use std::path::Path; use crate::lite_parse::{lite_parse, LiteCommand, LitePipeline}; use crate::path::expand_path; use crate::signature::SignatureRegistry; use log::trace; use nu_errors::{ArgumentError, ParseError}; use nu_protocol::hir::{ self, Binary, ClassifiedCommand, ClassifiedPipeline, Commands, Expression, ExternalArg, ExternalArgs, ExternalCommand, Flag, FlagKind, InternalCommand, Member, NamedArguments, Operator, SpannedExpression, Unit, }; use nu_protocol::{NamedType, PositionalType, Signature, SyntaxShape, UnspannedPathMember}; use nu_source::{Span, Spanned, SpannedItem, Tag}; use num_bigint::BigInt; /// Parses a simple column path, one without a variable (implied or explicit) at the head fn parse_simple_column_path(lite_arg: &Spanned) -> (SpannedExpression, Option) { let mut delimiter = '.'; let mut inside_delimiter = false; let mut output = vec![]; let mut current_part = String::new(); let mut start_index = 0; let mut last_index = 0; for (idx, c) in lite_arg.item.char_indices() { last_index = idx; if inside_delimiter { if c == delimiter { inside_delimiter = false; } } else if c == '\'' || c == '"' { inside_delimiter = true; delimiter = c; } else if c == '.' { let part_span = Span::new( lite_arg.span.start() + start_index, lite_arg.span.start() + idx, ); if let Ok(row_number) = current_part.parse::() { output.push(Member::Int(BigInt::from(row_number), part_span)); } else { let trimmed = trim_quotes(¤t_part); output.push(Member::Bare(trimmed.clone().spanned(part_span))); } current_part.clear(); // Note: I believe this is safe because of the delimiter we're using, but if we get fancy with // unicode we'll need to change this start_index = idx + '.'.len_utf8(); continue; } current_part.push(c); } if !current_part.is_empty() { let part_span = Span::new( lite_arg.span.start() + start_index, lite_arg.span.start() + last_index + 1, ); if let Ok(row_number) = current_part.parse::() { output.push(Member::Int(BigInt::from(row_number), part_span)); } else { let current_part = trim_quotes(¤t_part); output.push(Member::Bare(current_part.spanned(part_span))); } } ( SpannedExpression::new(Expression::simple_column_path(output), lite_arg.span), None, ) } /// Parses a column path, adding in the preceding reference to $it if it's elided fn parse_full_column_path(lite_arg: &Spanned) -> (SpannedExpression, Option) { let mut delimiter = '.'; let mut inside_delimiter = false; let mut output = vec![]; let mut current_part = String::new(); let mut start_index = 0; let mut last_index = 0; let mut head = None; for (idx, c) in lite_arg.item.char_indices() { last_index = idx; if inside_delimiter { if c == delimiter { inside_delimiter = false; } } else if c == '\'' || c == '"' { inside_delimiter = true; delimiter = c; } else if c == '.' { let part_span = Span::new( lite_arg.span.start() + start_index, lite_arg.span.start() + idx, ); if head.is_none() && current_part.clone().starts_with('$') { // We have the variable head head = Some(Expression::variable(current_part.clone(), part_span)) } else if let Ok(row_number) = current_part.parse::() { output.push( UnspannedPathMember::Int(BigInt::from(row_number)).into_path_member(part_span), ); } else { let current_part = trim_quotes(¤t_part); output.push( UnspannedPathMember::String(current_part.clone()).into_path_member(part_span), ); } current_part.clear(); // Note: I believe this is safe because of the delimiter we're using, but if we get fancy with // unicode we'll need to change this start_index = idx + '.'.len_utf8(); continue; } current_part.push(c); } if !current_part.is_empty() { let part_span = Span::new( lite_arg.span.start() + start_index, lite_arg.span.start() + last_index + 1, ); if head.is_none() { if current_part.starts_with('$') { // We have the variable head head = Some(Expression::variable(current_part, lite_arg.span)); } else if let Ok(row_number) = current_part.parse::() { output.push( UnspannedPathMember::Int(BigInt::from(row_number)).into_path_member(part_span), ); } else { let current_part = trim_quotes(¤t_part); output.push(UnspannedPathMember::String(current_part).into_path_member(part_span)); } } else if let Ok(row_number) = current_part.parse::() { output.push( UnspannedPathMember::Int(BigInt::from(row_number)).into_path_member(part_span), ); } else { let current_part = trim_quotes(¤t_part); output.push(UnspannedPathMember::String(current_part).into_path_member(part_span)); } } if let Some(head) = head { ( SpannedExpression::new( Expression::path(SpannedExpression::new(head, lite_arg.span), output), lite_arg.span, ), None, ) } else { ( SpannedExpression::new( Expression::path( SpannedExpression::new( Expression::variable("$it".into(), lite_arg.span), lite_arg.span, ), output, ), lite_arg.span, ), None, ) } } fn trim_quotes(input: &str) -> String { let mut chars = input.chars(); match (chars.next(), chars.next_back()) { (Some('\''), Some('\'')) => chars.collect(), (Some('"'), Some('"')) => chars.collect(), _ => input.to_string(), } } fn parse_range(lite_arg: &Spanned) -> (SpannedExpression, Option) { let numbers: Vec<_> = lite_arg.item.split("..").collect(); if numbers.len() != 2 { ( garbage(lite_arg.span), Some(ParseError::mismatch("range", lite_arg.clone())), ) } else if let Ok(lhs) = numbers[0].parse::() { if let Ok(rhs) = numbers[1].parse::() { ( SpannedExpression::new( Expression::range( SpannedExpression::new(Expression::integer(lhs), lite_arg.span), lite_arg.span, SpannedExpression::new(Expression::integer(rhs), lite_arg.span), ), lite_arg.span, ), None, ) } else { ( garbage(lite_arg.span), Some(ParseError::mismatch("range", lite_arg.clone())), ) } } else { ( garbage(lite_arg.span), Some(ParseError::mismatch("range", lite_arg.clone())), ) } } fn parse_operator(lite_arg: &Spanned) -> (SpannedExpression, Option) { let operator = if lite_arg.item == "==" { Operator::Equal } else if lite_arg.item == "!=" { Operator::NotEqual } else if lite_arg.item == "<" { Operator::LessThan } else if lite_arg.item == "<=" { Operator::LessThanOrEqual } else if lite_arg.item == ">" { Operator::GreaterThan } else if lite_arg.item == ">=" { Operator::GreaterThanOrEqual } else if lite_arg.item == "=~" { Operator::Contains } else if lite_arg.item == "!~" { Operator::NotContains } else if lite_arg.item == "+" { Operator::Plus } else if lite_arg.item == "-" { Operator::Minus } else if lite_arg.item == "*" { Operator::Multiply } else if lite_arg.item == "/" { Operator::Divide } else if lite_arg.item == "in:" { Operator::In } else if lite_arg.item == "&&" { Operator::And } else if lite_arg.item == "||" { Operator::Or } else { return ( garbage(lite_arg.span), Some(ParseError::mismatch("operator", lite_arg.clone())), ); }; ( SpannedExpression::new(Expression::operator(operator), lite_arg.span), None, ) } fn parse_unit(lite_arg: &Spanned) -> (SpannedExpression, Option) { let unit_groups = [ (Unit::Byte, vec!["b", "B"]), (Unit::Kilobyte, vec!["kb", "KB", "Kb"]), (Unit::Megabyte, vec!["mb", "MB", "Mb"]), (Unit::Gigabyte, vec!["gb", "GB", "Gb"]), (Unit::Terabyte, vec!["tb", "TB", "Tb"]), (Unit::Petabyte, vec!["pb", "PB", "Pb"]), (Unit::Second, vec!["s"]), (Unit::Minute, vec!["m"]), (Unit::Hour, vec!["h"]), (Unit::Day, vec!["d"]), (Unit::Week, vec!["w"]), (Unit::Month, vec!["M"]), (Unit::Year, vec!["y"]), ]; for unit_group in unit_groups.iter() { for unit in unit_group.1.iter() { if lite_arg.item.ends_with(unit) { let mut lhs = lite_arg.item.clone(); for _ in 0..unit.len() { lhs.pop(); } // these units are allowed to signed if let Ok(x) = lhs.parse::() { let lhs_span = Span::new(lite_arg.span.start(), lite_arg.span.start() + lhs.len()); let unit_span = Span::new(lite_arg.span.start() + lhs.len(), lite_arg.span.end()); return ( SpannedExpression::new( Expression::unit(x.spanned(lhs_span), unit_group.0.spanned(unit_span)), lite_arg.span, ), None, ); } } } } ( garbage(lite_arg.span), Some(ParseError::mismatch("unit", lite_arg.clone())), ) } /// Parses the given argument using the shape as a guide for how to correctly parse the argument fn parse_arg( expected_type: SyntaxShape, registry: &dyn SignatureRegistry, lite_arg: &Spanned, ) -> (SpannedExpression, Option) { if lite_arg.item.starts_with('$') { return parse_full_column_path(&lite_arg); } match expected_type { SyntaxShape::Number => { if let Ok(x) = lite_arg.item.parse::() { ( SpannedExpression::new(Expression::integer(x), lite_arg.span), None, ) } else if let Ok(x) = lite_arg.item.parse::() { ( SpannedExpression::new(Expression::decimal(x), lite_arg.span), None, ) } else { ( garbage(lite_arg.span), Some(ParseError::mismatch("number", lite_arg.clone())), ) } } SyntaxShape::Int => { if let Ok(x) = lite_arg.item.parse::() { ( SpannedExpression::new(Expression::integer(x), lite_arg.span), None, ) } else { ( garbage(lite_arg.span), Some(ParseError::mismatch("number", lite_arg.clone())), ) } } SyntaxShape::String => { let trimmed = trim_quotes(&lite_arg.item); ( SpannedExpression::new(Expression::string(trimmed), lite_arg.span), None, ) } SyntaxShape::Pattern => { let trimmed = trim_quotes(&lite_arg.item); let expanded = expand_path(&trimmed); ( SpannedExpression::new(Expression::pattern(expanded), lite_arg.span), None, ) } SyntaxShape::Range => parse_range(&lite_arg), SyntaxShape::Operator => parse_operator(&lite_arg), SyntaxShape::Unit => parse_unit(&lite_arg), SyntaxShape::Path => { let trimmed = trim_quotes(&lite_arg.item); let expanded = expand_path(&trimmed); let path = Path::new(&expanded); ( SpannedExpression::new(Expression::FilePath(path.to_path_buf()), lite_arg.span), None, ) } SyntaxShape::ColumnPath => parse_simple_column_path(lite_arg), SyntaxShape::FullColumnPath => parse_full_column_path(lite_arg), SyntaxShape::Any => { let shapes = vec![ SyntaxShape::Int, SyntaxShape::Number, SyntaxShape::Range, SyntaxShape::Unit, SyntaxShape::Block, SyntaxShape::Table, SyntaxShape::Parenthesized, SyntaxShape::String, ]; for shape in shapes.iter() { if let (s, None) = parse_arg(*shape, registry, lite_arg) { return (s, None); } } ( garbage(lite_arg.span), Some(ParseError::mismatch("any shape", lite_arg.clone())), ) } SyntaxShape::Table => { let mut chars = lite_arg.item.chars(); match (chars.next(), chars.next_back()) { (Some('['), Some(']')) => { // We have a literal row let string: String = chars.collect(); let mut error = None; // We haven't done much with the inner string, so let's go ahead and work with it let lite_pipeline = match lite_parse(&string, lite_arg.span.start() + 1) { Ok(lp) => lp, Err(e) => return (garbage(lite_arg.span), Some(e)), }; let mut output = vec![]; for lite_inner in &lite_pipeline.commands { let (arg, err) = parse_arg(SyntaxShape::Any, registry, &lite_inner.name); output.push(arg); if error.is_none() { error = err; } for arg in &lite_inner.args { let (arg, err) = parse_arg(SyntaxShape::Any, registry, &arg); output.push(arg); if error.is_none() { error = err; } } } ( SpannedExpression::new(Expression::List(output), lite_arg.span), error, ) } _ => ( garbage(lite_arg.span), Some(ParseError::mismatch("table", lite_arg.clone())), ), } } SyntaxShape::Parenthesized => { let mut chars = lite_arg.item.chars(); match (chars.next(), chars.next_back()) { (Some('('), Some(')')) => { // We have a literal row let string: String = chars.collect(); // We haven't done much with the inner string, so let's go ahead and work with it let mut lite_pipeline = match lite_parse(&string, lite_arg.span.start() + 1) { Ok(lp) => lp, Err(e) => return (garbage(lite_arg.span), Some(e)), }; let mut collection = vec![]; for lite_cmd in lite_pipeline.commands.iter_mut() { collection.push(lite_cmd.name.clone()); collection.append(&mut lite_cmd.args); } let (_, expr, err) = parse_math_expression(0, &collection[..], registry, false); (expr, err) } _ => ( garbage(lite_arg.span), Some(ParseError::mismatch("table", lite_arg.clone())), ), } } SyntaxShape::Block | SyntaxShape::Math => { // Blocks have one of two forms: the literal block and the implied block // To parse a literal block, we need to detect that what we have is itself a block let mut chars = lite_arg.item.chars(); match (chars.next(), chars.next_back()) { (Some('{'), Some('}')) => { // We have a literal block let string: String = chars.collect(); // We haven't done much with the inner string, so let's go ahead and work with it let lite_pipeline = match lite_parse(&string, lite_arg.span.start() + 1) { Ok(lp) => lp, Err(e) => return (garbage(lite_arg.span), Some(e)), }; let classified_block = classify_pipeline(&lite_pipeline, registry); let error = classified_block.failed; ( SpannedExpression::new( Expression::Block(classified_block.commands), lite_arg.span, ), error, ) } _ => { // We have an implied block, but we can't parse this here // it needed to have been parsed up higher where we have control over more than one arg ( garbage(lite_arg.span), Some(ParseError::mismatch("block", lite_arg.clone())), ) } } } } } /// Match the available flags in a signature with what the user provided. This will check both long-form flags (--full) and shorthand flags (-f) /// This also allows users to provide a group of shorthand flags (-af) that correspond to multiple shorthand flags at once. fn get_flags_from_flag( signature: &nu_protocol::Signature, cmd: &Spanned, arg: &Spanned, ) -> (Vec<(String, NamedType)>, Option) { if arg.item.starts_with('-') { // It's a flag (or set of flags) let mut output = vec![]; let mut error = None; let remainder: String = arg.item.chars().skip(1).collect(); if remainder.starts_with('-') { // Long flag expected let remainder: String = remainder.chars().skip(1).collect(); if let Some((named_type, _)) = signature.named.get(&remainder) { output.push((remainder.clone(), named_type.clone())); } else { error = Some(ParseError::argument_error( cmd.clone(), ArgumentError::UnexpectedFlag(arg.clone()), )); } } else { // Short flag(s) expected let mut starting_pos = arg.span.start() + 1; for c in remainder.chars() { let mut found = false; for (full_name, named_arg) in signature.named.iter() { if Some(c) == named_arg.0.get_short() { found = true; output.push((full_name.clone(), named_arg.0.clone())); break; } } if !found { error = Some(ParseError::argument_error( cmd.clone(), ArgumentError::UnexpectedFlag( arg.item .clone() .spanned(Span::new(starting_pos, starting_pos + c.len_utf8())), ), )); } starting_pos += c.len_utf8(); } } (output, error) } else { // It's not a flag, so don't bother with it (vec![], None) } } fn shorthand_reparse( left: SpannedExpression, orig_left: Option>, registry: &dyn SignatureRegistry, shorthand_mode: bool, ) -> (SpannedExpression, Option) { // If we're in shorthand mode, we need to reparse the left-hand side if possibe if shorthand_mode { if let Some(orig_left) = orig_left { parse_arg(SyntaxShape::FullColumnPath, registry, &orig_left) } else { (left, None) } } else { (left, None) } } fn parse_math_expression( incoming_idx: usize, lite_args: &[Spanned], registry: &dyn SignatureRegistry, shorthand_mode: bool, ) -> (usize, SpannedExpression, Option) { // Precedence parsing is included // Some notes: // * short_hand mode means that the left-hand side of an expression can point to a column-path. To make this possible, // we parse as normal, but then go back and when we detect a left-hand side, reparse that value if it's a string // * parens are handled earlier, so they're not handled explicitly here let mut idx = 0; let mut error = None; let mut working_exprs = vec![]; let mut prec = vec![]; let (lhs, err) = parse_arg(SyntaxShape::Any, registry, &lite_args[idx]); if error.is_none() { error = err; } working_exprs.push((Some(lite_args[idx].clone()), lhs)); idx += 1; prec.push(0); while idx < lite_args.len() { let (op, err) = parse_arg(SyntaxShape::Operator, registry, &lite_args[idx]); if error.is_none() { error = err; } idx += 1; if idx < lite_args.len() { trace!( "idx: {} working_exprs: {:#?} prec: {:?}", idx, working_exprs, prec ); let (rhs, err) = parse_arg(SyntaxShape::Any, registry, &lite_args[idx]); if error.is_none() { error = err; } let next_prec = op.precedence(); if !prec.is_empty() && next_prec > *prec.last().expect("this shouldn't happen") { prec.push(next_prec); working_exprs.push((None, op)); working_exprs.push((Some(lite_args[idx].clone()), rhs)); } else { while !prec.is_empty() && *prec.last().expect("This shouldn't happen") >= next_prec && next_prec > 0 // Not garbage && working_exprs.len() >= 3 { // Pop 3 and create and expression, push and repeat trace!( "idx: {} working_exprs: {:#?} prec: {:?}", idx, working_exprs, prec ); let (_, right) = working_exprs.pop().expect("This shouldn't be possible"); let (_, op) = working_exprs.pop().expect("This shouldn't be possible"); let (orig_left, left) = working_exprs.pop().expect("This shouldn't be possible"); // If we're in shorthand mode, we need to reparse the left-hand side if possibe let (left, err) = shorthand_reparse(left, orig_left, registry, shorthand_mode); if error.is_none() { error = err; } let span = Span::new(left.span.start(), right.span.end()); working_exprs.push(( None, SpannedExpression { expr: Expression::Binary(Box::new(Binary { left, op, right })), span, }, )); prec.pop(); } working_exprs.push((None, op)); working_exprs.push((Some(lite_args[idx].clone()), rhs)); } idx += 1; } else { if error.is_none() { error = Some(ParseError::argument_error( lite_args[idx - 1].clone(), ArgumentError::MissingMandatoryPositional("right hand side".into()), )); } working_exprs.push((None, garbage(op.span))); working_exprs.push((None, garbage(op.span))); prec.push(0); } } while working_exprs.len() >= 3 { // Pop 3 and create and expression, push and repeat let (_, right) = working_exprs.pop().expect("This shouldn't be possible"); let (_, op) = working_exprs.pop().expect("This shouldn't be possible"); let (orig_left, left) = working_exprs.pop().expect("This shouldn't be possible"); let (left, err) = shorthand_reparse(left, orig_left, registry, shorthand_mode); if error.is_none() { error = err; } let span = Span::new(left.span.start(), right.span.end()); working_exprs.push(( None, SpannedExpression { expr: Expression::Binary(Box::new(Binary { left, op, right })), span, }, )); } let (orig_left, left) = working_exprs.pop().expect("This shouldn't be possible"); let (left, err) = shorthand_reparse(left, orig_left, registry, shorthand_mode); if error.is_none() { error = err; } (incoming_idx + idx, left, error) } fn classify_positional_arg( idx: usize, lite_cmd: &LiteCommand, positional_type: &PositionalType, registry: &dyn SignatureRegistry, ) -> (usize, SpannedExpression, Option) { let mut idx = idx; let mut error = None; let arg = match positional_type { PositionalType::Mandatory(_, SyntaxShape::Math) | PositionalType::Optional(_, SyntaxShape::Math) => { // A condition can take up multiple arguments, as we build the operation as // We need to do this here because in parse_arg, we have access to only one arg at a time if idx < lite_cmd.args.len() { if lite_cmd.args[idx].item.starts_with('{') { // It's an explicit math expression, so parse it deeper in let (arg, err) = parse_arg(SyntaxShape::Math, registry, &lite_cmd.args[idx]); if error.is_none() { error = err; } arg } else { let (new_idx, arg, err) = parse_math_expression(idx, &lite_cmd.args[idx..], registry, true); let span = arg.span; let mut commands = hir::Commands::new(span); commands.push(ClassifiedCommand::Expr(Box::new(arg))); let arg = SpannedExpression::new(Expression::Block(commands), span); idx = new_idx; if error.is_none() { error = err; } arg } } else { if error.is_none() { error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::MissingMandatoryPositional("condition".into()), )) } garbage(lite_cmd.span()) } } PositionalType::Mandatory(_, shape) => { let (arg, err) = parse_arg(*shape, registry, &lite_cmd.args[idx]); if error.is_none() { error = err; } arg } PositionalType::Optional(_, shape) => { let (arg, err) = parse_arg(*shape, registry, &lite_cmd.args[idx]); if error.is_none() { error = err; } arg } }; (idx, arg, error) } fn classify_internal_command( lite_cmd: &LiteCommand, registry: &dyn SignatureRegistry, signature: &Signature, ) -> (InternalCommand, Option) { // This is a known internal command, so we need to work with the arguments and parse them according to the expected types let mut internal_command = InternalCommand::new( lite_cmd.name.item.clone(), lite_cmd.name.span, lite_cmd.span(), ); internal_command.args.set_initial_flags(&signature); let mut idx = 0; let mut current_positional = 0; let mut named = NamedArguments::new(); let mut positional = vec![]; let mut error = None; while idx < lite_cmd.args.len() { if lite_cmd.args[idx].item.starts_with('-') && lite_cmd.args[idx].item.len() > 1 { let (named_types, err) = get_flags_from_flag(&signature, &lite_cmd.name, &lite_cmd.args[idx]); if err.is_none() { for (full_name, named_type) in &named_types { match named_type { NamedType::Mandatory(_, shape) | NamedType::Optional(_, shape) => { if idx == lite_cmd.args.len() { // Oops, we're missing the argument to our named argument if error.is_none() { error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::MissingValueForName(format!("{:?}", shape)), )); } } else { idx += 1; if lite_cmd.args.len() > idx { let (arg, err) = parse_arg(*shape, registry, &lite_cmd.args[idx]); named.insert_mandatory( full_name.clone(), lite_cmd.args[idx - 1].span, arg, ); if error.is_none() { error = err; } } else if error.is_none() { error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::MissingValueForName(full_name.to_owned()), )); } } } NamedType::Switch(_) => { named.insert_switch( full_name.clone(), Some(Flag::new(FlagKind::Longhand, lite_cmd.args[idx].span)), ); } } } } else { positional.push(garbage(lite_cmd.args[idx].span)); if error.is_none() { error = err; } } } else if signature.positional.len() > current_positional { let arg = { let (new_idx, expr, err) = classify_positional_arg( idx, &lite_cmd, &signature.positional[current_positional].0, registry, ); idx = new_idx; if error.is_none() { error = err; } expr }; positional.push(arg); current_positional += 1; } else if let Some((rest_type, _)) = &signature.rest_positional { let (arg, err) = parse_arg(*rest_type, registry, &lite_cmd.args[idx]); if error.is_none() { error = err; } positional.push(arg); current_positional += 1; } else { positional.push(garbage(lite_cmd.args[idx].span)); if error.is_none() { error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::UnexpectedArgument(lite_cmd.args[idx].clone()), )); } } idx += 1; } // Count the required positional arguments and ensure these have been met let mut required_arg_count = 0; for positional_arg in &signature.positional { if let PositionalType::Mandatory(_, _) = positional_arg.0 { required_arg_count += 1; } } if positional.len() < required_arg_count && error.is_none() { let (_, name) = &signature.positional[positional.len()]; error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::MissingMandatoryPositional(name.to_owned()), )); } if !named.is_empty() { internal_command.args.named = Some(named); } if !positional.is_empty() { internal_command.args.positional = Some(positional); } (internal_command, error) } /// Convert a lite-ly parsed pipeline into a fully classified pipeline, ready to be evaluated. /// This conversion does error-recovery, so the result is allowed to be lossy. A lossy unit is designated as garbage. /// Errors are returned as part of a side-car error rather than a Result to allow both error and lossy result simultaneously. pub fn classify_pipeline( lite_pipeline: &LitePipeline, registry: &dyn SignatureRegistry, ) -> ClassifiedPipeline { // FIXME: fake span let mut commands = Commands::new(Span::new(0, 0)); let mut error = None; for lite_cmd in lite_pipeline.commands.iter() { if lite_cmd.name.item.starts_with('^') { let cmd_name: String = lite_cmd.name.item.chars().skip(1).collect(); // This is an external command we should allow arguments to pass through with minimal parsing commands.push(ClassifiedCommand::External(ExternalCommand { name: cmd_name, name_tag: Tag::unknown_anchor(lite_cmd.name.span), args: ExternalArgs { list: lite_cmd .args .iter() .map(|x| ExternalArg { arg: x.item.clone(), tag: Tag::unknown_anchor(x.span), }) .collect(), span: Span::new(0, 0), }, })) } else if lite_cmd.name.item == "=" { let expr = if !lite_cmd.args.is_empty() { let (_, expr, err) = parse_math_expression(0, &lite_cmd.args[0..], registry, false); if error.is_none() { error = err; } expr } else { if error.is_none() { error = Some(ParseError::argument_error( lite_cmd.name.clone(), ArgumentError::MissingMandatoryPositional("an expression".into()), )) } garbage(lite_cmd.span()) }; commands.push(ClassifiedCommand::Expr(Box::new(expr))) } else if let Some(signature) = registry.get(&lite_cmd.name.item) { let (internal_command, err) = classify_internal_command(&lite_cmd, registry, &signature); if error.is_none() { error = err; } commands.push(ClassifiedCommand::Internal(internal_command)) } else { let trimmed = trim_quotes(&lite_cmd.name.item); let name = expand_path(&trimmed); // This is an external command we should allow arguments to pass through with minimal parsing commands.push(ClassifiedCommand::External(ExternalCommand { name, name_tag: Tag::unknown_anchor(lite_cmd.name.span), args: ExternalArgs { list: lite_cmd .args .iter() .map(|x| ExternalArg { arg: x.item.clone(), tag: Tag::unknown_anchor(x.span), }) .collect(), span: Span::new(0, 0), }, })) } } ClassifiedPipeline::new(commands, error) } /// Easy shorthand function to create a garbage expression at the given span pub fn garbage(span: Span) -> SpannedExpression { SpannedExpression::new(Expression::Garbage, span) }