lbrycrd/src/serialize.h

// Copyright (c) 2009-2010 Satoshi Nakamoto
// Copyright (c) 2009-2013 The Bitcoin developers
// Distributed under the MIT/X11 software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.

#ifndef BITCOIN_SERIALIZE_H
#define BITCOIN_SERIALIZE_H

#include "allocators.h"

#include <algorithm>
#include <assert.h>
#include <limits>
#include <ios>
#include <map>
#include <set>
#include <stdint.h>
#include <string>
#include <string.h>
#include <utility>
#include <vector>

#include <boost/tuple/tuple.hpp>
#include <boost/type_traits/is_fundamental.hpp>
#include <boost/typeof/typeof.hpp>

class CAutoFile;
class CDataStream;
class CScript;

static const unsigned int MAX_SIZE = 0x02000000;

// Used to bypass the rule against non-const reference to temporary
// where it makes sense with wrappers such as CFlatData or CTxDB
template<typename T>
inline T& REF(const T& val)
{
    return const_cast<T&>(val);
}

// Used to acquire a non-const pointer "this" to generate bodies
// of const serialization operations from a template
template<typename T>
inline T* NCONST_PTR(const T* val)
{
    return const_cast<T*>(val);
}

/** Get begin pointer of vector (non-const version).
 * @note These functions avoid the undefined case of indexing into an empty
 * vector, as well as that of indexing after the end of the vector.
 */
template <class T, class TAl>
inline T* begin_ptr(std::vector<T,TAl>& v)
{
    return v.empty() ? NULL : &v[0];
}
/** Get begin pointer of vector (const version) */
template <class T, class TAl>
inline const T* begin_ptr(const std::vector<T,TAl>& v)
{
    return v.empty() ? NULL : &v[0];
}
/** Get end pointer of vector (non-const version) */
template <class T, class TAl>
inline T* end_ptr(std::vector<T,TAl>& v)
{
    return v.empty() ? NULL : (&v[0] + v.size());
}
/** Get end pointer of vector (const version) */
template <class T, class TAl>
inline const T* end_ptr(const std::vector<T,TAl>& v)
{
    return v.empty() ? NULL : (&v[0] + v.size());
}

/////////////////////////////////////////////////////////////////
//
// Templates for serializing to anything that looks like a stream,
// i.e. anything that supports .read(char*, size_t) and .write(char*, size_t)
//

enum
{
    // primary actions
    SER_NETWORK         = (1 << 0),
    SER_DISK            = (1 << 1),
    SER_GETHASH         = (1 << 2),
};

#define READWRITE(obj)      (nSerSize += ::SerReadWrite(s, (obj), nType, nVersion, ser_action))

/* Implement three methods for serializable objects. These are actually wrappers over
 * "SerializationOp" template, which implements the body of each class' serialization
 * code. Adding "IMPLEMENT_SERIALIZE" in the body of the class causes these wrappers to be
 * added as members. */
#define IMPLEMENT_SERIALIZE                                                                         \
    size_t GetSerializeSize(int nType, int nVersion) const {                                        \
        ser_streamplaceholder s;                                                                    \
        return NCONST_PTR(this)->SerializationOp(s, CSerActionGetSerializeSize(), nType, nVersion); \
    }                                                                                               \
    template<typename Stream>                                                                       \
    void Serialize(Stream& s, int nType, int nVersion) const {                                      \
        NCONST_PTR(this)->SerializationOp(s, CSerActionSerialize(), nType, nVersion);               \
    }                                                                                               \
    template<typename Stream>                                                                       \
    void Unserialize(Stream& s, int nType, int nVersion) {                                          \
        SerializationOp(s, CSerActionUnserialize(), nType, nVersion);                               \
    }



//
// Basic types
//
#define WRITEDATA(s, obj)   s.write((char*)&(obj), sizeof(obj))
#define READDATA(s, obj)    s.read((char*)&(obj), sizeof(obj))

inline unsigned int GetSerializeSize(char a,               int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(signed char a,        int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(unsigned char a,      int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(signed short a,       int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(unsigned short a,     int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(signed int a,         int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(unsigned int a,       int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(signed long a,        int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(unsigned long a,      int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(signed long long a,   int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(unsigned long long a, int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(float a,              int, int=0) { return sizeof(a); }
inline unsigned int GetSerializeSize(double a,             int, int=0) { return sizeof(a); }

template<typename Stream> inline void Serialize(Stream& s, char a,               int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, signed char a,        int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, unsigned char a,      int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, signed short a,       int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, unsigned short a,     int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, signed int a,         int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, unsigned int a,       int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, signed long a,        int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, unsigned long a,      int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, signed long long a,   int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, unsigned long long a, int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, float a,              int, int=0) { WRITEDATA(s, a); }
template<typename Stream> inline void Serialize(Stream& s, double a,             int, int=0) { WRITEDATA(s, a); }

template<typename Stream> inline void Unserialize(Stream& s, char& a,               int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, signed char& a,        int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, unsigned char& a,      int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, signed short& a,       int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, unsigned short& a,     int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, signed int& a,         int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, unsigned int& a,       int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, signed long& a,        int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, unsigned long& a,      int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, signed long long& a,   int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, unsigned long long& a, int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, float& a,              int, int=0) { READDATA(s, a); }
template<typename Stream> inline void Unserialize(Stream& s, double& a,             int, int=0) { READDATA(s, a); }

inline unsigned int GetSerializeSize(bool a, int, int=0)                          { return sizeof(char); }
template<typename Stream> inline void Serialize(Stream& s, bool a, int, int=0)    { char f=a; WRITEDATA(s, f); }
template<typename Stream> inline void Unserialize(Stream& s, bool& a, int, int=0) { char f; READDATA(s, f); a=f; }






//
// Compact size
//  size <  253        -- 1 byte
//  size <= USHRT_MAX  -- 3 bytes  (253 + 2 bytes)
//  size <= UINT_MAX   -- 5 bytes  (254 + 4 bytes)
//  size >  UINT_MAX   -- 9 bytes  (255 + 8 bytes)
//
inline unsigned int GetSizeOfCompactSize(uint64_t nSize)
{
    if (nSize < 253)             return sizeof(unsigned char);
    else if (nSize <= std::numeric_limits<unsigned short>::max()) return sizeof(unsigned char) + sizeof(unsigned short);
    else if (nSize <= std::numeric_limits<unsigned int>::max())  return sizeof(unsigned char) + sizeof(unsigned int);
    else                         return sizeof(unsigned char) + sizeof(uint64_t);
}

template<typename Stream>
void WriteCompactSize(Stream& os, uint64_t nSize)
{
    if (nSize < 253)
    {
        unsigned char chSize = nSize;
        WRITEDATA(os, chSize);
    }
    else if (nSize <= std::numeric_limits<unsigned short>::max())
    {
        unsigned char chSize = 253;
        unsigned short xSize = nSize;
        WRITEDATA(os, chSize);
        WRITEDATA(os, xSize);
    }
    else if (nSize <= std::numeric_limits<unsigned int>::max())
    {
        unsigned char chSize = 254;
        unsigned int xSize = nSize;
        WRITEDATA(os, chSize);
        WRITEDATA(os, xSize);
    }
    else
    {
        unsigned char chSize = 255;
        uint64_t xSize = nSize;
        WRITEDATA(os, chSize);
        WRITEDATA(os, xSize);
    }
    return;
}

template<typename Stream>
uint64_t ReadCompactSize(Stream& is)
{
    unsigned char chSize;
    READDATA(is, chSize);
    uint64_t nSizeRet = 0;
    if (chSize < 253)
    {
        nSizeRet = chSize;
    }
    else if (chSize == 253)
    {
        unsigned short xSize;
        READDATA(is, xSize);
        nSizeRet = xSize;
        if (nSizeRet < 253)
            throw std::ios_base::failure("non-canonical ReadCompactSize()");
    }
    else if (chSize == 254)
    {
        unsigned int xSize;
        READDATA(is, xSize);
        nSizeRet = xSize;
        if (nSizeRet < 0x10000u)
            throw std::ios_base::failure("non-canonical ReadCompactSize()");
    }
    else
    {
        uint64_t xSize;
        READDATA(is, xSize);
        nSizeRet = xSize;
        if (nSizeRet < 0x100000000LLu)
            throw std::ios_base::failure("non-canonical ReadCompactSize()");
    }
    if (nSizeRet > (uint64_t)MAX_SIZE)
        throw std::ios_base::failure("ReadCompactSize() : size too large");
    return nSizeRet;
}

// Variable-length integers: bytes are a MSB base-128 encoding of the number.
// The high bit in each byte signifies whether another digit follows. To make
// the encoding is one-to-one, one is subtracted from all but the last digit.
// Thus, the byte sequence a[] with length len, where all but the last byte
// has bit 128 set, encodes the number:
//
//   (a[len-1] & 0x7F) + sum(i=1..len-1, 128^i*((a[len-i-1] & 0x7F)+1))
//
// Properties:
// * Very small (0-127: 1 byte, 128-16511: 2 bytes, 16512-2113663: 3 bytes)
// * Every integer has exactly one encoding
// * Encoding does not depend on size of original integer type
// * No redundancy: every (infinite) byte sequence corresponds to a list
//   of encoded integers.
//
// 0:         [0x00]  256:        [0x81 0x00]
// 1:         [0x01]  16383:      [0xFE 0x7F]
// 127:       [0x7F]  16384:      [0xFF 0x00]
// 128:  [0x80 0x00]  16511: [0x80 0xFF 0x7F]
// 255:  [0x80 0x7F]  65535: [0x82 0xFD 0x7F]
// 2^32:           [0x8E 0xFE 0xFE 0xFF 0x00]

template<typename I>
inline unsigned int GetSizeOfVarInt(I n)
{
    int nRet = 0;
    while(true) {
        nRet++;
        if (n <= 0x7F)
            break;
        n = (n >> 7) - 1;
    }
    return nRet;
}

template<typename Stream, typename I>
void WriteVarInt(Stream& os, I n)
{
    unsigned char tmp[(sizeof(n)*8+6)/7];
    int len=0;
    while(true) {
        tmp[len] = (n & 0x7F) | (len ? 0x80 : 0x00);
        if (n <= 0x7F)
            break;
        n = (n >> 7) - 1;
        len++;
    }
    do {
        WRITEDATA(os, tmp[len]);
    } while(len--);
}

template<typename Stream, typename I>
I ReadVarInt(Stream& is)
{
    I n = 0;
    while(true) {
        unsigned char chData;
        READDATA(is, chData);
        n = (n << 7) | (chData & 0x7F);
        if (chData & 0x80)
            n++;
        else
            return n;
    }
}

#define FLATDATA(obj) REF(CFlatData((char*)&(obj), (char*)&(obj) + sizeof(obj)))
#define VARINT(obj) REF(WrapVarInt(REF(obj)))
#define LIMITED_STRING(obj,n) REF(LimitedString< n >(REF(obj)))

/** Wrapper for serializing arrays and POD.
 */
class CFlatData
{
protected:
    char* pbegin;
    char* pend;
public:
    CFlatData(void* pbeginIn, void* pendIn) : pbegin((char*)pbeginIn), pend((char*)pendIn) { }
    template <class T, class TAl>
    explicit CFlatData(std::vector<T,TAl> &v)
    {
        pbegin = (char*)begin_ptr(v);
        pend = (char*)end_ptr(v);
    }
    char* begin() { return pbegin; }
    const char* begin() const { return pbegin; }
    char* end() { return pend; }
    const char* end() const { return pend; }

    unsigned int GetSerializeSize(int, int=0) const
    {
        return pend - pbegin;
    }

    template<typename Stream>
    void Serialize(Stream& s, int, int=0) const
    {
        s.write(pbegin, pend - pbegin);
    }

    template<typename Stream>
    void Unserialize(Stream& s, int, int=0)
    {
        s.read(pbegin, pend - pbegin);
    }
};

template<typename I>
class CVarInt
{
protected:
    I &n;
public:
    CVarInt(I& nIn) : n(nIn) { }

    unsigned int GetSerializeSize(int, int) const {
        return GetSizeOfVarInt<I>(n);
    }

    template<typename Stream>
    void Serialize(Stream &s, int, int) const {
        WriteVarInt<Stream,I>(s, n);
    }

    template<typename Stream>
    void Unserialize(Stream& s, int, int) {
        n = ReadVarInt<Stream,I>(s);
    }
};

template<size_t Limit>
class LimitedString
{
protected:
    std::string& string;
public:
    LimitedString(std::string& string) : string(string) {}

    template<typename Stream>
    void Unserialize(Stream& s, int, int=0)
    {
        size_t size = ReadCompactSize(s);
        if (size > Limit) {
            throw std::ios_base::failure("String length limit exceeded");
        }
        string.resize(size);
        if (size != 0)
            s.read((char*)&string[0], size);
    }

    template<typename Stream>
    void Serialize(Stream& s, int, int=0) const
    {
        WriteCompactSize(s, string.size());
        if (!string.empty())
            s.write((char*)&string[0], string.size());
    }

    unsigned int GetSerializeSize(int, int=0) const
    {
        return GetSizeOfCompactSize(string.size()) + string.size();
    }
};

template<typename I>
CVarInt<I> WrapVarInt(I& n) { return CVarInt<I>(n); }

//
// Forward declarations
//

// string
template<typename C> unsigned int GetSerializeSize(const std::basic_string<C>& str, int, int=0);
template<typename Stream, typename C> void Serialize(Stream& os, const std::basic_string<C>& str, int, int=0);
template<typename Stream, typename C> void Unserialize(Stream& is, std::basic_string<C>& str, int, int=0);

// vector
template<typename T, typename A> unsigned int GetSerializeSize_impl(const std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&);
template<typename T, typename A> unsigned int GetSerializeSize_impl(const std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&);
template<typename T, typename A> inline unsigned int GetSerializeSize(const std::vector<T, A>& v, int nType, int nVersion);
template<typename Stream, typename T, typename A> void Serialize_impl(Stream& os, const std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&);
template<typename Stream, typename T, typename A> void Serialize_impl(Stream& os, const std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&);
template<typename Stream, typename T, typename A> inline void Serialize(Stream& os, const std::vector<T, A>& v, int nType, int nVersion);
template<typename Stream, typename T, typename A> void Unserialize_impl(Stream& is, std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&);
template<typename Stream, typename T, typename A> void Unserialize_impl(Stream& is, std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&);
template<typename Stream, typename T, typename A> inline void Unserialize(Stream& is, std::vector<T, A>& v, int nType, int nVersion);

// others derived from vector
extern inline unsigned int GetSerializeSize(const CScript& v, int nType, int nVersion);
template<typename Stream> void Serialize(Stream& os, const CScript& v, int nType, int nVersion);
template<typename Stream> void Unserialize(Stream& is, CScript& v, int nType, int nVersion);

// pair
template<typename K, typename T> unsigned int GetSerializeSize(const std::pair<K, T>& item, int nType, int nVersion);
template<typename Stream, typename K, typename T> void Serialize(Stream& os, const std::pair<K, T>& item, int nType, int nVersion);
template<typename Stream, typename K, typename T> void Unserialize(Stream& is, std::pair<K, T>& item, int nType, int nVersion);

// 3 tuple
template<typename T0, typename T1, typename T2> unsigned int GetSerializeSize(const boost::tuple<T0, T1, T2>& item, int nType, int nVersion);
template<typename Stream, typename T0, typename T1, typename T2> void Serialize(Stream& os, const boost::tuple<T0, T1, T2>& item, int nType, int nVersion);
template<typename Stream, typename T0, typename T1, typename T2> void Unserialize(Stream& is, boost::tuple<T0, T1, T2>& item, int nType, int nVersion);

// 4 tuple
template<typename T0, typename T1, typename T2, typename T3> unsigned int GetSerializeSize(const boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion);
template<typename Stream, typename T0, typename T1, typename T2, typename T3> void Serialize(Stream& os, const boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion);
template<typename Stream, typename T0, typename T1, typename T2, typename T3> void Unserialize(Stream& is, boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion);

// map
template<typename K, typename T, typename Pred, typename A> unsigned int GetSerializeSize(const std::map<K, T, Pred, A>& m, int nType, int nVersion);
template<typename Stream, typename K, typename T, typename Pred, typename A> void Serialize(Stream& os, const std::map<K, T, Pred, A>& m, int nType, int nVersion);
template<typename Stream, typename K, typename T, typename Pred, typename A> void Unserialize(Stream& is, std::map<K, T, Pred, A>& m, int nType, int nVersion);

// set
template<typename K, typename Pred, typename A> unsigned int GetSerializeSize(const std::set<K, Pred, A>& m, int nType, int nVersion);
template<typename Stream, typename K, typename Pred, typename A> void Serialize(Stream& os, const std::set<K, Pred, A>& m, int nType, int nVersion);
template<typename Stream, typename K, typename Pred, typename A> void Unserialize(Stream& is, std::set<K, Pred, A>& m, int nType, int nVersion);





//
// If none of the specialized versions above matched, default to calling member function.
// "int nType" is changed to "long nType" to keep from getting an ambiguous overload error.
// The compiler will only cast int to long if none of the other templates matched.
// Thanks to Boost serialization for this idea.
//
template<typename T>
inline unsigned int GetSerializeSize(const T& a, long nType, int nVersion)
{
    return a.GetSerializeSize((int)nType, nVersion);
}

template<typename Stream, typename T>
inline void Serialize(Stream& os, const T& a, long nType, int nVersion)
{
    a.Serialize(os, (int)nType, nVersion);
}

template<typename Stream, typename T>
inline void Unserialize(Stream& is, T& a, long nType, int nVersion)
{
    a.Unserialize(is, (int)nType, nVersion);
}





//
// string
//
template<typename C>
unsigned int GetSerializeSize(const std::basic_string<C>& str, int, int)
{
    return GetSizeOfCompactSize(str.size()) + str.size() * sizeof(str[0]);
}

template<typename Stream, typename C>
void Serialize(Stream& os, const std::basic_string<C>& str, int, int)
{
    WriteCompactSize(os, str.size());
    if (!str.empty())
        os.write((char*)&str[0], str.size() * sizeof(str[0]));
}

template<typename Stream, typename C>
void Unserialize(Stream& is, std::basic_string<C>& str, int, int)
{
    unsigned int nSize = ReadCompactSize(is);
    str.resize(nSize);
    if (nSize != 0)
        is.read((char*)&str[0], nSize * sizeof(str[0]));
}



//
// vector
//
template<typename T, typename A>
unsigned int GetSerializeSize_impl(const std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&)
{
    return (GetSizeOfCompactSize(v.size()) + v.size() * sizeof(T));
}

template<typename T, typename A>
unsigned int GetSerializeSize_impl(const std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&)
{
    unsigned int nSize = GetSizeOfCompactSize(v.size());
    for (typename std::vector<T, A>::const_iterator vi = v.begin(); vi != v.end(); ++vi)
        nSize += GetSerializeSize((*vi), nType, nVersion);
    return nSize;
}

template<typename T, typename A>
inline unsigned int GetSerializeSize(const std::vector<T, A>& v, int nType, int nVersion)
{
    return GetSerializeSize_impl(v, nType, nVersion, boost::is_fundamental<T>());
}


template<typename Stream, typename T, typename A>
void Serialize_impl(Stream& os, const std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&)
{
    WriteCompactSize(os, v.size());
    if (!v.empty())
        os.write((char*)&v[0], v.size() * sizeof(T));
}

template<typename Stream, typename T, typename A>
void Serialize_impl(Stream& os, const std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&)
{
    WriteCompactSize(os, v.size());
    for (typename std::vector<T, A>::const_iterator vi = v.begin(); vi != v.end(); ++vi)
        ::Serialize(os, (*vi), nType, nVersion);
}

template<typename Stream, typename T, typename A>
inline void Serialize(Stream& os, const std::vector<T, A>& v, int nType, int nVersion)
{
    Serialize_impl(os, v, nType, nVersion, boost::is_fundamental<T>());
}


template<typename Stream, typename T, typename A>
void Unserialize_impl(Stream& is, std::vector<T, A>& v, int nType, int nVersion, const boost::true_type&)
{
    // Limit size per read so bogus size value won't cause out of memory
    v.clear();
    unsigned int nSize = ReadCompactSize(is);
    unsigned int i = 0;
    while (i < nSize)
    {
        unsigned int blk = std::min(nSize - i, (unsigned int)(1 + 4999999 / sizeof(T)));
        v.resize(i + blk);
        is.read((char*)&v[i], blk * sizeof(T));
        i += blk;
    }
}

template<typename Stream, typename T, typename A>
void Unserialize_impl(Stream& is, std::vector<T, A>& v, int nType, int nVersion, const boost::false_type&)
{
    v.clear();
    unsigned int nSize = ReadCompactSize(is);
    unsigned int i = 0;
    unsigned int nMid = 0;
    while (nMid < nSize)
    {
        nMid += 5000000 / sizeof(T);
        if (nMid > nSize)
            nMid = nSize;
        v.resize(nMid);
        for (; i < nMid; i++)
            Unserialize(is, v[i], nType, nVersion);
    }
}

template<typename Stream, typename T, typename A>
inline void Unserialize(Stream& is, std::vector<T, A>& v, int nType, int nVersion)
{
    Unserialize_impl(is, v, nType, nVersion, boost::is_fundamental<T>());
}



//
// others derived from vector
//
inline unsigned int GetSerializeSize(const CScript& v, int nType, int nVersion)
{
    return GetSerializeSize((const std::vector<unsigned char>&)v, nType, nVersion);
}

template<typename Stream>
void Serialize(Stream& os, const CScript& v, int nType, int nVersion)
{
    Serialize(os, (const std::vector<unsigned char>&)v, nType, nVersion);
}

template<typename Stream>
void Unserialize(Stream& is, CScript& v, int nType, int nVersion)
{
    Unserialize(is, (std::vector<unsigned char>&)v, nType, nVersion);
}



//
// pair
//
template<typename K, typename T>
unsigned int GetSerializeSize(const std::pair<K, T>& item, int nType, int nVersion)
{
    return GetSerializeSize(item.first, nType, nVersion) + GetSerializeSize(item.second, nType, nVersion);
}

template<typename Stream, typename K, typename T>
void Serialize(Stream& os, const std::pair<K, T>& item, int nType, int nVersion)
{
    Serialize(os, item.first, nType, nVersion);
    Serialize(os, item.second, nType, nVersion);
}

template<typename Stream, typename K, typename T>
void Unserialize(Stream& is, std::pair<K, T>& item, int nType, int nVersion)
{
    Unserialize(is, item.first, nType, nVersion);
    Unserialize(is, item.second, nType, nVersion);
}



//
// 3 tuple
//
template<typename T0, typename T1, typename T2>
unsigned int GetSerializeSize(const boost::tuple<T0, T1, T2>& item, int nType, int nVersion)
{
    unsigned int nSize = 0;
    nSize += GetSerializeSize(boost::get<0>(item), nType, nVersion);
    nSize += GetSerializeSize(boost::get<1>(item), nType, nVersion);
    nSize += GetSerializeSize(boost::get<2>(item), nType, nVersion);
    return nSize;
}

template<typename Stream, typename T0, typename T1, typename T2>
void Serialize(Stream& os, const boost::tuple<T0, T1, T2>& item, int nType, int nVersion)
{
    Serialize(os, boost::get<0>(item), nType, nVersion);
    Serialize(os, boost::get<1>(item), nType, nVersion);
    Serialize(os, boost::get<2>(item), nType, nVersion);
}

template<typename Stream, typename T0, typename T1, typename T2>
void Unserialize(Stream& is, boost::tuple<T0, T1, T2>& item, int nType, int nVersion)
{
    Unserialize(is, boost::get<0>(item), nType, nVersion);
    Unserialize(is, boost::get<1>(item), nType, nVersion);
    Unserialize(is, boost::get<2>(item), nType, nVersion);
}



//
// 4 tuple
//
template<typename T0, typename T1, typename T2, typename T3>
unsigned int GetSerializeSize(const boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion)
{
    unsigned int nSize = 0;
    nSize += GetSerializeSize(boost::get<0>(item), nType, nVersion);
    nSize += GetSerializeSize(boost::get<1>(item), nType, nVersion);
    nSize += GetSerializeSize(boost::get<2>(item), nType, nVersion);
    nSize += GetSerializeSize(boost::get<3>(item), nType, nVersion);
    return nSize;
}

template<typename Stream, typename T0, typename T1, typename T2, typename T3>
void Serialize(Stream& os, const boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion)
{
    Serialize(os, boost::get<0>(item), nType, nVersion);
    Serialize(os, boost::get<1>(item), nType, nVersion);
    Serialize(os, boost::get<2>(item), nType, nVersion);
    Serialize(os, boost::get<3>(item), nType, nVersion);
}

template<typename Stream, typename T0, typename T1, typename T2, typename T3>
void Unserialize(Stream& is, boost::tuple<T0, T1, T2, T3>& item, int nType, int nVersion)
{
    Unserialize(is, boost::get<0>(item), nType, nVersion);
    Unserialize(is, boost::get<1>(item), nType, nVersion);
    Unserialize(is, boost::get<2>(item), nType, nVersion);
    Unserialize(is, boost::get<3>(item), nType, nVersion);
}



//
// map
//
template<typename K, typename T, typename Pred, typename A>
unsigned int GetSerializeSize(const std::map<K, T, Pred, A>& m, int nType, int nVersion)
{
    unsigned int nSize = GetSizeOfCompactSize(m.size());
    for (typename std::map<K, T, Pred, A>::const_iterator mi = m.begin(); mi != m.end(); ++mi)
        nSize += GetSerializeSize((*mi), nType, nVersion);
    return nSize;
}

template<typename Stream, typename K, typename T, typename Pred, typename A>
void Serialize(Stream& os, const std::map<K, T, Pred, A>& m, int nType, int nVersion)
{
    WriteCompactSize(os, m.size());
    for (typename std::map<K, T, Pred, A>::const_iterator mi = m.begin(); mi != m.end(); ++mi)
        Serialize(os, (*mi), nType, nVersion);
}

template<typename Stream, typename K, typename T, typename Pred, typename A>
void Unserialize(Stream& is, std::map<K, T, Pred, A>& m, int nType, int nVersion)
{
    m.clear();
    unsigned int nSize = ReadCompactSize(is);
    typename std::map<K, T, Pred, A>::iterator mi = m.begin();
    for (unsigned int i = 0; i < nSize; i++)
    {
        std::pair<K, T> item;
        Unserialize(is, item, nType, nVersion);
        mi = m.insert(mi, item);
    }
}



//
// set
//
template<typename K, typename Pred, typename A>
unsigned int GetSerializeSize(const std::set<K, Pred, A>& m, int nType, int nVersion)
{
    unsigned int nSize = GetSizeOfCompactSize(m.size());
    for (typename std::set<K, Pred, A>::const_iterator it = m.begin(); it != m.end(); ++it)
        nSize += GetSerializeSize((*it), nType, nVersion);
    return nSize;
}

template<typename Stream, typename K, typename Pred, typename A>
void Serialize(Stream& os, const std::set<K, Pred, A>& m, int nType, int nVersion)
{
    WriteCompactSize(os, m.size());
    for (typename std::set<K, Pred, A>::const_iterator it = m.begin(); it != m.end(); ++it)
        Serialize(os, (*it), nType, nVersion);
}

template<typename Stream, typename K, typename Pred, typename A>
void Unserialize(Stream& is, std::set<K, Pred, A>& m, int nType, int nVersion)
{
    m.clear();
    unsigned int nSize = ReadCompactSize(is);
    typename std::set<K, Pred, A>::iterator it = m.begin();
    for (unsigned int i = 0; i < nSize; i++)
    {
        K key;
        Unserialize(is, key, nType, nVersion);
        it = m.insert(it, key);
    }
}



//
// Support for IMPLEMENT_SERIALIZE and READWRITE macro
//
class CSerActionGetSerializeSize { };
class CSerActionSerialize { };
class CSerActionUnserialize { };

template<typename Stream, typename T>
inline unsigned int SerReadWrite(Stream& s, const T& obj, int nType, int nVersion, CSerActionGetSerializeSize ser_action)
{
    return ::GetSerializeSize(obj, nType, nVersion);
}

template<typename Stream, typename T>
inline unsigned int SerReadWrite(Stream& s, const T& obj, int nType, int nVersion, CSerActionSerialize ser_action)
{
    ::Serialize(s, obj, nType, nVersion);
    return 0;
}

template<typename Stream, typename T>
inline unsigned int SerReadWrite(Stream& s, T& obj, int nType, int nVersion, CSerActionUnserialize ser_action)
{
    ::Unserialize(s, obj, nType, nVersion);
    return 0;
}

struct ser_streamplaceholder { };









typedef std::vector<char, zero_after_free_allocator<char> > CSerializeData;

class CSizeComputer
{
protected:
    size_t nSize;

public:
    int nType;
    int nVersion;

    CSizeComputer(int nTypeIn, int nVersionIn) : nSize(0), nType(nTypeIn), nVersion(nVersionIn) {}

    CSizeComputer& write(const char *psz, size_t nSize)
    {
        this->nSize += nSize;
        return *this;
    }

    template<typename T>
    CSizeComputer& operator<<(const T& obj)
    {
        ::Serialize(*this, obj, nType, nVersion);
        return (*this);
    }

    size_t size() const {
        return nSize;
    }
};

/** Double ended buffer combining vector and stream-like interfaces.
 *
 * >> and << read and write unformatted data using the above serialization templates.
 * Fills with data in linear time; some stringstream implementations take N^2 time.
 */
class CDataStream
{
protected:
    typedef CSerializeData vector_type;
    vector_type vch;
    unsigned int nReadPos;
public:
    int nType;
    int nVersion;

    typedef vector_type::allocator_type   allocator_type;
    typedef vector_type::size_type        size_type;
    typedef vector_type::difference_type  difference_type;
    typedef vector_type::reference        reference;
    typedef vector_type::const_reference  const_reference;
    typedef vector_type::value_type       value_type;
    typedef vector_type::iterator         iterator;
    typedef vector_type::const_iterator   const_iterator;
    typedef vector_type::reverse_iterator reverse_iterator;

    explicit CDataStream(int nTypeIn, int nVersionIn)
    {
        Init(nTypeIn, nVersionIn);
    }

    CDataStream(const_iterator pbegin, const_iterator pend, int nTypeIn, int nVersionIn) : vch(pbegin, pend)
    {
        Init(nTypeIn, nVersionIn);
    }

#if !defined(_MSC_VER) || _MSC_VER >= 1300
    CDataStream(const char* pbegin, const char* pend, int nTypeIn, int nVersionIn) : vch(pbegin, pend)
    {
        Init(nTypeIn, nVersionIn);
    }
#endif

    CDataStream(const vector_type& vchIn, int nTypeIn, int nVersionIn) : vch(vchIn.begin(), vchIn.end())
    {
        Init(nTypeIn, nVersionIn);
    }

    CDataStream(const std::vector<char>& vchIn, int nTypeIn, int nVersionIn) : vch(vchIn.begin(), vchIn.end())
    {
        Init(nTypeIn, nVersionIn);
    }

    CDataStream(const std::vector<unsigned char>& vchIn, int nTypeIn, int nVersionIn) : vch((char*)&vchIn.begin()[0], (char*)&vchIn.end()[0])
    {
        Init(nTypeIn, nVersionIn);
    }

    void Init(int nTypeIn, int nVersionIn)
    {
        nReadPos = 0;
        nType = nTypeIn;
        nVersion = nVersionIn;
    }

    CDataStream& operator+=(const CDataStream& b)
    {
        vch.insert(vch.end(), b.begin(), b.end());
        return *this;
    }

    friend CDataStream operator+(const CDataStream& a, const CDataStream& b)
    {
        CDataStream ret = a;
        ret += b;
        return (ret);
    }

    std::string str() const
    {
        return (std::string(begin(), end()));
    }


    //
    // Vector subset
    //
    const_iterator begin() const                     { return vch.begin() + nReadPos; }
    iterator begin()                                 { return vch.begin() + nReadPos; }
    const_iterator end() const                       { return vch.end(); }
    iterator end()                                   { return vch.end(); }
    size_type size() const                           { return vch.size() - nReadPos; }
    bool empty() const                               { return vch.size() == nReadPos; }
    void resize(size_type n, value_type c=0)         { vch.resize(n + nReadPos, c); }
    void reserve(size_type n)                        { vch.reserve(n + nReadPos); }
    const_reference operator[](size_type pos) const  { return vch[pos + nReadPos]; }
    reference operator[](size_type pos)              { return vch[pos + nReadPos]; }
    void clear()                                     { vch.clear(); nReadPos = 0; }
    iterator insert(iterator it, const char& x=char()) { return vch.insert(it, x); }
    void insert(iterator it, size_type n, const char& x) { vch.insert(it, n, x); }

    void insert(iterator it, std::vector<char>::const_iterator first, std::vector<char>::const_iterator last)
    {
        assert(last - first >= 0);
        if (it == vch.begin() + nReadPos && (unsigned int)(last - first) <= nReadPos)
        {
            // special case for inserting at the front when there's room
            nReadPos -= (last - first);
            memcpy(&vch[nReadPos], &first[0], last - first);
        }
        else
            vch.insert(it, first, last);
    }

#if !defined(_MSC_VER) || _MSC_VER >= 1300
    void insert(iterator it, const char* first, const char* last)
    {
        assert(last - first >= 0);
        if (it == vch.begin() + nReadPos && (unsigned int)(last - first) <= nReadPos)
        {
            // special case for inserting at the front when there's room
            nReadPos -= (last - first);
            memcpy(&vch[nReadPos], &first[0], last - first);
        }
        else
            vch.insert(it, first, last);
    }
#endif

    iterator erase(iterator it)
    {
        if (it == vch.begin() + nReadPos)
        {
            // special case for erasing from the front
            if (++nReadPos >= vch.size())
            {
                // whenever we reach the end, we take the opportunity to clear the buffer
                nReadPos = 0;
                return vch.erase(vch.begin(), vch.end());
            }
            return vch.begin() + nReadPos;
        }
        else
            return vch.erase(it);
    }

    iterator erase(iterator first, iterator last)
    {
        if (first == vch.begin() + nReadPos)
        {
            // special case for erasing from the front
            if (last == vch.end())
            {
                nReadPos = 0;
                return vch.erase(vch.begin(), vch.end());
            }
            else
            {
                nReadPos = (last - vch.begin());
                return last;
            }
        }
        else
            return vch.erase(first, last);
    }

    inline void Compact()
    {
        vch.erase(vch.begin(), vch.begin() + nReadPos);
        nReadPos = 0;
    }

    bool Rewind(size_type n)
    {
        // Rewind by n characters if the buffer hasn't been compacted yet
        if (n > nReadPos)
            return false;
        nReadPos -= n;
        return true;
    }


    //
    // Stream subset
    //
    bool eof() const             { return size() == 0; }
    CDataStream* rdbuf()         { return this; }
    int in_avail()               { return size(); }

    void SetType(int n)          { nType = n; }
    int GetType()                { return nType; }
    void SetVersion(int n)       { nVersion = n; }
    int GetVersion()             { return nVersion; }
    void ReadVersion()           { *this >> nVersion; }
    void WriteVersion()          { *this << nVersion; }

    CDataStream& read(char* pch, size_t nSize)
    {
        // Read from the beginning of the buffer
        unsigned int nReadPosNext = nReadPos + nSize;
        if (nReadPosNext >= vch.size())
        {
            if (nReadPosNext > vch.size())
            {
                throw std::ios_base::failure("CDataStream::read() : end of data");
            }
            memcpy(pch, &vch[nReadPos], nSize);
            nReadPos = 0;
            vch.clear();
            return (*this);
        }
        memcpy(pch, &vch[nReadPos], nSize);
        nReadPos = nReadPosNext;
        return (*this);
    }

    CDataStream& ignore(int nSize)
    {
        // Ignore from the beginning of the buffer
        assert(nSize >= 0);
        unsigned int nReadPosNext = nReadPos + nSize;
        if (nReadPosNext >= vch.size())
        {
            if (nReadPosNext > vch.size())
                throw std::ios_base::failure("CDataStream::ignore() : end of data");
            nReadPos = 0;
            vch.clear();
            return (*this);
        }
        nReadPos = nReadPosNext;
        return (*this);
    }

    CDataStream& write(const char* pch, size_t nSize)
    {
        // Write to the end of the buffer
        vch.insert(vch.end(), pch, pch + nSize);
        return (*this);
    }

    template<typename Stream>
    void Serialize(Stream& s, int nType, int nVersion) const
    {
        // Special case: stream << stream concatenates like stream += stream
        if (!vch.empty())
            s.write((char*)&vch[0], vch.size() * sizeof(vch[0]));
    }

    template<typename T>
    unsigned int GetSerializeSize(const T& obj)
    {
        // Tells the size of the object if serialized to this stream
        return ::GetSerializeSize(obj, nType, nVersion);
    }

    template<typename T>
    CDataStream& operator<<(const T& obj)
    {
        // Serialize to this stream
        ::Serialize(*this, obj, nType, nVersion);
        return (*this);
    }

    template<typename T>
    CDataStream& operator>>(T& obj)
    {
        // Unserialize from this stream
        ::Unserialize(*this, obj, nType, nVersion);
        return (*this);
    }

    void GetAndClear(CSerializeData &data) {
        data.insert(data.end(), begin(), end());
        clear();
    }
};










/** RAII wrapper for FILE*.
 *
 * Will automatically close the file when it goes out of scope if not null.
 * If you're returning the file pointer, return file.release().
 * If you need to close the file early, use file.fclose() instead of fclose(file).
 */
class CAutoFile
{
protected:
    FILE* file;
public:
    int nType;
    int nVersion;

    CAutoFile(FILE* filenew, int nTypeIn, int nVersionIn)
    {
        file = filenew;
        nType = nTypeIn;
        nVersion = nVersionIn;
    }

    ~CAutoFile()
    {
        fclose();
    }

    void fclose()
    {
        if (file != NULL && file != stdin && file != stdout && file != stderr)
            ::fclose(file);
        file = NULL;
    }

    FILE* release()             { FILE* ret = file; file = NULL; return ret; }
    operator FILE*()            { return file; }
    FILE* operator->()          { return file; }
    FILE& operator*()           { return *file; }
    FILE** operator&()          { return &file; }
    FILE* operator=(FILE* pnew) { return file = pnew; }
    bool operator!()            { return (file == NULL); }


    //
    // Stream subset
    //
    void SetType(int n)          { nType = n; }
    int GetType()                { return nType; }
    void SetVersion(int n)       { nVersion = n; }
    int GetVersion()             { return nVersion; }
    void ReadVersion()           { *this >> nVersion; }
    void WriteVersion()          { *this << nVersion; }

    CAutoFile& read(char* pch, size_t nSize)
    {
        if (!file)
            throw std::ios_base::failure("CAutoFile::read : file handle is NULL");
        if (fread(pch, 1, nSize, file) != nSize)
            throw std::ios_base::failure(feof(file) ? "CAutoFile::read : end of file" : "CAutoFile::read : fread failed");
        return (*this);
    }

    CAutoFile& write(const char* pch, size_t nSize)
    {
        if (!file)
            throw std::ios_base::failure("CAutoFile::write : file handle is NULL");
        if (fwrite(pch, 1, nSize, file) != nSize)
            throw std::ios_base::failure("CAutoFile::write : write failed");
        return (*this);
    }

    template<typename T>
    unsigned int GetSerializeSize(const T& obj)
    {
        // Tells the size of the object if serialized to this stream
        return ::GetSerializeSize(obj, nType, nVersion);
    }

    template<typename T>
    CAutoFile& operator<<(const T& obj)
    {
        // Serialize to this stream
        if (!file)
            throw std::ios_base::failure("CAutoFile::operator<< : file handle is NULL");
        ::Serialize(*this, obj, nType, nVersion);
        return (*this);
    }

    template<typename T>
    CAutoFile& operator>>(T& obj)
    {
        // Unserialize from this stream
        if (!file)
            throw std::ios_base::failure("CAutoFile::operator>> : file handle is NULL");
        ::Unserialize(*this, obj, nType, nVersion);
        return (*this);
    }
};

/** Wrapper around a FILE* that implements a ring buffer to
 *  deserialize from. It guarantees the ability to rewind
 *  a given number of bytes. */
class CBufferedFile
{
private:
    FILE *src;          // source file
    uint64_t nSrcPos;     // how many bytes have been read from source
    uint64_t nReadPos;    // how many bytes have been read from this
    uint64_t nReadLimit;  // up to which position we're allowed to read
    uint64_t nRewind;     // how many bytes we guarantee to rewind
    std::vector<char> vchBuf; // the buffer

protected:
    // read data from the source to fill the buffer
    bool Fill() {
        unsigned int pos = nSrcPos % vchBuf.size();
        unsigned int readNow = vchBuf.size() - pos;
        unsigned int nAvail = vchBuf.size() - (nSrcPos - nReadPos) - nRewind;
        if (nAvail < readNow)
            readNow = nAvail;
        if (readNow == 0)
            return false;
        size_t read = fread((void*)&vchBuf[pos], 1, readNow, src);
        if (read == 0) {
            throw std::ios_base::failure(feof(src) ? "CBufferedFile::Fill : end of file" : "CBufferedFile::Fill : fread failed");
        } else {
            nSrcPos += read;
            return true;
        }
    }

public:
    int nType;
    int nVersion;

    CBufferedFile(FILE *fileIn, uint64_t nBufSize, uint64_t nRewindIn, int nTypeIn, int nVersionIn) :
        src(fileIn), nSrcPos(0), nReadPos(0), nReadLimit((uint64_t)(-1)), nRewind(nRewindIn), vchBuf(nBufSize, 0),
        nType(nTypeIn), nVersion(nVersionIn) {
    }

    // check whether we're at the end of the source file
    bool eof() const {
        return nReadPos == nSrcPos && feof(src);
    }

    // read a number of bytes
    CBufferedFile& read(char *pch, size_t nSize) {
        if (nSize + nReadPos > nReadLimit)
            throw std::ios_base::failure("Read attempted past buffer limit");
        if (nSize + nRewind > vchBuf.size())
            throw std::ios_base::failure("Read larger than buffer size");
        while (nSize > 0) {
            if (nReadPos == nSrcPos)
                Fill();
            unsigned int pos = nReadPos % vchBuf.size();
            size_t nNow = nSize;
            if (nNow + pos > vchBuf.size())
                nNow = vchBuf.size() - pos;
            if (nNow + nReadPos > nSrcPos)
                nNow = nSrcPos - nReadPos;
            memcpy(pch, &vchBuf[pos], nNow);
            nReadPos += nNow;
            pch += nNow;
            nSize -= nNow;
        }
        return (*this);
    }

    // return the current reading position
    uint64_t GetPos() {
        return nReadPos;
    }

    // rewind to a given reading position
    bool SetPos(uint64_t nPos) {
        nReadPos = nPos;
        if (nReadPos + nRewind < nSrcPos) {
            nReadPos = nSrcPos - nRewind;
            return false;
        } else if (nReadPos > nSrcPos) {
            nReadPos = nSrcPos;
            return false;
        } else {
            return true;
        }
    }

    bool Seek(uint64_t nPos) {
        long nLongPos = nPos;
        if (nPos != (uint64_t)nLongPos)
            return false;
        if (fseek(src, nLongPos, SEEK_SET))
            return false;
        nLongPos = ftell(src);
        nSrcPos = nLongPos;
        nReadPos = nLongPos;
        return true;
    }

    // prevent reading beyond a certain position
    // no argument removes the limit
    bool SetLimit(uint64_t nPos = (uint64_t)(-1)) {
        if (nPos < nReadPos)
            return false;
        nReadLimit = nPos;
        return true;
    }

    template<typename T>
    CBufferedFile& operator>>(T& obj) {
        // Unserialize from this stream
        ::Unserialize(*this, obj, nType, nVersion);
        return (*this);
    }

    // search for a given byte in the stream, and remain positioned on it
    void FindByte(char ch) {
        while (true) {
            if (nReadPos == nSrcPos)
                Fill();
            if (vchBuf[nReadPos % vchBuf.size()] == ch)
                break;
            nReadPos++;
        }
    }
};

#endif