This application is composed of two parts:
- the server (
scrcpy-server
), to be executed on the device, - the client (the
scrcpy
binary), executed on the host computer.
The client is responsible to push the server to the device and start its execution.
Once the client and the server are connected to each other, the server initially sends device information (name and initial screen dimensions), then starts to send a raw H.264 video stream of the device screen. The client decodes the video frames, and display them as soon as possible, without buffering, to minimize latency. The client is not aware of the device rotation (which is handled by the server), it just knows the dimensions of the video frames.
The client captures relevant keyboard and mouse events, that it transmits to the server, which injects them to the device.
Capturing the screen requires some privileges, which are granted to shell
.
The server is a Java application (with a public static void main(String... args)
method), compiled against the Android framework, and executed as
shell
on the Android device.
To run such a Java application, the classes must be dexed (typically,
to classes.dex
). If my.package.MainClass
is the main class, compiled to
classes.dex
, pushed to the device in /data/local/tmp
, then it can be run
with:
adb shell CLASSPATH=/data/local/tmp/classes.dex \
app_process / my.package.MainClass
The path /data/local/tmp
is a good candidate to push the server, since it's
readable and writable by shell
, but not world-writable, so a malicious
application may not replace the server just before the client executes it.
Instead of a raw dex file, app_process
accepts a jar containing
classes.dex
(e.g. an APK). For simplicity, and to benefit from the gradle
build system, the server is built to an (unsigned) APK (renamed to
scrcpy-server
).
Hidden methods
Although compiled against the Android framework, hidden methods and classes are not directly accessible (and they may differ from one Android version to another).
They can be called using reflection though. The communication with hidden components is provided by wrappers classes and aidl.
The server uses 3 threads:
- the main thread, encoding and streaming the video to the client;
- the controller thread, listening for control messages (typically, keyboard and mouse events) from the client;
- the receiver thread (managed by the controller), sending device messges to the clients (currently, it is only used to send the device clipboard content).
Since the video encoding is typically hardware, there would be no benefit in encoding and streaming in two different threads.
The encoding is managed by ScreenEncoder
.
The video is encoded using the MediaCodec
API. The codec takes its input
from a surface associated to the display, and writes the resulting H.264
stream to the provided output stream (the socket connected to the client).
On device rotation, the codec, surface and display are reinitialized, and a new video stream is produced.
New frames are produced only when changes occur on the surface. This is good because it avoids to send unnecessary frames, but there are drawbacks:
- it does not send any frame on start if the device screen does not change,
- after fast motion changes, the last frame may have poor quality.
Both problems are solved by the flag
KEY_REPEAT_PREVIOUS_FRAME_AFTER
.
Control messages are received from the client by the Controller
(run in a
separate thread). There are several types of input events:
- keycode (cf
KeyEvent
), - text (special characters may not be handled by keycodes directly),
- mouse motion/click,
- mouse scroll,
- other commands (e.g. to switch the screen on or to copy the clipboard).
Some of them need to inject input events to the system. To do so, they use the
hidden method InputManager.injectInputEvent
(exposed by our
InputManager
wrapper).
The client relies on SDL, which provides cross-platform API for UI, input events, threading, etc.
The video stream is decoded by libav (FFmpeg).
On startup, in addition to libav and SDL initialization, the client must push and start the server on the device, and open two sockets (one for the video stream, one for control) so that they may communicate.
Note that the client-server roles are expressed at the application level:
- the server serves video stream and handle requests from the client,
- the client controls the device through the server.
However, the roles are reversed at the network level:
- the client opens a server socket and listen on a port before starting the server,
- the server connects to the client.
This role inversion guarantees that the connection will not fail due to race conditions, and avoids polling.
(Note that over TCP/IP, the roles are not reversed, due to a bug in adb reverse
. See commit 1038bad and issue #5.)
Once the server is connected, it sends the device information (name and initial screen dimensions). Thus, the client may init the window and renderer, before the first frame is available.
To minimize startup time, SDL initialization is performed while listening for the connection from the server (see commit 90a46b4).
The client uses 4 threads:
- the main thread, executing the SDL event loop,
- the stream thread, receiving the video and used for decoding and recording,
- the controller thread, sending control messages to the server,
- the receiver thread (managed by the controller), receiving device messages from the server.
In addition, another thread can be started if necessary to handle APK installation or file push requests (via drag&drop on the main window) or to print the framerate regularly in the console.
The video stream is received from the socket (connected to the server on the device) in a separate thread.
If a decoder is present (i.e. --no-display
is not set), then it uses libav
to decode the H.264 stream from the socket, and notifies the main thread when a
new frame is available.
There are two frames simultaneously in memory:
- the decoding frame, written by the decoder from the decoder thread,
- the rendering frame, rendered in a texture from the main thread.
When a new decoded frame is available, the decoder swaps the decoding and rendering frame (with proper synchronization). Thus, it immediately starts to decode a new frame while the main thread renders the last one.
If a recorder is present (i.e. --record
is enabled), then it muxes the raw
H.264 packet to the output video file.
+----------+ +----------+
---> | decoder | ---> | screen |
+---------+ / +----------+ +----------+
socket ---> | stream | ----
+---------+ \ +----------+
---> | recorder |
+----------+
The controller is responsible to send control messages to the device. It runs in a separate thread, to avoid I/O on the main thread.
On SDL event, received on the main thread, the input manager creates appropriate control messages. It is responsible to convert SDL events to Android events (using convert). It pushes the control messages to a queue hold by the controller. On its own thread, the controller takes messages from the queue, that it serializes and sends to the client.
Initialization, input events and rendering are all managed in the main thread.
Events are handled in the event loop, which either updates the screen or delegates to the input manager.
For more details, go read the code!
If you find a bug, or have an awesome idea to implement, please discuss and contribute ;-)
The server is pushed to the device by the client on startup.
To debug it, enable the server debugger during configuration:
meson x -Dserver_debugger=true
# or, if x is already configured
meson configure x -Dserver_debugger=true
If your device runs Android 8 or below, set the server_debugger_method
to
old
in addition:
meson x -Dserver_debugger=true -Dserver_debugger_method=old
# or, if x is already configured
meson configure x -Dserver_debugger=true -Dserver_debugger_method=old
Then recompile.
When you start scrcpy, it will start a debugger on port 5005 on the device. Redirect that port to the computer:
adb forward tcp:5005 tcp:5005
In Android Studio, Run > Debug > Edit configurations... On the left, click on
+
, Remote, and fill the form:
- Host:
localhost
- Port:
5005
Then click on Debug.