Flags.keyHasPostblit;
         if ((ti.key.flags | ti.value.flags) & 1)
             flags |= Flags.hasPointers;
     }

     Bucket[] buckets;
     uint used;
     uint deleted;
     TypeInfo_Struct entryTI;
     uint firstUsed;
     immutable uint keysz;
     immutable uint valsz;
     immutable uint valoff;
     Flags flags;

     enum Flags : ubyte
     {
         none = 0x0,
         keyHasPostblit = 0x1,
         hasPointers = 0x2,
     }

     @property size_t length() const pure nothrow @nogc
     {
         assert(used >= deleted);
         return used - deleted;
     }

     @property size_t dim() const pure nothrow @nogc @safe
     {
         return buckets.length;
     }

     @property size_t mask() const pure nothrow @nogc
     {
         return dim - 1;
     }

     // find the first slot to insert a value with hash
     inout(Bucket)* findSlotInsert(size_t hash) inout pure nothrow @nogc
     {
         for (size_t i = hash & mask, j = 1;; ++j)
         {
             if (!buckets[i].filled)
                 return &buckets[i];
             i = (i + j) & mask;
         }
     }

     // lookup a key
     inout(Bucket)* findSlotLookup(size_t hash, in void* pkey, in TypeInfo keyti) inout
     {
         for (size_t i = hash & mask, j = 1;; ++j)
         {
             if (buckets[i].hash == hash && keyti.equals(pkey, buckets[i].entry))
                 return &buckets[i];
             else if (buckets[i].empty)
                 return null;
             i = (i + j) & mask;
         }
     }

     void grow(in TypeInfo keyti)
     {
         // If there are so many deleted entries, that growing would push us
         // below the shrink threshold, we just purge deleted entries instead.
         if (length * SHRINK_DEN < GROW_FAC * dim * SHRINK_NUM)
             resize(dim);
         else
             resize(GROW_FAC * dim);
     }

     void shrink(in TypeInfo keyti)
     {
         if (dim > INIT_NUM_BUCKETS)
             resize(dim / GROW_FAC);
     }

     void resize(size_t ndim) pure nothrow
     {
         auto obuckets = buckets;
         buckets = allocBuckets(ndim);

         foreach (ref b; obuckets[firstUsed .. $])
             if (b.filled)
                 *findSlotInsert(b.hash) = b;

         firstUsed = 0;
         used -= deleted;
         deleted = 0;
         GC.free(obuckets.ptr); // safe to free b/c impossible to reference
     }

     void clear() pure nothrow
     {
         import core.stdc.string : memset;
         // clear all data, but don't change bucket array length
         memset(&buckets[firstUsed], 0, (buckets.length - firstUsed) * Bucket.sizeof);
         deleted = used = 0;
         firstUsed = cast(uint) dim;
     }
 }

 //==============================================================================
 // Bucket
 //------------------------------------------------------------------------------

 private struct Bucket
 {
 private pure nothrow @nogc:
     size_t hash;
     void* entry;

     @property bool empty() const
     {
         return hash == HASH_EMPTY;
     }

     @property bool deleted() const
     {
         return hash == HASH_DELETED;
     }

     @property bool filled() const @safe
     {
         return cast(ptrdiff_t) hash < 0;
     }
 }

 Bucket[] allocBuckets(size_t dim) @trusted pure nothrow
 {
     enum attr = GC.BlkAttr.NO_INTERIOR;
     immutable sz = dim * Bucket.sizeof;
     return (cast(Bucket*) GC.calloc(sz, attr))[0 .. dim];
 }

 //==============================================================================
 // Entry
 //------------------------------------------------------------------------------

 private void* allocEntry(in Impl* aa, in void* pkey)
 {
     import rt.lifetime : _d_newitemU;
     import core.stdc.string : memcpy, memset;

     immutable akeysz = aa.valoff;
     void* res = void;
     if (aa.entryTI)
         res = _d_newitemU(aa.entryTI);
     else
     {
         auto flags = (aa.flags & Impl.Flags.hasPointers) ? 0 : GC.BlkAttr.NO_SCAN;
         res = GC.malloc(akeysz + aa.valsz, flags);
     }

     memcpy(res, pkey, aa.keysz); // copy key
     memset(res + akeysz, 0, aa.valsz); // zero value

     return res;
 }

 package void entryDtor(void* p, const TypeInfo_Struct sti)
 {
     // key and value type info stored after the TypeInfo_Struct by tiEntry()
     auto sizeti = __traits(classInstanceSize, TypeInfo_Struct);
     auto extra = cast(const(TypeInfo)*)(cast(void*) sti + sizeti);
     extra[0].destroy(p);
     extra[1].destroy(p + talign(extra[0].tsize, extra[1].talign));
 }

 private bool hasDtor(const TypeInfo ti)
 {
     import rt.lifetime : unqualify;

     if (typeid(ti) is typeid(TypeInfo_Struct))
         if ((cast(TypeInfo_Struct) cast(void*) ti).xdtor)
             return true;
     if (typeid(ti) is typeid(TypeInfo_StaticArray))
         return hasDtor(unqualify(ti.next));

     return false;
 }

 // build type info for Entry with additional key and value fields
 TypeInfo_Struct fakeEntryTI(const TypeInfo keyti, const TypeInfo valti)
 {
     import rt.lifetime : unqualify;

     auto kti = unqualify(keyti);
     auto vti = unqualify(valti);
     if (!hasDtor(kti) && !hasDtor(vti))
         return null;

     // save kti and vti after type info for struct
     enum sizeti = __traits(classInstanceSize, TypeInfo_Struct);
     void* p = GC.malloc(sizeti + 2 * (void*).sizeof);
     import core.stdc.string : memcpy;

     memcpy(p, typeid(TypeInfo_Struct).initializer().ptr, sizeti);

     auto ti = cast(TypeInfo_Struct) p;
     auto extra = cast(TypeInfo*)(p + sizeti);
     extra[0] = cast() kti;
     extra[1] = cast() vti;

     static immutable tiName = __MODULE__ ~ ".Entry!(...)";
     ti.name = tiName;

     // we don't expect the Entry objects to be used outside of this module, so we have control
     // over the non-usage of the callback methods and other entries and can keep these null
     // xtoHash, xopEquals, xopCmp, xtoString and xpostblit
     ti.m_RTInfo = rtinfoNoPointers;
     immutable entrySize = talign(kti.tsize, vti.talign) + vti.tsize;
     ti.m_init = (cast(ubyte*) null)[0 .. entrySize]; // init length, but not ptr

     // xdtor needs to be built from the dtors of key and value for the GC
     ti.xdtorti = &entryDtor;

     ti.m_flags = TypeInfo_Struct.StructFlags.isDynamicType;
     ti.m_flags |= (keyti.flags | valti.flags) & TypeInfo_Struct.StructFlags.hasPointers;
     ti.m_align = cast(uint) max(kti.talign, vti.talign);

     return ti;
 }

 //==============================================================================
 // Helper functions
 //------------------------------------------------------------------------------

 private size_t talign(size_t tsize, size_t algn) @safe pure nothrow @nogc
 {
     immutable mask = algn - 1;
     assert(!(mask & algn));
     return (tsize + mask) & ~mask;
 }

 // mix hash to "fix" bad hash functions
 private size_t mix(size_t h) @safe pure nothrow @nogc
 {
     // final mix function of MurmurHash2
     enum m = 0x5bd1e995;
     h ^= h >> 13;
     h *= m;
     h ^= h >> 15;
     return h;
 }

 private size_t calcHash(in void* pkey, in TypeInfo keyti)
 {
     immutable hash = keyti.getHash(pkey);
     // highest bit is set to distinguish empty/deleted from filled buckets
     return mix(hash) | HASH_FILLED_MARK;
 }

 private size_t nextpow2(in size_t n) pure nothrow @nogc
 {
     import core.bitop : bsr;

     if (!n)
         return 1;

     const isPowerOf2 = !((n - 1) & n);
     return 1 << (bsr(n) + !isPowerOf2);
 }

 pure nothrow @nogc unittest
 {
     //                            0, 1, 2, 3, 4, 5, 6, 7, 8,  9
     foreach (const n, const pow2; [1, 1, 2, 4, 4, 8, 8, 8, 8, 16])
         assert(nextpow2(n) == pow2);
 }

 private T min(T)(T a, T b) pure nothrow @nogc
 {
     return a < b ? a : b;
 }

 private T max(T)(T a, T b) pure nothrow @nogc
 {
     return b < a ? a : b;
 }

 //==============================================================================
 // API Implementation
 //------------------------------------------------------------------------------

 /// Determine number of entries in associative array.
 extern (C) size_t _aaLen(in AA aa) pure nothrow @nogc
 {
     return aa ? aa.length : 0;
 }

 /******************************
  * Lookup *pkey in aa.
  * Called only from implementation of (aa[key]) expressions when value is mutable.
  * Params:
  *      aa = associative array opaque pointer
  *      ti = TypeInfo for the associative array
  *      valsz = ignored
  *      pkey = pointer to the key value
  * Returns:
  *      if key was in the aa, a mutable pointer to the existing value.
  *      If key was not in the aa, a mutable pointer to newly inserted value which
  *      is set to all zeros
  */
 extern (C) void* _aaGetY(AA* aa, const TypeInfo_AssociativeArray ti,
     in size_t valsz, in void* pkey)
 {
     bool found;
     return _aaGetX(aa, ti, valsz, pkey, found);
 }

 /******************************
  * Lookup *pkey in aa.
  * Called only from implementation of require
  * Params:
  *      aa = associative array opaque pointer
  *      ti = TypeInfo for the associative array
  *      valsz = ignored
  *      pkey = pointer to the key value
  *      found = true if the value was found
  * Returns:
  *      if key was in the aa, a mutable pointer to the existing value.
  *      If key was not in the aa, a mutable pointer to newly inserted value which
  *      is set to all zeros
  */
 extern (C) void* _aaGetX(AA* aa, const TypeInfo_AssociativeArray ti,
     in size_t valsz, in void* pkey, out bool found)
 {
     // lazily alloc implementation
     if (aa.impl is null)
         aa.impl = new Impl(ti);

     // get hash and bucket for key
     immutable hash = calcHash(pkey, ti.key);

     // found a value => return it
     if (auto p = aa.findSlotLookup(hash, pkey, ti.key))
     {
         found = true;
         return p.entry + aa.valoff;
     }

     auto p = aa.findSlotInsert(hash);
     if (p.deleted)
         --aa.deleted;
     // check load factor and possibly grow
     else if (++aa.used * GROW_DEN > aa.dim * GROW_NUM)
     {
         aa.grow(ti.key);
         p = aa.findSlotInsert(hash);
         assert(p.empty);
     }

     // update search cache and allocate entry
     aa.firstUsed = min(aa.firstUsed, cast(uint)(p - aa.buckets.ptr));
     p.hash = hash;
     p.entry = allocEntry(aa.impl, pkey);
     // postblit for key
     if (aa.flags & Impl.Flags.keyHasPostblit)
     {
         import rt.lifetime : __doPostblit, unqualify;

         __doPostblit(p.entry, aa.keysz, unqualify(ti.key));
     }
     // return pointer to value
     return p.entry + aa.valoff;
 }

 /******************************
  * Lookup *pkey in aa.
  * Called only from implementation of (aa[key]) expressions when value is not mutable.
  * Params:
  *      aa = associative array opaque pointer
  *      keyti = TypeInfo for the key
  *      valsz = ignored
  *      pkey = pointer to the key value
  * Returns:
  *      pointer to value if present, null otherwise
  */
 extern (C) inout(void)* _aaGetRvalueX(inout AA aa, in TypeInfo keyti, in size_t valsz,
     in void* pkey)
 {
     return _aaInX(aa, keyti, pkey);
 }

 /******************************
  * Lookup *pkey in aa.
  * Called only from implementation of (key in aa) expressions.
  * Params:
  *      aa = associative array opaque pointer
  *      keyti = TypeInfo for the key
  *      pkey = pointer to the key value
  * Returns:
  *      pointer to value if present, null otherwise
  */
 extern (C) inout(void)* _aaInX(inout AA aa, in TypeInfo keyti, in void* pkey)
 {
     if (aa.empty)
         return null;

     immutable hash = calcHash(pkey, keyti);
     if (auto p = aa.findSlotLookup(hash, pkey, keyti))
         return p.entry + aa.valoff;
     return null;
 }

 /// Delete entry in AA, return true if it was present
 extern (C) bool _aaDelX(AA aa, in TypeInfo keyti, in void* pkey)
 {
     if (aa.empty)
         return false;

     immutable hash = calcHash(pkey, keyti);
     if (auto p = aa.findSlotLookup(hash, pkey, keyti))
     {
         // clear entry
         p.hash = HASH_DELETED;
         p.entry = null;

         ++aa.deleted;
         if (aa.length * SHRINK_DEN < aa.dim * SHRINK_NUM)
             aa.shrink(keyti);

         return true;
     }
     return false;
 }

 /// Remove all elements from AA.
 extern (C) void _aaClear(AA aa) pure nothrow
 {
     if (!aa.empty)
     {
         aa.impl.clear();
     }
 }

 /// Rehash AA
 extern (C) void* _aaRehash(AA* paa, in TypeInfo keyti) pure nothrow
 {
     if (!paa.empty)
         paa.resize(nextpow2(INIT_DEN * paa.length / INIT_NUM));
     return *paa;
 }

 /// Return a GC allocated array of all values
 extern (C) inout(void[]) _aaValues(inout AA aa, in size_t keysz, in size_t valsz,
     const TypeInfo tiValueArray) pure nothrow
 {
     if (aa.empty)
         return null;

     import rt.lifetime : _d_newarrayU;

     auto res = _d_newarrayU(tiValueArray, aa.length).ptr;
     auto pval = res;

     immutable off = aa.valoff;
     foreach (b; aa.buckets[aa.firstUsed .. $])
     {
         if (!b.filled)
             continue;
         pval[0 .. valsz] = b.entry[off .. valsz + off];
         pval += valsz;
     }
     // postblit is done in object.values
     return (cast(inout(void)*) res)[0 .. aa.length]; // fake length, return number of elements
 }

 /// Return a GC allocated array of all keys
 extern (C) inout(void[]) _aaKeys(inout AA aa, in size_t keysz, const TypeInfo tiKeyArray) pure nothrow
 {
     if (aa.empty)
         return null;

     import rt.lifetime : _d_newarrayU;

     auto res = _d_newarrayU(tiKeyArray, aa.length).ptr;
     auto pkey = res;

     foreach (b; aa.buckets[aa.firstUsed .. $])
     {
         if (!b.filled)
             continue;
         pkey[0 .. keysz] = b.entry[0 .. keysz];
         pkey += keysz;
     }
     // postblit is done in object.keys
     return (cast(inout(void)*) res)[0 .. aa.length]; // fake length, return number of elements
 }

 // opApply callbacks are extern(D)
 extern (D) alias dg_t = int delegate(void*);
 extern (D) alias dg2_t = int delegate(void*, void*);

 /// foreach opApply over all values
 extern (C) int _aaApply(AA aa, in size_t keysz, dg_t dg)
 {
     if (aa.empty)
         return 0;

     immutable off = aa.valoff;
     foreach (b; aa.buckets)
     {
         if (!b.filled)
             continue;
         if (auto res = dg(b.entry + off))
             return res;
     }
     return 0;
 }

 /// foreach opApply over all key/value pairs
 extern (C) int _aaApply2(AA aa, in size_t keysz, dg2_t dg)
 {
     if (aa.empty)
         return 0;

     immutable off = aa.valoff;
     foreach (b; aa.buckets)
     {
         if (!b.filled)
             continue;
         if (auto res = dg(b.entry, b.entry + off))
             return res;
     }
     return 0;
 }

 /// Construct an associative array of type ti from keys and value
 extern (C) Impl* _d_assocarrayliteralTX(const TypeInfo_AssociativeArray ti, void[] keys,
     void[] vals)
 {
     assert(keys.length == vals.length);

     immutable keysz = ti.key.tsize;
     immutable valsz = ti.value.tsize;
     immutable length = keys.length;

     if (!length)
         return null;

     auto aa = new Impl(ti, nextpow2(INIT_DEN * length / INIT_NUM));

     void* pkey = keys.ptr;
     void* pval = vals.ptr;
     immutable off = aa.valoff;
     uint actualLength = 0;
     foreach (_; 0 .. length)
     {
         immutable hash = calcHash(pkey, ti.key);

         auto p = aa.findSlotLookup(hash, pkey, ti.key);
         if (p is null)
         {
             p = aa.findSlotInsert(hash);
             p.hash = hash;
             p.entry = allocEntry(aa, pkey); // move key, no postblit
             aa.firstUsed = min(aa.firstUsed, cast(uint)(p - aa.buckets.ptr));
             actualLength++;
         }
         else if (aa.entryTI && hasDtor(ti.value))
         {
             // destroy existing value before overwriting it
             ti.value.destroy(p.entry + off);
         }
         // set hash and blit value
         auto pdst = p.entry + off;
         pdst[0 .. valsz] = pval[0 .. valsz]; // move value, no postblit

         pkey += keysz;
         pval += valsz;
     }
     aa.used = actualLength;
     return aa;
 }

 /// compares 2 AAs for equality
 extern (C) int _aaEqual(in TypeInfo tiRaw, in AA aa1, in AA aa2)
 {
     if (aa1.impl is aa2.impl)
         return true;

     immutable len = _aaLen(aa1);
     if (len != _aaLen(aa2))
         return false;

     if (!len) // both empty
         return true;

     import rt.lifetime : unqualify;

     auto uti = unqualify(tiRaw);
     auto ti = *cast(TypeInfo_AssociativeArray*)&uti;
     // compare the entries
     immutable off = aa1.valoff;
     foreach (b1; aa1.buckets)
     {
         if (!b1.filled)
             continue;
         auto pb2 = aa2.findSlotLookup(b1.hash, b1.entry, ti.key);
         if (pb2 is null || !ti.value.equals(b1.entry + off, pb2.entry + off))
             return false;
     }
     return true;
 }

 /// compute a hash
 extern (C) hash_t _aaGetHash(in AA* aa, in TypeInfo tiRaw) nothrow
 {
     if (aa.empty)
         return 0;

     import rt.lifetime : unqualify;

     auto uti = unqualify(tiRaw);
     auto ti = *cast(TypeInfo_AssociativeArray*)&uti;
     immutable off = aa.valoff;
     auto keyHash = &ti.key.getHash;
     auto valHash = &ti.value.getHash;

     size_t h;
     foreach (b; aa.buckets)
     {
         if (!b.filled)
             continue;
         size_t[2] h2 = [keyHash(b.entry), valHash(b.entry + off)];
         // use addition here, so that hash is independent of element order
         h += hashOf(h2);
     }

     return h;
 }

 /**
  * _aaRange implements a ForwardRange
  */
 struct Range
 {
     Impl* impl;
     size_t idx;
     alias impl this;
 }

 extern (C) pure nothrow @nogc @safe
 {
     Range _aaRange(AA aa)
     {
         if (!aa)
             return Range();

         foreach (i; aa.firstUsed .. aa.dim)
         {
             if (aa.buckets[i].filled)
                 return Range(aa.impl, i);
         }
         return Range(aa, aa.dim);
     }

     bool _aaRangeEmpty(Range r)
     {
         return r.impl is null || r.idx >= r.dim;
     }

     void* _aaRangeFrontKey(Range r)
     {
         assert(!_aaRangeEmpty(r));
         if (r.idx >= r.dim)
             return null;
         return r.buckets[r.idx].entry;
     }

     void* _aaRangeFrontValue(Range r)
     {
         assert(!_aaRangeEmpty(r));
         if (r.idx >= r.dim)
             return null;

         auto entry = r.buckets[r.idx].entry;
         return entry is null ?
             null :
             (() @trusted { return entry + r.valoff; } ());
     }

     void _aaRangePopFront(ref Range r)
     {
         if (r.idx >= r.dim) return;
         for (++r.idx; r.idx < r.dim; ++r.idx)
         {
             if (r.buckets[r.idx].filled)
                 break;
         }
     }
 }

 // Most tests are now in in test_aa.d

 // test postblit for AA literals
 unittest
 {
     static struct T
     {
         ubyte field;
         static size_t postblit, dtor;
         this(this)
         {
             ++postblit;
         }

         ~this()
         {
             ++dtor;
         }
     }

     T t;
     auto aa1 = [0 : t, 1 : t];
     assert(T.dtor == 0 && T.postblit == 2);
     aa1[0] = t;
     assert(T.dtor == 1 && T.postblit == 3);

     T.dtor = 0;
     T.postblit = 0;

     auto aa2 = [0 : t, 1 : t, 0 : t]; // literal with duplicate key => value overwritten
     assert(T.dtor == 1 && T.postblit == 3);

     T.dtor = 0;
     T.postblit = 0;

     auto aa3 = [t : 0];
     assert(T.dtor == 0 && T.postblit == 1);
     aa3[t] = 1;
     assert(T.dtor == 0 && T.postblit == 1);
     aa3.remove(t);
     assert(T.dtor == 0 && T.postblit == 1);
     aa3[t] = 2;
     assert(T.dtor == 0 && T.postblit == 2);

     // dtor will be called by GC finalizers
     aa1 = null;
     aa2 = null;
     aa3 = null;
     GC.runFinalizers((cast(char*)(&entryDtor))[0 .. 1]);
     assert(T.dtor == 6 && T.postblit == 2);
 }
	/**
	* Implementation of associative arrays.
	*
	* Copyright: Copyright Digital Mars 2000 - 2015.
	* License: $(WEB www.boost.org/LICENSE_1_0.txt, Boost License 1.0).
	* Authors: Martin Nowak
	*/
	module rt.aaA;

	/// AA version for debuggers, bump whenever changing the layout
	extern (C) immutable int _aaVersion = 1;

	import core.memory : GC;

	// grow threshold
	private enum GROW_NUM = 4;
	private enum GROW_DEN = 5;
	// shrink threshold
	private enum SHRINK_NUM = 1;
	private enum SHRINK_DEN = 8;
	// grow factor
	private enum GROW_FAC = 4;
	// growing the AA doubles it's size, so the shrink threshold must be
	// smaller than half the grow threshold to have a hysteresis
	static assert(GROW_FAC * SHRINK_NUM * GROW_DEN < GROW_NUM * SHRINK_DEN);
	// initial load factor (for literals), mean of both thresholds
	private enum INIT_NUM = (GROW_DEN * SHRINK_NUM + GROW_NUM * SHRINK_DEN) / 2;
	private enum INIT_DEN = SHRINK_DEN * GROW_DEN;

	private enum INIT_NUM_BUCKETS = 8;
	// magic hash constants to distinguish empty, deleted, and filled buckets
	private enum HASH_EMPTY = 0;
	private enum HASH_DELETED = 0x1;
	private enum HASH_FILLED_MARK = size_t(1) << 8 * size_t.sizeof - 1;

	/// Opaque AA wrapper
	struct AA
	{
	Impl* impl;
	alias impl this;

	private @property bool empty() const pure nothrow @nogc
	{
	return impl is null \|\| !impl.length;
	}
	}

	private struct Impl
	{
	private:
	this(in TypeInfo_AssociativeArray ti, size_t sz = INIT_NUM_BUCKETS)
	{
	keysz = cast(uint) ti.key.tsize;
	valsz = cast(uint) ti.value.tsize;
	buckets = allocBuckets(sz);
	firstUsed = cast(uint) buckets.length;
	entryTI = fakeEntryTI(ti.key, ti.value);
	valoff = cast(uint) talign(keysz, ti.value.talign);

	import rt.lifetime : hasPostblit, unqualify;

	if (hasPostblit(unqualify(ti.key)))
	flags \|= Flags.keyHasPostblit;
	if ((ti.key.flags \| ti.value.flags) & 1)
	flags \|= Flags.hasPointers;
	}

	Bucket[] buckets;
	uint used;
	uint deleted;
	TypeInfo_Struct entryTI;
	uint firstUsed;
	immutable uint keysz;
	immutable uint valsz;
	immutable uint valoff;
	Flags flags;

	enum Flags : ubyte
	{
	none = 0x0,
	keyHasPostblit = 0x1,
	hasPointers = 0x2,
	}

	@property size_t length() const pure nothrow @nogc
	{
	assert(used >= deleted);
	return used - deleted;
	}

	@property size_t dim() const pure nothrow @nogc @safe
	{
	return buckets.length;
	}

	@property size_t mask() const pure nothrow @nogc
	{
	return dim - 1;
	}

	// find the first slot to insert a value with hash
	inout(Bucket)* findSlotInsert(size_t hash) inout pure nothrow @nogc
	{
	for (size_t i = hash & mask, j = 1;; ++j)
	{
	if (!buckets[i].filled)
	return &buckets[i];
	i = (i + j) & mask;
	}
	}

	// lookup a key
	inout(Bucket)* findSlotLookup(size_t hash, in void* pkey, in TypeInfo keyti) inout
	{
	for (size_t i = hash & mask, j = 1;; ++j)
	{
	if (buckets[i].hash == hash && keyti.equals(pkey, buckets[i].entry))
	return &buckets[i];
	else if (buckets[i].empty)
	return null;
	i = (i + j) & mask;
	}
	}

	void grow(in TypeInfo keyti)
	{
	// If there are so many deleted entries, that growing would push us
	// below the shrink threshold, we just purge deleted entries instead.
	if (length * SHRINK_DEN < GROW_FAC * dim * SHRINK_NUM)
	resize(dim);
	else
	resize(GROW_FAC * dim);
	}

	void shrink(in TypeInfo keyti)
	{
	if (dim > INIT_NUM_BUCKETS)
	resize(dim / GROW_FAC);
	}

	void resize(size_t ndim) pure nothrow
	{
	auto obuckets = buckets;
	buckets = allocBuckets(ndim);

	foreach (ref b; obuckets[firstUsed .. $])
	if (b.filled)
	*findSlotInsert(b.hash) = b;

	firstUsed = 0;
	used -= deleted;
	deleted = 0;
	GC.free(obuckets.ptr); // safe to free b/c impossible to reference
	}

	void clear() pure nothrow
	{
	import core.stdc.string : memset;
	// clear all data, but don't change bucket array length
	memset(&buckets[firstUsed], 0, (buckets.length - firstUsed) * Bucket.sizeof);
	deleted = used = 0;
	firstUsed = cast(uint) dim;
	}
	}

	//==============================================================================
	// Bucket
	//------------------------------------------------------------------------------

	private struct Bucket
	{
	private pure nothrow @nogc:
	size_t hash;
	void* entry;

	@property bool empty() const
	{
	return hash == HASH_EMPTY;
	}

	@property bool deleted() const
	{
	return hash == HASH_DELETED;
	}

	@property bool filled() const @safe
	{
	return cast(ptrdiff_t) hash < 0;
	}
	}

	Bucket[] allocBuckets(size_t dim) @trusted pure nothrow
	{
	enum attr = GC.BlkAttr.NO_INTERIOR;
	immutable sz = dim * Bucket.sizeof;
	return (cast(Bucket*) GC.calloc(sz, attr))[0 .. dim];
	}

	//==============================================================================
	// Entry
	//------------------------------------------------------------------------------

	private void* allocEntry(in Impl* aa, in void* pkey)
	{
	import rt.lifetime : _d_newitemU;
	import core.stdc.string : memcpy, memset;

	immutable akeysz = aa.valoff;
	void* res = void;
	if (aa.entryTI)
	res = _d_newitemU(aa.entryTI);
	else
	{
	auto flags = (aa.flags & Impl.Flags.hasPointers) ? 0 : GC.BlkAttr.NO_SCAN;
	res = GC.malloc(akeysz + aa.valsz, flags);
	}

	memcpy(res, pkey, aa.keysz); // copy key
	memset(res + akeysz, 0, aa.valsz); // zero value

	return res;
	}

	package void entryDtor(void* p, const TypeInfo_Struct sti)
	{
	// key and value type info stored after the TypeInfo_Struct by tiEntry()
	auto sizeti = __traits(classInstanceSize, TypeInfo_Struct);
	auto extra = cast(const(TypeInfo))(cast(void) sti + sizeti);
	extra[0].destroy(p);
	extra[1].destroy(p + talign(extra[0].tsize, extra[1].talign));
	}

	private bool hasDtor(const TypeInfo ti)
	{
	import rt.lifetime : unqualify;

	if (typeid(ti) is typeid(TypeInfo_Struct))
	if ((cast(TypeInfo_Struct) cast(void*) ti).xdtor)
	return true;
	if (typeid(ti) is typeid(TypeInfo_StaticArray))
	return hasDtor(unqualify(ti.next));

	return false;
	}

	// build type info for Entry with additional key and value fields
	TypeInfo_Struct fakeEntryTI(const TypeInfo keyti, const TypeInfo valti)
	{
	import rt.lifetime : unqualify;

	auto kti = unqualify(keyti);
	auto vti = unqualify(valti);
	if (!hasDtor(kti) && !hasDtor(vti))
	return null;

	// save kti and vti after type info for struct
	enum sizeti = __traits(classInstanceSize, TypeInfo_Struct);
	void* p = GC.malloc(sizeti + 2 * (void*).sizeof);
	import core.stdc.string : memcpy;

	memcpy(p, typeid(TypeInfo_Struct).initializer().ptr, sizeti);

	auto ti = cast(TypeInfo_Struct) p;
	auto extra = cast(TypeInfo*)(p + sizeti);
	extra[0] = cast() kti;
	extra[1] = cast() vti;

	static immutable tiName = __MODULE__ ~ ".Entry!(...)";
	ti.name = tiName;

	// we don't expect the Entry objects to be used outside of this module, so we have control
	// over the non-usage of the callback methods and other entries and can keep these null
	// xtoHash, xopEquals, xopCmp, xtoString and xpostblit
	ti.m_RTInfo = rtinfoNoPointers;
	immutable entrySize = talign(kti.tsize, vti.talign) + vti.tsize;
	ti.m_init = (cast(ubyte*) null)[0 .. entrySize]; // init length, but not ptr

	// xdtor needs to be built from the dtors of key and value for the GC
	ti.xdtorti = &entryDtor;

	ti.m_flags = TypeInfo_Struct.StructFlags.isDynamicType;
	ti.m_flags \|= (keyti.flags \| valti.flags) & TypeInfo_Struct.StructFlags.hasPointers;
	ti.m_align = cast(uint) max(kti.talign, vti.talign);

	return ti;
	}

	//==============================================================================
	// Helper functions
	//------------------------------------------------------------------------------

	private size_t talign(size_t tsize, size_t algn) @safe pure nothrow @nogc
	{
	immutable mask = algn - 1;
	assert(!(mask & algn));
	return (tsize + mask) & ~mask;
	}

	// mix hash to "fix" bad hash functions
	private size_t mix(size_t h) @safe pure nothrow @nogc
	{
	// final mix function of MurmurHash2
	enum m = 0x5bd1e995;
	h ^= h >> 13;
	h *= m;
	h ^= h >> 15;
	return h;
	}

	private size_t calcHash(in void* pkey, in TypeInfo keyti)
	{
	immutable hash = keyti.getHash(pkey);
	// highest bit is set to distinguish empty/deleted from filled buckets
	return mix(hash) \| HASH_FILLED_MARK;
	}

	private size_t nextpow2(in size_t n) pure nothrow @nogc
	{
	import core.bitop : bsr;

	if (!n)
	return 1;

	const isPowerOf2 = !((n - 1) & n);
	return 1 << (bsr(n) + !isPowerOf2);
	}

	pure nothrow @nogc unittest
	{
	// 0, 1, 2, 3, 4, 5, 6, 7, 8, 9
	foreach (const n, const pow2; [1, 1, 2, 4, 4, 8, 8, 8, 8, 16])
	assert(nextpow2(n) == pow2);
	}

	private T min(T)(T a, T b) pure nothrow @nogc
	{
	return a < b ? a : b;
	}

	private T max(T)(T a, T b) pure nothrow @nogc
	{
	return b < a ? a : b;
	}

	//==============================================================================
	// API Implementation
	//------------------------------------------------------------------------------

	/// Determine number of entries in associative array.
	extern (C) size_t _aaLen(in AA aa) pure nothrow @nogc
	{
	return aa ? aa.length : 0;
	}

	/******************************
	* Lookup *pkey in aa.
	* Called only from implementation of (aa[key]) expressions when value is mutable.
	* Params:
	* aa = associative array opaque pointer
	* ti = TypeInfo for the associative array
	* valsz = ignored
	* pkey = pointer to the key value
	* Returns:
	* if key was in the aa, a mutable pointer to the existing value.
	* If key was not in the aa, a mutable pointer to newly inserted value which
	* is set to all zeros
	*/
	extern (C) void* _aaGetY(AA* aa, const TypeInfo_AssociativeArray ti,
	in size_t valsz, in void* pkey)
	{
	bool found;
	return _aaGetX(aa, ti, valsz, pkey, found);
	}

	/******************************
	* Lookup *pkey in aa.
	* Called only from implementation of require
	* Params:
	* aa = associative array opaque pointer
	* ti = TypeInfo for the associative array
	* valsz = ignored
	* pkey = pointer to the key value
	* found = true if the value was found
	* Returns:
	* if key was in the aa, a mutable pointer to the existing value.
	* If key was not in the aa, a mutable pointer to newly inserted value which
	* is set to all zeros
	*/
	extern (C) void* _aaGetX(AA* aa, const TypeInfo_AssociativeArray ti,
	in size_t valsz, in void* pkey, out bool found)
	{
	// lazily alloc implementation
	if (aa.impl is null)
	aa.impl = new Impl(ti);

	// get hash and bucket for key
	immutable hash = calcHash(pkey, ti.key);

	// found a value => return it
	if (auto p = aa.findSlotLookup(hash, pkey, ti.key))
	{
	found = true;
	return p.entry + aa.valoff;
	}

	auto p = aa.findSlotInsert(hash);
	if (p.deleted)
	--aa.deleted;
	// check load factor and possibly grow
	else if (++aa.used * GROW_DEN > aa.dim * GROW_NUM)
	{
	aa.grow(ti.key);
	p = aa.findSlotInsert(hash);
	assert(p.empty);
	}

	// update search cache and allocate entry
	aa.firstUsed = min(aa.firstUsed, cast(uint)(p - aa.buckets.ptr));
	p.hash = hash;
	p.entry = allocEntry(aa.impl, pkey);
	// postblit for key
	if (aa.flags & Impl.Flags.keyHasPostblit)
	{
	import rt.lifetime : __doPostblit, unqualify;

	__doPostblit(p.entry, aa.keysz, unqualify(ti.key));
	}
	// return pointer to value
	return p.entry + aa.valoff;
	}

	/******************************
	* Lookup *pkey in aa.
	* Called only from implementation of (aa[key]) expressions when value is not mutable.
	* Params:
	* aa = associative array opaque pointer
	* keyti = TypeInfo for the key
	* valsz = ignored
	* pkey = pointer to the key value
	* Returns:
	* pointer to value if present, null otherwise
	*/
	extern (C) inout(void)* _aaGetRvalueX(inout AA aa, in TypeInfo keyti, in size_t valsz,
	in void* pkey)
	{
	return _aaInX(aa, keyti, pkey);
	}

	/******************************
	* Lookup *pkey in aa.
	* Called only from implementation of (key in aa) expressions.
	* Params:
	* aa = associative array opaque pointer
	* keyti = TypeInfo for the key
	* pkey = pointer to the key value
	* Returns:
	* pointer to value if present, null otherwise
	*/
	extern (C) inout(void)* _aaInX(inout AA aa, in TypeInfo keyti, in void* pkey)
	{
	if (aa.empty)
	return null;

	immutable hash = calcHash(pkey, keyti);
	if (auto p = aa.findSlotLookup(hash, pkey, keyti))
	return p.entry + aa.valoff;
	return null;
	}

	/// Delete entry in AA, return true if it was present
	extern (C) bool _aaDelX(AA aa, in TypeInfo keyti, in void* pkey)
	{
	if (aa.empty)
	return false;

	immutable hash = calcHash(pkey, keyti);
	if (auto p = aa.findSlotLookup(hash, pkey, keyti))
	{
	// clear entry
	p.hash = HASH_DELETED;
	p.entry = null;

	++aa.deleted;
	if (aa.length * SHRINK_DEN < aa.dim * SHRINK_NUM)
	aa.shrink(keyti);

	return true;
	}
	return false;
	}

	/// Remove all elements from AA.
	extern (C) void _aaClear(AA aa) pure nothrow
	{
	if (!aa.empty)
	{
	aa.impl.clear();
	}
	}

	/// Rehash AA
	extern (C) void* _aaRehash(AA* paa, in TypeInfo keyti) pure nothrow
	{
	if (!paa.empty)
	paa.resize(nextpow2(INIT_DEN * paa.length / INIT_NUM));
	return *paa;
	}

	/// Return a GC allocated array of all values
	extern (C) inout(void[]) _aaValues(inout AA aa, in size_t keysz, in size_t valsz,
	const TypeInfo tiValueArray) pure nothrow
	{
	if (aa.empty)
	return null;

	import rt.lifetime : _d_newarrayU;

	auto res = _d_newarrayU(tiValueArray, aa.length).ptr;
	auto pval = res;

	immutable off = aa.valoff;
	foreach (b; aa.buckets[aa.firstUsed .. $])
	{
	if (!b.filled)
	continue;
	pval[0 .. valsz] = b.entry[off .. valsz + off];
	pval += valsz;
	}
	// postblit is done in object.values
	return (cast(inout(void)*) res)[0 .. aa.length]; // fake length, return number of elements
	}

	/// Return a GC allocated array of all keys
	extern (C) inout(void[]) _aaKeys(inout AA aa, in size_t keysz, const TypeInfo tiKeyArray) pure nothrow
	{
	if (aa.empty)
	return null;

	import rt.lifetime : _d_newarrayU;

	auto res = _d_newarrayU(tiKeyArray, aa.length).ptr;
	auto pkey = res;

	foreach (b; aa.buckets[aa.firstUsed .. $])
	{
	if (!b.filled)
	continue;
	pkey[0 .. keysz] = b.entry[0 .. keysz];
	pkey += keysz;
	}
	// postblit is done in object.keys
	return (cast(inout(void)*) res)[0 .. aa.length]; // fake length, return number of elements
	}

	// opApply callbacks are extern(D)
	extern (D) alias dg_t = int delegate(void*);
	extern (D) alias dg2_t = int delegate(void, void);

	/// foreach opApply over all values
	extern (C) int _aaApply(AA aa, in size_t keysz, dg_t dg)
	{
	if (aa.empty)
	return 0;

	immutable off = aa.valoff;
	foreach (b; aa.buckets)
	{
	if (!b.filled)
	continue;
	if (auto res = dg(b.entry + off))
	return res;
	}
	return 0;
	}

	/// foreach opApply over all key/value pairs
	extern (C) int _aaApply2(AA aa, in size_t keysz, dg2_t dg)
	{
	if (aa.empty)
	return 0;

	immutable off = aa.valoff;
	foreach (b; aa.buckets)
	{
	if (!b.filled)
	continue;
	if (auto res = dg(b.entry, b.entry + off))
	return res;
	}
	return 0;
	}

	/// Construct an associative array of type ti from keys and value
	extern (C) Impl* _d_assocarrayliteralTX(const TypeInfo_AssociativeArray ti, void[] keys,
	void[] vals)
	{
	assert(keys.length == vals.length);

	immutable keysz = ti.key.tsize;
	immutable valsz = ti.value.tsize;
	immutable length = keys.length;

	if (!length)
	return null;

	auto aa = new Impl(ti, nextpow2(INIT_DEN * length / INIT_NUM));

	void* pkey = keys.ptr;
	void* pval = vals.ptr;
	immutable off = aa.valoff;
	uint actualLength = 0;
	foreach (_; 0 .. length)
	{
	immutable hash = calcHash(pkey, ti.key);

	auto p = aa.findSlotLookup(hash, pkey, ti.key);
	if (p is null)
	{
	p = aa.findSlotInsert(hash);
	p.hash = hash;
	p.entry = allocEntry(aa, pkey); // move key, no postblit
	aa.firstUsed = min(aa.firstUsed, cast(uint)(p - aa.buckets.ptr));
	actualLength++;
	}
	else if (aa.entryTI && hasDtor(ti.value))
	{
	// destroy existing value before overwriting it
	ti.value.destroy(p.entry + off);
	}
	// set hash and blit value
	auto pdst = p.entry + off;
	pdst[0 .. valsz] = pval[0 .. valsz]; // move value, no postblit

	pkey += keysz;
	pval += valsz;
	}
	aa.used = actualLength;
	return aa;
	}

	/// compares 2 AAs for equality
	extern (C) int _aaEqual(in TypeInfo tiRaw, in AA aa1, in AA aa2)
	{
	if (aa1.impl is aa2.impl)
	return true;

	immutable len = _aaLen(aa1);
	if (len != _aaLen(aa2))
	return false;

	if (!len) // both empty
	return true;

	import rt.lifetime : unqualify;

	auto uti = unqualify(tiRaw);
	auto ti = cast(TypeInfo_AssociativeArray)&uti;
	// compare the entries
	immutable off = aa1.valoff;
	foreach (b1; aa1.buckets)
	{
	if (!b1.filled)
	continue;
	auto pb2 = aa2.findSlotLookup(b1.hash, b1.entry, ti.key);
	if (pb2 is null \|\| !ti.value.equals(b1.entry + off, pb2.entry + off))
	return false;
	}
	return true;
	}

	/// compute a hash
	extern (C) hash_t _aaGetHash(in AA* aa, in TypeInfo tiRaw) nothrow
	{
	if (aa.empty)
	return 0;

	import rt.lifetime : unqualify;

	auto uti = unqualify(tiRaw);
	auto ti = cast(TypeInfo_AssociativeArray)&uti;
	immutable off = aa.valoff;
	auto keyHash = &ti.key.getHash;
	auto valHash = &ti.value.getHash;

	size_t h;
	foreach (b; aa.buckets)
	{
	if (!b.filled)
	continue;
	size_t[2] h2 = [keyHash(b.entry), valHash(b.entry + off)];
	// use addition here, so that hash is independent of element order
	h += hashOf(h2);
	}

	return h;
	}

	/**
	* _aaRange implements a ForwardRange
	*/
	struct Range
	{
	Impl* impl;
	size_t idx;
	alias impl this;
	}

	extern (C) pure nothrow @nogc @safe
	{
	Range _aaRange(AA aa)
	{
	if (!aa)
	return Range();

	foreach (i; aa.firstUsed .. aa.dim)
	{
	if (aa.buckets[i].filled)
	return Range(aa.impl, i);
	}
	return Range(aa, aa.dim);
	}

	bool _aaRangeEmpty(Range r)
	{
	return r.impl is null \|\| r.idx >= r.dim;
	}

	void* _aaRangeFrontKey(Range r)
	{
	assert(!_aaRangeEmpty(r));
	if (r.idx >= r.dim)
	return null;
	return r.buckets[r.idx].entry;
	}

	void* _aaRangeFrontValue(Range r)
	{
	assert(!_aaRangeEmpty(r));
	if (r.idx >= r.dim)
	return null;

	auto entry = r.buckets[r.idx].entry;
	return entry is null ?
	null :
	(() @trusted { return entry + r.valoff; } ());
	}

	void _aaRangePopFront(ref Range r)
	{
	if (r.idx >= r.dim) return;
	for (++r.idx; r.idx < r.dim; ++r.idx)
	{
	if (r.buckets[r.idx].filled)
	break;
	}
	}
	}

	// Most tests are now in in test_aa.d

	// test postblit for AA literals
	unittest
	{
	static struct T
	{
	ubyte field;
	static size_t postblit, dtor;
	this(this)
	{
	++postblit;
	}

	~this()
	{
	++dtor;
	}
	}

	T t;
	auto aa1 = [0 : t, 1 : t];
	assert(T.dtor == 0 && T.postblit == 2);
	aa1[0] = t;
	assert(T.dtor == 1 && T.postblit == 3);

	T.dtor = 0;
	T.postblit = 0;

	auto aa2 = [0 : t, 1 : t, 0 : t]; // literal with duplicate key => value overwritten
	assert(T.dtor == 1 && T.postblit == 3);

	T.dtor = 0;
	T.postblit = 0;

	auto aa3 = [t : 0];
	assert(T.dtor == 0 && T.postblit == 1);
	aa3[t] = 1;
	assert(T.dtor == 0 && T.postblit == 1);
	aa3.remove(t);
	assert(T.dtor == 0 && T.postblit == 1);
	aa3[t] = 2;
	assert(T.dtor == 0 && T.postblit == 2);

	// dtor will be called by GC finalizers
	aa1 = null;
	aa2 = null;
	aa3 = null;
	GC.runFinalizers((cast(char*)(&entryDtor))[0 .. 1]);
	assert(T.dtor == 6 && T.postblit == 2);
	}