SharpRTSP 1.6.0
See the version list below for details.
dotnet add package SharpRTSP --version 1.6.0
NuGet\Install-Package SharpRTSP -Version 1.6.0
<PackageReference Include="SharpRTSP" Version="1.6.0" />
paket add SharpRTSP --version 1.6.0
#r "nuget: SharpRTSP, 1.6.0"
// Install SharpRTSP as a Cake Addin #addin nuget:?package=SharpRTSP&version=1.6.0 // Install SharpRTSP as a Cake Tool #tool nuget:?package=SharpRTSP&version=1.6.0
Sharp RTSP
A C# library to build RTSP Clients, RTSP Servers and handle RTP data streams. The library has several examples.
- RTSP Client Example - will connect to a RTSP server and receive Video and Audio in H264, H265/HEVC, G711, AAC and AMR formats. UDP, TCP and Multicast are supported. The data received is written to files.
- RTSP Camera Server Example - A YUV Image Generator and a very simple H264 Encoder generate H264 NALs which are then delivered via a RTSP Server to clients
- RTP Receiver - will recieve RTP and RTCP packets and pass them to a transport handler
- RTSP Server - will accept RTSP connections and talk to clients
- RTP Sender - will send RTP packets to clients
- Transport Handler - Transport hanlders for H264, H265/HEVC, G711 and AMR are provided.
:warning: : This library does not handle the decoding of the video or audio (eg converting H264 into a bitmap). SharpRTSP is limited to the transport layer and generates the raw data that you need to feed into a video decoder or audio decoder. Many people use FFMPEG or use Hardware Accelerated Operating System APIs to do the decoding.
Walkthrough of the RTSP Client Example
This is a walkthrough of an old version of the RTSP Client Example which highlights the main way to use the library.
STEP 1 - Open TCP Socket connection to the RTSP Server
// Connect to a RTSP Server tcp_socket = new Rtsp.RtspTcpTransport(host,port); if (tcp_socket.Connected == false) { Console.WriteLine("Error - did not connect"); return; }
This opens a connection for a 'TCP' mode RTSP/RTP session where RTP packets are set in the RTSP socket.
STEP 2 - Create a RTSP Listener and attach it to the RTSP TCP Socket
// Connect a RTSP Listener to the TCP Socket to send messages and listen for replies rtsp_client = new Rtsp.RtspListener(tcp_socket); rtsp_client.MessageReceived += Rtsp_client_MessageReceived; rtsp_client.DataReceived += Rtsp_client_DataReceived; rtsp_client.Start(); // start reading messages from the server
The RTSP Listener class lets you SEND messages to the RTSP Server (see below).
The RTSP Listner class has a worker thread that listens for replies from the RTSP Server.
When replies are received the MessageReceived Event is fired.
When RTP packets are received the DataReceived Event is fired.STEP 3 - Send Messages to the RTSP Server
The samples below show how to send messages.
Send OPTIONS with this code :
Rtsp.Messages.RtspRequest options_message = new Rtsp. Messages.RtspRequestOptions(); options_message.RtspUri = new Uri(url); rtsp_client.SendMessage(options_message);
Send DESCRIBE with this code :
// send the Describe Rtsp.Messages.RtspRequest describe_message = new Rtsp.Messages.RtspRequestDescribe(); describe_message.RtspUri = new Uri(url); rtsp_client.SendMessage(describe_message); // The reply will include the SDP data
Send SETUP with this code :
// the value of 'control' comes from parsing the SDP for the desired video or audio sub-stream Rtsp.Messages.RtspRequest setup_message = new Rtsp.Messages.RtspRequestSetup(); setup_message.RtspUri = new Uri(url + "/" + control); setup_message.AddHeader("Transport: RTP/AVP/TCP;interleaved=0"); rtsp_client.SendMessage(setup_message); // The reply will include the Session
Send PLAY with this code :
// the value of 'session' comes from the reply of the SETUP command Rtsp.Messages.RtspRequest play_message = new Rtsp.Messages.RtspRequestPlay(); play_message.RtspUri = new Uri(url); play_message.Session = session; rtsp_client.SendMessage(play_message);
STEP 4 - Handle Replies when the MessageReceived event is fired
This example assumes the main program sends an OPTIONS Command.
It looks for a reply from the server for OPTIONS and then sends DESCRIBE.
It looks for a reply from the server for DESCRIBE and then sends SETUP (for the video stream)
It looks for a reply from the server for SETUP and then sends PLAY.
Once PLAY has been sent the video, in the form of RTP packets, will be received.private void Rtsp_client_MessageReceived(object sender, Rtsp.RtspChunkEventArgs e) { Rtsp.Messages.RtspResponse message = e.Message as Rtsp.Messages.RtspResponse; Console.WriteLine("Received " + message.OriginalRequest.ToString()); if (message.OriginalRequest != null && message.OriginalRequest is Rtsp.Messages.RtspRequestOptions) { // send the DESCRIBE Rtsp.Messages.RtspRequest describe_message = new Rtsp.Messages.RtspRequestDescribe(); describe_message.RtspUri = new Uri(url); rtsp_client.SendMessage(describe_message); } if (message.OriginalRequest != null && message.OriginalRequest is Rtsp.Messages.RtspRequestDescribe) { // Got a reply for DESCRIBE // Examine the SDP Console.Write(System.Text.Encoding.UTF8.GetString(message.Data)); Rtsp.Sdp.SdpFile sdp_data; using (StreamReader sdp_stream = new StreamReader(new MemoryStream(message.Data))) { sdp_data = Rtsp.Sdp.SdpFile.Read(sdp_stream); } // Process each 'Media' Attribute in the SDP. // If the attribute is for Video, then send a SETUP for (int x = 0; x < sdp_data.Medias.Count; x++) { if (sdp_data.Medias[x].GetMediaType() == Rtsp.Sdp.Media.MediaType.video) { // seach the atributes for control, fmtp and rtpmap String control = ""; // the "track" or "stream id" String fmtp = ""; // holds SPS and PPS String rtpmap = ""; // holds the Payload format, 96 is often used with H264 foreach (Rtsp.Sdp.Attribut attrib in sdp_data.Medias[x].Attributs) { if (attrib.Key.Equals("control")) control = attrib.Value; if (attrib.Key.Equals("fmtp")) fmtp = attrib.Value; if (attrib.Key.Equals("rtpmap")) rtpmap = attrib.Value; } // Get the Payload format number for the Video Stream String[] split_rtpmap = rtpmap.Split(' '); video_payload = 0; bool result = Int32.TryParse(split_rtpmap[0], out video_payload); // Send SETUP for the Video Stream // using Interleaved mode (RTP frames over the RTSP socket) Rtsp.Messages.RtspRequest setup_message = new Rtsp.Messages.RtspRequestSetup(); setup_message.RtspUri = new Uri(url + "/" + control); setup_message.AddHeader("Transport: RTP/AVP/TCP;interleaved=0"); rtsp_client.SendMessage(setup_message); } } } if (message.OriginalRequest != null && message.OriginalRequest is Rtsp.Messages.RtspRequestSetup) { // Got Reply to SETUP Console.WriteLine("Got reply from Setup. Session is " + message.Session); String session = message.Session; // Session value used with Play, Pause, Teardown // Send PLAY Rtsp.Messages.RtspRequest play_message = new Rtsp.Messages.RtspRequestPlay(); play_message.RtspUri = new Uri(url); play_message.Session = session; rtsp_client.SendMessage(play_message); } if (message.OriginalRequest != null && message.OriginalRequest is Rtsp.Messages.RtspRequestPlay) { // Got Reply to PLAY Console.WriteLine("Got reply from Play " + message.Command); } }
STEP 5 - Handle RTP Video
This code handles each incoming RTP packet, combining RTP packets that are all part of the same frame of vdeo (using the Marker Bit). Once a full frame is received it can be passed to a De-packetiser to get the compressed video data
List<byte[]> temporary_rtp_payloads = new List<byte[]>(); private void Rtsp_client_DataReceived(object sender, Rtsp.RtspChunkEventArgs e) { // RTP Packet Header // 0 - Version, P, X, CC, M, PT and Sequence Number //32 - Timestamp //64 - SSRC //96 - CSRCs (optional) //nn - Extension ID and Length //nn - Extension header int rtp_version = (e.Message.Data[0] >> 6); int rtp_padding = (e.Message.Data[0] >> 5) & 0x01; int rtp_extension = (e.Message.Data[0] >> 4) & 0x01; int rtp_csrc_count = (e.Message.Data[0] >> 0) & 0x0F; int rtp_marker = (e.Message.Data[1] >> 7) & 0x01; int rtp_payload_type = (e.Message.Data[1] >> 0) & 0x7F; uint rtp_sequence_number = ((uint)e.Message.Data[2] << 8) + (uint)(e.Message.Data[3]); uint rtp_timestamp = ((uint)e.Message.Data[4] <<24) + (uint)(e.Message.Data[5] << 16) + (uint)(e.Message.Data[6] << 8) + (uint)(e.Message.Data[7]); uint rtp_ssrc = ((uint)e.Message.Data[8] << 24) + (uint)(e.Message.Data[9] << 16) + (uint)(e.Message.Data[10] << 8) + (uint)(e.Message.Data[11]); int rtp_payload_start = 4 // V,P,M,SEQ + 4 // time stamp + 4 // ssrc + (4 * rtp_csrc_count); // zero or more csrcs uint rtp_extension_id = 0; uint rtp_extension_size = 0; if (rtp_extension == 1) { rtp_extension_id = ((uint)e.Message.Data[rtp_payload_start + 0] << 8) + (uint)(e.Message.Data[rtp_payload_start + 1] << 0); rtp_extension_size = ((uint)e.Message.Data[rtp_payload_start + 2] << 8) + (uint)(e.Message.Data[rtp_payload_start + 3] << 0); rtp_payload_start += 4 + (int)rtp_extension_size; // extension header and extension payload } Console.WriteLine("RTP Data" + " V=" + rtp_version + " P=" + rtp_padding + " X=" + rtp_extension + " CC=" + rtp_csrc_count + " M=" + rtp_marker + " PT=" + rtp_payload_type + " Seq=" + rtp_sequence_number + " Time=" + rtp_timestamp + " SSRC=" + rtp_ssrc + " Size=" + e.Message.Data.Length); if (rtp_payload_type != video_payload) { Console.WriteLine("Ignoring this RTP payload"); return; // ignore this data } // If rtp_marker is '1' then this is the final transmission for this packet. // If rtp_marker is '0' we need to accumulate data with the same timestamp // ToDo - Check Timestamp matches // Add to the tempoary_rtp List byte[] rtp_payload = new byte[e.Message.Data.Length - rtp_payload_start]; // payload with RTP header removed System.Array.Copy(e.Message.Data, rtp_payload_start, rtp_payload, 0, rtp_payload.Length); // copy payload temporary_rtp_payloads.Add(rtp_payload); if (rtp_marker == 1) { // Process the RTP frame Process_RTP_Frame(temporary_rtp_payloads); temporary_rtp_payloads.Clear(); } }
STEP 6 - Process RTP frame
An RTP frame consists of 1 or more RTP packets
H264 video is packed into one or more RTP packets and this sample extracts Normal Packing and Fragmented Unit type A packing (the common two)
This example writes the video to a .264 file which can be played with FFPLAYFileStream fs = null; byte[] nal_header = new byte[]{ 0x00, 0x00, 0x00, 0x01 }; int norm, fu_a, fu_b, stap_a, stap_b, mtap16, mtap24 = 0; // stats counters public void Process_RTP_Frame(List<byte[]>rtp_payloads) { Console.WriteLine("RTP Data comprised of " + rtp_payloads.Count + " rtp packets"); if (fs == null) { // Create the file String filename = "rtsp_capture_" + DateTime.Now.ToString("yyyyMMdd_HHmmss") + ".h264"; fs = new FileStream(filename, FileMode.Create); // TODO. Get SPS and PPS from the SDP Attributes (the fmtp attribute) and write to the file // for IP cameras that only out the SPS and PPS out-of-band } for (int payload_index = 0; payload_index < rtp_payloads.Count; payload_index++) { // Examine the first rtp_payload and the first byte (the NAL header) int nal_header_f_bit = (rtp_payloads[payload_index][0] >> 7) & 0x01; int nal_header_nri = (rtp_payloads[payload_index][0] >> 5) & 0x03; int nal_header_type = (rtp_payloads[payload_index][0] >> 0) & 0x1F; // If the NAL Header Type is in the range 1..23 this is a normal NAL (not fragmented) // So write the NAL to the file if (nal_header_type >= 1 && nal_header_type <= 23) { Console.WriteLine("Normal NAL"); norm++; fs.Write(nal_header, 0, nal_header.Length); fs.Write(rtp_payloads[payload_index], 0, rtp_payloads[payload_index].Length); } else if (nal_header_type == 24) { // There are 4 types of Aggregation Packet (multiple NALs in one RTP packet) Console.WriteLine("Agg STAP-A not supported"); stap_a++; } else if (nal_header_type == 25) { // There are 4 types of Aggregation Packet (multiple NALs in one RTP packet) Console.WriteLine("Agg STAP-B not supported"); stap_b++; } else if (nal_header_type == 26) { // There are 4 types of Aggregation Packet (multiple NALs in one RTP packet) Console.WriteLine("Agg MTAP16 not supported"); mtap16++; } else if (nal_header_type == 27) { // There are 4 types of Aggregation Packet (multiple NALs in one RTP packet) Console.WriteLine("Agg MTAP24 not supported"); mtap24++; } else if (nal_header_type == 28) { Console.WriteLine("Fragmented Packet Type FU-A"); fu_a++; // Parse Fragmentation Unit Header int fu_header_s = (rtp_payloads[payload_index][1] >> 7) & 0x01; // start marker int fu_header_e = (rtp_payloads[payload_index][1] >> 6) & 0x01; // end marker int fu_header_r = (rtp_payloads[payload_index][1] >> 5) & 0x01; // reserved. should be 0 int fu_header_type = (rtp_payloads[payload_index][1] >> 0) & 0x1F; // Original NAL unit header Console.WriteLine("Frag FU-A s="+fu_header_s + "e="+fu_header_e); // Start Flag set if (fu_header_s == 1) { // Write 00 00 00 01 header fs.Write(nal_header, 0, nal_header.Length); // 0x00 0x00 0x00 0x01 // Modify the NAL Header that was at the start of the RTP packet // Keep the F and NRI flags but substitute the type field with the fu_header_type byte reconstructed_nal_type = (byte)((nal_header_nri << 5) + fu_header_type); fs.WriteByte(reconstructed_nal_type); // NAL Unit Type fs.Write(rtp_payloads[payload_index], 2, rtp_payloads[payload_index].Length - 2); // start after NAL Unit Type and FU Header byte } if (fu_header_s == 0) { // append this payload to the output NAL stream // Data starts after the NAL Unit Type byte and the FU Header byte fs.Write(rtp_payloads[payload_index], 2, rtp_payloads[payload_index].Length-2); // start after NAL Unit Type and FU Header byte } } else if (nal_header_type == 29) { Console.WriteLine("Fragmented Packet FU-B not supported"); fu_b++; } else { Console.WriteLine("Unknown NAL header " + nal_header_type); } } // ensure video is written to disk fs.Flush(true); // Print totals Console.WriteLine("Norm=" + norm + " ST-A=" + stap_a + " ST-B=" + stap_b + " M16=" + mtap16 + " M24=" + mtap24 + " FU-A=" + fu_a + " FU-B=" + fu_b); }
Product | Versions Compatible and additional computed target framework versions. |
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.NET | net5.0 was computed. net5.0-windows was computed. net6.0 was computed. net6.0-android was computed. net6.0-ios was computed. net6.0-maccatalyst was computed. net6.0-macos was computed. net6.0-tvos was computed. net6.0-windows was computed. net7.0 was computed. net7.0-android was computed. net7.0-ios was computed. net7.0-maccatalyst was computed. net7.0-macos was computed. net7.0-tvos was computed. net7.0-windows was computed. net8.0 is compatible. net8.0-android was computed. net8.0-browser was computed. net8.0-ios was computed. net8.0-maccatalyst was computed. net8.0-macos was computed. net8.0-tvos was computed. net8.0-windows was computed. |
.NET Core | netcoreapp2.0 was computed. netcoreapp2.1 was computed. netcoreapp2.2 was computed. netcoreapp3.0 was computed. netcoreapp3.1 was computed. |
.NET Standard | netstandard2.0 is compatible. netstandard2.1 is compatible. |
.NET Framework | net461 was computed. net462 was computed. net463 was computed. net47 was computed. net471 was computed. net472 was computed. net48 was computed. net481 was computed. |
MonoAndroid | monoandroid was computed. |
MonoMac | monomac was computed. |
MonoTouch | monotouch was computed. |
Tizen | tizen40 was computed. tizen60 was computed. |
Xamarin.iOS | xamarinios was computed. |
Xamarin.Mac | xamarinmac was computed. |
Xamarin.TVOS | xamarintvos was computed. |
Xamarin.WatchOS | xamarinwatchos was computed. |
-
.NETStandard 2.0
- Microsoft.CSharp (>= 4.7.0)
- Microsoft.Extensions.Logging.Abstractions (>= 8.0.1)
- System.Configuration.ConfigurationManager (>= 8.0.0)
- System.IO.Pipelines (>= 8.0.0)
-
.NETStandard 2.1
- Microsoft.CSharp (>= 4.7.0)
- Microsoft.Extensions.Logging.Abstractions (>= 8.0.1)
- System.Configuration.ConfigurationManager (>= 8.0.0)
- System.IO.Pipelines (>= 8.0.0)
-
net8.0
- Microsoft.CSharp (>= 4.7.0)
- Microsoft.Extensions.Logging.Abstractions (>= 8.0.1)
- System.Configuration.ConfigurationManager (>= 8.0.0)
- System.IO.Pipelines (>= 8.0.0)
NuGet packages (3)
Showing the top 3 NuGet packages that depend on SharpRTSP:
Package | Downloads |
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SharpRTSPClient
Simple RTSP client. Supports H264, H265 and AAC. |
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SharpRTSPServer
Simple RTSP server. Supports H264, H265 and AAC. |
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MsM.SharpRTSPtoWebRTC
A C# implementation of the RTSP to WebRTC gateway that allows you to stream RTSP from various sources to the web browser. It is implemented in netstandard2.0 without any native dependencies. Suppports H264 and H265 re-streaming (H265 in WebRTC is only available in Safari). Audio transcoding from AAC to Opus is also supported. |
GitHub repositories (1)
Showing the top 1 popular GitHub repositories that depend on SharpRTSP:
Repository | Stars |
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ngraziano/SharpRTSP
A RTSP handling library
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Version | Downloads | Last updated |
---|---|---|
1.8.0 | 335 | 11/15/2024 |
1.7.0 | 1,508 | 9/11/2024 |
1.6.0 | 178 | 9/7/2024 |
1.5.1 | 539 | 9/2/2024 |
1.5.0 | 328 | 8/15/2024 |
1.4.3 | 2,842 | 5/14/2024 |
1.4.2 | 809 | 4/17/2024 |
1.4.1 | 249 | 4/11/2024 |
1.4.0 | 118 | 4/11/2024 |
1.3.2 | 322 | 3/21/2024 |
1.3.1 | 138 | 3/20/2024 |
1.3.0 | 179 | 3/11/2024 |
1.2.3 | 324 | 2/8/2024 |
1.2.2 | 125 | 2/7/2024 |
1.2.1 | 170 | 2/5/2024 |
1.2.0 | 125 | 2/4/2024 |
1.1.0 | 941 | 12/15/2023 |
1.0.0 | 8,987 | 3/20/2022 |