87 lines
2.5 KiB
Bash
87 lines
2.5 KiB
Bash
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# Using shell in other languages
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Bash is incredibly concise at allowing programs to interact on a basic level,
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however it severely lacks control flow and sensible data structures, which make
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it a bad choice for logic-heavy scripting
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In these cases we can attempt to recreate the high-level control bash has over
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programs in other languages. All languages are able to call programs exactly
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like bash, though almost all of them are much more verbose
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The examples below use translate line of bash
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```bash
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swaymsg -t get_tree | jq '.nodes[1].nodes[].representation' | tr -d '\"'
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```
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## Python
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A great and portable choice for easy scripting
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```python
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from subprocess import Popen, PIPE
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p1 = Popen(["swaymsg", "-t", "get_tree"], stdout=PIPE);
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p2 = Popen(["jq", ".nodes[1].nodes[].representation"],
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stdin=PIPE,
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stdout=PIPE);
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p3 = Popen(["tr", "-d", '"'), stdin=PIPE, stdout=PIPE)
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p1_stdout, _ = p1.communicate(timeout=1)
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p2_stdout, _ = p2.communicate(p1_stdout, timeout=1)
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p3_stdout, _ = p3.communicate(p2_stdout, timeout=1)
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print(str(p3_stdout))
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```
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Shell-like strings can easily be split into the args lists required by Popen
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```python
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from shlex import split as shsplit
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# ...
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p3 = Popen(shsplit("tr -d '\"'"), stdin=PIPE, stdout=PIPE)
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# ...
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```
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Do not use pipes even in the shsplit strings. Pipes must be manually managed,
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unless the `shell=True` parameter is passed to Popen. However, that essentially
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completely gives up control over the subprocess, so it's highly not recommend
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## Rust
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Rust is very fast, though not very portable. Portable binaries can be made by
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compiling with a musl libc target. That way everything will be statically linked
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into the binary, which typically makes it work across all Linux systems
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```bash
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cargo build --release --target=x86_64-unknown-linux-musl
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```
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Rust is extremely verbose, though allows for very fine error handling. The below
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uses unwrap mostly
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```rust
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use std::io::{self, BufRead, BufReader};
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use std::process::{Command, Stdio, ChildStdout};
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fn get_tree() -> io::Result<ChildStdout> {
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let swaymsg = Command::new("swaymsg")
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.arg("-t")
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.arg("get_tree")
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.stdout(Stdio::piped())
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.spawn()?;
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let jq = Command::new("jq")
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.arg(".nodes[1].nodes[].representation")
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.stdin(swaymsg.stdout.unwrap())
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.stdout(Stdio::piped())
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.spawn()
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.expect("`jq` binary is not available");
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let tr = Command::new("tr")
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.arg("-d")
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.arg("\"")
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.stdin(jq.stdout.unwrap())
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.stdout(Stdio::piped())
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.spawn()?;
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Ok(tr.stdout.unwrap())
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}
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```
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