// Copyright 2009-2021 Intel Corporation
// SPDX-License-Identifier: Apache-2.0

#pragma once

#include "default.h"
#include "device.h"
#include "scene.h"
#include "../builders/primref.h"

#include "../../common/tasking/taskscheduler.h"

namespace embree
{
  class FastAllocator
  {
    /*! maximum supported alignment */
    static const size_t maxAlignment = 64;
    
    /*! maximum allocation size */

    /* default settings */
    //static const size_t defaultBlockSize = 4096;
#define maxAllocationSize size_t(2*1024*1024-maxAlignment)

    static const size_t MAX_THREAD_USED_BLOCK_SLOTS = 8;

  public:

    struct ThreadLocal2;
    enum AllocationType { ALIGNED_MALLOC, EMBREE_OS_MALLOC, SHARED, ANY_TYPE };

    /*! Per thread structure holding the current memory block. */
    struct __aligned(64) ThreadLocal
    {
      ALIGNED_CLASS_(64);
    public:

      /*! Constructor for usage with ThreadLocalData */
      __forceinline ThreadLocal (ThreadLocal2* parent)
        : parent(parent), ptr(nullptr), cur(0), end(0), allocBlockSize(0), bytesUsed(0), bytesWasted(0) {}

      /*! initialize allocator */
      void init(FastAllocator* alloc)
      {
        ptr = nullptr;
        cur = end = 0;
        bytesUsed = 0;
        bytesWasted = 0;
        allocBlockSize = 0;
        if (alloc) allocBlockSize = alloc->defaultBlockSize;
      }

      /* Allocate aligned memory from the threads memory block. */
      __forceinline void* malloc(FastAllocator* alloc, size_t bytes, size_t align = 16)
      {
        /* bind the thread local allocator to the proper FastAllocator*/
        parent->bind(alloc);

        assert(align <= maxAlignment);
        bytesUsed += bytes;

        /* try to allocate in local block */
        size_t ofs = (align - cur) & (align-1);
        cur += bytes + ofs;
        if (likely(cur <= end)) { bytesWasted += ofs; return &ptr[cur - bytes]; }
        cur -= bytes + ofs;

        /* if allocation is too large allocate with parent allocator */
        if (4*bytes > allocBlockSize) {
          return alloc->malloc(bytes,maxAlignment,false);
        }

        /* get new partial block if allocation failed */
        size_t blockSize = allocBlockSize;
        ptr = (char*) alloc->malloc(blockSize,maxAlignment,true);
        bytesWasted += end-cur;
        cur = 0; end = blockSize;

        /* retry allocation */
        ofs = (align - cur) & (align-1);
        cur += bytes + ofs;
        if (likely(cur <= end)) { bytesWasted += ofs; return &ptr[cur - bytes]; }
        cur -= bytes + ofs;

        /* get new full block if allocation failed */
        blockSize = allocBlockSize;
        ptr = (char*) alloc->malloc(blockSize,maxAlignment,false);
        bytesWasted += end-cur;
        cur = 0; end = blockSize;

        /* retry allocation */
        ofs = (align - cur) & (align-1);
        cur += bytes + ofs;
        if (likely(cur <= end)) { bytesWasted += ofs; return &ptr[cur - bytes]; }
        cur -= bytes + ofs;

        /* should never happen as large allocations get handled specially above */
        assert(false);
        return nullptr;
      }

      __forceinline size_t getUsedBytes() const { return bytesUsed; }

      /*! returns amount of free bytes */
      __forceinline size_t getFreeBytes() const { return end-cur; }

      /*! returns amount of wasted bytes */
      __forceinline size_t getWastedBytes() const { return bytesWasted; }

    private:
      ThreadLocal2* parent;
      char*  ptr;            //!< pointer to memory block
      size_t cur;            //!< current location of the allocator
      size_t end;            //!< end of the memory block
      size_t allocBlockSize; //!< block size for allocations
      size_t bytesUsed;      //!< number of total bytes allocated
      size_t bytesWasted;    //!< number of bytes wasted
    };

    /*! Two thread local structures. */
    struct __aligned(64) ThreadLocal2
    {
      ALIGNED_CLASS_(64);
    public:

      __forceinline ThreadLocal2()
        : alloc(nullptr), alloc0(this), alloc1(this) {}

      /*! bind to fast allocator */
      __forceinline void bind(FastAllocator* alloc_i) 
      {
        assert(alloc_i);
        if (alloc.load() == alloc_i) return;
        Lock<MutexSys> lock(mutex);
        //if (alloc.load() == alloc_i) return; // not required as only one thread calls bind
        if (alloc.load()) {
          alloc.load()->bytesUsed   += alloc0.getUsedBytes()   + alloc1.getUsedBytes();
          alloc.load()->bytesFree   += alloc0.getFreeBytes()   + alloc1.getFreeBytes();
          alloc.load()->bytesWasted += alloc0.getWastedBytes() + alloc1.getWastedBytes();
        }
        alloc0.init(alloc_i);
        alloc1.init(alloc_i);
        alloc.store(alloc_i);
        alloc_i->join(this);
      }

      /*! unbind to fast allocator */
      void unbind(FastAllocator* alloc_i) 
      {
        assert(alloc_i);
        if (alloc.load() != alloc_i) return;
        Lock<MutexSys> lock(mutex);
        if (alloc.load() != alloc_i) return; // required as a different thread calls unbind
        alloc.load()->bytesUsed   += alloc0.getUsedBytes()   + alloc1.getUsedBytes();
        alloc.load()->bytesFree   += alloc0.getFreeBytes()   + alloc1.getFreeBytes();
        alloc.load()->bytesWasted += alloc0.getWastedBytes() + alloc1.getWastedBytes();
        alloc0.init(nullptr);
        alloc1.init(nullptr);
        alloc.store(nullptr);
      }

    public:
      MutexSys mutex;
      std::atomic<FastAllocator*> alloc;  //!< parent allocator
      ThreadLocal alloc0;
      ThreadLocal alloc1;
    };

    FastAllocator (Device* device,
                   bool osAllocation,
                   bool useUSM = false,
                   bool blockAllocation = true)
      : device(device)
      , slotMask(0)
      , defaultBlockSize(PAGE_SIZE)
      , estimatedSize(0)
      , growSize(PAGE_SIZE)
      , maxGrowSize(maxAllocationSize)
      , usedBlocks(nullptr)
      , freeBlocks(nullptr)
      , useUSM(useUSM)
      , blockAllocation(blockAllocation)
      , use_single_mode(false)
      , log2_grow_size_scale(0)
      , bytesUsed(0)
      , bytesFree(0)
      , bytesWasted(0)
      , atype(osAllocation ? EMBREE_OS_MALLOC : ALIGNED_MALLOC)
      , primrefarray(device,0)
    {
      if (osAllocation && useUSM)
        throw std::runtime_error("USM allocation cannot be combined with OS allocation.");

      for (size_t i=0; i<MAX_THREAD_USED_BLOCK_SLOTS; i++)
      {
        threadUsedBlocks[i] = nullptr;
        threadBlocks[i] = nullptr;
        //assert(!slotMutex[i].isLocked());
      }
    }

    ~FastAllocator () {
      clear();
    }

    /*! returns the device attached to this allocator */
    Device* getDevice() {
      return device;
    }

    void share(mvector<PrimRef>& primrefarray_i) {
      primrefarray = std::move(primrefarray_i);
    }

    void unshare(mvector<PrimRef>& primrefarray_o)
    {
      reset(); // this removes blocks that are allocated inside the shared primref array
      primrefarray_o = std::move(primrefarray);
    }

    /*! returns first fast thread local allocator */
    __forceinline ThreadLocal* _threadLocal() {
      return &threadLocal2()->alloc0;
    }

    void setOSallocation(bool flag)
    {
      atype = flag ? EMBREE_OS_MALLOC : ALIGNED_MALLOC;
    }

  private:

    /*! returns both fast thread local allocators */
    __forceinline ThreadLocal2* threadLocal2() 
    {
      ThreadLocal2* alloc = thread_local_allocator2;
      if (alloc == nullptr) {
        thread_local_allocator2 = alloc = new ThreadLocal2;
        Lock<MutexSys> lock(s_thread_local_allocators_lock);
        s_thread_local_allocators.push_back(make_unique(alloc));
      }
      return alloc;
    }

  public:

    __forceinline void join(ThreadLocal2* alloc)
    {
      Lock<MutexSys> lock(s_thread_local_allocators_lock);
      thread_local_allocators.push_back(alloc);
    }

  public:

    struct CachedAllocator
    {
      __forceinline CachedAllocator(void* ptr)
        : alloc(nullptr), talloc0(nullptr), talloc1(nullptr) 
      {
        assert(ptr == nullptr);
      }

      __forceinline CachedAllocator(FastAllocator* alloc, ThreadLocal2* talloc)
        : alloc(alloc), talloc0(&talloc->alloc0), talloc1(alloc->use_single_mode ? &talloc->alloc0 : &talloc->alloc1) {}

      __forceinline operator bool () const {
        return alloc != nullptr;
      }

      __forceinline void* operator() (size_t bytes, size_t align = 16) const {
        return talloc0->malloc(alloc,bytes,align);
      }

      __forceinline void* malloc0 (size_t bytes, size_t align = 16) const {
        return talloc0->malloc(alloc,bytes,align);
      }

      __forceinline void* malloc1 (size_t bytes, size_t align = 16) const {
        return talloc1->malloc(alloc,bytes,align);
      }

    public:
      FastAllocator* alloc;
      ThreadLocal* talloc0;
      ThreadLocal* talloc1;
    };

    __forceinline CachedAllocator getCachedAllocator() {
      return CachedAllocator(this,threadLocal2());
    }

    /*! Builder interface to create thread local allocator */
    struct Create
    {
    public:
      __forceinline Create (FastAllocator* allocator) : allocator(allocator) {}
      __forceinline CachedAllocator operator() () const { return allocator->getCachedAllocator();  }

    private:
      FastAllocator* allocator;
    };

    void internal_fix_used_blocks()
    {
      /* move thread local blocks to global block list */
      for (size_t i = 0; i < MAX_THREAD_USED_BLOCK_SLOTS; i++)
      {
        while (threadBlocks[i].load() != nullptr) {
          Block* nextUsedBlock = threadBlocks[i].load()->next;
          threadBlocks[i].load()->next = usedBlocks.load();
          usedBlocks = threadBlocks[i].load();
          threadBlocks[i] = nextUsedBlock;
        }
        threadBlocks[i] = nullptr;
      }
    }

    static const size_t threadLocalAllocOverhead = 20; //! 20 means 5% parallel allocation overhead through unfilled thread local blocks
    static const size_t mainAllocOverheadStatic  = 20;  //! 20 means 5% allocation overhead through unfilled main alloc blocks
    static const size_t mainAllocOverheadDynamic = 8;  //! 20 means 12.5% allocation overhead through unfilled main alloc blocks

    /* calculates a single threaded threshold for the builders such
     * that for small scenes the overhead of partly allocated blocks
     * per thread is low */
    size_t fixSingleThreadThreshold(size_t branchingFactor, size_t defaultThreshold, size_t numPrimitives, size_t bytesEstimated)
    {
      if (numPrimitives == 0 || bytesEstimated == 0) 
        return defaultThreshold;

      /* calculate block size in bytes to fulfill threadLocalAllocOverhead constraint */
      const size_t single_mode_factor = use_single_mode ? 1 : 2;
      const size_t threadCount = TaskScheduler::threadCount();
      const size_t singleThreadBytes = single_mode_factor*threadLocalAllocOverhead*defaultBlockSize;

      /* if we do not have to limit number of threads use optimal thresdhold */
      if ( (bytesEstimated+(singleThreadBytes-1))/singleThreadBytes >= threadCount)
        return defaultThreshold;

      /* otherwise limit number of threads by calculating proper single thread threshold */
      else {
        double bytesPerPrimitive = double(bytesEstimated)/double(numPrimitives);
        return size_t(ceil(branchingFactor*singleThreadBytes/bytesPerPrimitive)); 
      }
    }

    __forceinline size_t alignSize(size_t i) {
      return (i+127)/128*128;
    }

    /*! initializes the grow size */
    __forceinline void initGrowSizeAndNumSlots(size_t bytesEstimated, bool fast) 
    {
      /* we do not need single thread local allocator mode */
      use_single_mode = false;
     
      /* calculate growSize such that at most mainAllocationOverhead gets wasted when a block stays unused */
      size_t mainAllocOverhead = fast ? mainAllocOverheadDynamic : mainAllocOverheadStatic;
      size_t blockSize = alignSize(bytesEstimated/mainAllocOverhead);
      growSize = maxGrowSize = clamp(blockSize,size_t(1024),maxAllocationSize);

      /* if we reached the maxAllocationSize for growSize, we can
       * increase the number of allocation slots by still guaranteeing
       * the mainAllocationOverhead */
      slotMask = 0x0;

      if (MAX_THREAD_USED_BLOCK_SLOTS >= 2 && bytesEstimated > 2*mainAllocOverhead*growSize) slotMask = 0x1;
      if (MAX_THREAD_USED_BLOCK_SLOTS >= 4 && bytesEstimated > 4*mainAllocOverhead*growSize) slotMask = 0x3;
      if (MAX_THREAD_USED_BLOCK_SLOTS >= 8 && bytesEstimated > 8*mainAllocOverhead*growSize) slotMask = 0x7;
      if (MAX_THREAD_USED_BLOCK_SLOTS >= 8 && bytesEstimated > 16*mainAllocOverhead*growSize) { growSize *= 2; } /* if the overhead is tiny, double the growSize */

      /* set the thread local alloc block size */
      size_t defaultBlockSizeSwitch = PAGE_SIZE+maxAlignment;
      
      /* for sufficiently large scene we can increase the defaultBlockSize over the defaultBlockSizeSwitch size */
#if 0 // we do not do this as a block size of 4160 if for some reason best for KNL
      const size_t threadCount = TaskScheduler::threadCount();
      const size_t single_mode_factor = use_single_mode ? 1 : 2;
      const size_t singleThreadBytes = single_mode_factor*threadLocalAllocOverhead*defaultBlockSizeSwitch;
      if (bytesEstimated+(singleThreadBytes-1))/singleThreadBytes >= threadCount)
        defaultBlockSize = min(max(defaultBlockSizeSwitch,bytesEstimated/(single_mode_factor*threadLocalAllocOverhead*threadCount)),growSize);

      /* otherwise we grow the defaultBlockSize up to defaultBlockSizeSwitch */
        else
#endif
        defaultBlockSize = clamp(blockSize,size_t(1024),defaultBlockSizeSwitch);

      if (bytesEstimated == 0) {
        maxGrowSize = maxAllocationSize; // special mode if builder cannot estimate tree size
        defaultBlockSize = defaultBlockSizeSwitch;
      }
      log2_grow_size_scale = 0;
      
      if (device->alloc_main_block_size != 0) growSize = device->alloc_main_block_size;
      if (device->alloc_num_main_slots >= 1 ) slotMask = 0x0;
      if (device->alloc_num_main_slots >= 2 ) slotMask = 0x1;
      if (device->alloc_num_main_slots >= 4 ) slotMask = 0x3;
      if (device->alloc_num_main_slots >= 8 ) slotMask = 0x7;
      if (device->alloc_thread_block_size != 0) defaultBlockSize = device->alloc_thread_block_size;
      if (device->alloc_single_thread_alloc != -1) use_single_mode = device->alloc_single_thread_alloc;
    }

    /*! initializes the allocator */
    void init(size_t bytesAllocate, size_t bytesReserve, size_t bytesEstimate)
    {
      internal_fix_used_blocks();
      /* distribute the allocation to multiple thread block slots */
      slotMask = MAX_THREAD_USED_BLOCK_SLOTS-1; // FIXME: remove
      if (usedBlocks.load() || freeBlocks.load()) { reset(); return; }
      if (bytesReserve == 0) bytesReserve = bytesAllocate;
      freeBlocks = Block::create(device,useUSM,bytesAllocate,bytesReserve,nullptr,atype);
      estimatedSize = bytesEstimate;
      initGrowSizeAndNumSlots(bytesEstimate,true);
    }

    /*! initializes the allocator */
    void init_estimate(size_t bytesEstimate)
    {
      internal_fix_used_blocks();
      if (usedBlocks.load() || freeBlocks.load()) { reset(); return; }
      /* single allocator mode ? */
      estimatedSize = bytesEstimate;
      //initGrowSizeAndNumSlots(bytesEstimate,false);
      initGrowSizeAndNumSlots(bytesEstimate,false);

    }

    /*! frees state not required after build */
    __forceinline void cleanup()
    {
      internal_fix_used_blocks();

      /* unbind all thread local allocators */
      for (auto alloc : thread_local_allocators) alloc->unbind(this);
      thread_local_allocators.clear();
    }

    /*! resets the allocator, memory blocks get reused */
    void reset ()
    {
      internal_fix_used_blocks();

      bytesUsed.store(0);
      bytesFree.store(0);
      bytesWasted.store(0);

      /* reset all used blocks and move them to begin of free block list */
      while (usedBlocks.load() != nullptr) {
        usedBlocks.load()->reset_block();
        Block* nextUsedBlock = usedBlocks.load()->next;
        usedBlocks.load()->next = freeBlocks.load();
        freeBlocks = usedBlocks.load();
        usedBlocks = nextUsedBlock;
      }

      /* remove all shared blocks as they are re-added during build */
      freeBlocks.store(Block::remove_shared_blocks(freeBlocks.load()));

      for (size_t i=0; i<MAX_THREAD_USED_BLOCK_SLOTS; i++)
      {
        threadUsedBlocks[i] = nullptr;
        threadBlocks[i] = nullptr;
      }
      
      /* unbind all thread local allocators */
      for (auto alloc : thread_local_allocators) alloc->unbind(this);
      thread_local_allocators.clear();
    }

    /*! frees all allocated memory */
    __forceinline void clear()
    {
      cleanup();
      bytesUsed.store(0);
      bytesFree.store(0);
      bytesWasted.store(0);
      if (usedBlocks.load() != nullptr) usedBlocks.load()->clear_list(device,useUSM); usedBlocks = nullptr;
      if (freeBlocks.load() != nullptr) freeBlocks.load()->clear_list(device,useUSM); freeBlocks = nullptr;
      for (size_t i=0; i<MAX_THREAD_USED_BLOCK_SLOTS; i++) {
        threadUsedBlocks[i] = nullptr;
        threadBlocks[i] = nullptr;
      }
      primrefarray.clear();
    }

    __forceinline size_t incGrowSizeScale()
    {
      size_t scale = log2_grow_size_scale.fetch_add(1)+1;
      return size_t(1) << min(size_t(16),scale);
    }

    /*! thread safe allocation of memory */
    void* malloc(size_t& bytes, size_t align, bool partial)
    {
      assert(align <= maxAlignment);

      while (true)
      {
        /* allocate using current block */
        size_t threadID = TaskScheduler::threadID();
        size_t slot = threadID & slotMask;
        Block* myUsedBlocks = threadUsedBlocks[slot];
        if (myUsedBlocks) {
          void* ptr = myUsedBlocks->malloc(device,bytes,align,partial);
          if (ptr == nullptr && !blockAllocation)
            throw std::bad_alloc();
          if (ptr) return ptr;
        }

        /* throw error if allocation is too large */
        if (bytes > maxAllocationSize)
          throw_RTCError(RTC_ERROR_UNKNOWN,"allocation is too large");

        /* parallel block creation in case of no freeBlocks, avoids single global mutex */
        if (likely(freeBlocks.load() == nullptr))
        {
          Lock<MutexSys> lock(slotMutex[slot]);
          if (myUsedBlocks == threadUsedBlocks[slot]) {
            const size_t alignedBytes = (bytes+(align-1)) & ~(align-1);
            const size_t allocSize = max(min(growSize,maxGrowSize),alignedBytes);
            assert(allocSize >= bytes);
            threadBlocks[slot] = threadUsedBlocks[slot] = Block::create(device,useUSM,allocSize,allocSize,threadBlocks[slot],atype); // FIXME: a large allocation might throw away a block here!
            // FIXME: a direct allocation should allocate inside the block here, and not in the next loop! a different thread could do some allocation and make the large allocation fail.
          }
          continue;
        }

        /* if this fails allocate new block */
        {
          Lock<MutexSys> lock(mutex);
          if (myUsedBlocks == threadUsedBlocks[slot])
          {
            if (freeBlocks.load() != nullptr) {
              Block* nextFreeBlock = freeBlocks.load()->next;
              freeBlocks.load()->next = usedBlocks;
              __memory_barrier();
              usedBlocks = freeBlocks.load();
              threadUsedBlocks[slot] = freeBlocks.load();
              freeBlocks = nextFreeBlock;
            } else {
              const size_t allocSize = min(growSize*incGrowSizeScale(),maxGrowSize);
              usedBlocks = threadUsedBlocks[slot] = Block::create(device,useUSM,allocSize,allocSize,usedBlocks,atype); // FIXME: a large allocation should get delivered directly, like above!
            }
          }
        }
      }
    }

    /*! add new block */
    void addBlock(void* ptr, ssize_t bytes)
    {
      Lock<MutexSys> lock(mutex);
      const size_t sizeof_Header = offsetof(Block,data[0]);
      void* aptr = (void*) ((((size_t)ptr)+maxAlignment-1) & ~(maxAlignment-1));
      size_t ofs = (size_t) aptr - (size_t) ptr;
      bytes -= ofs;
      if (bytes < 4096) return; // ignore empty or very small blocks
      freeBlocks = new (aptr) Block(SHARED,bytes-sizeof_Header,bytes-sizeof_Header,freeBlocks,ofs);
    }

    /* special allocation only used from morton builder only a single time for each build */
    void* specialAlloc(size_t bytes)
    {
      assert(freeBlocks.load() != nullptr && freeBlocks.load()->getBlockAllocatedBytes() >= bytes);
      return freeBlocks.load()->ptr();
    }

    struct Statistics
    {
      Statistics ()
      : bytesUsed(0), bytesFree(0), bytesWasted(0) {}

      Statistics (size_t bytesUsed, size_t bytesFree, size_t bytesWasted)
      : bytesUsed(bytesUsed), bytesFree(bytesFree), bytesWasted(bytesWasted) {}

      Statistics (FastAllocator* alloc, AllocationType atype, bool huge_pages = false)
      : bytesUsed(0), bytesFree(0), bytesWasted(0)
      {
        Block* usedBlocks = alloc->usedBlocks.load();
        Block* freeBlocks = alloc->freeBlocks.load();
        if (usedBlocks) bytesUsed += usedBlocks->getUsedBytes(atype,huge_pages);
        if (freeBlocks) bytesFree += freeBlocks->getAllocatedBytes(atype,huge_pages);
        if (usedBlocks) bytesFree += usedBlocks->getFreeBytes(atype,huge_pages);
        if (freeBlocks) bytesWasted += freeBlocks->getWastedBytes(atype,huge_pages);
        if (usedBlocks) bytesWasted += usedBlocks->getWastedBytes(atype,huge_pages);
      }

      std::string str(size_t numPrimitives)
      {
        std::stringstream str;
        str.setf(std::ios::fixed, std::ios::floatfield);
        str << "used = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesUsed << " MB, "
            << "free = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesFree << " MB, "
            << "wasted = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesWasted << " MB, "            
            << "total = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesAllocatedTotal() << " MB, "
            << "#bytes/prim = " << std::setw(6) << std::setprecision(2) << double(bytesAllocatedTotal())/double(numPrimitives);
        return str.str();
      }

      friend Statistics operator+ ( const Statistics& a, const Statistics& b)
      {
        return Statistics(a.bytesUsed+b.bytesUsed,
                          a.bytesFree+b.bytesFree,
                          a.bytesWasted+b.bytesWasted);
      }

      size_t bytesAllocatedTotal() const {
        return bytesUsed + bytesFree + bytesWasted;
      }

    public:
      size_t bytesUsed;
      size_t bytesFree;
      size_t bytesWasted;
    };

    Statistics getStatistics(AllocationType atype, bool huge_pages = false) {
      return Statistics(this,atype,huge_pages);
    }

    size_t getUsedBytes() {
      return bytesUsed;
    }

    size_t getWastedBytes() {
      return bytesWasted;
    }

    struct AllStatistics
    {
      AllStatistics (FastAllocator* alloc)

      : bytesUsed(alloc->bytesUsed),
        bytesFree(alloc->bytesFree),
        bytesWasted(alloc->bytesWasted),
        stat_all(alloc,ANY_TYPE),
        stat_malloc(alloc,ALIGNED_MALLOC),
        stat_4K(alloc,EMBREE_OS_MALLOC,false),
        stat_2M(alloc,EMBREE_OS_MALLOC,true),
        stat_shared(alloc,SHARED) {}

      AllStatistics (size_t bytesUsed,
                     size_t bytesFree,
                     size_t bytesWasted,
                     Statistics stat_all,
                     Statistics stat_malloc,
                     Statistics stat_4K,
                     Statistics stat_2M,
                     Statistics stat_shared)

      : bytesUsed(bytesUsed),
        bytesFree(bytesFree),
        bytesWasted(bytesWasted),
        stat_all(stat_all),
        stat_malloc(stat_malloc),
        stat_4K(stat_4K),
        stat_2M(stat_2M),
        stat_shared(stat_shared) {}

      friend AllStatistics operator+ (const AllStatistics& a, const AllStatistics& b)
      {
        return AllStatistics(a.bytesUsed+b.bytesUsed,
                             a.bytesFree+b.bytesFree,
                             a.bytesWasted+b.bytesWasted,
                             a.stat_all + b.stat_all,
                             a.stat_malloc + b.stat_malloc,
                             a.stat_4K + b.stat_4K,
                             a.stat_2M + b.stat_2M,
                             a.stat_shared + b.stat_shared);
      }

      void print(size_t numPrimitives)
      {
        std::stringstream str0;
        str0.setf(std::ios::fixed, std::ios::floatfield);
        str0 << "  alloc : " 
             << "used = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesUsed << " MB, "
             << "                                                            " 
             << "#bytes/prim = " << std::setw(6) << std::setprecision(2) << double(bytesUsed)/double(numPrimitives);
        std::cout << str0.str() << std::endl;
      
        std::stringstream str1;
        str1.setf(std::ios::fixed, std::ios::floatfield);
        str1 << "  alloc : " 
             << "used = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesUsed << " MB, "
             << "free = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesFree << " MB, "            
             << "wasted = " << std::setw(7) << std::setprecision(3) << 1E-6f*bytesWasted << " MB, "            
             << "total = " << std::setw(7) << std::setprecision(3) << 1E-6f*(bytesUsed+bytesFree+bytesWasted) << " MB, "
             << "#bytes/prim = " << std::setw(6) << std::setprecision(2) << double(bytesUsed+bytesFree+bytesWasted)/double(numPrimitives);
        std::cout << str1.str() << std::endl;
     
        std::cout << "  total : " << stat_all.str(numPrimitives) << std::endl;
        std::cout << "  4K    : " << stat_4K.str(numPrimitives) << std::endl;
        std::cout << "  2M    : " << stat_2M.str(numPrimitives) << std::endl;
        std::cout << "  malloc: " << stat_malloc.str(numPrimitives) << std::endl;
        std::cout << "  shared: " << stat_shared.str(numPrimitives) << std::endl;
      }

    private:
      size_t bytesUsed;
      size_t bytesFree;
      size_t bytesWasted;
      Statistics stat_all;
      Statistics stat_malloc;
      Statistics stat_4K;
      Statistics stat_2M;
      Statistics stat_shared;
    };

    void print_blocks()
    {
      std::cout << "  estimatedSize = " << estimatedSize
                << ", slotMask = " << slotMask
                << ", use_single_mode = " << use_single_mode
                << ", maxGrowSize = " << maxGrowSize
                << ", defaultBlockSize = " << defaultBlockSize
                << std::endl;

      std::cout << "  used blocks = ";
      if (usedBlocks.load() != nullptr) usedBlocks.load()->print_list();
      std::cout << "[END]" << std::endl;

      std::cout << "  free blocks = ";
      if (freeBlocks.load() != nullptr) freeBlocks.load()->print_list();
      std::cout << "[END]" << std::endl;
    }

  private:

    struct Block
    {
      __forceinline static void* blockAlignedMalloc(Device* device, bool useUSM, size_t bytesAllocate, size_t bytesAlignment)
      {
        if (useUSM) return device->malloc(bytesAllocate, bytesAlignment);
	else        return alignedMalloc (bytesAllocate, bytesAlignment);
      }

      __forceinline static void blockAlignedFree(Device* device, bool useUSM, void* ptr)
      {
        if (useUSM) return device->free(ptr);
	else        return alignedFree(ptr);
      }

      static Block* create(Device* device, bool useUSM, size_t bytesAllocate, size_t bytesReserve, Block* next, AllocationType atype)
      {
        /* We avoid using os_malloc for small blocks as this could
         * cause a risk of fragmenting the virtual address space and
         * reach the limit of vm.max_map_count = 65k under Linux. */
        if (atype == EMBREE_OS_MALLOC && bytesAllocate < maxAllocationSize)
          atype = ALIGNED_MALLOC;

        /* we need to additionally allocate some header */
        const size_t sizeof_Header = offsetof(Block,data[0]);
        bytesAllocate = sizeof_Header+bytesAllocate;
        bytesReserve  = sizeof_Header+bytesReserve;

        /* consume full 4k pages with using os_malloc */
        if (atype == EMBREE_OS_MALLOC) {
          bytesAllocate = ((bytesAllocate+PAGE_SIZE-1) & ~(PAGE_SIZE-1));
          bytesReserve  = ((bytesReserve +PAGE_SIZE-1) & ~(PAGE_SIZE-1));
        }

        /* either use alignedMalloc or os_malloc */
        void *ptr = nullptr;
        if (atype == ALIGNED_MALLOC)
        {
          /* special handling for default block size */
          if (bytesAllocate == (2*PAGE_SIZE_2M))
          {
            const size_t alignment = maxAlignment;
            if (device) device->memoryMonitor(bytesAllocate+alignment,false);
            ptr = blockAlignedMalloc(device,useUSM,bytesAllocate,alignment);

            /* give hint to transparently convert these pages to 2MB pages */
            const size_t ptr_aligned_begin = ((size_t)ptr) & ~size_t(PAGE_SIZE_2M-1);
            os_advise((void*)(ptr_aligned_begin +              0),PAGE_SIZE_2M); // may fail if no memory mapped before block
            os_advise((void*)(ptr_aligned_begin + 1*PAGE_SIZE_2M),PAGE_SIZE_2M);
            os_advise((void*)(ptr_aligned_begin + 2*PAGE_SIZE_2M),PAGE_SIZE_2M); // may fail if no memory mapped after block

            return new (ptr) Block(ALIGNED_MALLOC,bytesAllocate-sizeof_Header,bytesAllocate-sizeof_Header,next,alignment);
          }
          else
          {
            const size_t alignment = maxAlignment;
            if (device) device->memoryMonitor(bytesAllocate+alignment,false);
            ptr = blockAlignedMalloc(device,useUSM,bytesAllocate,alignment);
            return new (ptr) Block(ALIGNED_MALLOC,bytesAllocate-sizeof_Header,bytesAllocate-sizeof_Header,next,alignment);
          }
        }
        else if (atype == EMBREE_OS_MALLOC)
        {
          if (device) device->memoryMonitor(bytesAllocate,false);
          bool huge_pages; ptr = os_malloc(bytesReserve,huge_pages);
          return new (ptr) Block(EMBREE_OS_MALLOC,bytesAllocate-sizeof_Header,bytesReserve-sizeof_Header,next,0,huge_pages);
        }
        else
          assert(false);

        return NULL;
      }

      Block (AllocationType atype, size_t bytesAllocate, size_t bytesReserve, Block* next, size_t wasted, bool huge_pages = false)
      : cur(0), allocEnd(bytesAllocate), reserveEnd(bytesReserve), next(next), wasted(wasted), atype(atype), huge_pages(huge_pages)
      {
        assert((((size_t)&data[0]) & (maxAlignment-1)) == 0);
      }

      static Block* remove_shared_blocks(Block* head)
      {
        Block** prev_next = &head;
        for (Block* block = head; block; block = block->next) {
          if (block->atype == SHARED) *prev_next = block->next;
          else                         prev_next = &block->next;
        }
        return head;
      }

      void clear_list(Device* device, bool useUSM)
      {
        Block* block = this;
        while (block) {
          Block* next = block->next;
          block->clear_block(device, useUSM);
          block = next;
        }
      }

      void clear_block (Device* device, bool useUSM)
      {
        const size_t sizeof_Header = offsetof(Block,data[0]);
        const ssize_t sizeof_Alloced = wasted+sizeof_Header+getBlockAllocatedBytes();

        if (atype == ALIGNED_MALLOC) {
          blockAlignedFree(device, useUSM, this);
          if (device) device->memoryMonitor(-sizeof_Alloced,true);
        }

        else if (atype == EMBREE_OS_MALLOC) {
         size_t sizeof_This = sizeof_Header+reserveEnd;
         os_free(this,sizeof_This,huge_pages);
         if (device) device->memoryMonitor(-sizeof_Alloced,true);
        }

        else /* if (atype == SHARED) */ {
        }
      }

      void* malloc(MemoryMonitorInterface* device, size_t& bytes_in, size_t align, bool partial)
      {
        size_t bytes = bytes_in;
        assert(align <= maxAlignment);
        bytes = (bytes+(align-1)) & ~(align-1);
        if (unlikely(cur+bytes > reserveEnd && !partial)) return nullptr;
        const size_t i = cur.fetch_add(bytes);
        if (unlikely(i+bytes > reserveEnd && !partial)) return nullptr;
        if (unlikely(i > reserveEnd)) return nullptr;
        bytes_in = bytes = min(bytes,reserveEnd-i);

        if (i+bytes > allocEnd) {
          if (device) device->memoryMonitor(i+bytes-max(i,allocEnd),true);
        }
        return &data[i];
      }

      void* ptr() {
        return &data[cur];
      }

      void reset_block ()
      {
        allocEnd = max(allocEnd,(size_t)cur);
        cur = 0;
      }

      size_t getBlockUsedBytes() const {
        return min(size_t(cur),reserveEnd);
      }

      size_t getBlockFreeBytes() const {
        return getBlockAllocatedBytes() - getBlockUsedBytes();
      }

      size_t getBlockAllocatedBytes() const {
        return min(max(allocEnd,size_t(cur)),reserveEnd);
      }

      size_t getBlockWastedBytes() const {
        const size_t sizeof_Header = offsetof(Block,data[0]);
        return sizeof_Header + wasted;
      }

      size_t getBlockReservedBytes() const {
        return reserveEnd;
      }
  
      bool hasType(AllocationType atype_i, bool huge_pages_i) const
      {
        if      (atype_i == ANY_TYPE ) return true;
        else if (atype   == EMBREE_OS_MALLOC) return atype_i == atype && huge_pages_i == huge_pages;
        else                           return atype_i == atype;
      }

      size_t getUsedBytes(AllocationType atype, bool huge_pages = false) const {
        size_t bytes = 0;
        for (const Block* block = this; block; block = block->next) {
          if (!block->hasType(atype,huge_pages)) continue;
          bytes += block->getBlockUsedBytes();
        }
        return bytes;
      }

      size_t getFreeBytes(AllocationType atype, bool huge_pages = false) const {
        size_t bytes = 0;
        for (const Block* block = this; block; block = block->next) {
          if (!block->hasType(atype,huge_pages)) continue;
          bytes += block->getBlockFreeBytes();
        }
        return bytes;
      }

      size_t getWastedBytes(AllocationType atype, bool huge_pages = false) const {
        size_t bytes = 0;
        for (const Block* block = this; block; block = block->next) {
          if (!block->hasType(atype,huge_pages)) continue;
          bytes += block->getBlockWastedBytes();
        }
        return bytes;
      }

      size_t getAllocatedBytes(AllocationType atype, bool huge_pages = false) const {
        size_t bytes = 0;
        for (const Block* block = this; block; block = block->next) {
          if (!block->hasType(atype,huge_pages)) continue;
          bytes += block->getBlockAllocatedBytes();
        }
        return bytes;
      }

      void print_list ()
      {
        for (const Block* block = this; block; block = block->next)
          block->print_block();
      }

      void print_block() const
      {
        if (atype == ALIGNED_MALLOC) std::cout << "A";
        else if (atype == EMBREE_OS_MALLOC) std::cout << "O";
        else if (atype == SHARED) std::cout << "S";
        if (huge_pages) std::cout << "H";
        size_t bytesUsed = getBlockUsedBytes();
        size_t bytesFree = getBlockFreeBytes();
        size_t bytesWasted = getBlockWastedBytes();
        std::cout << "[" << bytesUsed << ", " << bytesFree << ", " << bytesWasted << "] ";
      }

    public:
      std::atomic<size_t> cur;        //!< current location of the allocator
      std::atomic<size_t> allocEnd;   //!< end of the allocated memory region
      std::atomic<size_t> reserveEnd; //!< end of the reserved memory region
      Block* next;               //!< pointer to next block in list
      size_t wasted;             //!< amount of memory wasted through block alignment
      AllocationType atype;      //!< allocation mode of the block
      bool huge_pages;           //!< whether the block uses huge pages
      char align[maxAlignment-5*sizeof(size_t)-sizeof(AllocationType)-sizeof(bool)]; //!< align data to maxAlignment
      char data[1];              //!< here starts memory to use for allocations
    };

  public:
    static const size_t blockHeaderSize = offsetof(Block,data[0]);

  private:
    Device* device;
    size_t slotMask;
    size_t defaultBlockSize;
    size_t estimatedSize;
    size_t growSize;
    size_t maxGrowSize;

    MutexSys mutex;
    MutexSys slotMutex[MAX_THREAD_USED_BLOCK_SLOTS];
    std::atomic<Block*> threadUsedBlocks[MAX_THREAD_USED_BLOCK_SLOTS];
    std::atomic<Block*> threadBlocks[MAX_THREAD_USED_BLOCK_SLOTS];
    std::atomic<Block*> usedBlocks;
    std::atomic<Block*> freeBlocks;

    bool useUSM;
    bool blockAllocation = true;
    bool use_single_mode;

    std::atomic<size_t> log2_grow_size_scale; //!< log2 of scaling factor for grow size // FIXME: remove
    std::atomic<size_t> bytesUsed;
    std::atomic<size_t> bytesFree;
    std::atomic<size_t> bytesWasted;

    static __thread ThreadLocal2* thread_local_allocator2;
    static MutexSys s_thread_local_allocators_lock;
    static std::vector<std::unique_ptr<ThreadLocal2>> s_thread_local_allocators;

    std::vector<ThreadLocal2*> thread_local_allocators;
    AllocationType atype;

    mvector<PrimRef> primrefarray;     //!< primrefarray used to allocate nodes
  };
}