use { derive_more::Display, error_stack::{bail, report, Context, Report, Result, ResultExt}, fatfs::{FileSystem, FormatVolumeOptions, FsOptions, ReadWriteSeek}, std::{ fmt::Display, fs::{self, File}, io::{self, Write}, path::Path, process::{exit, Command}, }, }; fn main() -> Result<(), Error> { let mut args = std::env::args(); args.next(); // let disk_meta = fs::metadata("target/disk.img").unwrap(); // let config_meta = fs::metadata("system.toml").unwrap(); // if disk_meta.modified().unwrap() < config_meta.modified().unwrap() { // // TODO: work on adding in system.toml support // // TODO: rebuild the disk // } match args.next().as_deref() { Some("build" | "b") => { let mut release = false; let mut target = Target::X86_64; for arg in args { if arg == "-r" || arg == "--release" { release = true; } else if arg == "rv64" || arg == "riscv64" || arg == "riscv64-virt" { target = Target::Riscv64Virt; } else if arg == "arm64" || arg == "aarch64" || arg == "aarch64-virt" { target = Target::Aarch64; } else { return Err(report!(Error::InvalidSubCom)); } } assemble()?; build(release, target).change_context(Error::Build) } Some("run" | "r") => { let mut release = false; let mut target = Target::X86_64; for arg in args { if arg == "-r" || arg == "--release" { release = true; } else if arg == "rv64" || arg == "riscv64" || arg == "riscv64-virt" { target = Target::Riscv64Virt; } else if arg == "arm64" || arg == "aarch64" || arg == "aarch64-virt" { target = Target::Aarch64; } else { return Err(report!(Error::InvalidSubCom)); } } assemble()?; build(release, target)?; run(release, target) } Some("help" | "h") => { println!(concat!( "AbleOS RepBuild\n", "Subcommands:\n", " build (b): Build a bootable disk image\n", " help (h): Print this message\n", " run (r): Build and run AbleOS in QEMU\n\n", "Options for build and run:\n", " -r: build in release mode", " [target]: sets target" ),); Ok(()) } _ => Err(report!(Error::InvalidSubCom)), } } fn assemble() -> Result<(), Error> { match std::fs::create_dir("target/test-programs") { Ok(_) => (), Err(e) if e.kind() == std::io::ErrorKind::AlreadyExists => (), Err(e) => return Err(Report::new(e).change_context(Error::Io)), } for entry in std::fs::read_dir("sysdata/test-programs") .map_err(Report::from) .change_context(Error::Io)? { let entry = entry.map_err(Report::from).change_context(Error::Io)?; if !entry .file_type() .map_err(Report::from) .change_context(Error::Io)? .is_file() { continue; } let name = entry.file_name(); let name = name.to_string_lossy(); let name = name.trim_end_matches(".rhai"); let mut out = File::options() .write(true) .create(true) .open(Path::new("target/test-programs").join(format!("{name}.hbf"))) .map_err(Report::from) .change_context(Error::Io)?; out.set_len(0) .map_err(Report::from) .change_context(Error::Io)?; hbasm::assembler(&mut out, |engine| engine.run_file(entry.path())) .map_err(|e| report!(Error::Assembler).attach_printable(e.to_string()))?; } Ok(()) } fn get_fs() -> Result, io::Error> { let filename = "sysdata/system_config.toml"; // Read the contents of the file using a `match` block // to return the `data: Ok(c)` as a `String` // or handle any `errors: Err(_)`. let contents = match fs::read_to_string(filename) { // If successful return the files text as `contents`. // `c` is a local variable. Ok(c) => c, // Handle the `error` case. Err(_) => { // Write `msg` to `stderr`. eprintln!("Could not read file `{}`", filename); // Exit the program with exit code `1`. exit(1); } }; use toml::Value; let mut limine_str = String::new(); let mut data: Value = toml::from_str(&contents).unwrap(); let boot_table = data.get_mut("boot"); let limine_table = boot_table.unwrap().get_mut("limine").unwrap(); let default_entry = limine_table.get("default_entry").unwrap(); let timeout = limine_table.get("timeout").unwrap(); let interface_resolution = limine_table.get("interface_resolution").unwrap(); let verbose = limine_table.get("verbose").unwrap(); let term_wallpaper = limine_table.get("term_wallpaper").unwrap(); let vb_post = match verbose.as_bool().unwrap() { true => "yes", false => "no", }; let term_background = limine_table .get("term_backdrop") .unwrap_or(&Value::Integer(0)); let base = format!( "DEFAULT_ENTRY={} TIMEOUT={} VERBOSE={} INTERFACE_RESOLUTION={} # Terminal related settings TERM_WALLPAPER={} TERM_BACKDROP={} ", default_entry, timeout, vb_post, interface_resolution, term_wallpaper.as_str().unwrap(), term_background ); limine_str.push_str(&base); let boot_entries = limine_table.as_table_mut().unwrap(); let mut real_boot_entries = boot_entries.clone(); for (key, value) in boot_entries.into_iter() { if !value.is_table() { real_boot_entries.remove(key); } } for (name, mut value) in real_boot_entries { let comment = value.get("comment").unwrap(); let protocol = value.get("protocol").unwrap(); let resolution = value.get("resolution").unwrap(); let kernel_path = value.get("kernel_path").unwrap(); let kernel_cmdline = value.get("kernel_cmdline").unwrap(); let text_entry = format!( " :{} COMMENT={} PROTOCOL={} RESOLUTION={} KERNEL_PATH={} KERNEL_CMDLINE={} ", name, comment.as_str().unwrap(), protocol.as_str().unwrap(), resolution.as_str().unwrap(), kernel_path.as_str().unwrap(), kernel_cmdline, ); limine_str.push_str(&text_entry); let modules = value.get_mut("modules").unwrap().as_table_mut().unwrap(); // let mut real_modules = modules.clone(); for (key, value) in modules.into_iter() { if value.is_table() { let path = value.get("path").unwrap(); let cmd_line = value.get("cmd_line").unwrap(); let a = format!( " MODULE_PATH={} MODULE_CMDLINE={}\n\n", path.as_str().unwrap(), cmd_line ); limine_str.push_str(&a); } } } let mut img = File::options() .read(true) .write(true) .create(true) .open(Path::new("target/disk.img"))?; img.set_len(1024 * 1024 * 64)?; fatfs::format_volume(&mut img, FormatVolumeOptions::new())?; let fs = FileSystem::new(img, FsOptions::new())?; let bootdir = fs.root_dir().create_dir("efi")?.create_dir("boot")?; let mut f = fs.root_dir().create_file("limine.cfg")?; let a = f.write(limine_str.as_bytes())?; drop(f); io::copy( &mut File::open("limine/BOOTX64.EFI") .map_err(Report::from) .attach_printable("Copying Limine (x86_64): have you pulled the submodule?")?, &mut bootdir.create_file("bootx64.efi")?, )?; io::copy( &mut File::open("limine/BOOTAA64.EFI") .map_err(Report::from) .attach_printable("Copying Limine (ARM): have you pulled the submodule?")?, &mut bootdir.create_file("bootaa64.efi")?, )?; // TODO: Remove this and replace it with pulling executables from the system_config for fpath in [ "sysdata/background.bmp", "target/test-programs/failure.hbf", "target/test-programs/ecall.hbf", "target/test-programs/main.hbf", "target/test-programs/serial_driver.hbf", "target/test-programs/vfs_test.hbf", "target/test-programs/sds_test.hbf", "target/test-programs/limine_framebuffer_driver.hbf", "target/test-programs/keyboard_driver.hbf", ] { let path = Path::new(fpath); io::copy( &mut File::open(path)?, &mut fs .root_dir() .create_file(&path.file_name().unwrap().to_string_lossy())?, )?; } drop(bootdir); Ok(fs) } fn build(release: bool, target: Target) -> Result<(), Error> { let fs = get_fs().change_context(Error::Io)?; let mut com = Command::new("cargo"); com.current_dir("kernel"); com.args(["b"]); if release { com.arg("-r"); } if target == Target::Riscv64Virt { com.args(["--target", "targets/riscv64-virt-ableos.json"]); } if target == Target::Aarch64 { com.args(["--target", "targets/aarch64-virt-ableos.json"]); } match com.status() { Ok(s) if s.code() != Some(0) => bail!(Error::Build), Err(e) => bail!(report!(e).change_context(Error::Build)), _ => (), } let mut path: String = "kernel".to_string(); let kernel_dir = match target { Target::X86_64 => { path.push_str("_x86-64"); "target/x86_64-ableos" } Target::Riscv64Virt => "target/riscv64-virt-ableos", Target::Aarch64 => { path.push_str("_aarch64"); "target/aarch64-virt-ableos" } }; (|| -> std::io::Result<_> { io::copy( &mut File::open( Path::new(kernel_dir) .join(if release { "release" } else { "debug" }) .join("kernel"), )?, &mut fs.root_dir().create_file(&path)?, ) .map(|_| ()) })() .map_err(Report::from) .change_context(Error::Io) } fn run(release: bool, target: Target) -> Result<(), Error> { let mut com = match target { Target::X86_64 => Command::new("qemu-system-x86_64"), Target::Riscv64Virt => Command::new("qemu-system-riscv64"), Target::Aarch64 => Command::new("qemu-system-aarch64"), }; let ovmf_path = fetch_ovmf(target); match target { Target::X86_64 => { #[rustfmt::skip] com.args([ "-bios", &ovmf_path.change_context(Error::OvmfFetch)?, "-drive", "file=target/disk.img,format=raw", "-m", "4G", "-smp", "cores=4", // "-enable-kvm", "-cpu", "Broadwell-v4" ]); } Target::Riscv64Virt => { #[rustfmt::skip] com.args([ "-M", "virt", "-m", "128M", "-serial", "stdio", "-kernel", if release { "target/riscv64-virt-ableos/release/kernel" } else { "target/riscv64-virt-ableos/debug/kernel" } ]); } Target::Aarch64 => { #[rustfmt::skip] com.args([ "-M", "virt", "-cpu", "cortex-a72", "-device", "ramfb", "-device", "qemu-xhci", "-device", "usb-kbd", "-m", "2G", "-bios", &ovmf_path.change_context(Error::OvmfFetch)?, "-drive", "file=target/disk.img,format=raw", ]); } } match com .status() .map_err(Report::from) .change_context(Error::ProcessSpawn)? { s if s.success() => Ok(()), s => Err(report!(Error::Qemu(s.code()))), } } fn fetch_ovmf(target: Target) -> Result { let (ovmf_url, ovmf_path) = match target { Target::X86_64 => ( "https://retrage.github.io/edk2-nightly/bin/RELEASEX64_OVMF.fd", "target/RELEASEX64_OVMF.fd", ), Target::Riscv64Virt => return Err(OvmfFetchError::Empty.into()), Target::Aarch64 => ( "https://retrage.github.io/edk2-nightly/bin/RELEASEAARCH64_QEMU_EFI.fd", "target/RELEASEAARCH64_QEMU_EFI.fd", ), }; let mut file = match std::fs::metadata(ovmf_path) { Err(e) if e.kind() == std::io::ErrorKind::NotFound => std::fs::OpenOptions::new() .create(true) .write(true) .read(true) .open(ovmf_path) .map_err(Report::from) .change_context(OvmfFetchError::Io)?, Ok(_) => return Ok(ovmf_path.to_owned()), Err(e) => return Err(report!(e).change_context(OvmfFetchError::Io)), }; let mut bytes = reqwest::blocking::get(ovmf_url) .map_err(Report::from) .change_context(OvmfFetchError::Fetch)?; bytes .copy_to(&mut file) .map_err(Report::from) .change_context(OvmfFetchError::Io)?; Ok(ovmf_path.to_owned()) } #[derive(Debug, Display)] enum OvmfFetchError { #[display(fmt = "Failed to fetch OVMF package")] Fetch, #[display(fmt = "No OVMF package available")] Empty, #[display(fmt = "IO Error")] Io, } impl Context for OvmfFetchError {} #[derive(Clone, Copy, PartialEq, Eq)] enum Target { X86_64, Riscv64Virt, Aarch64, } #[derive(Debug, Display)] enum Error { #[display(fmt = "Failed to build the kernel")] Build, #[display(fmt = "Missing or invalid subcommand (available: build, run)")] InvalidSubCom, #[display(fmt = "IO Error")] Io, #[display(fmt = "Failed to spawn a process")] ProcessSpawn, #[display(fmt = "Failed to fetch UEFI firmware")] OvmfFetch, #[display(fmt = "Failed to assemble Holey Bytes code")] Assembler, #[display(fmt = "QEMU Error: {}", "fmt_qemu_err(*_0)")] Qemu(Option), } impl Context for Error {} fn fmt_qemu_err(e: Option) -> impl Display { struct W(Option); impl Display for W { fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { if let Some(c) = self.0 { c.fmt(f) } else { f.write_str("Interrupted by signal") } } } W(e) }