Boost C++ Libraries

...one of the most highly regarded and expertly designed C++ library projects in the world. Herb Sutter and Andrei Alexandrescu, C++ Coding Standards

This is the documentation for a snapshot of the develop branch, built from commit cdb310143f.
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Buffer-Oriented Serializing

An instance of serializer can be invoked directly, without using the provided stream operations. This could be useful for implementing algorithms on objects whose interface does not conform to Stream. For example, a libuv socket. The serializer interface is interactive; the caller invokes it repeatedly to produce buffers until all of the serialized octets have been generated. Then the serializer is destroyed.

To obtain the serialized next buffer sequence, call serializer::next. Then, call serializer::consume to indicate the number of bytes consumed. This updates the next set of buffers to be returned, if any. serializer::next takes an error code parameter and invokes a visitor argument with the error code and buffer of unspecified type. In C++14 this is easily expressed with a generic lambda. The function serializer::is_done will return true when all the buffers have been produced. This C++14 example prints the buffers to standard output:

template<bool isRequest, class Body, class Fields>
void
print_cxx14(message<isRequest, Body, Fields> const& m)
{
    error_code ec;
    serializer<isRequest, Body, Fields> sr{m};
    do
    {
        sr.next(ec,
            [&sr](error_code& ec, auto const& buffer)
            {
                ec = {};
                std::cout << make_printable(buffer);
                sr.consume(buffer_bytes(buffer));
            });
    }
    while(! ec && ! sr.is_done());
    if(! ec)
        std::cout << std::endl;
    else
        std::cerr << ec.message() << std::endl;
}

Generic lambda expressions are only available in C++14 or later. A functor with a templated function call operator is necessary to use C++11 as shown:

template<class Serializer>
struct lambda
{
    Serializer& sr;

    lambda(Serializer& sr_) : sr(sr_) {}

    template<class ConstBufferSequence>
    void operator()(error_code& ec, ConstBufferSequence const& buffer) const
    {
        ec = {};
        std::cout << make_printable(buffer);
        sr.consume(buffer_bytes(buffer));
    }
};

template<bool isRequest, class Body, class Fields>
void
print(message<isRequest, Body, Fields> const& m)
{
    error_code ec;
    serializer<isRequest, Body, Fields> sr{m};
    do
    {
        sr.next(ec, lambda<decltype(sr)>{sr});
    }
    while(! ec && ! sr.is_done());
    if(! ec)
        std::cout << std::endl;
    else
        std::cerr << ec.message() << std::endl;
}
Split Serialization

In some cases, such as the handling of the Expect: 100-continue field, it may be desired to first serialize the header, perform some other action, and then continue with serialization of the body. This is accomplished by calling serializer::split with a boolean indicating that when buffers are produced, the last buffer containing serialized header octets will not contain any octets corresponding to the body. The function serializer::is_header_done informs the caller whether the header been serialized fully. In this C++14 example we print the header first, followed by the body:

template<bool isRequest, class Body, class Fields>
void
split_print_cxx14(message<isRequest, Body, Fields> const& m)
{
    error_code ec;
    serializer<isRequest, Body, Fields> sr{m};
    sr.split(true);
    std::cout << "Header:" << std::endl;
    do
    {
        sr.next(ec,
            [&sr](error_code& ec, auto const& buffer)
            {
                ec = {};
                std::cout << make_printable(buffer);
                sr.consume(buffer_bytes(buffer));
            });
    }
    while(! sr.is_header_done());
    if(! ec && ! sr.is_done())
    {
        std::cout << "Body:" << std::endl;
        do
        {
            sr.next(ec,
                [&sr](error_code& ec, auto const& buffer)
                {
                    ec = {};
                    std::cout << make_printable(buffer);
                    sr.consume(buffer_bytes(buffer));
                });
        }
        while(! ec && ! sr.is_done());
    }
    if(ec)
        std::cerr << ec.message() << std::endl;
}

The standard library provides the type std::ostream for performing high level write operations on character streams. The variable std::cout is based on this output stream. This example uses the buffer oriented interface of serializer to write an HTTP message to a std::ostream:

// The detail namespace means "not public"
namespace detail {

// This helper is needed for C++11.
// When invoked with a buffer sequence, writes the buffers `to the std::ostream`.
template<class Serializer>
class write_ostream_helper
{
    Serializer& sr_;
    std::ostream& os_;

public:
    write_ostream_helper(Serializer& sr, std::ostream& os)
        : sr_(sr)
        , os_(os)
    {
    }

    // This function is called by the serializer
    template<class ConstBufferSequence>
    void
    operator()(error_code& ec, ConstBufferSequence const& buffers) const
    {
        // Error codes must be cleared on success
        ec = {};

        // Keep a running total of how much we wrote
        std::size_t bytes_transferred = 0;

        // Loop over the buffer sequence
        for(auto it = boost::asio::buffer_sequence_begin(buffers);
            it != boost::asio::buffer_sequence_end(buffers); ++it)
        {
            // This is the next buffer in the sequence
            boost::asio::const_buffer const buffer = *it;

            // Write it to the std::ostream
            os_.write(
                reinterpret_cast<char const*>(buffer.data()),
                buffer.size());

            // If the std::ostream fails, convert it to an error code
            if(os_.fail())
            {
                ec = make_error_code(errc::io_error);
                return;
            }

            // Adjust our running total
            bytes_transferred += buffer_size(buffer);
        }

        // Inform the serializer of the amount we consumed
        sr_.consume(bytes_transferred);
    }
};

} // detail

/** Write a message to a `std::ostream`.

    This function writes the serialized representation of the
    HTTP/1 message to the sream.

    @param os The `std::ostream` to write to.

    @param msg The message to serialize.

    @param ec Set to the error, if any occurred.
*/
template<
    bool isRequest,
    class Body,
    class Fields>
void
write_ostream(
    std::ostream& os,
    message<isRequest, Body, Fields>& msg,
    error_code& ec)
{
    // Create the serializer instance
    serializer<isRequest, Body, Fields> sr{msg};

    // This lambda is used as the "visit" function
    detail::write_ostream_helper<decltype(sr)> lambda{sr, os};
    do
    {
        // In C++14 we could use a generic lambda but since we want
        // to require only C++11, the lambda is written out by hand.
        // This function call retrieves the next serialized buffers.
        sr.next(ec, lambda);
        if(ec)
            return;
    }
    while(! sr.is_done());
}
[Tip] Tip

Serializing to a std::ostream could be implemented using an alternate strategy: adapt the std::ostream interface to a SyncWriteStream, enabling use with the library's existing stream algorithms. This is left as an exercise for the reader.


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