use std::collections::VecDeque; use crate::{builtin::{alias::alias, cd::cd, echo::echo, export::export, flowctl::flowctl, jobctl::{continue_job, jobs, JobBehavior}, pwd::pwd, shift::shift, source::source}, exec_input, jobs::{dispatch_job, ChildProc, Job, JobBldr, JobStack}, libsh::{error::{ShErr, ShErrKind, ShResult, ShResultExt}, utils::RedirVecUtils}, prelude::*, procio::{IoFrame, IoMode, IoStack}, state::{self, read_logic, read_vars, write_logic, write_vars, ShFunc, VarTab}}; use super::{lex::{LexFlags, LexStream, Span, Tk, TkFlags, KEYWORDS}, AssignKind, CaseNode, CondNode, ConjunctNode, ConjunctOp, LoopKind, NdFlags, NdRule, Node, ParseStream, ParsedSrc, Redir, RedirType}; pub enum AssignBehavior { Export, Set } /// Arguments to the execvpe function pub struct ExecArgs { pub cmd: (CString,Span), pub argv: Vec, pub envp: Vec } impl ExecArgs { pub fn new(argv: Vec) -> ShResult { assert!(!argv.is_empty()); let argv = prepare_argv(argv)?; let cmd = Self::get_cmd(&argv); let argv = Self::get_argv(argv); let envp = Self::get_envp(); Ok(Self { cmd, argv, envp }) } pub fn get_cmd(argv: &[(String,Span)]) -> (CString,Span) { (CString::new(argv[0].0.as_str()).unwrap(),argv[0].1.clone()) } pub fn get_argv(argv: Vec<(String,Span)>) -> Vec { argv.into_iter().map(|s| CString::new(s.0).unwrap()).collect() } pub fn get_envp() -> Vec { std::env::vars().map(|v| CString::new(format!("{}={}",v.0,v.1)).unwrap()).collect() } } pub struct Dispatcher { nodes: VecDeque, pub io_stack: IoStack, pub job_stack: JobStack } impl Dispatcher { pub fn new(nodes: Vec) -> Self { let nodes = VecDeque::from(nodes); Self { nodes, io_stack: IoStack::new(), job_stack: JobStack::new() } } pub fn begin_dispatch(&mut self) -> ShResult<()> { flog!(TRACE, "beginning dispatch"); while let Some(node) = self.nodes.pop_front() { let blame = node.get_span(); self.dispatch_node(node).try_blame(blame)?; } Ok(()) } pub fn dispatch_node(&mut self, node: Node) -> ShResult<()> { match node.class { NdRule::Conjunction {..} => self.exec_conjunction(node)?, NdRule::Pipeline {..} => self.exec_pipeline(node)?, NdRule::IfNode {..} => self.exec_if(node)?, NdRule::LoopNode {..} => self.exec_loop(node)?, NdRule::CaseNode {..} => self.exec_case(node)?, NdRule::BraceGrp {..} => self.exec_brc_grp(node)?, NdRule::FuncDef {..} => self.exec_func_def(node)?, NdRule::Command {..} => self.dispatch_cmd(node)?, _ => unreachable!() } Ok(()) } pub fn dispatch_cmd(&mut self, node: Node) -> ShResult<()> { let Some(cmd) = node.get_command() else { return self.exec_cmd(node) // Argv is empty, probably an assignment }; if cmd.flags.contains(TkFlags::BUILTIN) { self.exec_builtin(node) } else if is_func(node.get_command().cloned()) { self.exec_func(node) } else { self.exec_cmd(node) } } pub fn exec_conjunction(&mut self, conjunction: Node) -> ShResult<()> { let NdRule::Conjunction { elements } = conjunction.class else { unreachable!() }; let mut elem_iter = elements.into_iter(); while let Some(element) = elem_iter.next() { let ConjunctNode { cmd, operator } = element; self.dispatch_node(*cmd)?; let status = state::get_status(); match operator { ConjunctOp::And => if status != 0 { break }, ConjunctOp::Or => if status == 0 { break }, ConjunctOp::Null => break } } Ok(()) } pub fn exec_func_def(&mut self, func_def: Node) -> ShResult<()> { let blame = func_def.get_span(); let NdRule::FuncDef { name, body } = func_def.class else { unreachable!() }; let body_span = body.get_span(); let body = body_span.as_str().to_string(); let name = name.span.as_str().strip_suffix("()").unwrap(); if KEYWORDS.contains(&name) { return Err( ShErr::full( ShErrKind::SyntaxErr, format!("function: Forbidden function name `{name}`"), blame ) ) } let mut func_parser = ParsedSrc::new(Rc::new(body)); func_parser.parse_src()?; // Parse the function let func = ShFunc::new(func_parser); write_logic(|l| l.insert_func(name, func)); // Store the AST Ok(()) } pub fn exec_func(&mut self, func: Node) -> ShResult<()> { let blame = func.get_span().clone(); let NdRule::Command { assignments, mut argv } = func.class else { unreachable!() }; self.set_assignments(assignments, AssignBehavior::Export); self.io_stack.append_to_frame(func.redirs); let func_name = argv.remove(0).span.as_str().to_string(); if let Some(func) = read_logic(|l| l.get_func(&func_name)) { let scope_snapshot = read_vars(|v| v.clone()); // Set up the inner scope write_vars(|v| { **v = VarTab::new(); v.clear_args(); for arg in argv { v.bpush_arg(arg.to_string()); } }); if let Err(e) = self.exec_brc_grp((*func).clone()) { write_vars(|v| **v = scope_snapshot); match e.kind() { ShErrKind::FuncReturn(code) => { state::set_status(*code); return Ok(()) } _ => return Err(e.into()) } } // Return to the outer scope write_vars(|v| **v = scope_snapshot); Ok(()) } else { Err( ShErr::full( ShErrKind::InternalErr, format!("Failed to find function '{}'",func_name), blame ) ) } } pub fn exec_brc_grp(&mut self, brc_grp: Node) -> ShResult<()> { let NdRule::BraceGrp { body } = brc_grp.class else { unreachable!() }; let mut io_frame = self.io_stack.pop_frame(); io_frame.extend(brc_grp.redirs); for node in body { let blame = node.get_span(); self.io_stack.push_frame(io_frame.clone()); self.dispatch_node(node).try_blame(blame)?; } Ok(()) } pub fn exec_case(&mut self, case_stmt: Node) -> ShResult<()> { let NdRule::CaseNode { pattern, case_blocks } = case_stmt.class else { unreachable!() }; self.io_stack.append_to_frame(case_stmt.redirs); flog!(DEBUG,pattern.span.as_str()); let exp_pattern = pattern.clone().expand(pattern.span.clone(), pattern.flags.clone())?; let pattern_raw = exp_pattern .get_words() .first() .map(|s| s.to_string()) .unwrap_or_default(); flog!(DEBUG,exp_pattern); for block in case_blocks { let CaseNode { pattern, body } = block; let block_pattern_raw = pattern.span.as_str().trim_end_matches(')').trim(); // Split at '|' to allow for multiple patterns like `foo|bar)` let block_patterns = block_pattern_raw.split('|'); for pattern in block_patterns { if pattern_raw == pattern || pattern == "*" { for node in &body { self.dispatch_node(node.clone())?; } } } } Ok(()) } pub fn exec_loop(&mut self, loop_stmt: Node) -> ShResult<()> { let NdRule::LoopNode { kind, cond_node } = loop_stmt.class else { unreachable!(); }; let keep_going = |kind: LoopKind, status: i32| -> bool { match kind { LoopKind::While => status == 0, LoopKind::Until => status != 0 } }; let io_frame = self.io_stack.pop_frame(); let (mut cond_frame,mut body_frame) = io_frame.split_frame(); let (in_redirs,out_redirs) = loop_stmt.redirs.split_by_channel(); cond_frame.extend(in_redirs); body_frame.extend(out_redirs); let CondNode { cond, body } = cond_node; 'outer: loop { self.io_stack.push(cond_frame.clone()); if let Err(e) = self.dispatch_node(*cond.clone()) { state::set_status(1); return Err(e.into()); } let status = state::get_status(); if keep_going(kind,status) { self.io_stack.push(body_frame.clone()); for node in &body { if let Err(e) = self.dispatch_node(node.clone()) { match e.kind() { ShErrKind::LoopBreak(code) => { state::set_status(*code); break 'outer } ShErrKind::LoopContinue(code) => { state::set_status(*code); continue 'outer } _ => return Err(e.into()) } } } } else { break } } Ok(()) } pub fn exec_if(&mut self, if_stmt: Node) -> ShResult<()> { let NdRule::IfNode { cond_nodes, else_block } = if_stmt.class else { unreachable!(); }; // Pop the current frame and split it let io_frame = self.io_stack.pop_frame(); let (mut cond_frame,mut body_frame) = io_frame.split_frame(); let (in_redirs,out_redirs) = if_stmt.redirs.split_by_channel(); cond_frame.extend(in_redirs); // Condition gets input redirs body_frame.extend(out_redirs); // Body gets output redirs for node in cond_nodes { let CondNode { cond, body } = node; self.io_stack.push(cond_frame.clone()); if let Err(e) = self.dispatch_node(*cond) { state::set_status(1); return Err(e.into()); } match state::get_status() { 0 => { for body_node in body { self.io_stack.push(body_frame.clone()); self.dispatch_node(body_node)?; } } _ => continue } } if !else_block.is_empty() { for node in else_block { self.io_stack.push(body_frame.clone()); self.dispatch_node(node)?; } } Ok(()) } pub fn exec_pipeline(&mut self, pipeline: Node) -> ShResult<()> { let NdRule::Pipeline { cmds, pipe_err: _ } = pipeline.class else { unreachable!() }; self.job_stack.new_job(); // Zip the commands and their respective pipes into an iterator let pipes_and_cmds = get_pipe_stack(cmds.len()) .into_iter() .zip(cmds); for ((rpipe,wpipe), cmd) in pipes_and_cmds { if let Some(pipe) = rpipe { self.io_stack.push_to_frame(pipe); } if let Some(pipe) = wpipe { self.io_stack.push_to_frame(pipe); } self.dispatch_node(cmd)?; } let job = self.job_stack.finalize_job().unwrap(); let is_bg = pipeline.flags.contains(NdFlags::BACKGROUND); dispatch_job(job, is_bg)?; Ok(()) } pub fn exec_builtin(&mut self, mut cmd: Node) -> ShResult<()> { let NdRule::Command { ref mut assignments, argv: _ } = &mut cmd.class else { unreachable!() }; let env_vars_to_unset = self.set_assignments(mem::take(assignments), AssignBehavior::Export); let cmd_raw = cmd.get_command().unwrap(); let curr_job_mut = self.job_stack.curr_job_mut().unwrap(); let io_stack_mut = &mut self.io_stack; flog!(TRACE, "doing builtin"); let result = match cmd_raw.span.as_str() { "echo" => echo(cmd, io_stack_mut, curr_job_mut), "cd" => cd(cmd, curr_job_mut), "export" => export(cmd, io_stack_mut, curr_job_mut), "pwd" => pwd(cmd, io_stack_mut, curr_job_mut), "source" => source(cmd, curr_job_mut), "shift" => shift(cmd, curr_job_mut), "fg" => continue_job(cmd, curr_job_mut, JobBehavior::Foregound), "bg" => continue_job(cmd, curr_job_mut, JobBehavior::Background), "jobs" => jobs(cmd, io_stack_mut, curr_job_mut), "alias" => alias(cmd, io_stack_mut, curr_job_mut), "return" => flowctl(cmd, ShErrKind::FuncReturn(0)), "break" => flowctl(cmd, ShErrKind::LoopBreak(0)), "continue" => flowctl(cmd, ShErrKind::LoopContinue(0)), "exit" => flowctl(cmd, ShErrKind::CleanExit(0)), _ => unimplemented!("Have not yet added support for builtin '{}'", cmd_raw.span.as_str()) }; for var in env_vars_to_unset { env::set_var(&var, ""); } if let Err(e) = result { state::set_status(1); return Err(e.into()) } Ok(()) } pub fn exec_cmd(&mut self, cmd: Node) -> ShResult<()> { let NdRule::Command { assignments, argv } = cmd.class else { unreachable!() }; let mut env_vars_to_unset = vec![]; if !assignments.is_empty() { let assign_behavior = if argv.is_empty() { AssignBehavior::Set } else { AssignBehavior::Export }; env_vars_to_unset = self.set_assignments(assignments, assign_behavior); } if argv.is_empty() { return Ok(()) } self.io_stack.append_to_frame(cmd.redirs); let exec_args = ExecArgs::new(argv)?; let io_frame = self.io_stack.pop_frame(); run_fork( io_frame, Some(exec_args), self.job_stack.curr_job_mut().unwrap(), def_child_action, def_parent_action )?; for var in env_vars_to_unset { std::env::set_var(&var, ""); } Ok(()) } pub fn set_assignments(&self, assigns: Vec, behavior: AssignBehavior) -> Vec { let mut new_env_vars = vec![]; match behavior { AssignBehavior::Export => { for assign in assigns { let NdRule::Assignment { kind, var, val } = assign.class else { unreachable!() }; let var = var.span.as_str(); let val = val.span.as_str(); match kind { AssignKind::Eq => std::env::set_var(var, val), AssignKind::PlusEq => todo!(), AssignKind::MinusEq => todo!(), AssignKind::MultEq => todo!(), AssignKind::DivEq => todo!(), } new_env_vars.push(var.to_string()); } } AssignBehavior::Set => { for assign in assigns { let NdRule::Assignment { kind, var, val } = assign.class else { unreachable!() }; let var = var.span.as_str(); let val = val.span.as_str(); match kind { AssignKind::Eq => write_vars(|v| v.new_var(var, val)), AssignKind::PlusEq => todo!(), AssignKind::MinusEq => todo!(), AssignKind::MultEq => todo!(), AssignKind::DivEq => todo!(), } } } } new_env_vars } } pub fn prepare_argv(argv: Vec) -> ShResult> { let mut args = vec![]; for arg in argv { let flags = arg.flags; let span = arg.span.clone(); let expanded = arg.expand(span.clone(), flags)?; for exp in expanded.get_words() { args.push((exp,span.clone())) } } Ok(args) } pub fn run_fork<'t,C,P>( io_frame: IoFrame, exec_args: Option, job: &mut JobBldr, child_action: C, parent_action: P, ) -> ShResult<()> where C: Fn(IoFrame,Option), P: Fn(IoFrame,&mut JobBldr,Option<&str>,Pid) -> ShResult<()> { match unsafe { fork()? } { ForkResult::Child => { child_action(io_frame,exec_args); exit(0); // Just in case } ForkResult::Parent { child } => { let cmd = if let Some(args) = exec_args { Some(args.cmd.0.to_str().unwrap().to_string()) } else { None }; parent_action(io_frame,job,cmd.as_deref(),child) } } } /// The default behavior for the child process after forking pub fn def_child_action(mut io_frame: IoFrame, exec_args: Option) { if let Err(e) = io_frame.redirect() { eprintln!("{e}"); } let exec_args = exec_args.unwrap(); let cmd = &exec_args.cmd.0; let span = exec_args.cmd.1; let Err(e) = execvpe(&cmd, &exec_args.argv, &exec_args.envp); let cmd = cmd.to_str().unwrap().to_string(); match e { Errno::ENOENT => { let err = ShErr::full( ShErrKind::CmdNotFound(cmd), "", span ); eprintln!("{err}"); } _ => { let err = ShErr::full( ShErrKind::Errno, format!("{e}"), span ); eprintln!("{err}"); } } exit(e as i32) } /// The default behavior for the parent process after forking pub fn def_parent_action( io_frame: IoFrame, job: &mut JobBldr, cmd: Option<&str>, child_pid: Pid ) -> ShResult<()> { let child_pgid = if let Some(pgid) = job.pgid() { pgid } else { job.set_pgid(child_pid); child_pid }; let child = ChildProc::new(child_pid, cmd, Some(child_pgid))?; job.push_child(child); Ok(()) } /// Initialize the pipes for a pipeline /// The first command gets `(None, WPipe)` /// The last command gets `(RPipe, None)` /// Commands inbetween get `(RPipe, WPipe)` /// If there is only one command, it gets `(None, None)` pub fn get_pipe_stack(num_cmds: usize) -> Vec<(Option,Option)> { let mut stack = Vec::with_capacity(num_cmds); let mut prev_read: Option = None; for i in 0..num_cmds { if i == num_cmds - 1 { stack.push((prev_read.take(), None)); } else { let (rpipe,wpipe) = IoMode::get_pipes(); let r_redir = Redir::new(rpipe, RedirType::Input); let w_redir = Redir::new(wpipe, RedirType::Output); // Push (prev_read, Some(w_redir)) and set prev_read to r_redir stack.push((prev_read.take(), Some(w_redir))); prev_read = Some(r_redir); } } stack } pub fn is_func(tk: Option) -> bool { let Some(tk) = tk else { return false }; read_logic(|l| l.get_func(&tk.to_string())).is_some() }