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h265_transcode.rs
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h265_transcode.rs
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use std::{io::Write, path::Path, thread};
use ffmpeg_sidecar::{
command::FfmpegCommand,
event::{FfmpegEvent, LogLevel},
};
/// 1. Read an H265 source video from file
/// 2. Decode video
/// 3. Composite with an overlay image rendered by Rust
/// 4. Re-encode back to H265 to file
///
/// ```console
/// cargo run --example h265_transcode
/// ```
fn main() {
// Create an H265 source video as a starting point
let input_path = "output/h265.mp4";
if !Path::new(input_path).exists() {
create_h265_source(input_path);
}
// One instance decodes H265 to raw frames
let mut input = FfmpegCommand::new()
.input(input_path)
.rawvideo()
.spawn()
.unwrap();
// Frames can be transformed by Iterator `.map()`.
// This example is a no-op, with frames passed through unaltered.
let transformed_frames = input.iter().unwrap().filter_frames();
// You could easily add some "middleware" processing here:
// - overlay or composite another RGB image (or even another Ffmpeg Iterator)
// - apply a filter like blur or convolution
// Note: some of these operations are also possible with FFmpeg's (somewhat arcane)
// `filtergraph` API, but doing it in Rust gives you much finer-grained
// control, debuggability, and modularity -- you can pull in any Rust crate
// you need.
// A second instance encodes the updated frames back to H265
let mut output = FfmpegCommand::new()
.args([
"-f", "rawvideo", "-pix_fmt", "rgb24", "-s", "600x800", "-r", "30",
]) // note: should be possible to infer these params from the source input stream
.input("-")
.args(["-c:v", "libx265"])
.args(["-y", "output/h265_overlay.mp4"])
.spawn()
.unwrap();
// Connect the two instances
let mut stdin = output.take_stdin().unwrap();
thread::spawn(move || {
// `for_each` blocks through the end of the iterator,
// so we run it in another thread.
transformed_frames.for_each(|f| {
stdin.write(&f.data).ok();
});
});
// On the main thread, run the output instance to completion
output.iter().unwrap().for_each(|e| match e {
FfmpegEvent::Log(LogLevel::Error, e) => println!("Error: {}", e),
FfmpegEvent::Progress(p) => println!("Progress: {} / 00:00:15", p.time),
_ => {}
});
}
/// Create a H265 source video from scratch
fn create_h265_source(path_str: &str) {
println!("Creating H265 source video: {}", path_str);
FfmpegCommand::new()
.args("-f lavfi -i testsrc=size=600x800:rate=30:duration=15 -c:v libx265".split(' '))
.arg(path_str)
.spawn()
.unwrap()
.iter()
.unwrap()
.for_each(|e| match e {
FfmpegEvent::Log(LogLevel::Error, e) => println!("Error: {}", e),
FfmpegEvent::Progress(p) => println!("Progress: {} / 00:00:15", p.time),
_ => {}
});
println!("Created H265 source video: {}", path_str);
}