uvgrtp-base/src/formats/media.cc

#ifdef __linux__
#else
#endif

#include <map>
#include <unordered_map>

#include "formats/media.hh"

#define INVALID_SEQ 0xffffffff

uvg_rtp::formats::media::media(uvg_rtp::socket *socket, uvg_rtp::rtp *rtp_ctx, int flags):
    socket_(socket), rtp_ctx_(rtp_ctx), flags_(flags)
{
}

uvg_rtp::formats::media::~media()
{
}

rtp_error_t uvg_rtp::formats::media::push_frame(uint8_t *data, size_t data_len, int flags)
{
    if (!data || !data_len)
        return RTP_INVALID_VALUE;

    return __push_frame(data, data_len, flags);
}

rtp_error_t uvg_rtp::formats::media::push_frame(std::unique_ptr<uint8_t[]> data, size_t data_len, int flags)
{
    if (!data || !data_len)
        return RTP_INVALID_VALUE;

    return __push_frame(data.get(), data_len, flags);
}

rtp_error_t uvg_rtp::formats::media::__push_frame(uint8_t *data, size_t data_len, int flags)
{
    std::vector<std::pair<size_t, uint8_t *>> buffers;
    size_t payload_size = rtp_ctx_->get_payload_size();
    uint8_t header[uvg_rtp::frame::HEADER_SIZE_RTP];

    /* fill RTP header with our session's values
     * and push the header to the buffer vector to use vectored I/O */
    rtp_ctx_->fill_header(header);
    buffers.push_back(std::make_pair(sizeof(header), header));
    buffers.push_back(std::make_pair(data_len,       data));

    if (data_len > payload_size) {
        if (flags_ & RCE_FRAGMENT_GENERIC) {

            rtp_error_t ret   = RTP_OK;
            ssize_t data_left = data_len;
            ssize_t data_pos  = 0;

            /* set marker bit for the first fragment */
            header[1] |= (1 << 7);

            while (data_left > (ssize_t)payload_size) {
                buffers.at(1).first  = payload_size;
                buffers.at(1).second = data + data_pos;

                if ((ret = socket_->sendto(buffers, 0)) != RTP_OK)
                    return ret;

                rtp_ctx_->update_sequence(header);

                data_pos  += payload_size;
                data_left -= payload_size;

                /* clear marker bit for middle fragments */
                header[1] &= 0x7f;
            }

            /* set marker bit for the last frame */
            header[1] |= (1 << 7);

            buffers.at(1).first  = data_left;
            buffers.at(1).second = data + data_pos;

            return socket_->sendto(buffers, 0);

        } else {
            LOG_WARN("Packet is larger (%zu bytes) than payload_size (%zu bytes)", data_len, payload_size);
        }
    }

    return socket_->sendto(buffers, 0);
}

static rtp_error_t packet_handler(ssize_t size, void *packet, int flags, uvg_rtp::frame::rtp_frame **out)
{

    struct frame_info {
        uint32_t s_seq;
        uint32_t e_seq;
        size_t npkts;
        size_t size;
        std::map<uint16_t, uvg_rtp::frame::rtp_frame *> fragments;
    };
    static std::unordered_map<uint32_t, frame_info> frames;

    rtp_error_t ret = RTP_OK;
    auto frame      = *out;
    uint32_t ts     = frame->header.timestamp;
    uint32_t seq    = frame->header.seq;
    size_t recv     = 0;

    /* If fragmentation of generic frame has not been enabled, we can just return the frame
     * in "out" because RTP packet handler has done all the necessasry stuff for small RTP packets */
    if (!(flags & RCE_FRAGMENT_GENERIC))
        return RTP_PKT_READY;

    if (frames.find(ts) != frames.end()) {
        frames[ts].npkts++;
        frames[ts].fragments[seq] = frame;
        frames[ts].size += frame->payload_len;

        if (frame->header.marker)
            frames[ts].e_seq = seq;

        if (frames[ts].e_seq != INVALID_SEQ && frames[ts].s_seq != INVALID_SEQ) {
            if (frames[ts].s_seq > frames[ts].e_seq)
                recv = 0xffff - frames[ts].s_seq + frames[ts].e_seq + 2;
            else
                recv = frames[ts].e_seq - frames[ts].s_seq + 1;

            if (recv == frames[ts].npkts) {
                auto retframe = uvg_rtp::frame::alloc_rtp_frame(frames[ts].size);
                size_t ptr    = 0;

                std::memcpy(&retframe->header, &frame->header, sizeof(frame->header));

                for (auto& frag : frames[ts].fragments) {
                    std::memcpy(
                        retframe->payload + ptr,
                        frag.second->payload,
                        frag.second->payload_len
                    );
                    ptr += frag.second->payload_len;
                    (void)uvg_rtp::frame::dealloc_frame(frag.second);
                }

                frames.erase(ts);
                (void)uvg_rtp::frame::dealloc_frame(*out);
                *out = retframe;
                return RTP_PKT_READY;
            }
        }
    } else {
        if (frame->header.marker) {
            frames[ts].npkts          = 1;
            frames[ts].s_seq          = seq;
            frames[ts].e_seq          = INVALID_SEQ;
            frames[ts].fragments[seq] = frame;
        } else {
            return RTP_PKT_READY;
        }
    }

    return RTP_OK;
}
Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00			`#ifdef __linux__`
			`#else`
			`#endif`

Implement RTP packet handler for generic frames Remove the old generic interface and replace it with the push_frame() implemented in some previous commit and with the new packet handler implemented in this commit. All media formats that do not require extra processing (such as Opus) should use the generic interface. 2020-08-04 10:28:26 +00:00			`#include <map>`
			`#include <unordered_map>`

Move Media object code to formats directory 2020-08-04 08:32:50 +00:00			`#include "formats/media.hh"`
Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00
Implement RTP packet handler for generic frames Remove the old generic interface and replace it with the push_frame() implemented in some previous commit and with the new packet handler implemented in this commit. All media formats that do not require extra processing (such as Opus) should use the generic interface. 2020-08-04 10:28:26 +00:00			`#define INVALID_SEQ 0xffffffff`

Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00			`uvg_rtp::formats::media::media(uvg_rtp::socket socket, uvg_rtp::rtp rtp_ctx, int flags):`
			`socket_(socket), rtp_ctx_(rtp_ctx), flags_(flags)`
			`{`
			`}`

			`uvg_rtp::formats::media::~media()`
			`{`
			`}`

			`rtp_error_t uvg_rtp::formats::media::push_frame(uint8_t *data, size_t data_len, int flags)`
			`{`
			`if (!data \|\| !data_len)`
			`return RTP_INVALID_VALUE;`

			`return __push_frame(data, data_len, flags);`
			`}`

			`rtp_error_t uvg_rtp::formats::media::push_frame(std::unique_ptr<uint8_t[]> data, size_t data_len, int flags)`
			`{`
			`if (!data \|\| !data_len)`
			`return RTP_INVALID_VALUE;`

			`return __push_frame(data.get(), data_len, flags);`
			`}`

			`rtp_error_t uvg_rtp::formats::media::__push_frame(uint8_t *data, size_t data_len, int flags)`
			`{`
Implement push_frame() for generic media formats 2020-08-04 09:06:41 +00:00			`std::vector<std::pair<size_t, uint8_t *>> buffers;`
			`size_t payload_size = rtp_ctx_->get_payload_size();`
			`uint8_t header[uvg_rtp::frame::HEADER_SIZE_RTP];`

			`/* fill RTP header with our session's values`
			`* and push the header to the buffer vector to use vectored I/O */`
			`rtp_ctx_->fill_header(header);`
			`buffers.push_back(std::make_pair(sizeof(header), header));`
			`buffers.push_back(std::make_pair(data_len, data));`

			`if (data_len > payload_size) {`
			`if (flags_ & RCE_FRAGMENT_GENERIC) {`

			`rtp_error_t ret = RTP_OK;`
			`ssize_t data_left = data_len;`
			`ssize_t data_pos = 0;`

			`/* set marker bit for the first fragment */`
			`header[1] \|= (1 << 7);`

			`while (data_left > (ssize_t)payload_size) {`
			`buffers.at(1).first = payload_size;`
			`buffers.at(1).second = data + data_pos;`

			`if ((ret = socket_->sendto(buffers, 0)) != RTP_OK)`
			`return ret;`

			`rtp_ctx_->update_sequence(header);`

			`data_pos += payload_size;`
			`data_left -= payload_size;`

			`/* clear marker bit for middle fragments */`
			`header[1] &= 0x7f;`
			`}`

			`/* set marker bit for the last frame */`
			`header[1] \|= (1 << 7);`

			`buffers.at(1).first = data_left;`
			`buffers.at(1).second = data + data_pos;`

			`return socket_->sendto(buffers, 0);`

			`} else {`
			`LOG_WARN("Packet is larger (%zu bytes) than payload_size (%zu bytes)", data_len, payload_size);`
			`}`
			`}`

			`return socket_->sendto(buffers, 0);`
Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00			`}`

Pass RTP context flags to RTP packet dispatcher and handlers Context flags may contain important information about how a packet should be handled (such as RCE_FRAGMENT_GENERIC or RCE_HEVC_NO_INTRA_DELAY) 2020-08-04 10:08:35 +00:00			`static rtp_error_t packet_handler(ssize_t size, void packet, int flags, uvg_rtp::frame::rtp_frame *out)`
Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00			`{`
Implement RTP packet handler for generic frames Remove the old generic interface and replace it with the push_frame() implemented in some previous commit and with the new packet handler implemented in this commit. All media formats that do not require extra processing (such as Opus) should use the generic interface. 2020-08-04 10:28:26 +00:00
			`struct frame_info {`
			`uint32_t s_seq;`
			`uint32_t e_seq;`
			`size_t npkts;`
			`size_t size;`
			`std::map<uint16_t, uvg_rtp::frame::rtp_frame *> fragments;`
			`};`
			`static std::unordered_map<uint32_t, frame_info> frames;`

			`rtp_error_t ret = RTP_OK;`
			`auto frame = *out;`
			`uint32_t ts = frame->header.timestamp;`
			`uint32_t seq = frame->header.seq;`
			`size_t recv = 0;`

			`/* If fragmentation of generic frame has not been enabled, we can just return the frame`
			`* in "out" because RTP packet handler has done all the necessasry stuff for small RTP packets */`
			`if (!(flags & RCE_FRAGMENT_GENERIC))`
			`return RTP_PKT_READY;`

			`if (frames.find(ts) != frames.end()) {`
			`frames[ts].npkts++;`
			`frames[ts].fragments[seq] = frame;`
			`frames[ts].size += frame->payload_len;`

			`if (frame->header.marker)`
			`frames[ts].e_seq = seq;`

			`if (frames[ts].e_seq != INVALID_SEQ && frames[ts].s_seq != INVALID_SEQ) {`
			`if (frames[ts].s_seq > frames[ts].e_seq)`
			`recv = 0xffff - frames[ts].s_seq + frames[ts].e_seq + 2;`
			`else`
			`recv = frames[ts].e_seq - frames[ts].s_seq + 1;`

			`if (recv == frames[ts].npkts) {`
			`auto retframe = uvg_rtp::frame::alloc_rtp_frame(frames[ts].size);`
			`size_t ptr = 0;`

			`std::memcpy(&retframe->header, &frame->header, sizeof(frame->header));`

			`for (auto& frag : frames[ts].fragments) {`
			`std::memcpy(`
			`retframe->payload + ptr,`
			`frag.second->payload,`
			`frag.second->payload_len`
			`);`
			`ptr += frag.second->payload_len;`
			`(void)uvg_rtp::frame::dealloc_frame(frag.second);`
			`}`

			`frames.erase(ts);`
			`(void)uvg_rtp::frame::dealloc_frame(*out);`
			`*out = retframe;`
			`return RTP_PKT_READY;`
			`}`
			`}`
			`} else {`
			`if (frame->header.marker) {`
			`frames[ts].npkts = 1;`
			`frames[ts].s_seq = seq;`
			`frames[ts].e_seq = INVALID_SEQ;`
			`frames[ts].fragments[seq] = frame;`
			`} else {`
			`return RTP_PKT_READY;`
			`}`
			`}`

Introduce Media object Media is the base class from which all other media formats inherit the common operations. Media object contains two push_frame()s: one for normal pointers and one for smart pointers. It also contains a packet handler which is called by the RTP packet dispatcher when a UDP datagram is received. All media formats must implement packet_handler() and __push_frame() methods. If the media media format does not require any extra processing (such as Opus), it can directly use the Media object and its implementation of __push_frame() and packet_handler(). Media object implements the generic interface which supports sending any kind of data and a uvgRTP-specific way of fragmenting/reconstructing generic RTP frames which can be enabled with RCE_FRAGMENT_GENERIC. 2020-08-03 07:10:29 +00:00			`return RTP_OK;`
			`}`