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** packaging of this file. Please review the following information to
** ensure the GNU Lesser General Public License version 3 requirements
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** Alternatively, this file may be used under the terms of the GNU
** General Public License version 2.0 or (at your option) the GNU General
** Public license version 3 or any later version approved by the KDE Free
** Qt Foundation. The licenses are as published by the Free Software
** Foundation and appearing in the file LICENSE.GPL2 and LICENSE.GPL3
** included in the packaging of this file. Please review the following
** information to ensure the GNU General Public License requirements will
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****************************************************************************/

#ifndef QV4GC_H
#define QV4GC_H

//
//  W A R N I N G
//  -------------
//
// This file is not part of the Qt API.  It exists purely as an
// implementation detail.  This header file may change from version to
// version without notice, or even be removed.
//
// We mean it.
//

#include <private/qv4global_p.h>
#include <private/qv4value_p.h>
#include <private/qv4scopedvalue_p.h>
#include <private/qv4object_p.h>
#include <private/qv4mmdefs_p.h>
#include <QVector>

#define QV4_MM_MAXBLOCK_SHIFT "QV4_MM_MAXBLOCK_SHIFT"
#define QV4_MM_MAX_CHUNK_SIZE "QV4_MM_MAX_CHUNK_SIZE"
#define QV4_MM_STATS "QV4_MM_STATS"

#define MM_DEBUG 0

QT_BEGIN_NAMESPACE

namespace QV4 {

struct ChunkAllocator;
struct MemorySegment;

struct BlockAllocator {
    BlockAllocator(ChunkAllocator *chunkAllocator, ExecutionEngine *engine)
        : chunkAllocator(chunkAllocator), engine(engine)
    {
        memset(freeBins, 0, sizeof(freeBins));
    }

    enum { NumBins = 8 };

    static inline size_t binForSlots(size_t nSlots) {
        return nSlots >= NumBins ? NumBins - 1 : nSlots;
    }

    HeapItem *allocate(size_t size, bool forceAllocation = false);

    size_t totalSlots() const {
        return Chunk::AvailableSlots*chunks.size();
    }

    size_t allocatedMem() const {
        return chunks.size()*Chunk::DataSize;
    }
    size_t usedMem() const {
        uint used = 0;
        for (auto c : chunks)
            used += c->nUsedSlots()*Chunk::SlotSize;
        return used;
    }

    void sweep();
    void freeAll();
    void resetBlackBits();
    void collectGrayItems(MarkStack *markStack);

    // bump allocations
    HeapItem *nextFree = nullptr;
    size_t nFree = 0;
    size_t usedSlotsAfterLastSweep = 0;
    HeapItem *freeBins[NumBins];
    ChunkAllocator *chunkAllocator;
    ExecutionEngine *engine;
    std::vector<Chunk *> chunks;
    uint *allocationStats = nullptr;
};

struct HugeItemAllocator {
    HugeItemAllocator(ChunkAllocator *chunkAllocator, ExecutionEngine *engine)
        : chunkAllocator(chunkAllocator), engine(engine)
    {}

    HeapItem *allocate(size_t size);
    void sweep(ClassDestroyStatsCallback classCountPtr);
    void freeAll();
    void resetBlackBits();
    void collectGrayItems(MarkStack *markStack);

    size_t usedMem() const {
        size_t used = 0;
        for (const auto &c : chunks)
            used += c.size;
        return used;
    }

    ChunkAllocator *chunkAllocator;
    ExecutionEngine *engine;
    struct HugeChunk {
        MemorySegment *segment;
        Chunk *chunk;
        size_t size;
    };

    std::vector<HugeChunk> chunks;
};


class Q_QML_EXPORT MemoryManager
{
    Q_DISABLE_COPY(MemoryManager);

public:
    MemoryManager(ExecutionEngine *engine);
    ~MemoryManager();

    // TODO: this is only for 64bit (and x86 with SSE/AVX), so exend it for other architectures to be slightly more efficient (meaning, align on 8-byte boundaries).
    // Note: all occurrences of "16" in alloc/dealloc are also due to the alignment.
    Q_DECL_CONSTEXPR static inline std::size_t align(std::size_t size)
    { return (size + Chunk::SlotSize - 1) & ~(Chunk::SlotSize - 1); }

    template<typename ManagedType>
    inline typename ManagedType::Data *allocManaged(std::size_t size)
    {
        Q_STATIC_ASSERT(std::is_trivial< typename ManagedType::Data >::value);
        size = align(size);
        Heap::Base *o = allocData(size);
        InternalClass *ic = ManagedType::defaultInternalClass(engine);
        ic = ic->changeVTable(ManagedType::staticVTable());
        o->internalClass = ic;
        Q_ASSERT(o->internalClass && o->internalClass->vtable);
        return static_cast<typename ManagedType::Data *>(o);
    }

    template<typename ManagedType>
    inline typename ManagedType::Data *allocManaged(std::size_t size, InternalClass *ic)
    {
        Q_STATIC_ASSERT(std::is_trivial< typename ManagedType::Data >::value);
        size = align(size);
        Heap::Base *o = allocData(size);
        o->internalClass = ic;
        Q_ASSERT(o->internalClass && o->internalClass->vtable);
        Q_ASSERT(ic->vtable == ManagedType::staticVTable());
        return static_cast<typename ManagedType::Data *>(o);
    }

    template <typename ObjectType>
    typename ObjectType::Data *allocateObject(InternalClass *ic)
    {
        Heap::Object *o = allocObjectWithMemberData(ObjectType::staticVTable(), ic->size);
        o->internalClass = ic;
        Q_ASSERT(o->internalClass && o->internalClass->vtable);
        Q_ASSERT(ic->vtable == ObjectType::staticVTable());
        return static_cast<typename ObjectType::Data *>(o);
    }

    template <typename ObjectType>
    typename ObjectType::Data *allocateObject()
    {
        InternalClass *ic = ObjectType::defaultInternalClass(engine);
        ic = ic->changeVTable(ObjectType::staticVTable());
        ic = ic->changePrototype(ObjectType::defaultPrototype(engine)->d());
        Heap::Object *o = allocObjectWithMemberData(ObjectType::staticVTable(), ic->size);
        o->internalClass = ic;
        Q_ASSERT(o->internalClass && o->internalClass->vtable);
        Q_ASSERT(o->internalClass->prototype == ObjectType::defaultPrototype(engine)->d());
        return static_cast<typename ObjectType::Data *>(o);
    }

    template <typename ManagedType, typename Arg1>
    typename ManagedType::Data *allocWithStringData(std::size_t unmanagedSize, Arg1 arg1)
    {
        typename ManagedType::Data *o = reinterpret_cast<typename ManagedType::Data *>(allocString(unmanagedSize));
        o->internalClass = ManagedType::defaultInternalClass(engine);
        Q_ASSERT(o->internalClass && o->internalClass->vtable);
        o->init(arg1);
        return o;
    }

    template <typename ObjectType>
    typename ObjectType::Data *allocObject(InternalClass *ic)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        t->d_unchecked()->init();
        return t->d();
    }

    template <typename ObjectType>
    typename ObjectType::Data *allocObject(InternalClass *ic, Object *prototype)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        Q_ASSERT(t->internalClass()->prototype == (prototype ? prototype->d() : nullptr));
        Q_UNUSED(prototype);
        t->d_unchecked()->init();
        return t->d();
    }

    template <typename ObjectType, typename Arg1>
    typename ObjectType::Data *allocObject(InternalClass *ic, Object *prototype, Arg1 arg1)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        Q_ASSERT(t->internalClass()->prototype == (prototype ? prototype->d() : nullptr));
        Q_UNUSED(prototype);
        t->d_unchecked()->init(arg1);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2>
    typename ObjectType::Data *allocObject(InternalClass *ic, Object *prototype, Arg1 arg1, Arg2 arg2)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        Q_ASSERT(t->internalClass()->prototype == (prototype ? prototype->d() : nullptr));
        Q_UNUSED(prototype);
        t->d_unchecked()->init(arg1, arg2);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2, typename Arg3>
    typename ObjectType::Data *allocObject(InternalClass *ic, Object *prototype, Arg1 arg1, Arg2 arg2, Arg3 arg3)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        Q_ASSERT(t->internalClass()->prototype == (prototype ? prototype->d() : nullptr));
        Q_UNUSED(prototype);
        t->d_unchecked()->init(arg1, arg2, arg3);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2, typename Arg3, typename Arg4>
    typename ObjectType::Data *allocObject(InternalClass *ic, Object *prototype, Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>(ic));
        Q_ASSERT(t->internalClass()->prototype == (prototype ? prototype->d() : nullptr));
        Q_UNUSED(prototype);
        t->d_unchecked()->init(arg1, arg2, arg3, arg4);
        return t->d();
    }

    template <typename ObjectType>
    typename ObjectType::Data *allocObject()
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>());
        t->d_unchecked()->init();
        return t->d();
    }

    template <typename ObjectType, typename Arg1>
    typename ObjectType::Data *allocObject(Arg1 arg1)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>());
        t->d_unchecked()->init(arg1);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2>
    typename ObjectType::Data *allocObject(Arg1 arg1, Arg2 arg2)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>());
        t->d_unchecked()->init(arg1, arg2);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2, typename Arg3>
    typename ObjectType::Data *allocObject(Arg1 arg1, Arg2 arg2, Arg3 arg3)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>());
        t->d_unchecked()->init(arg1, arg2, arg3);
        return t->d();
    }

    template <typename ObjectType, typename Arg1, typename Arg2, typename Arg3, typename Arg4>
    typename ObjectType::Data *allocObject(Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4)
    {
        Scope scope(engine);
        Scoped<ObjectType> t(scope, allocateObject<ObjectType>());
        t->d_unchecked()->init(arg1, arg2, arg3, arg4);
        return t->d();
    }


    template <typename ManagedType>
    typename ManagedType::Data *alloc()
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init();
        return t->d();
    }

    template <typename ManagedType, typename Arg1>
    typename ManagedType::Data *alloc(Arg1 arg1)
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init(arg1);
        return t->d();
    }

    template <typename ManagedType, typename Arg1, typename Arg2>
    typename ManagedType::Data *alloc(Arg1 arg1, Arg2 arg2)
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init(arg1, arg2);
        return t->d();
    }

    template <typename ManagedType, typename Arg1, typename Arg2, typename Arg3>
    typename ManagedType::Data *alloc(Arg1 arg1, Arg2 arg2, Arg3 arg3)
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init(arg1, arg2, arg3);
        return t->d();
    }

    template <typename ManagedType, typename Arg1, typename Arg2, typename Arg3, typename Arg4>
    typename ManagedType::Data *alloc(Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4)
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init(arg1, arg2, arg3, arg4);
        return t->d();
    }

    template <typename ManagedType, typename Arg1, typename Arg2, typename Arg3, typename Arg4, typename Arg5>
    typename ManagedType::Data *alloc(Arg1 arg1, Arg2 arg2, Arg3 arg3, Arg4 arg4, Arg5 arg5)
    {
        Scope scope(engine);
        Scoped<ManagedType> t(scope, allocManaged<ManagedType>(sizeof(typename ManagedType::Data)));
        t->d_unchecked()->init(arg1, arg2, arg3, arg4, arg5);
        return t->d();
    }

    void runGC();

    void dumpStats() const;

    size_t getUsedMem() const;
    size_t getAllocatedMem() const;
    size_t getLargeItemsMem() const;

    // called when a JS object grows itself. Specifically: Heap::String::append
    void changeUnmanagedHeapSizeUsage(qptrdiff delta) { unmanagedHeapSize += delta; }

protected:
    /// expects size to be aligned
    Heap::Base *allocString(std::size_t unmanagedSize);
    Heap::Base *allocData(std::size_t size);
    Heap::Object *allocObjectWithMemberData(const QV4::VTable *vtable, uint nMembers);

private:
    void collectFromJSStack(MarkStack *markStack) const;
    void mark();
    void sweep(bool lastSweep = false, ClassDestroyStatsCallback classCountPtr = nullptr);
    bool shouldRunGC() const;
    void collectRoots(MarkStack *markStack);

public:
    QV4::ExecutionEngine *engine;
    ChunkAllocator *chunkAllocator;
    BlockAllocator blockAllocator;
    HugeItemAllocator hugeItemAllocator;
    PersistentValueStorage *m_persistentValues;
    PersistentValueStorage *m_weakValues;
    QVector<Value *> m_pendingFreedObjectWrapperValue;

    std::size_t unmanagedHeapSize = 0; // the amount of bytes of heap that is not managed by the memory manager, but which is held onto by managed items.
    std::size_t unmanagedHeapSizeGCLimit;
    std::size_t usedSlotsAfterLastFullSweep = 0;

    bool gcBlocked = false;
    bool aggressiveGC = false;
    bool gcStats = false;
    bool gcCollectorStats = false;

    struct {
        size_t maxReservedMem = 0;
        size_t maxAllocatedMem = 0;
        size_t maxUsedMem = 0;
        uint allocations[BlockAllocator::NumBins];
    } statistics;
};

}

QT_END_NAMESPACE

#endif // QV4GC_H