GitHub - chronoxor/CppSerialization: Performance comparison of the most popular C++ serialization protocols such as Cap'n'Proto, FastBinaryEncoding, Flatbuffers, Protobuf, JSON (original) (raw)

CppSerialization

C++ Serialization Library provides functionality to serialize/deserialize objects using different protocols such as Cap'n'Proto, FastBinaryEncoding, Flatbuffers, Protobuf, SimpleBinaryEncoding, zpp::bits, JSON.

Performance comparison based on the Domain model with one account, one wallet and three orders total size of 128 bytes:

CppSerialization API reference

Contents

• Features
• Requirements
• How to build?
• Domain model
• Cap'n'Proto serialization
  • Cap'n'Proto schema
  • Cap'n'Proto schema compilation
  • Cap'n'Proto serialization methods
  • Cap'n'Proto example
  • Cap'n'Proto performance
• FastBinaryEncoding serialization
  • FastBinaryEncoding schema
  • FastBinaryEncoding schema compilation
  • FastBinaryEncoding serialization methods
  • FastBinaryEncoding example
  • FastBinaryEncoding performance
• FlatBuffers serialization
  • FlatBuffers schema
  • FlatBuffers schema compilation
  • FlatBuffers serialization methods
  • FlatBuffers example
  • FlatBuffers performance
• Protobuf serialization
  • Protobuf schema
  • Protobuf schema compilation
  • Protobuf serialization methods
  • Protobuf example
  • Protobuf performance
• SimpleBinaryEncoding serialization
  • SimpleBinaryEncoding schema
  • SimpleBinaryEncoding schema compilation
  • SimpleBinaryEncoding serialization methods
  • SimpleBinaryEncoding example
  • SimpleBinaryEncoding performance
• zpp::bits serialization
  • zpp::bits serialization methods
  • zpp::bits example
  • zpp::bits performance
• JSON serialization
  • JSON serialization methods
  • JSON example
  • JSON performance

Features

• Cross platform (Linux, MacOS, Windows)
• Binary serialization using Cap'n'Proto library
• Binary serialization using FastBinaryEncoding library
• Binary serialization using FlatBuffers library
• Binary serialization using Protobuf library
• Binary serialization using SimpleBinaryEncoding library
• Binary serialization using zpp::bits library
• JSON serialization using RapidJSON library

Requirements

• Linux
• MacOS
• Windows
• cmake
• gcc
• git
• gil
• python3

Optional:

• clang
• CLion
• MSYS2
• MinGW
• Visual Studio

How to build?

Linux: install required packages

sudo apt-get install -y binutils-dev uuid-dev

Install gil (git links) tool

Setup repository

git clone https://github.com/chronoxor/CppSerialization.git cd CppSerialization gil update

Linux

MacOS

Windows (MSYS2)

Windows (MinGW)

Windows (Visual Studio)

Domain model

The first step you should perform to use CppSerialization library is to provide a domain model (aka business objects). Domain model is a set of structures or classes that related to each other and might be aggregated in some hierarchy.

There is an example domain model which describes Account-Balance-Orders relation of some abstract trading platform:

#include #include

namespace TradeProto {

enum class OrderSide : uint8_t { BUY, SELL };

enum class OrderType : uint8_t { MARKET, LIMIT, STOP };

struct Order { int Id; char Symbol[10]; OrderSide Side; OrderType Type; double Price; double Volume;

Order() : Order(0, "<\?\?\?>", OrderSide::BUY, OrderType::MARKET, 0.0, 0.0) {}
Order(int id, const std::string& symbol, OrderSide side, OrderType type, double price, double volume)
{
    Id = id;
    std::memcpy(Symbol, symbol.c_str(), std::min(symbol.size() + 1, sizeof(Symbol)));
    Side = side;
    Type = type;
    Price = price;
    Volume = volume;
}

};

struct Balance { char Currency[10]; double Amount;

Balance() : Balance("<\?\?\?>", 0.0) {}
Balance(const std::string& currency, double amount)
{
    std::memcpy(Currency, currency.c_str(), std::min(currency.size() + 1, sizeof(Currency)));
    Amount = amount;
}

};

struct Account { int Id; std::string Name; Balance Wallet; std::vector Orders;

Account() : Account(0, "<\?\?\?>", "<\?\?\?>", 0.0) {}
Account(int id, const char* name, const char* currency, double amount) : Wallet(currency, amount)
{
    Id = id;
    Name = name;
}

};

} // namespace TradeProto

The next step you should provide serialization methods for the domain model.

Cap'n'Proto serialization

Cap'n'Proto serialization is based on Cap'n'Proto library.

Cap'n'Proto schema

Cap'n'Proto serialization starts with describing a model schema. For our domain model the schema will be the following:

Unique file ID, generated by 'capnp id'

@0xd4b6e00623bed170;

using Cxx = import "/capnp/c++.capnp"; $Cxx.namespace("Trade::capnproto");

enum OrderSide { buy @0; sell @1; }

enum OrderType { market @0; limit @1; stop @2; }

struct Order { id @0 : Int32; symbol @1 : Text; side @2 : OrderSide; type @3 : OrderType; price @4 : Float64 = 0.0; volume @5 : Float64 = 0.0; }

struct Balance { currency @0 : Text; amount @1 : Float64 = 0.0; }

struct Account { id @0 : Int32; name @1 : Text; wallet @2 : Balance; orders @3 : List(Order); }

Cap'n'Proto schema compilation

The next step is a schema compilation using 'capnpc' utility which will create a generated code for required programming language.

The following command will create a C++ generated code:

capnp compile -I capnproto/c++/src -oc++ trade.capnp

It is possible to use capnp_generate_cpp() in CMakeLists.txt to generate code using 'cmake' utility:

capnp_generate_cpp(CAPNP_HEADERS CAPNP_SOURCES trade.capnp)

As the result 'trade.capnp.h' and 'trade.capnp.c++' files will be generated.

Cap'n'Proto serialization methods

Finally you should extend your domain model with a Cap'n'Proto serialization methods:

#include "capnp/serialize.h" #include "capnproto/trade.capnp.h"

#include

namespace TradeProto {

struct Order { ...

// Cap'n'Proto serialization

void Serialize(Trade::capnproto::Order::Builder& builder)
{
    builder.setId(Id);
    builder.setSymbol(Symbol);
    builder.setSide((Trade::capnproto::OrderSide)Side);
    builder.setType((Trade::capnproto::OrderType)Type);
    builder.setPrice(Price);
    builder.setVolume(Volume);
}

void Deserialize(const Trade::capnproto::Order::Reader& reader)
{
    Id = reader.getId();
    std::string symbol = reader.getSymbol();
    std::memcpy(Symbol, symbol.c_str(), std::min(symbol.size() + 1, sizeof(Symbol)));
    Side = (OrderSide)reader.getSide();
    Type = (OrderType)reader.getType();
    Price = reader.getPrice();
    Volume = reader.getVolume();
}

...

};

struct Balance { ...

// Cap'n'Proto serialization

void Serialize(Trade::capnproto::Balance::Builder& builder)
{
    builder.setCurrency(Currency);
    builder.setAmount(Amount);
}

void Deserialize(const Trade::capnproto::Balance::Reader& reader)
{
    std::string currency = reader.getCurrency();
    std::memcpy(Currency, currency.c_str(), std::min(currency.size() + 1, sizeof(Currency)));
    Amount = reader.getAmount();
}

...

};

struct Account { ...

// Cap'n'Proto serialization

void Serialize(Trade::capnproto::Account::Builder& builder)
{
    builder.setId(Id);
    builder.setName(Name);
    auto wallet = builder.initWallet();
    Wallet.Serialize(wallet);
    auto orders = builder.initOrders((unsigned)Orders.size());
    unsigned index = 0;
    for (auto& order : Orders)
    {
        auto o = orders[index++];
        order.Serialize(o);
    }
}

void Deserialize(const Trade::capnproto::Account::Reader& reader)
{
    Id = reader.getId();
    Name = reader.getName().cStr();
    Wallet.Deserialize(reader.getWallet());
    Orders.clear();
    for (auto o : reader.getOrders())
    {
        Order order;
        order.Deserialize(o);
        Orders.emplace_back(order);
    }
}

...

};

} // namespace TradeProto

Cap'n'Proto example

Here comes the usage example of Cap'n'Proto serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the Cap'n'Proto buffer
capnp::MallocMessageBuilder output;
Trade::capnproto::Account::Builder builder = output.initRoot<Trade::capnproto::Account>();
account.Serialize(builder);
kj::VectorOutputStream buffer;
writeMessage(buffer, output);

// Show original and Cap'n'Proto serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "Cap'n'Proto size: " << buffer.getArray().size() << std::endl;

// Deserialize the account from the Cap'n'Proto buffer
kj::ArrayInputStream array(buffer.getArray());
capnp::InputStreamMessageReader input(array);
TradeProto::Account deserialized;
deserialized.Deserialize(input.getRoot<Trade::capnproto::Account>());

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
Cap'n'Proto size: 208

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

Cap'n'Proto performance

Cap'n'Proto serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.136 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:05:35 2025
UTC timestamp: Wed Jul 16 17:05:35 2025
===============================================================================
Benchmark: Cap'n'Proto-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: Cap'n'Proto-Serialize
Average time: 247 ns/op
Minimal time: 244 ns/op
Maximal time: 254 ns/op
Total time: 4.762 s
Total operations: 19242126
Total bytes: 4.484 GiB
Operations throughput: 4040127 ops/s
Bytes throughput: 961.717 MiB/s
Custom values:
        MessageSize: 208
        OriginalSize: 128
===============================================================================

Cap'n'Proto deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.116 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:06:37 2025
UTC timestamp: Wed Jul 16 17:06:37 2025
===============================================================================
Benchmark: Cap'n'Proto-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: Cap'n'Proto-Deserialize
Average time: 184 ns/op
Minimal time: 183 ns/op
Maximal time: 184 ns/op
Total time: 4.959 s
Total operations: 26913647
Total bytes: 6.262 GiB
Operations throughput: 5426756 ops/s
Bytes throughput: 1.267 GiB/s
Custom values:
        MessageSize: 208
        OriginalSize: 128
===============================================================================

FastBinaryEncoding serialization

FastBinaryEncoding serialization is based on FastBinaryEncoding library.

FastBinaryEncoding schema

FastBinaryEncoding serialization starts with describing a model schema. For our domain model the schema will be the following:

package trade

enum OrderSide : byte { buy; sell; }

enum OrderType : byte { market; limit; stop; }

struct Order { [key] int32 id; string symbol; OrderSide side; OrderType type; double price = 0.0; double volume = 0.0; }

struct Balance { [key] string currency; double amount = 0.0; }

struct Account { [key] int32 id; string name; Balance wallet; Order[] orders; }

FastBinaryEncoding schema compilation

The next step is a schema compilation using 'fbec' utility which will create a generated code for required programming language.

The following command will create a C++ generated code:

fbec --cpp --input=trade.fbe --output=.

It is possible to use add_custom_command() in CMakeLists.txt to generate code using 'cmake' utility:

add_custom_command(TARGET example POST_BUILD COMMAND fbec --cpp --input=trade.fbe --output=.)

As the result 'fbe.h' and 'trade.h' files will be generated.

FastBinaryEncoding serialization methods

Finally you should extend your domain model with a FastBinaryEncoding serialization methods:

#include "fbe/trade_models.h"

#include

namespace TradeProto {

struct Order { ...

// FastBinaryEncoding serialization

template <class TBuffer>
void Serialize(FBE::FieldModel<TBuffer, trade::Order>& model)
{
    size_t model_begin = model.set_begin();
    model.id.set(Id);
    model.symbol.set(Symbol);
    model.side.set((trade::OrderSide)Side);
    model.type.set((trade::OrderType)Type);
    model.price.set(Price);
    model.volume.set(Volume);
    model.set_end(model_begin);
}

template <class TBuffer>
void Deserialize(const FBE::FieldModel<TBuffer, trade::Order>& model)
{
    size_t model_begin = model.get_begin();
    model.id.get(Id);
    model.symbol.get(Symbol);
    trade::OrderSide side;
    model.side.get(side);
    Side = (OrderSide)side;
    trade::OrderType type;
    model.type.get(type);
    Type = (OrderType)type;
    model.price.get(Price);
    model.volume.get(Volume);
    model.get_end(model_begin);
}

...

};

struct Balance { ...

// FastBinaryEncoding serialization

template <class TBuffer>
void Serialize(FBE::FieldModel<TBuffer, trade::Balance>& model)
{
    size_t model_begin = model.set_begin();
    model.currency.set(Currency);
    model.amount.set(Amount);
    model.set_end(model_begin);
}

template <class TBuffer>
void Deserialize(const FBE::FieldModel<TBuffer, trade::Balance>& model)
{
    size_t model_begin = model.get_begin();
    model.currency.get(Currency);
    model.amount.get(Amount);
    model.get_end(model_begin);
}

...

};

struct Account { ...

// FastBinaryEncoding serialization

template <class TBuffer>
void Serialize(FBE::FieldModel<TBuffer, trade::Account>& model)
{
    size_t model_begin = model.set_begin();
    model.id.set(Id);
    model.name.set(Name);
    Wallet.Serialize(model.wallet);
    auto order_model = model.orders.resize(Orders.size());
    for (auto& order : Orders)
    {
        order.Serialize(order_model);
        order_model.fbe_shift(order_model.fbe_size());
    }
    model.set_end(model_begin);
}

template <class TBuffer>
void Deserialize(const FBE::FieldModel<TBuffer, trade::Account>& model)
{
    size_t model_begin = model.get_begin();
    model.id.get(Id);
    model.name.get(Name);
    Wallet.Deserialize(model.wallet);
    Orders.clear();
    for (size_t i = 0; i < model.orders.size(); ++i)
    {
        Order order;
        order.Deserialize(model.orders[i]);
        Orders.emplace_back(order);
    }
    model.get_end(model_begin);
}

...

};

} // namespace TradeProto

FastBinaryEncoding example

Here comes the usage example of FastBinaryEncoding serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the FBE buffer
FBE::trade::AccountModel<FBE::WriteBuffer> writer;
size_t model_begin = writer.create_begin();
account.Serialize(writer.model);
size_t serialized = writer.create_end(model_begin);
assert(writer.verify() && "Model is broken!");

// Show original and FBE serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "FBE size: " << serialized << std::endl;

// Deserialize the account from the FBE buffer
TradeProto::Account deserialized;
FBE::trade::AccountModel<FBE::ReadBuffer> reader;
reader.attach(writer.buffer());
assert(reader.verify() && "Model is broken!");
deserialized.Deserialize(reader.model);

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
FBE size: 234

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

FastBinaryEncoding performance

FastBinaryEncoding serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.179 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:08:14 2025
UTC timestamp: Wed Jul 16 17:08:14 2025
===============================================================================
Benchmark: FastBinaryEncoding-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: FastBinaryEncoding-Serialize
Average time: 77 ns/op
Minimal time: 77 ns/op
Maximal time: 81 ns/op
Total time: 5.204 s
Total operations: 66877702
Total bytes: 17.501 GiB
Operations throughput: 12849579 ops/s
Bytes throughput: 3.369 GiB/s
Custom values:
        MessageSize: 234
        OriginalSize: 128
===============================================================================

FastBinaryEncoding deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.194 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:10:03 2025
UTC timestamp: Wed Jul 16 17:10:03 2025
===============================================================================
Benchmark: FastBinaryEncoding-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: FastBinaryEncoding-Deserialize
Average time: 84 ns/op
Minimal time: 82 ns/op
Maximal time: 85 ns/op
Total time: 5.271 s
Total operations: 62074518
Total bytes: 16.239 GiB
Operations throughput: 11775531 ops/s
Bytes throughput: 3.081 GiB/s
Custom values:
        MessageSize: 234
        OriginalSize: 128
===============================================================================

FlatBuffers serialization

FlatBuffers serialization is based on FlatBuffers library.

FlatBuffers schema

FlatBuffers serialization starts with describing a model schema. For our domain model the schema will be the following:

namespace Trade.flatbuf;

enum OrderSide : byte { buy, sell }

enum OrderType : byte { market, limit, stop }

table Order { id : int; symbol : string; side : OrderSide; type : OrderType; price : double = 0.0; volume : double = 0.0; }

table Balance { currency : string; amount : double = 0.0; }

table Account { id : int; name : string; wallet : Balance; orders : [Order]; }

root_type Account;

FlatBuffers schema compilation

The next step is a schema compilation using 'flatc' utility which will create a generated code for required programming language.

The following command will create a C++ generated code:

flatc --cpp --scoped-enums -o . trade.fbs

It is possible to use add_custom_command() in CMakeLists.txt to generate code using 'cmake' utility:

add_custom_command(TARGET example POST_BUILD COMMAND flatc --cpp --scoped-enums -o . trade.fbs)

As the result 'domain_generated.h' file will be generated.

FlatBuffers serialization methods

Finally you should extend your domain model with a FlatBuffers serialization methods:

#include "flatbuffers/trade_generated.h"

#include

namespace TradeProto {

struct Order { ...

// FlatBuffers serialization

flatbuffers::Offset<Trade::flatbuf::Order> Serialize(flatbuffers::FlatBufferBuilder& builder)
{
    return Trade::flatbuf::CreateOrderDirect(builder, Id, Symbol, (Trade::flatbuf::OrderSide)Side, (Trade::flatbuf::OrderType)Type, Price, Volume);
}

void Deserialize(const Trade::flatbuf::Order& value)
{
    Id = value.id();
    std::string symbol = value.symbol()->str();
    std::memcpy(Symbol, symbol.c_str(), std::min(symbol.size() + 1, sizeof(Symbol)));
    Side = (OrderSide)value.side();
    Type = (OrderType)value.type();
    Price = value.price();
    Volume = value.volume();
}

...

};

struct Balance { ...

// FlatBuffers serialization

flatbuffers::Offset<Trade::flatbuf::Balance> Serialize(flatbuffers::FlatBufferBuilder& builder)
{
    return Trade::flatbuf::CreateBalanceDirect(builder, Currency, Amount);
}

void Deserialize(const Trade::flatbuf::Balance& value)
{
    std::string currency = value.currency()->str();
    std::memcpy(Currency, currency.c_str(), std::min(currency.size() + 1, sizeof(Currency)));
    Amount = value.amount();
}

...

};

struct Account { ...

// FlatBuffers serialization

flatbuffers::Offset<Trade::flatbuf::Account> Serialize(flatbuffers::FlatBufferBuilder& builder)
{
    auto wallet = Wallet.Serialize(builder);
    std::vector<flatbuffers::Offset<Trade::flatbuf::Order>> orders;
    for (auto& order : Orders)
        orders.emplace_back(order.Serialize(builder));
    return Trade::flatbuf::CreateAccountDirect(builder, Id, Name.c_str(), wallet, &orders);
}

void Deserialize(const Trade::flatbuf::Account& value)
{
    Id = value.id();
    Name = value.name()->str();
    Wallet.Deserialize(*value.wallet());
    Orders.clear();
    for (auto o : *value.orders())
    {
        Order order;
        order.Deserialize(*o);
        Orders.emplace_back(order);
    }
}

...

};

} // namespace TradeProto

FlatBuffers example

Here comes the usage example of FlatBuffers serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the FlatBuffer buffer
flatbuffers::FlatBufferBuilder builder;
builder.Finish(account.Serialize(builder));

// Show original and FlatBuffer serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "FlatBuffer size: " << builder.GetSize() << std::endl;

// Deserialize the account from the FlatBuffer buffer
TradeProto::Account deserialized;
deserialized.Deserialize(*Trade::flatbuf::GetAccount(builder.GetBufferPointer()));

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
FlatBuffer size: 280

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

FlatBuffers performance

FlatBuffers serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.270 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:11:16 2025
UTC timestamp: Wed Jul 16 17:11:16 2025
===============================================================================
Benchmark: FlatBuffers-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: FlatBuffers-Serialize
Average time: 272 ns/op
Minimal time: 272 ns/op
Maximal time: 273 ns/op
Total time: 4.947 s
Total operations: 18131562
Total bytes: 5.689 GiB
Operations throughput: 3664742 ops/s
Bytes throughput: 1.150 GiB/s
Custom values:
        MessageSize: 280
        OriginalSize: 128
===============================================================================

FlatBuffers deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.323 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:13:23 2025
UTC timestamp: Wed Jul 16 17:13:23 2025
===============================================================================
Benchmark: FlatBuffers-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: FlatBuffers-Deserialize
Average time: 81 ns/op
Minimal time: 77 ns/op
Maximal time: 81 ns/op
Total time: 5.320 s
Total operations: 65603873
Total bytes: 20.541 GiB
Operations throughput: 12329743 ops/s
Bytes throughput: 3.878 GiB/s
Custom values:
        MessageSize: 280
        OriginalSize: 128
===============================================================================

Protobuf serialization

Protobuf serialization is based on Protobuf library.

Protobuf schema

Protobuf serialization starts with describing a model schema. For our domain model the schema will be the following:

syntax = "proto3"; package Trade.protobuf;

enum OrderSide { buy = 0; sell = 1; }

enum OrderType { market = 0; limit = 1; stop = 2; }

message Order { int32 id = 1; string symbol = 2; OrderSide side = 3; OrderType type = 4; double price = 5; double volume = 6; }

message Balance { string currency = 1; double amount = 2; }

message Account { int32 id = 1; string name = 2; Balance wallet = 3; repeated Order orders = 4; }

Protobuf schema compilation

The next step is a schema compilation using 'protoc' utility which will create a generated code for required programming language.

The following command will create a C++ generated code:

protoc --proto_path=. --cpp_out=. trade.proto

It is possible to use add_custom_command() in CMakeLists.txt to generate code using 'cmake' utility:

add_custom_command(TARGET example POST_BUILD COMMAND protoc --proto_path=. --cpp_out=. trade.proto)

As the result 'trade.pb.h' and 'trade.pb.cc' files will be generated.

Protobuf serialization methods

Finally you should extend your domain model with a FlatBuffers serialization methods:

#include "protobuf/trade.pb.h"

#include

namespace TradeProto {

struct Order { ...

// Protobuf serialization

Trade::protobuf::Order& Serialize(Trade::protobuf::Order& value)
{
    value.set_id(Id);
    value.set_symbol(Symbol);
    value.set_side((Trade::protobuf::OrderSide)Side);
    value.set_type((Trade::protobuf::OrderType)Type);
    value.set_price(Price);
    value.set_volume(Volume);
    return value;
}

void Deserialize(const Trade::protobuf::Order& value)
{
    Id = value.id();
    std::string symbol = value.symbol();
    std::memcpy(Symbol, symbol.c_str(), std::min(symbol.size() + 1, sizeof(Symbol)));
    Side = (OrderSide)value.side();
    Type = (OrderType)value.type();
    Price = value.price();
    Volume = value.volume();
}

...

};

struct Balance { ...

// Protobuf serialization

Trade::protobuf::Balance& Serialize(Trade::protobuf::Balance& value)
{
    value.set_currency(Currency);
    value.set_amount(Amount);
    return value;
}

void Deserialize(const Trade::protobuf::Balance& value)
{
    std::string currency = value.currency();
    std::memcpy(Currency, currency.c_str(), std::min(currency.size() + 1, sizeof(Currency)));
    Amount = value.amount();
}

...

};

struct Account { ...

// Protobuf serialization

Trade::protobuf::Account& Serialize(Trade::protobuf::Account& value)
{
    value.set_id(id);
    value.set_name(Name);
    value.set_allocated_wallet(&Wallet.Serialize(*value.wallet().New(value.GetArena())));
    for (auto& order : Orders)
        order.Serialize(*value.add_orders());
    return value;
}

void Deserialize(const Trade::protobuf::Account& value)
{
    Id = value.id();
    Name = value.name();
    Wallet.Deserialize(value.wallet());
    Orders.clear();
    for (int i = 0; i < value.orders_size(); ++i)
    {
        Order order;
        order.Deserialize(value.orders(i));
        Orders.emplace_back(order);
    }
}

...

};

} // namespace TradeProto

Protobuf example

Here comes the usage example of Protobuf serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the Protobuf buffer
Trade::protobuf::Account output;
account.Serialize(output);
auto buffer = output.SerializeAsString();

// Show original and Protobuf serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "Protobuf size: " << buffer.size() << std::endl;

// Deserialize the account from the Protobuf buffer
Trade::protobuf::Account input;
input.ParseFromString(buffer);
TradeProto::Account deserialized;
deserialized.Deserialize(input);

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

// Delete all global objects allocated by Protobuf
google::protobuf::ShutdownProtobufLibrary();

return 0;

}

Output of the example is the following:

Original size: 128
Protobuf size: 120

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

Protobuf performance

Protobuf serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.339 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:15:26 2025
UTC timestamp: Wed Jul 16 17:15:26 2025
===============================================================================
Benchmark: Protobuf-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: Protobuf-Serialize
Average time: 322 ns/op
Minimal time: 322 ns/op
Maximal time: 323 ns/op
Total time: 4.989 s
Total operations: 15458464
Total bytes: 2.074 GiB
Operations throughput: 3098338 ops/s
Bytes throughput: 425.503 MiB/s
Custom values:
        MessageSize: 120
        OriginalSize: 128
===============================================================================

Protobuf deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.248 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:16:37 2025
UTC timestamp: Wed Jul 16 17:16:37 2025
===============================================================================
Benchmark: Protobuf-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: Protobuf-Deserialize
Average time: 351 ns/op
Minimal time: 351 ns/op
Maximal time: 352 ns/op
Total time: 4.959 s
Total operations: 14111610
Total bytes: 1.913 GiB
Operations throughput: 2845506 ops/s
Bytes throughput: 390.789 MiB/s
Custom values:
        MessageSize: 120
        OriginalSize: 128
===============================================================================

SimpleBinaryEncoding serialization

SimpleBinaryEncoding serialization is based on SimpleBinaryEncoding library.

SimpleBinaryEncoding schema

SimpleBinaryEncoding serialization starts with describing a model schema. For our domain model the schema will be the following:

<sbe:messageSchema xmlns:sbe="http://fixprotocol.io/2016/sbe" package="sbe" id="1" version="1" semanticVersion="5.2" description="Trade schema" byteOrder="littleEndian"> 0 1 0 1 2 <sbe:message name="Account" id="1">

SimpleBinaryEncoding schema compilation

The next step is a schema compilation using 'sbe' utility which will create a generated code for required programming language.

The following command will create a C++ generated code:

java -Dsbe.target.language=cpp -jar sbe-all-1.29.0.jar trade.sbe.xml

As the result required C++ header files will be generated.

SimpleBinaryEncoding serialization methods

Finally you should extend your domain model with a SimpleBinaryEncoding serialization methods:

#include "fbe/trade_models.h"

#include

namespace TradeProto {

struct Order { ...

// SimpleBinaryEncoding serialization

void Serialize(sbe::Order& model)
{
    model.id(Id);
    model.putSymbol(Symbol);
    model.side((sbe::OrderSide::Value)Side);
    model.type((sbe::OrderType::Value)Type);
    model.price(Price);
    model.volume(Volume);
}

void Deserialize(sbe::Order& model)
{
    Id = model.id();
    model.getSymbol(Symbol, sizeof(Symbol));
    Side = (OrderSide)model.side();
    Type = (OrderType)model.type();
    Price = model.price();
    Volume = model.volume();
}

...

};

struct Balance { ...

// SimpleBinaryEncoding serialization

void Serialize(sbe::Balance& model)
{
    model.putCurrency(Currency);
    model.amount(Amount);
}

void Deserialize(sbe::Balance& model)
{
    model.getCurrency(Currency, sizeof(Currency));
    Amount = model.amount();
}

...

};

struct Account { ...

// SimpleBinaryEncoding serialization

void Serialize(sbe::Account& model)
{
    model.id(Id);
    model.putName(Name);
    Wallet.Serialize(model.wallet());
    auto orders = model.ordersCount((uint16_t)Orders.size());
    for (auto& order : Orders)
        order.Serialize(orders.next().order());
}

void Deserialize(sbe::Account& model)
{
    Id = model.id();
    Name = model.getNameAsString();
    Wallet.Deserialize(model.wallet());
    Orders.clear();
    auto orders = model.orders();
    for (int i = 0; i < orders.count(); ++i)
    {
        Order order;
        order.Deserialize(orders.next().order());
        Orders.emplace_back(order);
    }
}

...

};

} // namespace TradeProto

SimpleBinaryEncoding example

Here comes the usage example of SimpleBinaryEncoding serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the SBE buffer
char buffer[1024];
sbe::MessageHeader header;
header.wrap(buffer, 0, 1, sizeof(buffer))
   .blockLength(sbe::Account::sbeBlockLength())
   .templateId(sbe::Account::sbeTemplateId())
   .schemaId(sbe::Account::sbeSchemaId())
   .version(sbe::Account::sbeSchemaVersion());
sbe::Account message;
message.wrapForEncode(buffer, header.encodedLength(), sizeof(buffer));
account.Serialize(message);

// Show original and SBE serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "SBE size: " << header.encodedLength() + message.encodedLength() << std::endl;

// Deserialize the account from the SBE buffer
header.wrap(buffer, 0, 1, sizeof(buffer));
int actingVersion = header.version();
int actingBlockLength = header.blockLength();
message.wrapForDecode(buffer, header.encodedLength(), actingBlockLength, actingVersion, sizeof(buffer));
TradeProto::Account deserialized;
deserialized.Deserialize(message);

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
SBE size: 138

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

SimpleBinaryEncoding performance

SimpleBinaryEncoding serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.311 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:17:49 2025
UTC timestamp: Wed Jul 16 17:17:49 2025
===============================================================================
Benchmark: SimpleBinaryEncoding-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: SimpleBinaryEncoding-Serialize
Average time: 35 ns/op
Minimal time: 35 ns/op
Maximal time: 35 ns/op
Total time: 5.926 s
Total operations: 168709597
Total bytes: 26.020 GiB
Operations throughput: 28467195 ops/s
Bytes throughput: 4.399 GiB/s
Custom values:
        MessageSize: 138
        OriginalSize: 128
===============================================================================

SimpleBinaryEncoding deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.261 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:19:22 2025
UTC timestamp: Wed Jul 16 17:19:22 2025
===============================================================================
Benchmark: SimpleBinaryEncoding-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: SimpleBinaryEncoding-Deserialize
Average time: 52 ns/op
Minimal time: 52 ns/op
Maximal time: 52 ns/op
Total time: 5.432 s
Total operations: 104359134
Total bytes: 16.097 GiB
Operations throughput: 19211002 ops/s
Bytes throughput: 2.985 GiB/s
Custom values:
        MessageSize: 138
        OriginalSize: 128
===============================================================================

zpp::bits serialization

zpp::bits serialization is based on zpp::bits library.

zpp::bits serialization methods

Finally you should extend your domain model with a zpp::bits serialization methods:

#include "fbe/trade_models.h"

#include

namespace TradeProto {

struct Order { ...

// zpp::bits serialization

using serialize = zpp::bits::members<6>;

...

};

struct Balance { ...

// zpp::bits serialization

using serialize = zpp::bits::members<2>;

...

};

struct Account { ...

// zpp::bits serialization

using serialize = zpp::bits::members<4>;

...

};

} // namespace TradeProto

zpp::bits example

Here comes the usage example of zpp::bits serialize/deserialize functionality:

#include "../proto/trade.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the zpp::bits buffer
auto [buffer, out] = zpp::bits::data_out();
(void) out(account);

// Show original and zpp::bits serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "zpp::bits size: " << buffer.size() << std::endl;

// Deserialize the account from the zpp::bits buffer
TradeProto::Account deserialized;
(void) zpp::bits::in{buffer}(deserialized);

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (const auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
zpp::bits size: 130

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

zpp::bits performance

zpp::bits serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.142 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:38:54 2025
UTC timestamp: Wed Jul 16 17:38:54 2025
===============================================================================
Benchmark: zpp::bits-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: zpp::bits-Serialize
Average time: 34 ns/op
Minimal time: 33 ns/op
Maximal time: 35 ns/op
Total time: 5.790 s
Total operations: 168487238
Total bytes: 24.490 GiB
Operations throughput: 29095978 ops/s
Bytes throughput: 4.232 GiB/s
Custom values:
        MessageSize: 130
        OriginalSize: 128
===============================================================================

zpp::bits deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.159 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:39:52 2025
UTC timestamp: Wed Jul 16 17:39:52 2025
===============================================================================
Benchmark: zpp::bits-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: zpp::bits-Deserialize
Average time: 37 ns/op
Minimal time: 36 ns/op
Maximal time: 37 ns/op
Total time: 5.652 s
Total operations: 152512801
Total bytes: 22.161 GiB
Operations throughput: 26982853 ops/s
Bytes throughput: 3.942 GiB/s
Custom values:
        MessageSize: 130
        OriginalSize: 128
===============================================================================

JSON serialization

JSON serialization is based on RapidJSON library.

JSON serialization methods

Finally you should extend your domain model with a JSON serialization methods:

#include "serialization/json/serializer.h" #include "serialization/json/deserializer.h"

namespace TradeProto {

struct Order { ...

// JSON serialization

template<typename OutputStream>
void Serialize(CppSerialization::JSON::Serializer<OutputStream>& serializer)
{
    serializer.StartObject();
    serializer.Pair("id", Id);
    serializer.Pair("symbol", Symbol);
    serializer.Pair("side", (int)Side);
    serializer.Pair("type", (int)Type);
    serializer.Pair("price", Price);
    serializer.Pair("volume", Volume);
    serializer.EndObject();
}

template<typename JSON>
void Deserialize(const JSON& json)
{
    using namespace CppSerialization::JSON;

    Deserializer::Find(json, "id", Id);
    Deserializer::Find(json, "symbol", Symbol);
    int side = 0; Deserializer::Find(json, "side", side); Side = (OrderSide)side;
    int type = 0; Deserializer::Find(json, "type", type); Type = (OrderType)type;
    Deserializer::Find(json, "price", Price);
    Deserializer::Find(json, "volume", Volume);
}

...

};

struct Balance { ...

// JSON serialization

template<typename OutputStream>
void Serialize(CppSerialization::JSON::Serializer<OutputStream>& serializer)
{
    serializer.StartObject();
    serializer.Pair("currency", Currency);
    serializer.Pair("amount", Amount);
    serializer.EndObject();
}

template<typename JSON>
void Deserialize(const JSON& json)
{
    using namespace CppSerialization::JSON;

    Deserializer::Find(json, "currency", Currency);
    Deserializer::Find(json, "amount", Amount);
}

...

};

struct Account { ...

// JSON serialization

template<typename OutputStream>
void Serialize(CppSerialization::JSON::Serializer<OutputStream>& serializer)
{
    serializer.StartObject();
    serializer.Pair("id", Id);
    serializer.Pair("name", Name);
    serializer.Key("wallet");
    Wallet.Serialize(serializer);
    serializer.Key("orders");
    serializer.StartArray();
    for (auto& order : Orders)
        order.Serialize(serializer);
    serializer.EndArray();
    serializer.EndObject();
}

template<typename JSON>
void Deserialize(const JSON& json)
{
    using namespace CppSerialization::JSON;

    Deserializer::Find(json, "id", Id);
    Deserializer::Find(json, "name", Name);
    Deserializer::FindObject(json, "wallet", [this](const Value::ConstObject& object)
    {
        Wallet.Deserialize(object);
    });
    Orders.clear();
    Deserializer::FindArray(json, "orders", [this](const Value& item)
    {
        Order order;
        order.Deserialize(item);
        Orders.emplace_back(order);
    });
}

...

};

} // namespace TradeProto

JSON example

Here comes the usage example of JSON serialize/deserialize functionality:

#include "../proto/trade.h"

#include "serialization/json/parser.h"

#include

int main(int argc, char** argv) { // Create a new account with some orders TradeProto::Account account(1, "Test", "USD", 1000); account.Orders.emplace_back(TradeProto::Order(1, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::MARKET, 1.23456, 1000)); account.Orders.emplace_back(TradeProto::Order(2, "EURUSD", TradeProto::OrderSide::SELL, TradeProto::OrderType::LIMIT, 1.0, 100)); account.Orders.emplace_back(TradeProto::Order(3, "EURUSD", TradeProto::OrderSide::BUY, TradeProto::OrderType::STOP, 1.5, 10));

// Serialize the account to the JSON buffer
CppSerialization::JSON::StringBuffer buffer;
CppSerialization::JSON::Serializer<CppSerialization::JSON::StringBuffer> serializer(buffer);
account.Serialize(serializer);

// Show original and JSON serialized sizes
std::cout << "Original size: " << account.size() << std::endl;
std::cout << "JSON content: " << buffer.GetString() << std::endl;
std::cout << "JSON size: " << buffer.GetSize() << std::endl;

// Parse JSON string
CppSerialization::JSON::Document json = CppSerialization::JSON::Parser::Parse(buffer.GetString());

// Deserialize the account from the JSON buffer
TradeProto::Account deserialized;
deserialized.Deserialize(json);

// Show account content
std::cout << std::endl;
std::cout << "Account.Id = " << deserialized.Id << std::endl;
std::cout << "Account.Name = " << deserialized.Name << std::endl;
std::cout << "Account.Wallet.Currency = " << deserialized.Wallet.Currency << std::endl;
std::cout << "Account.Wallet.Amount = " << deserialized.Wallet.Amount << std::endl;
for (auto& order : deserialized.Orders)
{
    std::cout << "Account.Order => Id: " << order.Id
        << ", Symbol: " << order.Symbol
        << ", Side: " << (int)order.Side
        << ", Type: " << (int)order.Type
        << ", Price: " << order.Price
        << ", Volume: " << order.Volume
        << std::endl;
}

return 0;

}

Output of the example is the following:

Original size: 128
JSON content: {"id":1,"name":"Test","wallet":{"currency":"USD","amount":1000.0},"orders":[{"id":1,"symbol":"EURUSD","side":0,"type":0,"price":1.23456,"volume":1000.0},{"id":2,"symbol":"EURUSD","side":1,"type":1,"price":1.0,"volume":100.0},{"id":3,"symbol":"EURUSD","side":0,"type":2,"price":1.5,"volume":10.0}]}
JSON size: 297

Account.Id = 1
Account.Name = Test
Account.Wallet.Currency = USD
Account.Wallet.Amount = 1000
Account.Order => Id: 1, Symbol: EURUSD, Side: 0, Type: 0, Price: 1.23456, Volume: 1000
Account.Order => Id: 2, Symbol: EURUSD, Side: 1, Type: 1, Price: 1, Volume: 100
Account.Order => Id: 3, Symbol: EURUSD, Side: 0, Type: 2, Price: 1.5, Volume: 10

JSON performance

JSON serialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.041 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:29:18 2025
UTC timestamp: Wed Jul 16 17:29:18 2025
===============================================================================
Benchmark: JSON-Serialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: JSON-Serialize
Average time: 696 ns/op
Minimal time: 695 ns/op
Maximal time: 710 ns/op
Total time: 4.932 s
Total operations: 7078563
Total bytes: 2.357 GiB
Operations throughput: 1435099 ops/s
Bytes throughput: 487.794 MiB/s
Custom values:
        MessageSize: 297
        OriginalSize: 128
===============================================================================

JSON document parsing performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.154 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:30:48 2025
UTC timestamp: Wed Jul 16 17:30:48 2025
===============================================================================
Benchmark: JSON-Parse
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: JSON-Parse
Average time: 771 ns/op
Minimal time: 771 ns/op
Maximal time: 779 ns/op
Total time: 4.914 s
Total operations: 6372779
Total bytes: 2.118 GiB
Operations throughput: 1296734 ops/s
Bytes throughput: 440.764 MiB/s
Custom values:
        MessageSize: 297
===============================================================================

JSON deserialization performance of the provided domain model is the following:

===============================================================================
CppBenchmark report. Version 1.0.5.0
===============================================================================
CPU architecture: Apple M1 Pro
CPU logical cores: 10
CPU physical cores: 10
CPU clock speed: 2.400 GHz
CPU Hyper-Threading: disabled
RAM total: 32.000 GiB
RAM free: 1.240 GiB
===============================================================================
OS version: 24.5.0
OS bits: 64-bit
Process bits: 64-bit
Process configuration: release
Local timestamp: Wed Jul 16 19:31:50 2025
UTC timestamp: Wed Jul 16 17:31:50 2025
===============================================================================
Benchmark: JSON-Deserialize
Attempts: 5
Duration: 5 seconds
-------------------------------------------------------------------------------
Phase: JSON-Deserialize
Average time: 291 ns/op
Minimal time: 291 ns/op
Maximal time: 292 ns/op
Total time: 4.924 s
Total operations: 16884318
Total bytes: 77.297 MiB
Operations throughput: 3428637 ops/s
Bytes throughput: 15.711 MiB/s
Custom values:
        MessageSize: 297
        OriginalSize: 128
===============================================================================