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nushell/crates/nu-parser/src/parse_keywords.rs
Stefan Holderbach cc39069e13
Reuse existing small allocations if possible (#12335) 
Those allocations are all small and insignificant in the grand scheme of
things and the optimizer may be able to resolve some of those but better
to be nice anyways.

Primarily inspired by the new
[`clippy::assigning_clones`](https://rust-lang.github.io/rust-clippy/master/index.html#/assigning_clones)

- **Avoid reallocs with `clone_from` in `nu-parser`**
- **Avoid realloc on assignment in `Stack`**
- **Fix `clippy::assigning_clones` in `nu-cli`**
- **Reuse allocations in `nu-explore` if possible**
2024-03-30 14:04:11 +01:00

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use crate::{
exportable::Exportable,
parse_block,
parser::{parse_redirection, redirecting_builtin_error},
parser_path::ParserPath,
type_check::{check_block_input_output, type_compatible},
};
use itertools::Itertools;
use log::trace;
use nu_path::canonicalize_with;
use nu_protocol::{
ast::{
Argument, Block, Call, Expr, Expression, ImportPattern, ImportPatternHead,
ImportPatternMember, Pipeline, PipelineElement,
},
engine::{StateWorkingSet, DEFAULT_OVERLAY_NAME},
eval_const::eval_constant,
span, Alias, BlockId, DeclId, Module, ModuleId, ParseError, PositionalArg,
ResolvedImportPattern, Span, Spanned, SyntaxShape, Type, Value, VarId,
};
use std::{
collections::{HashMap, HashSet},
path::{Path, PathBuf},
sync::Arc,
};
pub const LIB_DIRS_VAR: &str = "NU_LIB_DIRS";
#[cfg(feature = "plugin")]
pub const PLUGIN_DIRS_VAR: &str = "NU_PLUGIN_DIRS";
use crate::{
is_math_expression_like,
known_external::KnownExternal,
lex,
lite_parser::{lite_parse, LiteCommand},
parser::{
check_call, check_name, garbage, garbage_pipeline, parse, parse_call, parse_expression,
parse_full_signature, parse_import_pattern, parse_internal_call, parse_multispan_value,
parse_string, parse_value, parse_var_with_opt_type, trim_quotes, ParsedInternalCall,
},
unescape_unquote_string, Token, TokenContents,
};
/// These parser keywords can be aliased
pub const ALIASABLE_PARSER_KEYWORDS: &[&[u8]] = &[b"overlay hide", b"overlay new", b"overlay use"];
pub const RESERVED_VARIABLE_NAMES: [&str; 3] = ["in", "nu", "env"];
/// These parser keywords cannot be aliased (either not possible, or support not yet added)
pub const UNALIASABLE_PARSER_KEYWORDS: &[&[u8]] = &[
b"export",
b"def",
b"export def",
b"for",
b"extern",
b"export extern",
b"alias",
b"export alias",
b"export-env",
b"module",
b"use",
b"export use",
b"hide",
// b"overlay",
// b"overlay hide",
// b"overlay new",
// b"overlay use",
b"let",
b"const",
b"mut",
b"source",
b"where",
b"register",
];
/// Check whether spans start with a parser keyword that can be aliased
pub fn is_unaliasable_parser_keyword(working_set: &StateWorkingSet, spans: &[Span]) -> bool {
// try two words
if let (Some(span1), Some(span2)) = (spans.first(), spans.get(1)) {
let cmd_name = working_set.get_span_contents(span(&[*span1, *span2]));
return UNALIASABLE_PARSER_KEYWORDS.contains(&cmd_name);
}
// try one word
if let Some(span1) = spans.first() {
let cmd_name = working_set.get_span_contents(*span1);
UNALIASABLE_PARSER_KEYWORDS.contains(&cmd_name)
} else {
false
}
}
/// This is a new more compact method of calling parse_xxx() functions without repeating the
/// parse_call() in each function. Remaining keywords can be moved here.
pub fn parse_keyword(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Pipeline {
let call_expr = parse_call(working_set, &lite_command.parts, lite_command.parts[0]);
// if err.is_some() {
// return (Pipeline::from_vec(vec![call_expr]), err);
// }
if let Expression {
expr: Expr::Call(call),
..
} = call_expr.clone()
{
// Apply parse keyword side effects
let cmd = working_set.get_decl(call.decl_id);
// check help flag first.
if call.named_iter().any(|(flag, _, _)| flag.item == "help") {
let call_span = call.span();
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
}
match cmd.name() {
"overlay hide" => parse_overlay_hide(working_set, call),
"overlay new" => parse_overlay_new(working_set, call),
"overlay use" => parse_overlay_use(working_set, call),
_ => Pipeline::from_vec(vec![call_expr]),
}
} else {
Pipeline::from_vec(vec![call_expr])
}
}
pub fn parse_def_predecl(working_set: &mut StateWorkingSet, spans: &[Span]) {
let mut pos = 0;
let def_type_name = if spans.len() >= 3 {
// definition can't have only two spans, minimum is 3, e.g., 'extern spam []'
let first_word = working_set.get_span_contents(spans[0]);
if first_word == b"export" {
pos += 2;
} else {
pos += 1;
}
working_set.get_span_contents(spans[pos - 1]).to_vec()
} else {
return;
};
if def_type_name != b"def" && def_type_name != b"extern" {
return;
}
// Now, pos should point at the next span after the def-like call.
// Skip all potential flags, like --env, --wrapped or --help:
while pos < spans.len()
&& working_set
.get_span_contents(spans[pos])
.starts_with(&[b'-'])
{
pos += 1;
}
if pos >= spans.len() {
// This can happen if the call ends with a flag, e.g., 'def --help'
return;
}
// Now, pos should point at the command name.
let name_pos = pos;
let Some(name) = parse_string(working_set, spans[name_pos]).as_string() else {
return;
};
if name.contains('#')
|| name.contains('^')
|| name.parse::<bytesize::ByteSize>().is_ok()
|| name.parse::<f64>().is_ok()
{
working_set.error(ParseError::CommandDefNotValid(spans[name_pos]));
return;
}
// Find signature
let mut signature_pos = None;
while pos < spans.len() {
if working_set
.get_span_contents(spans[pos])
.starts_with(&[b'['])
|| working_set
.get_span_contents(spans[pos])
.starts_with(&[b'('])
{
signature_pos = Some(pos);
break;
}
pos += 1;
}
let Some(signature_pos) = signature_pos else {
return;
};
let mut allow_unknown_args = false;
for span in spans {
if working_set.get_span_contents(*span) == b"--wrapped" && def_type_name == b"def" {
allow_unknown_args = true;
}
}
let starting_error_count = working_set.parse_errors.len();
working_set.enter_scope();
// FIXME: because parse_signature will update the scope with the variables it sees
// we end up parsing the signature twice per def. The first time is during the predecl
// so that we can see the types that are part of the signature, which we need for parsing.
// The second time is when we actually parse the body itworking_set.
// We can't reuse the first time because the variables that are created during parse_signature
// are lost when we exit the scope below.
let sig = parse_full_signature(working_set, &spans[signature_pos..]);
working_set.parse_errors.truncate(starting_error_count);
working_set.exit_scope();
let Some(mut signature) = sig.as_signature() else {
return;
};
signature.name = name;
if allow_unknown_args {
signature.allows_unknown_args = true;
}
let decl = signature.predeclare();
if working_set.add_predecl(decl).is_some() {
working_set.error(ParseError::DuplicateCommandDef(spans[name_pos]));
}
}
pub fn parse_for(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Expression {
let spans = &lite_command.parts;
// Checking that the function is used with the correct name
// Maybe this is not necessary but it is a sanity check
if working_set.get_span_contents(spans[0]) != b"for" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'for' function".into(),
span(spans),
));
return garbage(spans[0]);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("for", redirection));
return garbage(spans[0]);
}
// Parsing the spans and checking that they match the register signature
// Using a parsed call makes more sense than checking for how many spans are in the call
// Also, by creating a call, it can be checked if it matches the declaration signature
let (call, call_span) = match working_set.find_decl(b"for") {
None => {
working_set.error(ParseError::UnknownState(
"internal error: for declaration not found".into(),
span(spans),
));
return garbage(spans[0]);
}
Some(decl_id) => {
working_set.enter_scope();
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
working_set.exit_scope();
let call_span = span(spans);
let decl = working_set.get_decl(decl_id);
let sig = decl.signature();
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &sig, &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage(spans[0]);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
};
}
// Let's get our block and make sure it has the right signature
if let Some(arg) = call.positional_nth(2) {
match arg {
Expression {
expr: Expr::Block(block_id),
..
}
| Expression {
expr: Expr::RowCondition(block_id),
..
} => {
let block = working_set.get_block_mut(*block_id);
block.signature = Box::new(sig);
}
_ => {}
}
}
(call, call_span)
}
};
// All positional arguments must be in the call positional vector by this point
let var_decl = call.positional_nth(0).expect("for call already checked");
let iteration_expr = call.positional_nth(1).expect("for call already checked");
let block = call.positional_nth(2).expect("for call already checked");
let iteration_expr_ty = iteration_expr.ty.clone();
// Figure out the type of the variable the `for` uses for iteration
let var_type = match iteration_expr_ty {
Type::List(x) => *x,
Type::Table(x) => Type::Record(x),
x => x,
};
if let (Some(var_id), Some(block_id)) = (&var_decl.as_var(), block.as_block()) {
working_set.set_variable_type(*var_id, var_type.clone());
let block = working_set.get_block_mut(block_id);
block.signature.required_positional.insert(
0,
PositionalArg {
name: String::new(),
desc: String::new(),
shape: var_type.to_shape(),
var_id: Some(*var_id),
default_value: None,
},
);
}
Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Nothing,
custom_completion: None,
}
}
/// If `name` is a keyword, emit an error.
fn verify_not_reserved_variable_name(working_set: &mut StateWorkingSet, name: &str, span: Span) {
if RESERVED_VARIABLE_NAMES.contains(&name) {
working_set.error(ParseError::NameIsBuiltinVar(name.to_string(), span))
}
}
// Returns also the parsed command name and ID
pub fn parse_def(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
module_name: Option<&[u8]>,
) -> (Pipeline, Option<(Vec<u8>, DeclId)>) {
let spans = &lite_command.parts[..];
let (usage, extra_usage) = working_set.build_usage(&lite_command.comments);
// Checking that the function is used with the correct name
// Maybe this is not necessary but it is a sanity check
// Note: "export def" is treated the same as "def"
let (name_span, split_id) =
if spans.len() > 1 && working_set.get_span_contents(spans[0]) == b"export" {
(spans[1], 2)
} else {
(spans[0], 1)
};
let def_call = working_set.get_span_contents(name_span).to_vec();
if def_call != b"def" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for def function".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("def", redirection));
return (garbage_pipeline(spans), None);
}
// Parsing the spans and checking that they match the register signature
// Using a parsed call makes more sense than checking for how many spans are in the call
// Also, by creating a call, it can be checked if it matches the declaration signature
let (call, call_span) = match working_set.find_decl(&def_call) {
None => {
working_set.error(ParseError::UnknownState(
"internal error: def declaration not found".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
Some(decl_id) => {
working_set.enter_scope();
let (command_spans, rest_spans) = spans.split_at(split_id);
// Find the first span that is not a flag
let mut decl_name_span = None;
for span in rest_spans {
if !working_set.get_span_contents(*span).starts_with(&[b'-']) {
decl_name_span = Some(*span);
break;
}
}
if let Some(name_span) = decl_name_span {
// Check whether name contains [] or () -- possible missing space error
if let Some(err) = detect_params_in_name(
working_set,
name_span,
String::from_utf8_lossy(&def_call).as_ref(),
) {
working_set.error(err);
return (garbage_pipeline(spans), None);
}
}
let starting_error_count = working_set.parse_errors.len();
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, span(command_spans), rest_spans, decl_id);
// This is to preserve the order of the errors so that
// the check errors below come first
let mut new_errors = working_set.parse_errors[starting_error_count..].to_vec();
working_set.parse_errors.truncate(starting_error_count);
working_set.exit_scope();
let call_span = span(spans);
let decl = working_set.get_decl(decl_id);
let sig = decl.signature();
// Let's get our block and make sure it has the right signature
if let Some(arg) = call.positional_nth(2) {
match arg {
Expression {
expr: Expr::Closure(block_id),
..
} => {
let block = working_set.get_block_mut(*block_id);
block.signature = Box::new(sig.clone());
}
_ => working_set.parse_errors.push(ParseError::Expected(
"definition body closure { ... }",
arg.span,
)),
}
}
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &sig, &call);
working_set.parse_errors.append(&mut new_errors);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return (garbage_pipeline(spans), None);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
None,
);
}
(call, call_span)
}
};
let Ok(has_env) = has_flag_const(working_set, &call, "env") else {
return (garbage_pipeline(spans), None);
};
let Ok(has_wrapped) = has_flag_const(working_set, &call, "wrapped") else {
return (garbage_pipeline(spans), None);
};
// All positional arguments must be in the call positional vector by this point
let name_expr = call.positional_nth(0).expect("def call already checked");
let sig = call.positional_nth(1).expect("def call already checked");
let block = call.positional_nth(2).expect("def call already checked");
let name = if let Some(name) = name_expr.as_string() {
if let Some(mod_name) = module_name {
if name.as_bytes() == mod_name {
let name_expr_span = name_expr.span;
working_set.error(ParseError::NamedAsModule(
"command".to_string(),
name,
"main".to_string(),
name_expr_span,
));
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
None,
);
}
}
name
} else {
working_set.error(ParseError::UnknownState(
"Could not get string from string expression".into(),
name_expr.span,
));
return (garbage_pipeline(spans), None);
};
let mut result = None;
if let (Some(mut signature), Some(block_id)) = (sig.as_signature(), block.as_block()) {
for arg_name in &signature.required_positional {
verify_not_reserved_variable_name(working_set, &arg_name.name, sig.span);
}
for arg_name in &signature.optional_positional {
verify_not_reserved_variable_name(working_set, &arg_name.name, sig.span);
}
for arg_name in &signature.rest_positional {
verify_not_reserved_variable_name(working_set, &arg_name.name, sig.span);
}
for flag_name in &signature.get_names() {
verify_not_reserved_variable_name(working_set, flag_name, sig.span);
}
if has_wrapped {
if let Some(rest) = &signature.rest_positional {
if let Some(var_id) = rest.var_id {
let rest_var = &working_set.get_variable(var_id);
if rest_var.ty != Type::Any && rest_var.ty != Type::List(Box::new(Type::String))
{
working_set.error(ParseError::TypeMismatchHelp(
Type::List(Box::new(Type::String)),
rest_var.ty.clone(),
rest_var.declaration_span,
format!("...rest-like positional argument used in 'def --wrapped' supports only strings. Change the type annotation of ...{} to 'string'.", &rest.name)));
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
result,
);
}
}
} else {
working_set.error(ParseError::MissingPositional("...rest-like positional argument".to_string(), name_expr.span, "def --wrapped must have a ...rest-like positional argument. Add '...rest: string' to the command's signature.".to_string()));
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
result,
);
}
}
if let Some(decl_id) = working_set.find_predecl(name.as_bytes()) {
let declaration = working_set.get_decl_mut(decl_id);
signature.name.clone_from(&name);
if !has_wrapped {
*signature = signature.add_help();
}
signature.usage = usage;
signature.extra_usage = extra_usage;
signature.allows_unknown_args = has_wrapped;
*declaration = signature.clone().into_block_command(block_id);
let block = working_set.get_block_mut(block_id);
block.signature = signature;
block.redirect_env = has_env;
if block.signature.input_output_types.is_empty() {
block
.signature
.input_output_types
.push((Type::Any, Type::Any));
}
let block = working_set.get_block(block_id);
let typecheck_errors = check_block_input_output(working_set, block);
working_set
.parse_errors
.extend_from_slice(&typecheck_errors);
result = Some((name.as_bytes().to_vec(), decl_id));
} else {
working_set.error(ParseError::InternalError(
"Predeclaration failed to add declaration".into(),
name_expr.span,
));
};
}
// It's OK if it returns None: The decl was already merged in previous parse pass.
working_set.merge_predecl(name.as_bytes());
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
result,
)
}
pub fn parse_extern(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
module_name: Option<&[u8]>,
) -> Pipeline {
let spans = &lite_command.parts;
let (usage, extra_usage) = working_set.build_usage(&lite_command.comments);
// Checking that the function is used with the correct name
// Maybe this is not necessary but it is a sanity check
let (name_span, split_id) =
if spans.len() > 1 && (working_set.get_span_contents(spans[0]) == b"export") {
(spans[1], 2)
} else {
(spans[0], 1)
};
let extern_call = working_set.get_span_contents(name_span).to_vec();
if extern_call != b"extern" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for extern command".into(),
span(spans),
));
return garbage_pipeline(spans);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("extern", redirection));
return garbage_pipeline(spans);
}
// Parsing the spans and checking that they match the register signature
// Using a parsed call makes more sense than checking for how many spans are in the call
// Also, by creating a call, it can be checked if it matches the declaration signature
let (call, call_span) = match working_set.find_decl(&extern_call) {
None => {
working_set.error(ParseError::UnknownState(
"internal error: def declaration not found".into(),
span(spans),
));
return garbage_pipeline(spans);
}
Some(decl_id) => {
working_set.enter_scope();
let (command_spans, rest_spans) = spans.split_at(split_id);
if let Some(name_span) = rest_spans.first() {
if let Some(err) = detect_params_in_name(
working_set,
*name_span,
String::from_utf8_lossy(&extern_call).as_ref(),
) {
working_set.error(err);
return garbage_pipeline(spans);
}
}
let ParsedInternalCall { call, .. } =
parse_internal_call(working_set, span(command_spans), rest_spans, decl_id);
working_set.exit_scope();
let call_span = span(spans);
//let decl = working_set.get_decl(decl_id);
//let sig = decl.signature();
(call, call_span)
}
};
let name_expr = call.positional_nth(0);
let sig = call.positional_nth(1);
let body = call.positional_nth(2);
if let (Some(name_expr), Some(sig)) = (name_expr, sig) {
if let (Some(name), Some(mut signature)) = (&name_expr.as_string(), sig.as_signature()) {
if let Some(mod_name) = module_name {
if name.as_bytes() == mod_name {
let name_expr_span = name_expr.span;
working_set.error(ParseError::NamedAsModule(
"known external".to_string(),
name.clone(),
"main".to_string(),
name_expr_span,
));
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
}
}
if let Some(decl_id) = working_set.find_predecl(name.as_bytes()) {
let declaration = working_set.get_decl_mut(decl_id);
let external_name = if let Some(mod_name) = module_name {
if name.as_bytes() == b"main" {
String::from_utf8_lossy(mod_name).to_string()
} else {
name.clone()
}
} else {
name.clone()
};
signature.name.clone_from(&external_name);
signature.usage.clone_from(&usage);
signature.extra_usage.clone_from(&extra_usage);
signature.allows_unknown_args = true;
if let Some(block_id) = body.and_then(|x| x.as_block()) {
if signature.rest_positional.is_none() {
working_set.error(ParseError::InternalError(
"Extern block must have a rest positional argument".into(),
name_expr.span,
));
} else {
*declaration = signature.clone().into_block_command(block_id);
working_set.get_block_mut(block_id).signature = signature;
}
} else {
let decl = KnownExternal {
name: external_name,
usage,
extra_usage,
signature,
};
*declaration = Box::new(decl);
}
} else {
working_set.error(ParseError::InternalError(
"Predeclaration failed to add declaration".into(),
spans[split_id],
));
};
}
if let Some(name) = name_expr.as_string() {
// It's OK if it returns None: The decl was already merged in previous parse pass.
working_set.merge_predecl(name.as_bytes());
} else {
working_set.error(ParseError::UnknownState(
"Could not get string from string expression".into(),
name_expr.span,
));
}
}
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}])
}
pub fn parse_alias(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
module_name: Option<&[u8]>,
) -> Pipeline {
let spans = &lite_command.parts;
let (name_span, split_id) =
if spans.len() > 1 && working_set.get_span_contents(spans[0]) == b"export" {
(spans[1], 2)
} else {
(spans[0], 1)
};
let name = working_set.get_span_contents(name_span);
if name != b"alias" {
working_set.error(ParseError::InternalError(
"Alias statement unparsable".into(),
span(spans),
));
return garbage_pipeline(spans);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("alias", redirection));
return garbage_pipeline(spans);
}
if let Some(span) = check_name(working_set, spans) {
return Pipeline::from_vec(vec![garbage(*span)]);
}
if let Some(decl_id) = working_set.find_decl(b"alias") {
let (command_spans, rest_spans) = spans.split_at(split_id);
let original_starting_error_count = working_set.parse_errors.len();
let ParsedInternalCall {
call: alias_call,
output,
..
} = parse_internal_call(working_set, span(command_spans), rest_spans, decl_id);
working_set
.parse_errors
.truncate(original_starting_error_count);
let Ok(has_help_flag) = has_flag_const(working_set, &alias_call, "help") else {
return garbage_pipeline(spans);
};
let alias_pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(alias_call.clone()),
span: span(spans),
ty: output,
custom_completion: None,
}]);
if has_help_flag {
return alias_pipeline;
}
let Some(alias_name_expr) = alias_call.positional_nth(0) else {
working_set.error(ParseError::UnknownState(
"Missing positional after call check".to_string(),
span(spans),
));
return garbage_pipeline(spans);
};
let alias_name = if let Some(name) = alias_name_expr.as_string() {
if name.contains('#')
|| name.contains('^')
|| name.parse::<bytesize::ByteSize>().is_ok()
|| name.parse::<f64>().is_ok()
{
working_set.error(ParseError::AliasNotValid(alias_name_expr.span));
return garbage_pipeline(spans);
} else {
name
}
} else {
working_set.error(ParseError::AliasNotValid(alias_name_expr.span));
return garbage_pipeline(spans);
};
if spans.len() >= split_id + 3 {
if let Some(mod_name) = module_name {
if alias_name.as_bytes() == mod_name {
working_set.error(ParseError::NamedAsModule(
"alias".to_string(),
alias_name,
"main".to_string(),
spans[split_id],
));
return alias_pipeline;
}
if alias_name == "main" {
working_set.error(ParseError::ExportMainAliasNotAllowed(spans[split_id]));
return alias_pipeline;
}
}
let _equals = working_set.get_span_contents(spans[split_id + 1]);
let replacement_spans = &spans[(split_id + 2)..];
let first_bytes = working_set.get_span_contents(replacement_spans[0]);
if first_bytes != b"if"
&& first_bytes != b"match"
&& is_math_expression_like(working_set, replacement_spans[0])
{
// TODO: Maybe we need to implement a Display trait for Expression?
let starting_error_count = working_set.parse_errors.len();
let expr = parse_expression(working_set, replacement_spans);
working_set.parse_errors.truncate(starting_error_count);
let msg = format!("{:?}", expr.expr);
let msg_parts: Vec<&str> = msg.split('(').collect();
working_set.error(ParseError::CantAliasExpression(
msg_parts[0].to_string(),
replacement_spans[0],
));
return alias_pipeline;
}
let starting_error_count = working_set.parse_errors.len();
working_set.search_predecls = false;
let expr = parse_call(working_set, replacement_spans, replacement_spans[0]);
working_set.search_predecls = true;
if starting_error_count != working_set.parse_errors.len() {
if let Some(e) = working_set.parse_errors.get(starting_error_count) {
if let ParseError::MissingPositional(..) = e {
working_set
.parse_errors
.truncate(original_starting_error_count);
// ignore missing required positional
} else {
return garbage_pipeline(replacement_spans);
}
}
}
let (command, wrapped_call) = match expr {
Expression {
expr: Expr::Call(ref rhs_call),
..
} => {
let cmd = working_set.get_decl(rhs_call.decl_id);
if cmd.is_parser_keyword()
&& !ALIASABLE_PARSER_KEYWORDS.contains(&cmd.name().as_bytes())
{
working_set.error(ParseError::CantAliasKeyword(
ALIASABLE_PARSER_KEYWORDS
.iter()
.map(|bytes| String::from_utf8_lossy(bytes).to_string())
.collect::<Vec<String>>()
.join(", "),
rhs_call.head,
));
return alias_pipeline;
}
(Some(cmd.clone_box()), expr)
}
Expression {
expr: Expr::ExternalCall(..),
..
} => (None, expr),
_ => {
working_set.error(ParseError::InternalError(
"Parsed call not a call".into(),
expr.span,
));
return alias_pipeline;
}
};
// Tries to build a useful usage string
let (usage, extra_usage) = match lite_command.comments.is_empty() {
// First from comments, if any are present
false => working_set.build_usage(&lite_command.comments),
// Then from the command itself
true => match alias_call.arguments.get(1) {
Some(Argument::Positional(Expression {
expr: Expr::Keyword(.., expr),
..
})) => {
let aliased = working_set.get_span_contents(expr.span);
(
format!("Alias for `{}`", String::from_utf8_lossy(aliased)),
String::new(),
)
}
// Then with a default.
_ => ("User declared alias".into(), String::new()),
},
};
let decl = Alias {
name: alias_name,
command,
wrapped_call,
usage,
extra_usage,
};
working_set.add_decl(Box::new(decl));
}
// special case for `alias foo=bar`
if spans.len() == 2 && working_set.get_span_contents(spans[1]).contains(&b'=') {
let arg = String::from_utf8_lossy(working_set.get_span_contents(spans[1]));
// split at '='. Note that the output must never be None, the
// `unwrap` is just to avoid the possibility of panic, if the
// invariant is broken.
let (name, initial_value) = arg.split_once('=').unwrap_or((&arg, ""));
let name = if name.is_empty() { "{name}" } else { name };
let initial_value = if initial_value.is_empty() {
"{initial_value}"
} else {
initial_value
};
working_set.error(ParseError::IncorrectValue(
"alias argument".into(),
spans[1],
format!("Make sure to put spaces around '=': alias {name} = {initial_value}"),
))
} else if spans.len() < 4 {
working_set.error(ParseError::IncorrectValue(
"Incomplete alias".into(),
span(&spans[..split_id]),
"incomplete alias".into(),
));
}
return alias_pipeline;
}
working_set.error(ParseError::InternalError(
"Alias statement unparsable".into(),
span(spans),
));
garbage_pipeline(spans)
}
// This one will trigger if `export` appears during eval, e.g., in a script
pub fn parse_export_in_block(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
) -> Pipeline {
let call_span = span(&lite_command.parts);
let full_name = if lite_command.parts.len() > 1 {
let sub = working_set.get_span_contents(lite_command.parts[1]);
match sub {
b"alias" => "export alias",
b"def" => "export def",
b"extern" => "export extern",
b"use" => "export use",
b"module" => "export module",
b"const" => "export const",
_ => "export",
}
} else {
"export"
};
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error(full_name, redirection));
return garbage_pipeline(&lite_command.parts);
}
if let Some(decl_id) = working_set.find_decl(full_name.as_bytes()) {
let ParsedInternalCall { call, output, .. } = parse_internal_call(
working_set,
if full_name == "export" {
lite_command.parts[0]
} else {
span(&lite_command.parts[0..2])
},
if full_name == "export" {
&lite_command.parts[1..]
} else {
&lite_command.parts[2..]
},
decl_id,
);
let decl = working_set.get_decl(decl_id);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage_pipeline(&lite_command.parts);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]);
}
} else {
working_set.error(ParseError::UnknownState(
format!("internal error: '{full_name}' declaration not found",),
span(&lite_command.parts),
));
return garbage_pipeline(&lite_command.parts);
};
if full_name == "export" {
// export by itself is meaningless
working_set.error(ParseError::UnexpectedKeyword(
"export".into(),
lite_command.parts[0],
));
return garbage_pipeline(&lite_command.parts);
}
match full_name {
"export alias" => parse_alias(working_set, lite_command, None),
"export def" => parse_def(working_set, lite_command, None).0,
"export const" => parse_const(working_set, &lite_command.parts[1..]),
"export use" => parse_use(working_set, lite_command).0,
"export module" => parse_module(working_set, lite_command, None).0,
"export extern" => parse_extern(working_set, lite_command, None),
_ => {
working_set.error(ParseError::UnexpectedKeyword(
full_name.into(),
lite_command.parts[0],
));
garbage_pipeline(&lite_command.parts)
}
}
}
// This one will trigger only in a module
pub fn parse_export_in_module(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
module_name: &[u8],
) -> (Pipeline, Vec<Exportable>) {
let spans = &lite_command.parts[..];
let export_span = if let Some(sp) = spans.first() {
if working_set.get_span_contents(*sp) != b"export" {
working_set.error(ParseError::UnknownState(
"expected export statement".into(),
span(spans),
));
return (garbage_pipeline(spans), vec![]);
}
*sp
} else {
working_set.error(ParseError::UnknownState(
"got empty input for parsing export statement".into(),
span(spans),
));
return (garbage_pipeline(spans), vec![]);
};
let export_decl_id = if let Some(id) = working_set.find_decl(b"export") {
id
} else {
working_set.error(ParseError::InternalError(
"missing export command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
let mut call = Box::new(Call {
head: spans[0],
decl_id: export_decl_id,
arguments: vec![],
parser_info: HashMap::new(),
});
let exportables = if let Some(kw_span) = spans.get(1) {
let kw_name = working_set.get_span_contents(*kw_span);
match kw_name {
b"def" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
pipe: lite_command.pipe,
redirection: lite_command.redirection.clone(),
};
let (pipeline, cmd_result) =
parse_def(working_set, &lite_command, Some(module_name));
let mut result = vec![];
if let Some((decl_name, decl_id)) = cmd_result {
result.push(Exportable::Decl {
name: decl_name.to_vec(),
id: decl_id,
});
}
let export_def_decl_id = if let Some(id) = working_set.find_decl(b"export def") {
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export def' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'def' call into the 'export def' in a very clumsy way
if let Some(Expr::Call(def_call)) = pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(def_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_def_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
result
}
b"extern" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
pipe: lite_command.pipe,
redirection: lite_command.redirection.clone(),
};
let extern_name = [b"export ", kw_name].concat();
let pipeline = parse_extern(working_set, &lite_command, Some(module_name));
let export_def_decl_id = if let Some(id) = working_set.find_decl(&extern_name) {
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export extern' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'def' call into the 'export def' in a very clumsy way
if let Some(Expr::Call(def_call)) = pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(def_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_def_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
let mut result = vec![];
let decl_name = match spans.get(2) {
Some(span) => working_set.get_span_contents(*span),
None => &[],
};
let decl_name = trim_quotes(decl_name);
if let Some(decl_id) = working_set.find_decl(decl_name) {
result.push(Exportable::Decl {
name: decl_name.to_vec(),
id: decl_id,
});
} else {
working_set.error(ParseError::InternalError(
"failed to find added declaration".into(),
span(&spans[1..]),
));
}
result
}
b"alias" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
pipe: lite_command.pipe,
redirection: lite_command.redirection.clone(),
};
let pipeline = parse_alias(working_set, &lite_command, Some(module_name));
let export_alias_decl_id = if let Some(id) = working_set.find_decl(b"export alias")
{
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export alias' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'alias' call into the 'export alias' in a very clumsy way
if let Some(Expr::Call(alias_call)) =
pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(alias_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_alias_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
let mut result = vec![];
let alias_name = match spans.get(2) {
Some(span) => working_set.get_span_contents(*span),
None => &[],
};
let alias_name = trim_quotes(alias_name);
if let Some(alias_id) = working_set.find_decl(alias_name) {
result.push(Exportable::Decl {
name: alias_name.to_vec(),
id: alias_id,
});
} else {
working_set.error(ParseError::InternalError(
"failed to find added alias".into(),
span(&spans[1..]),
));
}
result
}
b"use" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
pipe: lite_command.pipe,
redirection: lite_command.redirection.clone(),
};
let (pipeline, exportables) = parse_use(working_set, &lite_command);
let export_use_decl_id = if let Some(id) = working_set.find_decl(b"export use") {
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export use' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'use' call into the 'export use' in a very clumsy way
if let Some(Expr::Call(use_call)) = pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(use_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_use_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
exportables
}
b"module" => {
let (pipeline, maybe_module_id) =
parse_module(working_set, lite_command, Some(module_name));
let export_module_decl_id =
if let Some(id) = working_set.find_decl(b"export module") {
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export module' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'module' call into the 'export module' in a very clumsy way
if let Some(Expr::Call(module_call)) =
pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(module_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_module_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
let mut result = vec![];
if let Some(module_name_span) = spans.get(2) {
let module_name = working_set.get_span_contents(*module_name_span);
let module_name = trim_quotes(module_name);
if let Some(module_id) = maybe_module_id {
result.push(Exportable::Module {
name: working_set.get_module(module_id).name(),
id: module_id,
});
} else {
working_set.error(ParseError::InternalError(
format!(
"failed to find added module '{}'",
String::from_utf8_lossy(module_name)
),
span(&spans[1..]),
));
}
}
result
}
b"const" => {
let pipeline = parse_const(working_set, &spans[1..]);
let export_const_decl_id = if let Some(id) = working_set.find_decl(b"export const")
{
id
} else {
working_set.error(ParseError::InternalError(
"missing 'export const' command".into(),
export_span,
));
return (garbage_pipeline(spans), vec![]);
};
// Trying to warp the 'const' call into the 'export const' in a very clumsy way
if let Some(Expr::Call(def_call)) = pipeline.elements.first().map(|e| &e.expr.expr)
{
call.clone_from(def_call);
call.head = span(&spans[0..=1]);
call.decl_id = export_const_decl_id;
} else {
working_set.error(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
));
};
let mut result = vec![];
if let Some(var_name_span) = spans.get(2) {
let var_name = working_set.get_span_contents(*var_name_span);
let var_name = trim_quotes(var_name);
if let Some(var_id) = working_set.find_variable(var_name) {
if let Err(err) = working_set.get_constant(var_id) {
working_set.error(err);
} else {
result.push(Exportable::VarDecl {
name: var_name.to_vec(),
id: var_id,
});
}
} else {
working_set.error(ParseError::InternalError(
"failed to find added variable".into(),
span(&spans[1..]),
));
}
}
result
}
_ => {
working_set.error(ParseError::Expected(
"def, alias, use, module, const or extern keyword",
spans[1],
));
vec![]
}
}
} else {
working_set.error(ParseError::MissingPositional(
"def, alias, use, module, const or extern keyword".to_string(),
Span::new(export_span.end, export_span.end),
"def, alias, use, module, const or extern keyword".to_string(),
));
vec![]
};
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
exportables,
)
}
pub fn parse_export_env(
working_set: &mut StateWorkingSet,
spans: &[Span],
) -> (Pipeline, Option<BlockId>) {
if !spans.is_empty() && working_set.get_span_contents(spans[0]) != b"export-env" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'export-env' command".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
if spans.len() < 2 {
working_set.error(ParseError::MissingPositional(
"block".into(),
span(spans),
"export-env <block>".into(),
));
return (garbage_pipeline(spans), None);
}
let call = match working_set.find_decl(b"export-env") {
Some(decl_id) => {
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &[spans[1]], decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return (garbage_pipeline(spans), None);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
None,
);
}
call
}
None => {
working_set.error(ParseError::UnknownState(
"internal error: 'export-env' declaration not found".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
};
let block_id = if let Some(block) = call.positional_nth(0) {
if let Some(block_id) = block.as_block() {
block_id
} else {
working_set.error(ParseError::UnknownState(
"internal error: 'export-env' block is not a block".into(),
block.span,
));
return (garbage_pipeline(spans), None);
}
} else {
working_set.error(ParseError::UnknownState(
"internal error: 'export-env' block is missing".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
(pipeline, Some(block_id))
}
fn collect_first_comments(tokens: &[Token]) -> Vec<Span> {
let mut comments = vec![];
let mut tokens_iter = tokens.iter().peekable();
while let Some(token) = tokens_iter.next() {
match token.contents {
TokenContents::Comment => {
comments.push(token.span);
}
TokenContents::Eol => {
if let Some(Token {
contents: TokenContents::Eol,
..
}) = tokens_iter.peek()
{
if !comments.is_empty() {
break;
}
}
}
_ => {
comments.clear();
break;
}
}
}
comments
}
pub fn parse_module_block(
working_set: &mut StateWorkingSet,
span: Span,
module_name: &[u8],
) -> (Block, Module, Vec<Span>) {
working_set.enter_scope();
let source = working_set.get_span_contents(span);
let (output, err) = lex(source, span.start, &[], &[], false);
if let Some(err) = err {
working_set.error(err)
}
let module_comments = collect_first_comments(&output);
let (output, err) = lite_parse(&output);
if let Some(err) = err {
working_set.error(err)
}
for pipeline in &output.block {
if pipeline.commands.len() == 1 {
parse_def_predecl(working_set, &pipeline.commands[0].parts);
}
}
let mut module = Module::from_span(module_name.to_vec(), span);
let mut block = Block::new_with_capacity(output.block.len());
for pipeline in output.block.iter() {
if pipeline.commands.len() == 1 {
let command = &pipeline.commands[0];
let name = working_set.get_span_contents(command.parts[0]);
match name {
b"def" => {
block.pipelines.push(
parse_def(
working_set,
command,
None, // using commands named as the module locally is OK
)
.0,
)
}
b"const" => block
.pipelines
.push(parse_const(working_set, &command.parts)),
b"extern" => block
.pipelines
.push(parse_extern(working_set, command, None)),
b"alias" => {
block.pipelines.push(parse_alias(
working_set,
command,
None, // using aliases named as the module locally is OK
))
}
b"use" => {
let (pipeline, _) = parse_use(working_set, command);
block.pipelines.push(pipeline)
}
b"module" => {
let (pipeline, _) = parse_module(
working_set,
command,
None, // using modules named as the module locally is OK
);
block.pipelines.push(pipeline)
}
b"export" => {
let (pipe, exportables) =
parse_export_in_module(working_set, command, module_name);
for exportable in exportables {
match exportable {
Exportable::Decl { name, id } => {
if &name == b"main" {
if module.main.is_some() {
let err_span = if !pipe.elements.is_empty() {
if let Expr::Call(call) = &pipe.elements[0].expr.expr {
call.head
} else {
pipe.elements[0].expr.span
}
} else {
span
};
working_set.error(ParseError::ModuleDoubleMain(
String::from_utf8_lossy(module_name).to_string(),
err_span,
));
} else {
module.main = Some(id);
}
} else {
module.add_decl(name, id);
}
}
Exportable::Module { name, id } => {
if &name == b"mod" {
let (submodule_main, submodule_decls, submodule_submodules) = {
let submodule = working_set.get_module(id);
(submodule.main, submodule.decls(), submodule.submodules())
};
// Add submodule's decls to the parent module
for (decl_name, decl_id) in submodule_decls {
module.add_decl(decl_name, decl_id);
}
// Add submodule's main command to the parent module
if let Some(main_decl_id) = submodule_main {
if module.main.is_some() {
let err_span = if !pipe.elements.is_empty() {
if let Expr::Call(call) =
&pipe.elements[0].expr.expr
{
call.head
} else {
pipe.elements[0].expr.span
}
} else {
span
};
working_set.error(ParseError::ModuleDoubleMain(
String::from_utf8_lossy(module_name).to_string(),
err_span,
));
} else {
module.main = Some(main_decl_id);
}
}
// Add submodule's submodules to the parent module
for (submodule_name, submodule_id) in submodule_submodules {
module.add_submodule(submodule_name, submodule_id);
}
} else {
module.add_submodule(name, id);
}
}
Exportable::VarDecl { name, id } => {
module.add_variable(name, id);
}
}
}
block.pipelines.push(pipe)
}
b"export-env" => {
let (pipe, maybe_env_block) = parse_export_env(working_set, &command.parts);
if let Some(block_id) = maybe_env_block {
module.add_env_block(block_id);
}
block.pipelines.push(pipe)
}
_ => {
working_set.error(ParseError::ExpectedKeyword(
"def, const, extern, alias, use, module, export or export-env keyword"
.into(),
command.parts[0],
));
block.pipelines.push(garbage_pipeline(&command.parts))
}
}
} else {
working_set.error(ParseError::Expected("not a pipeline", span));
block.pipelines.push(garbage_pipeline(&[span]))
}
}
working_set.exit_scope();
(block, module, module_comments)
}
fn parse_module_file(
working_set: &mut StateWorkingSet,
path: ParserPath,
path_span: Span,
name_override: Option<String>,
) -> Option<ModuleId> {
if let Some(i) = working_set
.parsed_module_files
.iter()
.rposition(|p| p == path.path())
{
let mut files: Vec<String> = working_set
.parsed_module_files
.split_off(i)
.iter()
.map(|p| p.to_string_lossy().to_string())
.collect();
files.push(path.path().to_string_lossy().to_string());
let msg = files.join("\nuses ");
working_set.error(ParseError::CyclicalModuleImport(msg, path_span));
return None;
}
let module_name = if let Some(name) = name_override {
name
} else if let Some(stem) = path.file_stem() {
stem.to_string_lossy().to_string()
} else {
working_set.error(ParseError::ModuleNotFound(
path_span,
path.path().to_string_lossy().to_string(),
));
return None;
};
let contents = if let Some(contents) = path.read(working_set) {
contents
} else {
working_set.error(ParseError::ModuleNotFound(
path_span,
path.path().to_string_lossy().to_string(),
));
return None;
};
let file_id = working_set.add_file(path.path().to_string_lossy().to_string(), &contents);
let new_span = working_set.get_span_for_file(file_id);
if let Some(module_id) = working_set.find_module_by_span(new_span) {
return Some(module_id);
}
// Change the currently parsed directory
let prev_currently_parsed_cwd = if let Some(parent) = path.parent() {
working_set.currently_parsed_cwd.replace(parent.into())
} else {
working_set.currently_parsed_cwd.clone()
};
// Add the file to the stack of parsed module files
working_set.parsed_module_files.push(path.path_buf());
// Parse the module
let (block, module, module_comments) =
parse_module_block(working_set, new_span, module_name.as_bytes());
// Remove the file from the stack of parsed module files
working_set.parsed_module_files.pop();
// Restore the currently parsed directory back
working_set.currently_parsed_cwd = prev_currently_parsed_cwd;
let _ = working_set.add_block(Arc::new(block));
let module_id = working_set.add_module(&module_name, module, module_comments);
Some(module_id)
}
pub fn parse_module_file_or_dir(
working_set: &mut StateWorkingSet,
path: &[u8],
path_span: Span,
name_override: Option<String>,
) -> Option<ModuleId> {
let (module_path_str, err) = unescape_unquote_string(path, path_span);
if let Some(err) = err {
working_set.error(err);
return None;
}
let cwd = working_set.get_cwd();
let module_path =
if let Some(path) = find_in_dirs(&module_path_str, working_set, &cwd, LIB_DIRS_VAR) {
path
} else {
working_set.error(ParseError::ModuleNotFound(path_span, module_path_str));
return None;
};
if module_path.is_dir() {
if module_path.read_dir().is_none() {
working_set.error(ParseError::ModuleNotFound(
path_span,
module_path.path().to_string_lossy().to_string(),
));
return None;
};
let module_name = if let Some(stem) = module_path.file_stem() {
stem.to_string_lossy().to_string()
} else {
working_set.error(ParseError::ModuleNotFound(
path_span,
module_path.path().to_string_lossy().to_string(),
));
return None;
};
let mod_nu_path = module_path.clone().join("mod.nu");
if !(mod_nu_path.exists() && mod_nu_path.is_file()) {
working_set.error(ParseError::ModuleMissingModNuFile(
module_path.path().to_string_lossy().to_string(),
path_span,
));
return None;
}
if let Some(module_id) = parse_module_file(
working_set,
mod_nu_path,
path_span,
name_override.or(Some(module_name)),
) {
let module = working_set.get_module(module_id).clone();
let module_name = String::from_utf8_lossy(&module.name).to_string();
let module_comments = if let Some(comments) = working_set.get_module_comments(module_id)
{
comments.to_vec()
} else {
vec![]
};
let new_module_id = working_set.add_module(&module_name, module, module_comments);
Some(new_module_id)
} else {
None
}
} else if module_path.is_file() {
parse_module_file(working_set, module_path, path_span, name_override)
} else {
working_set.error(ParseError::ModuleNotFound(
path_span,
module_path.path().to_string_lossy().to_string(),
));
None
}
}
pub fn parse_module(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
module_name: Option<&[u8]>,
) -> (Pipeline, Option<ModuleId>) {
// TODO: Currently, module is closing over its parent scope (i.e., defs in the parent scope are
// visible and usable in this module's scope). We want to disable that for files.
let spans = &lite_command.parts;
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("module", redirection));
return (garbage_pipeline(spans), None);
}
let mut module_comments = lite_command.comments.clone();
let split_id = if spans.len() > 1 && working_set.get_span_contents(spans[0]) == b"export" {
2
} else {
1
};
let (call, call_span) = match working_set.find_decl(b"module") {
Some(decl_id) => {
let (command_spans, rest_spans) = spans.split_at(split_id);
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, span(command_spans), rest_spans, decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return (garbage_pipeline(spans), None);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
None,
);
}
(call, call_span)
}
None => {
working_set.error(ParseError::UnknownState(
"internal error: 'module' or 'export module' declaration not found".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
};
let (module_name_or_path, module_name_or_path_span, module_name_or_path_expr) =
if let Some(name) = call.positional_nth(0) {
if let Some(s) = name.as_string() {
if let Some(mod_name) = module_name {
if s.as_bytes() == mod_name {
working_set.error(ParseError::NamedAsModule(
"module".to_string(),
s,
"mod".to_string(),
name.span,
));
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
None,
);
}
}
(s, name.span, name.clone())
} else {
working_set.error(ParseError::UnknownState(
"internal error: name not a string".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
} else {
working_set.error(ParseError::UnknownState(
"internal error: missing positional".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
if spans.len() == split_id + 1 {
if let Some(module_id) = parse_module_file_or_dir(
working_set,
module_name_or_path.as_bytes(),
module_name_or_path_span,
None,
) {
return (pipeline, Some(module_id));
} else {
working_set.error(ParseError::ModuleNotFound(
module_name_or_path_span,
module_name_or_path,
));
return (pipeline, None);
}
}
if spans.len() < split_id + 2 {
working_set.error(ParseError::UnknownState(
"Expected structure: module <name> or module <name> <block>".into(),
span(spans),
));
return (garbage_pipeline(spans), None);
}
let module_name = module_name_or_path;
let block_span = spans[split_id + 1];
let block_bytes = working_set.get_span_contents(block_span);
let mut start = block_span.start;
let mut end = block_span.end;
if block_bytes.starts_with(b"{") {
start += 1;
} else {
working_set.error(ParseError::Expected("block", block_span));
return (garbage_pipeline(spans), None);
}
if block_bytes.ends_with(b"}") {
end -= 1;
} else {
working_set.error(ParseError::Unclosed("}".into(), Span::new(end, end)));
}
let block_span = Span::new(start, end);
let (block, module, inner_comments) =
parse_module_block(working_set, block_span, module_name.as_bytes());
let block_id = working_set.add_block(Arc::new(block));
module_comments.extend(inner_comments);
let module_id = working_set.add_module(&module_name, module, module_comments);
let block_expr = Expression {
expr: Expr::Block(block_id),
span: block_span,
ty: Type::Block,
custom_completion: None,
};
let module_decl_id = working_set
.find_decl(b"module")
.expect("internal error: missing module command");
let call = Box::new(Call {
head: span(&spans[..split_id]),
decl_id: module_decl_id,
arguments: vec![
Argument::Positional(module_name_or_path_expr),
Argument::Positional(block_expr),
],
parser_info: HashMap::new(),
});
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
Some(module_id),
)
}
pub fn parse_use(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
) -> (Pipeline, Vec<Exportable>) {
let spans = &lite_command.parts;
let (name_span, split_id) =
if spans.len() > 1 && working_set.get_span_contents(spans[0]) == b"export" {
(spans[1], 2)
} else {
(spans[0], 1)
};
let use_call = working_set.get_span_contents(name_span).to_vec();
if use_call != b"use" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'use' command".into(),
span(spans),
));
return (garbage_pipeline(spans), vec![]);
}
if working_set.get_span_contents(name_span) != b"use" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'use' command".into(),
span(spans),
));
return (garbage_pipeline(spans), vec![]);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("use", redirection));
return (garbage_pipeline(spans), vec![]);
}
let (call, call_span, args_spans) = match working_set.find_decl(b"use") {
Some(decl_id) => {
let (command_spans, rest_spans) = spans.split_at(split_id);
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, span(command_spans), rest_spans, decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return (garbage_pipeline(spans), vec![]);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
vec![],
);
}
(call, call_span, rest_spans)
}
None => {
working_set.error(ParseError::UnknownState(
"internal error: 'use' declaration not found".into(),
span(spans),
));
return (garbage_pipeline(spans), vec![]);
}
};
let import_pattern_expr = parse_import_pattern(working_set, args_spans);
let import_pattern = if let Expression {
expr: Expr::ImportPattern(import_pattern),
..
} = &import_pattern_expr
{
import_pattern.clone()
} else {
working_set.error(ParseError::UnknownState(
"internal error: Import pattern positional is not import pattern".into(),
import_pattern_expr.span,
));
return (garbage_pipeline(spans), vec![]);
};
let (mut import_pattern, module, module_id) = if let Some(module_id) = import_pattern.head.id {
let module = working_set.get_module(module_id).clone();
(
ImportPattern {
head: ImportPatternHead {
name: module.name.clone(),
id: Some(module_id),
span: import_pattern.head.span,
},
members: import_pattern.members,
hidden: HashSet::new(),
constants: vec![],
},
module,
module_id,
)
} else if let Some(module_id) = parse_module_file_or_dir(
working_set,
&import_pattern.head.name,
import_pattern.head.span,
None,
) {
let module = working_set.get_module(module_id).clone();
(
ImportPattern {
head: ImportPatternHead {
name: module.name.clone(),
id: Some(module_id),
span: import_pattern.head.span,
},
members: import_pattern.members,
hidden: HashSet::new(),
constants: vec![],
},
module,
module_id,
)
} else {
working_set.error(ParseError::ModuleNotFound(
import_pattern.head.span,
String::from_utf8_lossy(&import_pattern.head.name).to_string(),
));
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
vec![],
);
};
let (definitions, errors) = module.resolve_import_pattern(
working_set,
module_id,
&import_pattern.members,
None,
name_span,
);
working_set.parse_errors.extend(errors);
let mut constants = vec![];
for (name, const_val) in definitions.constants {
let const_var_id =
working_set.add_variable(name.clone(), name_span, const_val.get_type(), false);
working_set.set_variable_const_val(const_var_id, const_val);
constants.push((name, const_var_id));
}
let exportables = definitions
.decls
.iter()
.map(|(name, decl_id)| Exportable::Decl {
name: name.clone(),
id: *decl_id,
})
.chain(
definitions
.modules
.iter()
.map(|(name, module_id)| Exportable::Module {
name: name.clone(),
id: *module_id,
}),
)
.chain(
constants
.iter()
.map(|(name, variable_id)| Exportable::VarDecl {
name: name.clone(),
id: *variable_id,
}),
)
.collect();
import_pattern.constants = constants.iter().map(|(_, id)| *id).collect();
// Extend the current scope with the module's exportables
working_set.use_decls(definitions.decls);
working_set.use_modules(definitions.modules);
working_set.use_variables(constants);
// Create a new Use command call to pass the import pattern as parser info
let import_pattern_expr = Expression {
expr: Expr::ImportPattern(import_pattern),
span: span(args_spans),
ty: Type::Any,
custom_completion: None,
};
let mut call = call;
call.set_parser_info("import_pattern".to_string(), import_pattern_expr);
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
exportables,
)
}
pub fn parse_hide(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Pipeline {
let spans = &lite_command.parts;
if working_set.get_span_contents(spans[0]) != b"hide" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'hide' command".into(),
span(spans),
));
return garbage_pipeline(spans);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("hide", redirection));
return garbage_pipeline(spans);
}
let (call, args_spans) = match working_set.find_decl(b"hide") {
Some(decl_id) => {
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage_pipeline(spans);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]);
}
(call, &spans[1..])
}
None => {
working_set.error(ParseError::UnknownState(
"internal error: 'hide' declaration not found".into(),
span(spans),
));
return garbage_pipeline(spans);
}
};
let import_pattern_expr = parse_import_pattern(working_set, args_spans);
let import_pattern = if let Expression {
expr: Expr::ImportPattern(import_pattern),
..
} = &import_pattern_expr
{
import_pattern.clone()
} else {
working_set.error(ParseError::UnknownState(
"internal error: Import pattern positional is not import pattern".into(),
import_pattern_expr.span,
));
return garbage_pipeline(spans);
};
let bytes = working_set.get_span_contents(spans[0]);
if bytes == b"hide" && spans.len() >= 2 {
for span in spans[1..].iter() {
parse_string(working_set, *span);
}
// module used only internally, not saved anywhere
let (is_module, module) =
if let Some(module_id) = working_set.find_module(&import_pattern.head.name) {
(true, working_set.get_module(module_id).clone())
} else if import_pattern.members.is_empty() {
// The pattern head can be:
if let Some(id) = working_set.find_decl(&import_pattern.head.name) {
// a custom command,
let mut module = Module::new(b"tmp".to_vec());
module.add_decl(import_pattern.head.name.clone(), id);
(false, module)
} else {
// , or it could be an env var (handled by the engine)
(false, Module::new(b"tmp".to_vec()))
}
} else {
working_set.error(ParseError::ModuleNotFound(
spans[1],
String::from_utf8_lossy(&import_pattern.head.name).to_string(),
));
return garbage_pipeline(spans);
};
// This kind of inverts the import pattern matching found in parse_use()
let decls_to_hide = if import_pattern.members.is_empty() {
if is_module {
module.decl_names_with_head(&import_pattern.head.name)
} else {
module.decl_names()
}
} else {
match &import_pattern.members[0] {
ImportPatternMember::Glob { .. } => module.decl_names(),
ImportPatternMember::Name { name, span } => {
let mut decls = vec![];
if name == b"main" {
if module.main.is_some() {
decls.push(import_pattern.head.name.clone());
} else {
working_set.error(ParseError::ExportNotFound(*span));
}
} else if let Some(item) =
module.decl_name_with_head(name, &import_pattern.head.name)
{
decls.push(item);
} else {
working_set.error(ParseError::ExportNotFound(*span));
}
decls
}
ImportPatternMember::List { names } => {
let mut decls = vec![];
for (name, span) in names {
if name == b"main" {
if module.main.is_some() {
decls.push(import_pattern.head.name.clone());
} else {
working_set.error(ParseError::ExportNotFound(*span));
break;
}
} else if let Some(item) =
module.decl_name_with_head(name, &import_pattern.head.name)
{
decls.push(item);
} else {
working_set.error(ParseError::ExportNotFound(*span));
break;
}
}
decls
}
}
};
let import_pattern = {
let decls: HashSet<Vec<u8>> = decls_to_hide.iter().cloned().collect();
import_pattern.with_hidden(decls)
};
// TODO: `use spam; use spam foo; hide foo` will hide both `foo` and `spam foo` since
// they point to the same DeclId. Do we want to keep it that way?
working_set.hide_decls(&decls_to_hide);
// Create a new Use command call to pass the new import pattern
let import_pattern_expr = Expression {
expr: Expr::ImportPattern(import_pattern),
span: span(args_spans),
ty: Type::Any,
custom_completion: None,
};
let mut call = call;
call.set_parser_info("import_pattern".to_string(), import_pattern_expr);
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}])
} else {
working_set.error(ParseError::UnknownState(
"Expected structure: hide <name>".into(),
span(spans),
));
garbage_pipeline(spans)
}
}
pub fn parse_overlay_new(working_set: &mut StateWorkingSet, call: Box<Call>) -> Pipeline {
let call_span = call.span();
let (overlay_name, _) = if let Some(expr) = call.positional_nth(0) {
match eval_constant(working_set, expr) {
Ok(val) => match val.coerce_into_string() {
Ok(s) => (s, expr.span),
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
},
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
}
} else {
working_set.error(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
));
return garbage_pipeline(&[call_span]);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
let module_id = working_set.add_module(
&overlay_name,
Module::new(overlay_name.as_bytes().to_vec()),
vec![],
);
working_set.add_overlay(
overlay_name.as_bytes().to_vec(),
module_id,
vec![],
vec![],
false,
);
pipeline
}
pub fn parse_overlay_use(working_set: &mut StateWorkingSet, call: Box<Call>) -> Pipeline {
let call_span = call.span();
let (overlay_name, overlay_name_span) = if let Some(expr) = call.positional_nth(0) {
match eval_constant(working_set, expr) {
Ok(val) => match val.coerce_into_string() {
Ok(s) => (s, expr.span),
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
},
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
}
} else {
working_set.error(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
));
return garbage_pipeline(&[call_span]);
};
let new_name = if let Some(kw_expression) = call.positional_nth(1) {
if let Some(new_name_expression) = kw_expression.as_keyword() {
match eval_constant(working_set, new_name_expression) {
Ok(val) => match val.coerce_into_string() {
Ok(s) => Some(Spanned {
item: s,
span: new_name_expression.span,
}),
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
},
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
}
} else {
working_set.error(ParseError::ExpectedKeyword(
"as keyword".to_string(),
kw_expression.span,
));
return garbage_pipeline(&[call_span]);
}
} else {
None
};
let Ok(has_prefix) = has_flag_const(working_set, &call, "prefix") else {
return garbage_pipeline(&[call_span]);
};
let Ok(do_reload) = has_flag_const(working_set, &call, "reload") else {
return garbage_pipeline(&[call_span]);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call.clone()),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
let (final_overlay_name, origin_module, origin_module_id, is_module_updated) =
if let Some(overlay_frame) = working_set.find_overlay(overlay_name.as_bytes()) {
// Activate existing overlay
// First, check for errors
if has_prefix && !overlay_frame.prefixed {
working_set.error(ParseError::OverlayPrefixMismatch(
overlay_name,
"without".to_string(),
overlay_name_span,
));
return pipeline;
}
if !has_prefix && overlay_frame.prefixed {
working_set.error(ParseError::OverlayPrefixMismatch(
overlay_name,
"with".to_string(),
overlay_name_span,
));
return pipeline;
}
if let Some(new_name) = new_name {
if new_name.item != overlay_name {
working_set.error(ParseError::CantAddOverlayHelp(
format!(
"Cannot add overlay as '{}' because it already exists under the name '{}'",
new_name.item, overlay_name
),
new_name.span,
));
return pipeline;
}
}
let module_id = overlay_frame.origin;
if let Some(new_module_id) = working_set.find_module(overlay_name.as_bytes()) {
if !do_reload && (module_id == new_module_id) {
(
overlay_name,
Module::new(working_set.get_module(module_id).name.clone()),
module_id,
false,
)
} else {
// The origin module of an overlay changed => update it
(
overlay_name,
working_set.get_module(new_module_id).clone(),
new_module_id,
true,
)
}
} else {
let module_name = overlay_name.as_bytes().to_vec();
(overlay_name, Module::new(module_name), module_id, true)
}
} else {
// Create a new overlay
if let Some(module_id) =
// the name is a module
working_set.find_module(overlay_name.as_bytes())
{
(
new_name.map(|spanned| spanned.item).unwrap_or(overlay_name),
working_set.get_module(module_id).clone(),
module_id,
true,
)
} else if let Some(module_id) = parse_module_file_or_dir(
working_set,
overlay_name.as_bytes(),
overlay_name_span,
new_name.as_ref().map(|spanned| spanned.item.clone()),
) {
// try file or directory
let new_module = working_set.get_module(module_id).clone();
(
new_name
.map(|spanned| spanned.item)
.unwrap_or_else(|| String::from_utf8_lossy(&new_module.name).to_string()),
new_module,
module_id,
true,
)
} else {
working_set.error(ParseError::ModuleOrOverlayNotFound(overlay_name_span));
return pipeline;
}
};
let (definitions, errors) = if is_module_updated {
if has_prefix {
origin_module.resolve_import_pattern(
working_set,
origin_module_id,
&[],
Some(final_overlay_name.as_bytes()),
call.head,
)
} else {
origin_module.resolve_import_pattern(
working_set,
origin_module_id,
&[ImportPatternMember::Glob {
span: overlay_name_span,
}],
Some(final_overlay_name.as_bytes()),
call.head,
)
}
} else {
(ResolvedImportPattern::new(vec![], vec![], vec![]), vec![])
};
if errors.is_empty() {
working_set.add_overlay(
final_overlay_name.as_bytes().to_vec(),
origin_module_id,
definitions.decls,
definitions.modules,
has_prefix,
);
} else {
working_set.parse_errors.extend(errors);
}
// Change the call argument to include the Overlay expression with the module ID
let mut call = call;
call.set_parser_info(
"overlay_expr".to_string(),
Expression {
expr: Expr::Overlay(if is_module_updated {
Some(origin_module_id)
} else {
None
}),
span: overlay_name_span,
ty: Type::Any,
custom_completion: None,
},
);
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}])
}
pub fn parse_overlay_hide(working_set: &mut StateWorkingSet, call: Box<Call>) -> Pipeline {
let call_span = call.span();
let (overlay_name, overlay_name_span) = if let Some(expr) = call.positional_nth(0) {
match eval_constant(working_set, expr) {
Ok(val) => match val.coerce_into_string() {
Ok(s) => (s, expr.span),
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
},
Err(err) => {
working_set.error(err.wrap(working_set, call_span));
return garbage_pipeline(&[call_span]);
}
}
} else {
(
String::from_utf8_lossy(working_set.last_overlay_name()).to_string(),
call_span,
)
};
let Ok(keep_custom) = has_flag_const(working_set, &call, "keep-custom") else {
return garbage_pipeline(&[call_span]);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
if overlay_name == DEFAULT_OVERLAY_NAME {
working_set.error(ParseError::CantHideDefaultOverlay(
overlay_name,
overlay_name_span,
));
return pipeline;
}
if !working_set
.unique_overlay_names()
.contains(&overlay_name.as_bytes())
{
working_set.error(ParseError::ActiveOverlayNotFound(overlay_name_span));
return pipeline;
}
if working_set.num_overlays() < 2 {
working_set.error(ParseError::CantRemoveLastOverlay(overlay_name_span));
return pipeline;
}
working_set.remove_overlay(overlay_name.as_bytes(), keep_custom);
pipeline
}
pub fn parse_let(working_set: &mut StateWorkingSet, spans: &[Span]) -> Pipeline {
trace!("parsing: let");
// JT: Disabling check_name because it doesn't work with optional types in the declaration
// if let Some(span) = check_name(working_set, spans) {
// return Pipeline::from_vec(vec![garbage(*span)]);
// }
if let Some(decl_id) = working_set.find_decl(b"let") {
if spans.len() >= 4 {
// This is a bit of by-hand parsing to get around the issue where we want to parse in the reverse order
// so that the var-id created by the variable isn't visible in the expression that init it
for span in spans.iter().enumerate() {
let item = working_set.get_span_contents(*span.1);
// https://github.com/nushell/nushell/issues/9596, let = if $
// let x = 'f', = at least start from index 2
if item == b"=" && spans.len() > (span.0 + 1) && span.0 > 1 {
let (tokens, parse_error) = lex(
working_set.get_span_contents(nu_protocol::span(&spans[(span.0 + 1)..])),
spans[span.0 + 1].start,
&[],
&[],
true,
);
if let Some(parse_error) = parse_error {
working_set.parse_errors.push(parse_error)
}
let rvalue_span = nu_protocol::span(&spans[(span.0 + 1)..]);
let rvalue_block = parse_block(working_set, &tokens, rvalue_span, false, true);
let output_type = rvalue_block.output_type();
let block_id = working_set.add_block(Arc::new(rvalue_block));
let rvalue = Expression {
expr: Expr::Block(block_id),
span: rvalue_span,
ty: output_type,
custom_completion: None,
};
let mut idx = 0;
let (lvalue, explicit_type) =
parse_var_with_opt_type(working_set, &spans[1..(span.0)], &mut idx, false);
// check for extra tokens after the identifier
if idx + 1 < span.0 - 1 {
working_set.error(ParseError::ExtraTokens(spans[idx + 2]));
}
let var_name =
String::from_utf8_lossy(working_set.get_span_contents(lvalue.span))
.trim_start_matches('$')
.to_string();
if RESERVED_VARIABLE_NAMES.contains(&var_name.as_str()) {
working_set.error(ParseError::NameIsBuiltinVar(var_name, lvalue.span))
}
let var_id = lvalue.as_var();
let rhs_type = rvalue.ty.clone();
if let Some(explicit_type) = &explicit_type {
if !type_compatible(explicit_type, &rhs_type) {
working_set.error(ParseError::TypeMismatch(
explicit_type.clone(),
rhs_type.clone(),
nu_protocol::span(&spans[(span.0 + 1)..]),
));
}
}
if let Some(var_id) = var_id {
if explicit_type.is_none() {
working_set.set_variable_type(var_id, rhs_type);
}
}
let call = Box::new(Call {
decl_id,
head: spans[0],
arguments: vec![Argument::Positional(lvalue), Argument::Positional(rvalue)],
parser_info: HashMap::new(),
});
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: Type::Any,
custom_completion: None,
}]);
}
}
}
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: output,
custom_completion: None,
}]);
} else {
working_set.error(ParseError::UnknownState(
"internal error: let or const statements not found in core language".into(),
span(spans),
))
}
working_set.error(ParseError::UnknownState(
"internal error: let or const statement unparsable".into(),
span(spans),
));
garbage_pipeline(spans)
}
pub fn parse_const(working_set: &mut StateWorkingSet, spans: &[Span]) -> Pipeline {
trace!("parsing: const");
// JT: Disabling check_name because it doesn't work with optional types in the declaration
// if let Some(span) = check_name(working_set, spans) {
// return Pipeline::from_vec(vec![garbage(*span)]);
// }
if let Some(decl_id) = working_set.find_decl(b"const") {
let cmd = working_set.get_decl(decl_id);
let call_signature = cmd.signature().call_signature();
if spans.len() >= 4 {
// This is a bit of by-hand parsing to get around the issue where we want to parse in the reverse order
// so that the var-id created by the variable isn't visible in the expression that init it
for span in spans.iter().enumerate() {
let item = working_set.get_span_contents(*span.1);
// const x = 'f', = at least start from index 2
if item == b"=" && spans.len() > (span.0 + 1) && span.0 > 1 {
let mut idx = span.0;
let rvalue = parse_multispan_value(
working_set,
spans,
&mut idx,
&SyntaxShape::Keyword(b"=".to_vec(), Box::new(SyntaxShape::MathExpression)),
);
if idx < (spans.len() - 1) {
working_set
.error(ParseError::ExtraPositional(call_signature, spans[idx + 1]));
}
let mut idx = 0;
let (lvalue, explicit_type) =
parse_var_with_opt_type(working_set, &spans[1..(span.0)], &mut idx, false);
// check for extra tokens after the identifier
if idx + 1 < span.0 - 1 {
working_set.error(ParseError::ExtraTokens(spans[idx + 2]));
}
let var_name =
String::from_utf8_lossy(working_set.get_span_contents(lvalue.span))
.trim_start_matches('$')
.to_string();
if RESERVED_VARIABLE_NAMES.contains(&var_name.as_str()) {
working_set.error(ParseError::NameIsBuiltinVar(var_name, lvalue.span))
}
let var_id = lvalue.as_var();
let rhs_type = rvalue.ty.clone();
if let Some(explicit_type) = &explicit_type {
if !type_compatible(explicit_type, &rhs_type) {
working_set.error(ParseError::TypeMismatch(
explicit_type.clone(),
rhs_type.clone(),
nu_protocol::span(&spans[(span.0 + 1)..]),
));
}
}
if let Some(var_id) = var_id {
if explicit_type.is_none() {
working_set.set_variable_type(var_id, rhs_type);
}
match eval_constant(working_set, &rvalue) {
Ok(mut value) => {
// In case rhs is parsed as 'any' but is evaluated to a concrete
// type:
let mut const_type = value.get_type();
if let Some(explicit_type) = &explicit_type {
if !type_compatible(explicit_type, &const_type) {
working_set.error(ParseError::TypeMismatch(
explicit_type.clone(),
const_type.clone(),
nu_protocol::span(&spans[(span.0 + 1)..]),
));
}
let val_span = value.span();
// need to convert to Value::glob if rhs is string, and
// the const variable is annotated with glob type.
match value {
Value::String { val, .. }
if explicit_type == &Type::Glob =>
{
value = Value::glob(val, false, val_span);
const_type = value.get_type();
}
_ => {}
}
}
working_set.set_variable_type(var_id, const_type);
// Assign the constant value to the variable
working_set.set_variable_const_val(var_id, value);
}
Err(err) => working_set.error(err.wrap(working_set, rvalue.span)),
}
}
let call = Box::new(Call {
decl_id,
head: spans[0],
arguments: vec![Argument::Positional(lvalue), Argument::Positional(rvalue)],
parser_info: HashMap::new(),
});
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: Type::Any,
custom_completion: None,
}]);
}
}
}
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: output,
custom_completion: None,
}]);
} else {
working_set.error(ParseError::UnknownState(
"internal error: let or const statements not found in core language".into(),
span(spans),
))
}
working_set.error(ParseError::UnknownState(
"internal error: let or const statement unparsable".into(),
span(spans),
));
garbage_pipeline(spans)
}
pub fn parse_mut(working_set: &mut StateWorkingSet, spans: &[Span]) -> Pipeline {
trace!("parsing: mut");
// JT: Disabling check_name because it doesn't work with optional types in the declaration
// if let Some(span) = check_name(working_set, spans) {
// return Pipeline::from_vec(vec![garbage(*span)]);
// }
if let Some(decl_id) = working_set.find_decl(b"mut") {
if spans.len() >= 4 {
// This is a bit of by-hand parsing to get around the issue where we want to parse in the reverse order
// so that the var-id created by the variable isn't visible in the expression that init it
for span in spans.iter().enumerate() {
let item = working_set.get_span_contents(*span.1);
// mut x = 'f', = at least start from index 2
if item == b"=" && spans.len() > (span.0 + 1) && span.0 > 1 {
let (tokens, parse_error) = lex(
working_set.get_span_contents(nu_protocol::span(&spans[(span.0 + 1)..])),
spans[span.0 + 1].start,
&[],
&[],
true,
);
if let Some(parse_error) = parse_error {
working_set.parse_errors.push(parse_error)
}
let rvalue_span = nu_protocol::span(&spans[(span.0 + 1)..]);
let rvalue_block = parse_block(working_set, &tokens, rvalue_span, false, true);
let output_type = rvalue_block.output_type();
let block_id = working_set.add_block(Arc::new(rvalue_block));
let rvalue = Expression {
expr: Expr::Block(block_id),
span: rvalue_span,
ty: output_type,
custom_completion: None,
};
let mut idx = 0;
let (lvalue, explicit_type) =
parse_var_with_opt_type(working_set, &spans[1..(span.0)], &mut idx, true);
// check for extra tokens after the identifier
if idx + 1 < span.0 - 1 {
working_set.error(ParseError::ExtraTokens(spans[idx + 2]));
}
let var_name =
String::from_utf8_lossy(working_set.get_span_contents(lvalue.span))
.trim_start_matches('$')
.to_string();
if RESERVED_VARIABLE_NAMES.contains(&var_name.as_str()) {
working_set.error(ParseError::NameIsBuiltinVar(var_name, lvalue.span))
}
let var_id = lvalue.as_var();
let rhs_type = rvalue.ty.clone();
if let Some(explicit_type) = &explicit_type {
if !type_compatible(explicit_type, &rhs_type) {
working_set.error(ParseError::TypeMismatch(
explicit_type.clone(),
rhs_type.clone(),
nu_protocol::span(&spans[(span.0 + 1)..]),
));
}
}
if let Some(var_id) = var_id {
if explicit_type.is_none() {
working_set.set_variable_type(var_id, rhs_type);
}
}
let call = Box::new(Call {
decl_id,
head: spans[0],
arguments: vec![Argument::Positional(lvalue), Argument::Positional(rvalue)],
parser_info: HashMap::new(),
});
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: Type::Any,
custom_completion: None,
}]);
}
}
}
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: output,
custom_completion: None,
}]);
} else {
working_set.error(ParseError::UnknownState(
"internal error: let or const statements not found in core language".into(),
span(spans),
))
}
working_set.error(ParseError::UnknownState(
"internal error: let or const statement unparsable".into(),
span(spans),
));
garbage_pipeline(spans)
}
pub fn parse_source(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Pipeline {
let spans = &lite_command.parts;
let name = working_set.get_span_contents(spans[0]);
if name == b"source" || name == b"source-env" {
if let Some(redirection) = lite_command.redirection.as_ref() {
let name = if name == b"source" {
"source"
} else {
"source-env"
};
working_set.error(redirecting_builtin_error(name, redirection));
return garbage_pipeline(spans);
}
let scoped = name == b"source-env";
if let Some(decl_id) = working_set.find_decl(name) {
let cwd = working_set.get_cwd();
// Is this the right call to be using here?
// Some of the others (`parse_let`) use it, some of them (`parse_hide`) don't.
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage_pipeline(spans);
};
if is_help {
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: output,
custom_completion: None,
}]);
}
// Command and one file name
if spans.len() >= 2 {
let expr = parse_value(working_set, spans[1], &SyntaxShape::Any);
let val = match eval_constant(working_set, &expr) {
Ok(val) => val,
Err(err) => {
working_set.error(err.wrap(working_set, span(&spans[1..])));
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(&spans[1..]),
ty: Type::Any,
custom_completion: None,
}]);
}
};
let filename = match val.coerce_into_string() {
Ok(s) => s,
Err(err) => {
working_set.error(err.wrap(working_set, span(&spans[1..])));
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(&spans[1..]),
ty: Type::Any,
custom_completion: None,
}]);
}
};
if let Some(path) = find_in_dirs(&filename, working_set, &cwd, LIB_DIRS_VAR) {
if let Some(contents) = path.read(working_set) {
// Change currently parsed directory
let prev_currently_parsed_cwd = if let Some(parent) = path.parent() {
working_set.currently_parsed_cwd.replace(parent.into())
} else {
working_set.currently_parsed_cwd.clone()
};
// This will load the defs from the file into the
// working set, if it was a successful parse.
let block = parse(
working_set,
Some(&path.path().to_string_lossy()),
&contents,
scoped,
);
// Restore the currently parsed directory back
working_set.currently_parsed_cwd = prev_currently_parsed_cwd;
// Save the block into the working set
let block_id = working_set.add_block(block);
let mut call_with_block = call;
// FIXME: Adding this expression to the positional creates a syntax highlighting error
// after writing `source example.nu`
call_with_block.set_parser_info(
"block_id".to_string(),
Expression {
expr: Expr::Int(block_id as i64),
span: spans[1],
ty: Type::Any,
custom_completion: None,
},
);
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call_with_block),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
}
} else {
working_set.error(ParseError::SourcedFileNotFound(filename, spans[1]));
}
}
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
}
}
working_set.error(ParseError::UnknownState(
"internal error: source statement unparsable".into(),
span(spans),
));
garbage_pipeline(spans)
}
pub fn parse_where_expr(working_set: &mut StateWorkingSet, spans: &[Span]) -> Expression {
trace!("parsing: where");
if !spans.is_empty() && working_set.get_span_contents(spans[0]) != b"where" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for 'where' command".into(),
span(spans),
));
return garbage(span(spans));
}
if spans.len() < 2 {
working_set.error(ParseError::MissingPositional(
"row condition".into(),
span(spans),
"where <row_condition>".into(),
));
return garbage(span(spans));
}
let call = match working_set.find_decl(b"where") {
Some(decl_id) => {
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage(span(spans));
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
};
}
call
}
None => {
working_set.error(ParseError::UnknownState(
"internal error: 'where' declaration not found".into(),
span(spans),
));
return garbage(span(spans));
}
};
Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}
}
pub fn parse_where(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Pipeline {
let expr = parse_where_expr(working_set, &lite_command.parts);
let redirection = lite_command
.redirection
.as_ref()
.map(|r| parse_redirection(working_set, r));
let element = PipelineElement {
pipe: None,
expr,
redirection,
};
Pipeline {
elements: vec![element],
}
}
#[cfg(feature = "plugin")]
pub fn parse_register(working_set: &mut StateWorkingSet, lite_command: &LiteCommand) -> Pipeline {
use nu_plugin::{get_signature, PersistentPlugin, PluginDeclaration};
use nu_protocol::{
engine::Stack, IntoSpanned, PluginIdentity, PluginSignature, RegisteredPlugin,
};
let spans = &lite_command.parts;
let cwd = working_set.get_cwd();
// Checking that the function is used with the correct name
// Maybe this is not necessary but it is a sanity check
if working_set.get_span_contents(spans[0]) != b"register" {
working_set.error(ParseError::UnknownState(
"internal error: Wrong call name for parse plugin function".into(),
span(spans),
));
return garbage_pipeline(spans);
}
if let Some(redirection) = lite_command.redirection.as_ref() {
working_set.error(redirecting_builtin_error("register", redirection));
return garbage_pipeline(spans);
}
// Parsing the spans and checking that they match the register signature
// Using a parsed call makes more sense than checking for how many spans are in the call
// Also, by creating a call, it can be checked if it matches the declaration signature
let (call, call_span) = match working_set.find_decl(b"register") {
None => {
working_set.error(ParseError::UnknownState(
"internal error: Register declaration not found".into(),
span(spans),
));
return garbage_pipeline(spans);
}
Some(decl_id) => {
let ParsedInternalCall { call, output } =
parse_internal_call(working_set, spans[0], &spans[1..], decl_id);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
let starting_error_count = working_set.parse_errors.len();
check_call(working_set, call_span, &decl.signature(), &call);
let Ok(is_help) = has_flag_const(working_set, &call, "help") else {
return garbage_pipeline(spans);
};
if starting_error_count != working_set.parse_errors.len() || is_help {
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]);
}
(call, call_span)
}
};
// Extracting the required arguments from the call and keeping them together in a tuple
let arguments = call
.positional_nth(0)
.map(|expr| {
let val =
eval_constant(working_set, expr).map_err(|err| err.wrap(working_set, call.head))?;
let filename = val
.coerce_into_string()
.map_err(|err| err.wrap(working_set, call.head))?;
let Some(path) = find_in_dirs(&filename, working_set, &cwd, PLUGIN_DIRS_VAR) else {
return Err(ParseError::RegisteredFileNotFound(filename, expr.span));
};
if path.exists() && path.is_file() {
Ok((path, expr.span))
} else {
Err(ParseError::RegisteredFileNotFound(filename, expr.span))
}
})
.expect("required positional has being checked");
// Signature is an optional value from the call and will be used to decide if
// the plugin is called to get the signatures or to use the given signature
let signature = call.positional_nth(1).map(|expr| {
let signature = working_set.get_span_contents(expr.span);
serde_json::from_slice::<PluginSignature>(signature).map_err(|e| {
ParseError::LabeledError(
"Signature deserialization error".into(),
format!("unable to deserialize signature: {e}"),
spans[0],
)
})
});
// Shell is another optional value used as base to call shell to plugins
let shell = call.get_flag_expr("shell").map(|expr| {
let shell_expr = working_set.get_span_contents(expr.span);
String::from_utf8(shell_expr.to_vec())
.map_err(|_| ParseError::NonUtf8(expr.span))
.and_then(|name| {
canonicalize_with(&name, cwd)
.map_err(|_| ParseError::RegisteredFileNotFound(name, expr.span))
})
.and_then(|path| {
if path.exists() & path.is_file() {
Ok(path)
} else {
Err(ParseError::RegisteredFileNotFound(
format!("{path:?}"),
expr.span,
))
}
})
});
let shell = match shell {
None => None,
Some(path) => match path {
Ok(path) => Some(path),
Err(err) => {
working_set.error(err);
return Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]);
}
},
};
// We need the current environment variables for `python` based plugins
// Or we'll likely have a problem when a plugin is implemented in a virtual Python environment.
let get_envs = || {
let stack = Stack::new().capture();
nu_engine::env::env_to_strings(working_set.permanent_state, &stack)
};
let error = arguments.and_then(|(path, path_span)| {
let path = path.path_buf();
// Create the plugin identity. This validates that the plugin name starts with `nu_plugin_`
let identity =
PluginIdentity::new(path, shell).map_err(|err| err.into_spanned(path_span))?;
// Find garbage collection config
let gc_config = working_set
.get_config()
.plugin_gc
.get(identity.name())
.clone();
// Add it to the working set
let plugin = working_set.find_or_create_plugin(&identity, || {
Arc::new(PersistentPlugin::new(identity.clone(), gc_config))
});
// Downcast the plugin to `PersistentPlugin` - we generally expect this to succeed. The
// trait object only exists so that nu-protocol can contain plugins without knowing anything
// about their implementation, but we only use `PersistentPlugin` in practice.
let plugin: Arc<PersistentPlugin> = plugin.as_any().downcast().map_err(|_| {
ParseError::InternalError(
"encountered unexpected RegisteredPlugin type".into(),
spans[0],
)
})?;
let signatures = signature.map_or_else(
|| {
// It's important that the plugin is restarted if we're going to get signatures
//
// The user would expect that `register` would always run the binary to get new
// signatures, in case it was replaced with an updated binary
plugin.stop().map_err(|err| {
ParseError::LabeledError(
"Failed to restart plugin to get new signatures".into(),
err.to_string(),
spans[0],
)
})?;
let signatures = get_signature(plugin.clone(), get_envs).map_err(|err| {
ParseError::LabeledError(
"Error getting signatures".into(),
err.to_string(),
spans[0],
)
});
if signatures.is_ok() {
// mark plugins file as dirty only when the user is registering plugins
// and not when we evaluate plugin.nu on shell startup
working_set.mark_plugins_file_dirty();
}
signatures
},
|sig| sig.map(|sig| vec![sig]),
)?;
for signature in signatures {
// create plugin command declaration (need struct impl Command)
// store declaration in working set
let plugin_decl = PluginDeclaration::new(plugin.clone(), signature);
working_set.add_decl(Box::new(plugin_decl));
}
Ok(())
});
if let Err(err) = error {
working_set.error(err);
}
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Nothing,
custom_completion: None,
}])
}
pub fn find_dirs_var(working_set: &StateWorkingSet, var_name: &str) -> Option<VarId> {
working_set
.find_variable(format!("${}", var_name).as_bytes())
.filter(|var_id| working_set.get_variable(*var_id).const_val.is_some())
}
/// This helper function is used to find files during parsing
///
/// First, the actual current working directory is selected as
/// a) the directory of a file currently being parsed
/// b) current working directory (PWD)
///
/// Then, if the file is not found in the actual cwd, dirs_var is checked.
/// For now, we first check for a const with the name of `dirs_var_name`,
/// and if that's not found, then we try to look for an environment variable of the same name.
/// If there is a relative path in dirs_var, it is assumed to be relative to the actual cwd
/// determined in the first step.
///
/// Always returns an absolute path
pub fn find_in_dirs(
filename: &str,
working_set: &StateWorkingSet,
cwd: &str,
dirs_var_name: &str,
) -> Option<ParserPath> {
pub fn find_in_dirs_with_id(
filename: &str,
working_set: &StateWorkingSet,
cwd: &str,
dirs_var_name: &str,
) -> Option<ParserPath> {
// Choose whether to use file-relative or PWD-relative path
let actual_cwd = if let Some(currently_parsed_cwd) = &working_set.currently_parsed_cwd {
currently_parsed_cwd.as_path()
} else {
Path::new(cwd)
};
// Try if we have an existing virtual path
if let Some(virtual_path) = working_set.find_virtual_path(filename) {
return Some(ParserPath::from_virtual_path(
working_set,
filename,
virtual_path,
));
} else {
let abs_virtual_filename = actual_cwd.join(filename);
let abs_virtual_filename = abs_virtual_filename.to_string_lossy();
if let Some(virtual_path) = working_set.find_virtual_path(&abs_virtual_filename) {
return Some(ParserPath::from_virtual_path(
working_set,
&abs_virtual_filename,
virtual_path,
));
}
}
// Try if we have an existing physical path
if let Ok(p) = canonicalize_with(filename, actual_cwd) {
return Some(ParserPath::RealPath(p));
}
// Early-exit if path is non-existent absolute path
let path = Path::new(filename);
if !path.is_relative() {
return None;
}
// Look up relative path from NU_LIB_DIRS
working_set
.get_variable(find_dirs_var(working_set, dirs_var_name)?)
.const_val
.as_ref()?
.as_list()
.ok()?
.iter()
.map(|lib_dir| -> Option<PathBuf> {
let dir = lib_dir.to_path().ok()?;
let dir_abs = canonicalize_with(dir, actual_cwd).ok()?;
canonicalize_with(filename, dir_abs).ok()
})
.find(Option::is_some)
.flatten()
.map(ParserPath::RealPath)
}
// TODO: remove (see #8310)
// Same as find_in_dirs_with_id but using $env.NU_LIB_DIRS instead of constant
pub fn find_in_dirs_old(
filename: &str,
working_set: &StateWorkingSet,
cwd: &str,
dirs_env: &str,
) -> Option<PathBuf> {
// Choose whether to use file-relative or PWD-relative path
let actual_cwd = if let Some(currently_parsed_cwd) = &working_set.currently_parsed_cwd {
currently_parsed_cwd.as_path()
} else {
Path::new(cwd)
};
if let Ok(p) = canonicalize_with(filename, actual_cwd) {
Some(p)
} else {
let path = Path::new(filename);
if path.is_relative() {
if let Some(lib_dirs) = working_set.get_env_var(dirs_env) {
if let Ok(dirs) = lib_dirs.as_list() {
for lib_dir in dirs {
if let Ok(dir) = lib_dir.to_path() {
// make sure the dir is absolute path
if let Ok(dir_abs) = canonicalize_with(dir, actual_cwd) {
if let Ok(path) = canonicalize_with(filename, dir_abs) {
return Some(path);
}
}
}
}
None
} else {
None
}
} else {
None
}
} else {
None
}
}
}
find_in_dirs_with_id(filename, working_set, cwd, dirs_var_name).or_else(|| {
find_in_dirs_old(filename, working_set, cwd, dirs_var_name).map(ParserPath::RealPath)
})
}
fn detect_params_in_name(
working_set: &StateWorkingSet,
name_span: Span,
decl_name: &str,
) -> Option<ParseError> {
let name = working_set.get_span_contents(name_span);
let extract_span = |delim: u8| {
// it is okay to unwrap because we know the slice contains the byte
let (idx, _) = name
.iter()
.find_position(|c| **c == delim)
.unwrap_or((name.len(), &b' '));
let param_span = Span::new(name_span.start + idx - 1, name_span.start + idx - 1);
let error = ParseError::LabeledErrorWithHelp{
error: "no space between name and parameters".into(),
label: "expected space".into(),
help: format!("consider adding a space between the `{decl_name}` command's name and its parameters"),
span: param_span,
};
Some(error)
};
if name.contains(&b'[') {
extract_span(b'[')
} else if name.contains(&b'(') {
extract_span(b'(')
} else {
None
}
}
/// Run has_flag_const and push possible error to working_set
fn has_flag_const(working_set: &mut StateWorkingSet, call: &Call, name: &str) -> Result<bool, ()> {
call.has_flag_const(working_set, name).map_err(|err| {
working_set.error(err.wrap(working_set, call.span()));
})
}
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