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nushell/crates/nu-parser/src/parse_keywords.rs
pwygab 1a3762b905
prevent alias name from being filesize or number (#6595) 
* prevent alias name from being filesize or number

* add test

* fmt
2022-09-28 17:08:38 -05:00

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use nu_path::canonicalize_with;
use nu_protocol::{
ast::{
Argument, Block, Call, Expr, Expression, ImportPattern, ImportPatternHead,
ImportPatternMember, Pipeline,
},
engine::{StateWorkingSet, DEFAULT_OVERLAY_NAME},
span, BlockId, Exportable, Module, PositionalArg, Span, Spanned, SyntaxShape, Type,
};
use std::collections::HashSet;
use std::path::{Path, PathBuf};
static LIB_DIRS_ENV: &str = "NU_LIB_DIRS";
#[cfg(feature = "plugin")]
static PLUGIN_DIRS_ENV: &str = "NU_PLUGIN_DIRS";
use crate::{
known_external::KnownExternal,
lex, lite_parse,
lite_parse::LiteCommand,
parser::{
check_call, check_name, garbage, garbage_pipeline, parse, parse_internal_call,
parse_multispan_value, parse_signature, parse_string, parse_var_with_opt_type, trim_quotes,
ParsedInternalCall,
},
unescape_unquote_string, ParseError,
};
pub fn parse_def_predecl(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> Option<ParseError> {
let name = working_set.get_span_contents(spans[0]);
// handle "export def" same as "def"
let (name, spans) = if name == b"export" && spans.len() >= 2 {
(working_set.get_span_contents(spans[1]), &spans[1..])
} else {
(name, spans)
};
if (name == b"def" || name == b"def-env") && spans.len() >= 4 {
let (name_expr, ..) = parse_string(working_set, spans[1], expand_aliases_denylist);
let name = name_expr.as_string();
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_signature(working_set, spans[2], expand_aliases_denylist);
let signature = sig.as_signature();
working_set.exit_scope();
if let (Some(name), Some(mut signature)) = (name, signature) {
signature.name = name;
let decl = signature.predeclare();
if working_set.add_predecl(decl).is_some() {
return Some(ParseError::DuplicateCommandDef(spans[1]));
}
}
} else if name == b"extern" && spans.len() == 3 {
let (name_expr, ..) = parse_string(working_set, spans[1], expand_aliases_denylist);
let name = name_expr.as_string();
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_signature(working_set, spans[2], expand_aliases_denylist);
let signature = sig.as_signature();
working_set.exit_scope();
if let (Some(name), Some(mut signature)) = (name, signature) {
signature.name = name.clone();
//let decl = signature.predeclare();
let decl = KnownExternal {
name,
usage: "run external command".into(),
signature,
};
if working_set.add_predecl(Box::new(decl)).is_some() {
return Some(ParseError::DuplicateCommandDef(spans[1]));
}
}
}
None
}
pub fn parse_for(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Expression, Option<ParseError>) {
// 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" {
return (
garbage(spans[0]),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'for' function".into(),
span(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"for", &Type::Any) {
None => {
return (
garbage(spans[0]),
Some(ParseError::UnknownState(
"internal error: for declaration not found".into(),
span(spans),
)),
)
}
Some(decl_id) => {
working_set.enter_scope();
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
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::Block(block_id),
..
}
| Expression {
expr: Expr::RowCondition(block_id),
..
} => {
let block = working_set.get_block_mut(*block_id);
block.signature = Box::new(sig.clone());
}
_ => {}
}
}
err = check_call(call_span, &sig, &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
},
err,
);
}
(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 block = call.positional_nth(2).expect("for call already checked");
let error = None;
if let (Some(var_id), Some(block_id)) = (&var_decl.as_var(), block.as_block()) {
let block = working_set.get_block_mut(block_id);
block.signature.required_positional.insert(
0,
PositionalArg {
name: String::new(),
desc: String::new(),
shape: SyntaxShape::Any,
var_id: Some(*var_id),
default_value: None,
},
);
}
(
Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
},
error,
)
}
fn build_usage(working_set: &StateWorkingSet, spans: &[Span]) -> String {
let mut usage = String::new();
let mut num_spaces = 0;
let mut first = true;
// Use the comments to build the usage
for comment_part in spans {
let contents = working_set.get_span_contents(*comment_part);
let comment_line = if first {
// Count the number of spaces still at the front, skipping the '#'
let mut pos = 1;
while pos < contents.len() {
if let Some(b' ') = contents.get(pos) {
// continue
} else {
break;
}
pos += 1;
}
num_spaces = pos;
first = false;
String::from_utf8_lossy(&contents[pos..]).to_string()
} else {
let mut pos = 1;
while pos < contents.len() && pos < num_spaces {
if let Some(b' ') = contents.get(pos) {
// continue
} else {
break;
}
pos += 1;
}
String::from_utf8_lossy(&contents[pos..]).to_string()
};
if !usage.is_empty() {
usage.push('\n');
}
usage.push_str(&comment_line);
}
usage
}
pub fn parse_def(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
let spans = &lite_command.parts[..];
let usage = build_usage(working_set, &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" && def_call != b"def-env" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for def function".into(),
span(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(&def_call, &Type::Any) {
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: def declaration not found".into(),
span(spans),
)),
)
}
Some(decl_id) => {
working_set.enter_scope();
let (command_spans, rest_spans) = spans.split_at(split_id);
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(command_spans),
rest_spans,
decl_id,
expand_aliases_denylist,
);
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::Block(block_id),
..
}
| Expression {
expr: Expr::RowCondition(block_id),
..
} => {
let block = working_set.get_block_mut(*block_id);
block.signature = Box::new(sig.clone());
}
_ => {}
}
}
err = check_call(call_span, &sig, &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
(call, call_span)
}
};
// 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 mut error = None;
if let (Some(name), Some(mut signature), Some(block_id)) =
(&name_expr.as_string(), sig.as_signature(), block.as_block())
{
if let Some(decl_id) = working_set.find_predecl(name.as_bytes()) {
let declaration = working_set.get_decl_mut(decl_id);
signature.name = name.clone();
*signature = signature.add_help();
signature.usage = usage;
*declaration = signature.clone().into_block_command(block_id);
let mut block = working_set.get_block_mut(block_id);
block.signature = signature;
block.redirect_env = def_call == b"def-env";
} else {
error = error.or_else(|| {
Some(ParseError::InternalError(
"Predeclaration failed to add declaration".into(),
name_expr.span,
))
});
};
}
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 {
error = error.or_else(|| {
Some(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,
}]),
error,
)
}
pub fn parse_extern(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
let spans = &lite_command.parts;
let mut error = None;
let usage = build_usage(working_set, &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" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for extern function".into(),
span(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, &Type::Any) {
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: def declaration not found".into(),
span(spans),
)),
)
}
Some(decl_id) => {
working_set.enter_scope();
let (command_spans, rest_spans) = spans.split_at(split_id);
let ParsedInternalCall {
call, error: err, ..
} = parse_internal_call(
working_set,
span(command_spans),
rest_spans,
decl_id,
expand_aliases_denylist,
);
working_set.exit_scope();
error = error.or(err);
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);
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(decl_id) = working_set.find_predecl(name.as_bytes()) {
let declaration = working_set.get_decl_mut(decl_id);
signature.name = name.clone();
signature.usage = usage.clone();
let decl = KnownExternal {
name: name.to_string(),
usage,
signature,
};
*declaration = Box::new(decl);
} else {
error = error.or_else(|| {
Some(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 {
error = error.or_else(|| {
Some(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,
}]),
error,
)
}
pub fn parse_alias(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
let (name_span, alias_name, split_id) =
if spans.len() > 1 && working_set.get_span_contents(spans[0]) == b"export" {
(spans[1], spans.get(2), 2)
} else {
(spans[0], spans.get(1), 1)
};
let name = working_set.get_span_contents(name_span);
if name == b"alias" {
if let Some(alias_name) = alias_name {
let alias_name = String::from_utf8_lossy(working_set.get_span_contents(*alias_name));
if alias_name.parse::<bytesize::ByteSize>().is_ok() || alias_name.parse::<f64>().is_ok()
{
return (
Pipeline::from_vec(vec![garbage(name_span)]),
Some(ParseError::AliasNotValid(name_span)),
);
}
}
if let Some((span, err)) = check_name(working_set, spans) {
return (Pipeline::from_vec(vec![garbage(*span)]), Some(err));
}
if let Some(decl_id) = working_set.find_decl(b"alias", &Type::Any) {
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,
expand_aliases_denylist,
);
if call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: output,
custom_completion: None,
}]),
None,
);
}
if spans.len() >= split_id + 3 {
let alias_name = working_set.get_span_contents(spans[split_id]);
let alias_name = if alias_name.starts_with(b"\"")
&& alias_name.ends_with(b"\"")
&& alias_name.len() > 1
{
alias_name[1..(alias_name.len() - 1)].to_vec()
} else {
alias_name.to_vec()
};
let _equals = working_set.get_span_contents(spans[split_id + 1]);
let replacement = spans[(split_id + 2)..].to_vec();
working_set.add_alias(alias_name, replacement);
}
let err = if spans.len() < 4 {
Some(ParseError::IncorrectValue(
"Incomplete alias".into(),
span(&spans[..split_id]),
"incomplete alias".into(),
))
} else {
None
};
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
err,
);
}
}
(
garbage_pipeline(spans),
Some(ParseError::InternalError(
"Alias statement unparseable".into(),
span(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,
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
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" | b"def" | b"def-env" | b"extern" | b"use" => [b"export ", sub].concat(),
_ => b"export".to_vec(),
}
} else {
b"export".to_vec()
};
if let Some(decl_id) = working_set.find_decl(&full_name, &Type::Any) {
let ParsedInternalCall {
call,
error: mut err,
output,
..
} = parse_internal_call(
working_set,
if full_name == b"export" {
lite_command.parts[0]
} else {
span(&lite_command.parts[0..2])
},
if full_name == b"export" {
&lite_command.parts[1..]
} else {
&lite_command.parts[2..]
},
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
} else {
return (
garbage_pipeline(&lite_command.parts),
Some(ParseError::UnknownState(
format!(
"internal error: '{}' declaration not found",
String::from_utf8_lossy(&full_name)
),
span(&lite_command.parts),
)),
);
};
if &full_name == b"export" {
// export by itself is meaningless
return (
garbage_pipeline(&lite_command.parts),
Some(ParseError::UnexpectedKeyword(
"export".into(),
lite_command.parts[0],
)),
);
}
match full_name.as_slice() {
b"export alias" => parse_alias(working_set, &lite_command.parts, expand_aliases_denylist),
b"export def" | b"export def-env" => {
parse_def(working_set, lite_command, expand_aliases_denylist)
}
b"export use" => {
let (pipeline, _, err) =
parse_use(working_set, &lite_command.parts, expand_aliases_denylist);
(pipeline, err)
}
b"export extern" => parse_extern(working_set, lite_command, expand_aliases_denylist),
_ => (
garbage_pipeline(&lite_command.parts),
Some(ParseError::UnexpectedKeyword(
String::from_utf8_lossy(&full_name).to_string(),
lite_command.parts[0],
)),
),
}
}
// This one will trigger only in a module
pub fn parse_export_in_module(
working_set: &mut StateWorkingSet,
lite_command: &LiteCommand,
expand_aliases_denylist: &[usize],
) -> (Pipeline, Vec<Exportable>, Option<ParseError>) {
let spans = &lite_command.parts[..];
let mut error = None;
let export_span = if let Some(sp) = spans.get(0) {
if working_set.get_span_contents(*sp) != b"export" {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"expected export statement".into(),
span(spans),
)),
);
}
*sp
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"got empty input for parsing export statement".into(),
span(spans),
)),
);
};
let export_decl_id = if let Some(id) = working_set.find_decl(b"export", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing export command".into(),
export_span,
)),
);
};
let mut call = Box::new(Call {
head: spans[0],
decl_id: export_decl_id,
arguments: vec![],
redirect_stdout: true,
redirect_stderr: false,
});
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(),
};
let (pipeline, err) =
parse_def(working_set, &lite_command, expand_aliases_denylist);
error = error.or(err);
let export_def_decl_id =
if let Some(id) = working_set.find_decl(b"export def", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing 'export def' command".into(),
export_span,
)),
);
};
// Trying to warp the 'def' call into the 'export def' in a very clumsy way
if let Some(Expression {
expr: Expr::Call(ref def_call),
..
}) = pipeline.expressions.get(0)
{
call = def_call.clone();
call.head = span(&spans[0..=1]);
call.decl_id = export_def_decl_id;
} else {
error = error.or_else(|| {
Some(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
))
});
};
let mut result = vec![];
if let Some(decl_name_span) = spans.get(2) {
let decl_name = working_set.get_span_contents(*decl_name_span);
let decl_name = trim_quotes(decl_name);
if let Some(decl_id) = working_set.find_decl(decl_name, &Type::Any) {
result.push(Exportable::Decl {
name: decl_name.to_vec(),
id: decl_id,
});
} else {
error = error.or_else(|| {
Some(ParseError::InternalError(
"failed to find added declaration".into(),
span(&spans[1..]),
))
});
}
}
result
}
b"def-env" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
};
let (pipeline, err) =
parse_def(working_set, &lite_command, expand_aliases_denylist);
error = error.or(err);
let export_def_decl_id =
if let Some(id) = working_set.find_decl(b"export def-env", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing 'export def-env' command".into(),
export_span,
)),
);
};
// Trying to warp the 'def' call into the 'export def' in a very clumsy way
if let Some(Expression {
expr: Expr::Call(ref def_call),
..
}) = pipeline.expressions.get(0)
{
call = def_call.clone();
call.head = span(&spans[0..=1]);
call.decl_id = export_def_decl_id;
} else {
error = error.or_else(|| {
Some(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, &Type::Any) {
result.push(Exportable::Decl {
name: decl_name.to_vec(),
id: decl_id,
});
} else {
error = error.or_else(|| {
Some(ParseError::InternalError(
"failed to find added declaration".into(),
span(&spans[1..]),
))
});
}
result
}
b"extern" => {
let lite_command = LiteCommand {
comments: lite_command.comments.clone(),
parts: spans[1..].to_vec(),
};
let (pipeline, err) =
parse_extern(working_set, &lite_command, expand_aliases_denylist);
error = error.or(err);
let export_def_decl_id =
if let Some(id) = working_set.find_decl(b"export extern", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing 'export extern' command".into(),
export_span,
)),
);
};
// Trying to warp the 'def' call into the 'export def' in a very clumsy way
if let Some(Expression {
expr: Expr::Call(ref def_call),
..
}) = pipeline.expressions.get(0)
{
call = def_call.clone();
call.head = span(&spans[0..=1]);
call.decl_id = export_def_decl_id;
} else {
error = error.or_else(|| {
Some(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, &Type::Any) {
result.push(Exportable::Decl {
name: decl_name.to_vec(),
id: decl_id,
});
} else {
error = error.or_else(|| {
Some(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(),
};
let (pipeline, err) =
parse_alias(working_set, &lite_command.parts, expand_aliases_denylist);
error = error.or(err);
let export_alias_decl_id =
if let Some(id) = working_set.find_decl(b"export alias", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing 'export alias' command".into(),
export_span,
)),
);
};
// Trying to warp the 'alias' call into the 'export alias' in a very clumsy way
if let Some(Expression {
expr: Expr::Call(ref alias_call),
..
}) = pipeline.expressions.get(0)
{
call = alias_call.clone();
call.head = span(&spans[0..=1]);
call.decl_id = export_alias_decl_id;
} else {
error = error.or_else(|| {
Some(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_alias(alias_name) {
result.push(Exportable::Alias {
name: alias_name.to_vec(),
id: alias_id,
});
} else {
error = error.or_else(|| {
Some(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(),
};
let (pipeline, exportables, err) =
parse_use(working_set, &lite_command.parts, expand_aliases_denylist);
error = error.or(err);
let export_use_decl_id =
if let Some(id) = working_set.find_decl(b"export use", &Type::Any) {
id
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::InternalError(
"missing 'export use' command".into(),
export_span,
)),
);
};
// Trying to warp the 'use' call into the 'export use' in a very clumsy way
if let Some(Expression {
expr: Expr::Call(ref use_call),
..
}) = pipeline.expressions.get(0)
{
call = use_call.clone();
call.head = span(&spans[0..=1]);
call.decl_id = export_use_decl_id;
} else {
error = error.or_else(|| {
Some(ParseError::InternalError(
"unexpected output from parsing a definition".into(),
span(&spans[1..]),
))
});
};
exportables
}
_ => {
error = error.or_else(|| {
Some(ParseError::Expected(
// TODO: Fill in more keywords as they come
"def, def-env, alias, use, or env keyword".into(),
spans[1],
))
});
vec![]
}
}
} else {
error = error.or_else(|| {
Some(ParseError::MissingPositional(
"def, def-env, alias, or env keyword".into(), // TODO: keep filling more keywords as they come
Span {
start: export_span.end,
end: export_span.end,
},
"'def', `def-env`, `alias`, or 'env' keyword.".to_string(),
))
});
vec![]
};
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
exportables,
error,
)
}
pub fn parse_export_env(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<BlockId>, Option<ParseError>) {
if !spans.is_empty() && working_set.get_span_contents(spans[0]) != b"export-env" {
return (
garbage_pipeline(spans),
None,
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'export-env' command".into(),
span(spans),
)),
);
}
if spans.len() < 2 {
return (
garbage_pipeline(spans),
None,
Some(ParseError::MissingPositional(
"block".into(),
span(spans),
"export-env <block>".into(),
)),
);
}
let call = match working_set.find_decl(b"export-env", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
spans[0],
&[spans[1]],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
None,
err,
);
}
call
}
None => {
return (
garbage_pipeline(spans),
None,
Some(ParseError::UnknownState(
"internal error: 'export-env' declaration not found".into(),
span(spans),
)),
)
}
};
let block_id = if let Some(block) = call.positional_nth(0) {
if let Some(block_id) = block.as_block() {
block_id
} else {
return (
garbage_pipeline(spans),
None,
Some(ParseError::UnknownState(
"internal error: 'export-env' block is not a block".into(),
block.span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
None,
Some(ParseError::UnknownState(
"internal error: 'export-env' block is missing".into(),
span(spans),
)),
);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
(pipeline, Some(block_id), None)
}
pub fn parse_module_block(
working_set: &mut StateWorkingSet,
span: Span,
expand_aliases_denylist: &[usize],
) -> (Block, Module, Option<ParseError>) {
let mut error = None;
working_set.enter_scope();
let source = working_set.get_span_contents(span);
let (output, err) = lex(source, span.start, &[], &[], false);
error = error.or(err);
let (output, err) = lite_parse(&output);
error = error.or(err);
for pipeline in &output.block {
if pipeline.commands.len() == 1 {
parse_def_predecl(
working_set,
&pipeline.commands[0].parts,
expand_aliases_denylist,
);
}
}
let mut module = Module::from_span(span);
let block: Block = output
.block
.iter()
.map(|pipeline| {
if pipeline.commands.len() == 1 {
let name = working_set.get_span_contents(pipeline.commands[0].parts[0]);
let (pipeline, err) = match name {
b"def" | b"def-env" => {
let (pipeline, err) =
parse_def(working_set, &pipeline.commands[0], expand_aliases_denylist);
(pipeline, err)
}
b"extern" => {
let (pipeline, err) = parse_extern(
working_set,
&pipeline.commands[0],
expand_aliases_denylist,
);
(pipeline, err)
}
b"alias" => {
let (pipeline, err) = parse_alias(
working_set,
&pipeline.commands[0].parts,
expand_aliases_denylist,
);
(pipeline, err)
}
b"use" => {
let (pipeline, _, err) = parse_use(
working_set,
&pipeline.commands[0].parts,
expand_aliases_denylist,
);
(pipeline, err)
}
b"export" => {
let (pipe, exportables, err) = parse_export_in_module(
working_set,
&pipeline.commands[0],
expand_aliases_denylist,
);
if err.is_none() {
for exportable in exportables {
match exportable {
Exportable::Decl { name, id } => {
module.add_decl(name, id);
}
Exportable::Alias { name, id } => {
module.add_alias(name, id);
}
}
}
}
(pipe, err)
}
b"export-env" => {
let (pipe, maybe_env_block, err) = parse_export_env(
working_set,
&pipeline.commands[0].parts,
expand_aliases_denylist,
);
if let Some(block_id) = maybe_env_block {
module.add_env_block(block_id);
}
(pipe, err)
}
_ => (
garbage_pipeline(&pipeline.commands[0].parts),
Some(ParseError::ExpectedKeyword(
"def or export keyword".into(),
pipeline.commands[0].parts[0],
)),
),
};
if error.is_none() {
error = err;
}
pipeline
} else {
error = Some(ParseError::Expected("not a pipeline".into(), span));
garbage_pipeline(&[span])
}
})
.into();
working_set.exit_scope();
(block, module, error)
}
pub fn parse_module(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
// 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 mut error = None;
let bytes = working_set.get_span_contents(spans[0]);
if bytes == b"module" && spans.len() >= 3 {
let (module_name_expr, err) = parse_string(working_set, spans[1], expand_aliases_denylist);
error = error.or(err);
let module_name = module_name_expr
.as_string()
.expect("internal error: module name is not a string");
let block_span = spans[2];
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 {
return (
garbage_pipeline(spans),
Some(ParseError::Expected("block".into(), block_span)),
);
}
if block_bytes.ends_with(b"}") {
end -= 1;
} else {
error =
error.or_else(|| Some(ParseError::Unclosed("}".into(), Span { start: end, end })));
}
let block_span = Span { start, end };
let (block, module, err) =
parse_module_block(working_set, block_span, expand_aliases_denylist);
error = error.or(err);
let block_id = working_set.add_block(block);
let _ = working_set.add_module(&module_name, module);
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", &Type::Any)
.expect("internal error: missing module command");
let call = Box::new(Call {
head: spans[0],
decl_id: module_decl_id,
arguments: vec![
Argument::Positional(module_name_expr),
Argument::Positional(block_expr),
],
redirect_stdout: true,
redirect_stderr: false,
});
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
error,
)
} else {
(
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"Expected structure: module <name> {}".into(),
span(spans),
)),
)
}
}
pub fn parse_use(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Vec<Exportable>, Option<ParseError>) {
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" {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'use' command".into(),
span(spans),
)),
);
}
if working_set.get_span_contents(name_span) != b"use" {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'use' command".into(),
span(spans),
)),
);
}
let (call, call_span, use_decl_id) = match working_set.find_decl(b"use", &Type::Any) {
Some(decl_id) => {
let (command_spans, rest_spans) = spans.split_at(split_id);
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(command_spans),
rest_spans,
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
vec![],
err,
);
}
(call, call_span, decl_id)
}
None => {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"internal error: 'use' declaration not found".into(),
span(spans),
)),
)
}
};
let import_pattern = if let Some(expr) = call.positional_nth(0) {
if let Some(pattern) = expr.as_import_pattern() {
pattern
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"internal error: Import pattern positional is not import pattern".into(),
expr.span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
)),
);
};
let cwd = working_set.get_cwd();
let mut error = None;
// TODO: Add checking for importing too long import patterns, e.g.:
// > use spam foo non existent names here do not throw error
let (import_pattern, module) =
if let Some(module_id) = working_set.find_module(&import_pattern.head.name) {
(import_pattern, working_set.get_module(module_id).clone())
} else {
// It could be a file
// TODO: Do not close over when loading module from file?
let (module_filename, err) =
unescape_unquote_string(&import_pattern.head.name, import_pattern.head.span);
if err.is_none() {
if let Some(module_path) =
find_in_dirs(&module_filename, working_set, &cwd, LIB_DIRS_ENV)
{
if let Some(i) = working_set
.parsed_module_files
.iter()
.rposition(|p| p == &module_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(module_path.to_string_lossy().to_string());
let msg = files.join("\nuses ");
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
vec![],
Some(ParseError::CyclicalModuleImport(
msg,
import_pattern.head.span,
)),
);
}
let module_name = if let Some(stem) = module_path.file_stem() {
stem.to_string_lossy().to_string()
} else {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
vec![],
Some(ParseError::ModuleNotFound(import_pattern.head.span)),
);
};
if let Ok(contents) = std::fs::read(&module_path) {
let span_start = working_set.next_span_start();
working_set.add_file(module_filename, &contents);
let span_end = working_set.next_span_start();
// Change the currently parsed directory
let prev_currently_parsed_cwd = if let Some(parent) = module_path.parent() {
let prev = working_set.currently_parsed_cwd.clone();
working_set.currently_parsed_cwd = Some(parent.into());
prev
} else {
working_set.currently_parsed_cwd.clone()
};
// Add the file to the stack of parsed module files
working_set.parsed_module_files.push(module_path);
// Parse the module
let (block, module, err) = parse_module_block(
working_set,
Span::new(span_start, span_end),
expand_aliases_denylist,
);
error = error.or(err);
// 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(block);
let module_id = working_set.add_module(&module_name, module.clone());
(
ImportPattern {
head: ImportPatternHead {
name: module_name.into(),
id: Some(module_id),
span: import_pattern.head.span,
},
members: import_pattern.members,
hidden: HashSet::new(),
},
module,
)
} else {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
vec![],
Some(ParseError::ModuleNotFound(import_pattern.head.span)),
);
}
} else {
error = error.or(Some(ParseError::ModuleNotFound(import_pattern.head.span)));
let old_span = import_pattern.head.span;
let mut import_pattern = ImportPattern::new();
import_pattern.head.span = old_span;
(import_pattern, Module::new())
}
} else {
return (
garbage_pipeline(spans),
vec![],
Some(ParseError::NonUtf8(import_pattern.head.span)),
);
}
};
let (decls_to_use, aliases_to_use) = if import_pattern.members.is_empty() {
(
module.decls_with_head(&import_pattern.head.name),
module.aliases_with_head(&import_pattern.head.name),
)
} else {
match &import_pattern.members[0] {
ImportPatternMember::Glob { .. } => (module.decls(), module.aliases()),
ImportPatternMember::Name { name, span } => {
let mut decl_output = vec![];
let mut alias_output = vec![];
if let Some(id) = module.get_decl_id(name) {
decl_output.push((name.clone(), id));
} else if let Some(id) = module.get_alias_id(name) {
alias_output.push((name.clone(), id));
} else {
error = error.or(Some(ParseError::ExportNotFound(*span)))
}
(decl_output, alias_output)
}
ImportPatternMember::List { names } => {
let mut decl_output = vec![];
let mut alias_output = vec![];
for (name, span) in names {
if let Some(id) = module.get_decl_id(name) {
decl_output.push((name.clone(), id));
} else if let Some(id) = module.get_alias_id(name) {
alias_output.push((name.clone(), id));
} else {
error = error.or(Some(ParseError::ExportNotFound(*span)));
break;
}
}
(decl_output, alias_output)
}
}
};
let exportables = decls_to_use
.iter()
.map(|(name, decl_id)| Exportable::Decl {
name: name.clone(),
id: *decl_id,
})
.chain(
aliases_to_use
.iter()
.map(|(name, alias_id)| Exportable::Alias {
name: name.clone(),
id: *alias_id,
}),
)
.collect();
// Extend the current scope with the module's exportables
working_set.use_decls(decls_to_use);
working_set.use_aliases(aliases_to_use);
// Create a new Use command call to pass the new import pattern
let import_pattern_expr = Expression {
expr: Expr::ImportPattern(import_pattern),
span: span(&spans[1..]),
ty: Type::List(Box::new(Type::String)),
custom_completion: None,
};
let call = Box::new(Call {
head: span(spans.split_at(split_id).0),
decl_id: use_decl_id,
arguments: vec![Argument::Positional(import_pattern_expr)],
redirect_stdout: true,
redirect_stderr: false,
});
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
exportables,
error,
)
}
pub fn parse_hide(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
if working_set.get_span_contents(spans[0]) != b"hide" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'hide' command".into(),
span(spans),
)),
);
}
let (call, call_span, hide_decl_id) = match working_set.find_decl(b"hide", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
(call, call_span, decl_id)
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'hide' declaration not found".into(),
span(spans),
)),
)
}
};
let import_pattern = if let Some(expr) = call.positional_nth(0) {
if let Some(pattern) = expr.as_import_pattern() {
pattern
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Import pattern positional is not import pattern".into(),
call_span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
)),
);
};
let mut error = None;
let bytes = working_set.get_span_contents(spans[0]);
if bytes == b"hide" && spans.len() >= 2 {
for span in spans[1..].iter() {
let (_, err) = parse_string(working_set, *span, expand_aliases_denylist);
error = error.or(err);
}
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_alias(&import_pattern.head.name) {
// an alias,
let mut module = Module::new();
module.add_alias(import_pattern.head.name.clone(), id);
(false, module)
} else if let Some(id) = working_set.find_decl(&import_pattern.head.name, &Type::Any) {
// a custom command,
let mut module = Module::new();
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())
}
} else {
return (
garbage_pipeline(spans),
Some(ParseError::ModuleNotFound(spans[1])),
);
};
// This kind of inverts the import pattern matching found in parse_use()
let (aliases_to_hide, decls_to_hide) = if import_pattern.members.is_empty() {
if is_module {
(
module.alias_names_with_head(&import_pattern.head.name),
module.decl_names_with_head(&import_pattern.head.name),
)
} else {
(module.alias_names(), module.decl_names())
}
} else {
match &import_pattern.members[0] {
ImportPatternMember::Glob { .. } => (module.alias_names(), module.decl_names()),
ImportPatternMember::Name { name, span } => {
let mut aliases = vec![];
let mut decls = vec![];
if let Some(item) = module.alias_name_with_head(name, &import_pattern.head.name)
{
aliases.push(item);
} else if let Some(item) =
module.decl_name_with_head(name, &import_pattern.head.name)
{
decls.push(item);
} else {
error = error.or(Some(ParseError::ExportNotFound(*span)));
}
(aliases, decls)
}
ImportPatternMember::List { names } => {
let mut aliases = vec![];
let mut decls = vec![];
for (name, span) in names {
if let Some(item) =
module.alias_name_with_head(name, &import_pattern.head.name)
{
aliases.push(item);
} else if let Some(item) =
module.decl_name_with_head(name, &import_pattern.head.name)
{
decls.push(item);
} else {
error = error.or(Some(ParseError::ExportNotFound(*span)));
break;
}
}
(aliases, decls)
}
}
};
let import_pattern = {
let aliases: HashSet<Vec<u8>> = aliases_to_hide.iter().cloned().collect();
let decls: HashSet<Vec<u8>> = decls_to_hide.iter().cloned().collect();
import_pattern.with_hidden(decls.union(&aliases).cloned().collect())
};
// 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);
working_set.hide_aliases(&aliases_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(&spans[1..]),
ty: Type::List(Box::new(Type::String)),
custom_completion: None,
};
let call = Box::new(Call {
head: spans[0],
decl_id: hide_decl_id,
arguments: vec![Argument::Positional(import_pattern_expr)],
redirect_stdout: true,
redirect_stderr: false,
});
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
error,
)
} else {
(
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"Expected structure: hide <name>".into(),
span(spans),
)),
)
}
}
pub fn parse_overlay(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
if working_set.get_span_contents(spans[0]) != b"overlay" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'overlay' command".into(),
span(spans),
)),
);
}
if spans.len() > 1 {
let subcommand = working_set.get_span_contents(spans[1]);
match subcommand {
b"use" => {
return parse_overlay_use(working_set, spans, expand_aliases_denylist);
}
b"list" => {
// TODO: Abstract this code blob, it's repeated all over the place:
let call = match working_set.find_decl(b"overlay list", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(&spans[..2]),
if spans.len() > 2 { &spans[2..] } else { &[] },
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
call
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'overlay' declaration not found".into(),
span(spans),
)),
)
}
};
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
None,
);
}
b"new" => {
return parse_overlay_new(working_set, spans, expand_aliases_denylist);
}
b"hide" => {
return parse_overlay_hide(working_set, spans, expand_aliases_denylist);
}
_ => { /* continue parsing overlay */ }
}
}
let call = match working_set.find_decl(b"overlay", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
call
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'overlay' declaration not found".into(),
span(spans),
)),
)
}
};
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
None,
)
}
pub fn parse_overlay_new(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
if spans.len() > 1 && working_set.get_span_contents(span(&spans[0..2])) != b"overlay new" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'overlay new' command".into(),
span(spans),
)),
);
}
let (call, call_span) = match working_set.find_decl(b"overlay new", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(&spans[0..2]),
&spans[2..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
(call, call_span)
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'overlay new' declaration not found".into(),
span(spans),
)),
)
}
};
let (overlay_name, _) = if let Some(expr) = call.positional_nth(0) {
if let Some(s) = expr.as_string() {
(s, expr.span)
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Module name not a string".into(),
expr.span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
)),
);
};
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
let module_id = working_set.add_module(&overlay_name, Module::new());
working_set.add_overlay(
overlay_name.as_bytes().to_vec(),
module_id,
vec![],
vec![],
false,
);
(pipeline, None)
}
pub fn parse_overlay_use(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
if spans.len() > 1 && working_set.get_span_contents(span(&spans[0..2])) != b"overlay use" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'overlay use' command".into(),
span(spans),
)),
);
}
// TODO: Allow full import pattern as argument (requires custom naming of module/overlay)
let (call, call_span) = match working_set.find_decl(b"overlay use", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(&spans[0..2]),
&spans[2..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
(call, call_span)
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'overlay use' declaration not found".into(),
span(spans),
)),
)
}
};
let (overlay_name, overlay_name_span) = if let Some(expr) = call.positional_nth(0) {
if let Some(s) = expr.as_string() {
(s, expr.span)
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Module name not a string".into(),
expr.span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Missing required positional after call parsing".into(),
call_span,
)),
);
};
let new_name = if let Some(kw_expression) = call.positional_nth(1) {
if let Some(new_name_expression) = kw_expression.as_keyword() {
if let Some(new_name) = new_name_expression.as_string() {
Some(Spanned {
item: new_name,
span: new_name_expression.span,
})
} else {
return (
garbage_pipeline(spans),
Some(ParseError::TypeMismatch(
Type::String,
new_name_expression.ty.clone(),
new_name_expression.span,
)),
);
}
} else {
return (
garbage_pipeline(spans),
Some(ParseError::ExpectedKeyword(
"as keyword".to_string(),
kw_expression.span,
)),
);
}
} else {
None
};
let has_prefix = call.has_flag("prefix");
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call.clone()),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
let cwd = working_set.get_cwd();
let mut error = 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 {
return (
pipeline,
Some(ParseError::OverlayPrefixMismatch(
overlay_name,
"without".to_string(),
overlay_name_span,
)),
);
}
if !has_prefix && overlay_frame.prefixed {
return (
pipeline,
Some(ParseError::OverlayPrefixMismatch(
overlay_name,
"with".to_string(),
overlay_name_span,
)),
);
}
if let Some(new_name) = new_name {
if new_name.item != overlay_name {
return (
pipeline,
Some(ParseError::CantAddOverlayHelp(
format!("Cannot add overlay as '{}' because it already exsits under the name '{}'", new_name.item, overlay_name),
new_name.span,
)),
);
}
}
let module_id = overlay_frame.origin;
if let Some(new_module_id) = working_set.find_module(overlay_name.as_bytes()) {
if module_id == new_module_id {
(overlay_name, Module::new(), 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 {
(overlay_name, Module::new(), module_id, true)
}
} else {
// Create a new overlay from a module
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 {
// try if the name is a file
if let Ok(module_filename) =
String::from_utf8(trim_quotes(overlay_name.as_bytes()).to_vec())
{
if let Some(module_path) =
find_in_dirs(&module_filename, working_set, &cwd, LIB_DIRS_ENV)
{
let overlay_name = if let Some(stem) = module_path.file_stem() {
stem.to_string_lossy().to_string()
} else {
return (
pipeline,
Some(ParseError::ModuleOrOverlayNotFound(spans[1])),
);
};
if let Ok(contents) = std::fs::read(&module_path) {
let span_start = working_set.next_span_start();
working_set.add_file(module_filename, &contents);
let span_end = working_set.next_span_start();
// Change currently parsed directory
let prev_currently_parsed_cwd = if let Some(parent) = module_path.parent() {
let prev = working_set.currently_parsed_cwd.clone();
working_set.currently_parsed_cwd = Some(parent.into());
prev
} else {
working_set.currently_parsed_cwd.clone()
};
let (block, module, err) = parse_module_block(
working_set,
Span::new(span_start, span_end),
expand_aliases_denylist,
);
error = error.or(err);
// Restore the currently parsed directory back
working_set.currently_parsed_cwd = prev_currently_parsed_cwd;
let _ = working_set.add_block(block);
let module_id = working_set.add_module(&overlay_name, module.clone());
(
new_name.map(|spanned| spanned.item).unwrap_or(overlay_name),
module,
module_id,
true,
)
} else {
return (
pipeline,
Some(ParseError::ModuleOrOverlayNotFound(spans[1])),
);
}
} else {
return (
pipeline,
Some(ParseError::ModuleOrOverlayNotFound(overlay_name_span)),
);
}
} else {
return (garbage_pipeline(spans), Some(ParseError::NonUtf8(spans[1])));
}
}
};
let (decls_to_lay, aliases_to_lay) = if has_prefix {
(
origin_module.decls_with_head(final_overlay_name.as_bytes()),
origin_module.aliases_with_head(final_overlay_name.as_bytes()),
)
} else {
(origin_module.decls(), origin_module.aliases())
};
working_set.add_overlay(
final_overlay_name.as_bytes().to_vec(),
origin_module_id,
decls_to_lay,
aliases_to_lay,
has_prefix,
);
// Change the call argument to include the Overlay expression with the module ID
let mut call = call;
if let Some(overlay_expr) = call.positional_nth_mut(0) {
overlay_expr.expr = Expr::Overlay(if is_module_updated {
Some(origin_module_id)
} else {
None
});
} // no need to check for else since it was already checked
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
(pipeline, error)
}
pub fn parse_overlay_hide(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
if spans.len() > 1 && working_set.get_span_contents(span(&spans[0..2])) != b"overlay hide" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for 'overlay hide' command".into(),
span(spans),
)),
);
}
let call = match working_set.find_decl(b"overlay hide", &Type::Any) {
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
span(&spans[0..2]),
&spans[2..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
call
}
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: 'overlay hide' declaration not found".into(),
span(spans),
)),
)
}
};
let (overlay_name, overlay_name_span) = if let Some(expr) = call.positional_nth(0) {
if let Some(s) = expr.as_string() {
(s, expr.span)
} else {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Module name not a string".into(),
expr.span,
)),
);
}
} else {
(
String::from_utf8_lossy(working_set.last_overlay_name()).to_string(),
call.head,
)
};
let keep_custom = call.has_flag("keep-custom");
let pipeline = Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]);
if overlay_name == DEFAULT_OVERLAY_NAME {
return (
pipeline,
Some(ParseError::CantHideDefaultOverlay(
overlay_name,
overlay_name_span,
)),
);
}
if !working_set
.unique_overlay_names()
.contains(&overlay_name.as_bytes().to_vec())
{
return (
pipeline,
Some(ParseError::ActiveOverlayNotFound(overlay_name_span)),
);
}
if working_set.num_overlays() < 2 {
return (
pipeline,
Some(ParseError::CantRemoveLastOverlay(overlay_name_span)),
);
}
working_set.remove_overlay(overlay_name.as_bytes(), keep_custom);
(pipeline, None)
}
pub fn parse_let(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
let name = working_set.get_span_contents(spans[0]);
if name == b"let" {
if let Some((span, err)) = check_name(working_set, spans) {
return (Pipeline::from_vec(vec![garbage(*span)]), Some(err));
}
if let Some(decl_id) = working_set.find_decl(b"let", &Type::Any) {
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);
if item == b"=" && spans.len() > (span.0 + 1) {
let mut error = None;
let mut idx = span.0;
let (rvalue, err) = parse_multispan_value(
working_set,
spans,
&mut idx,
&SyntaxShape::Keyword(b"=".to_vec(), Box::new(SyntaxShape::Expression)),
expand_aliases_denylist,
);
error = error.or(err);
if idx < (spans.len() - 1) {
error = error.or(Some(ParseError::ExtraPositional(
call_signature,
spans[idx + 1],
)));
}
let mut idx = 0;
let (lvalue, err) =
parse_var_with_opt_type(working_set, &spans[1..(span.0)], &mut idx);
error = error.or(err);
let var_name =
String::from_utf8_lossy(working_set.get_span_contents(lvalue.span))
.to_string();
if ["in", "nu", "env", "nothing"].contains(&var_name.as_str()) {
error =
error.or(Some(ParseError::LetBuiltinVar(var_name, lvalue.span)));
}
let var_id = lvalue.as_var();
let rhs_type = rvalue.ty.clone();
if let Some(var_id) = var_id {
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),
],
redirect_stdout: true,
redirect_stderr: false,
});
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: Type::Any,
custom_completion: None,
}]),
error,
);
}
}
}
let ParsedInternalCall {
call,
error: err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
return (
Pipeline {
expressions: vec![Expression {
expr: Expr::Call(call),
span: nu_protocol::span(spans),
ty: output,
custom_completion: None,
}],
},
err,
);
}
}
(
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: let statement unparseable".into(),
span(spans),
)),
)
}
pub fn parse_source(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
let mut error = None;
let name = working_set.get_span_contents(spans[0]);
if name == b"source" || name == b"source-env" {
let scoped = name == b"source-env";
if let Some(decl_id) = working_set.find_decl(name, &Type::Any) {
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,
error: err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
error = error.or(err);
if error.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: output,
custom_completion: None,
}]),
error,
);
}
// Command and one file name
if spans.len() >= 2 {
let name_expr = working_set.get_span_contents(spans[1]);
let (filename, err) = unescape_unquote_string(name_expr, spans[1]);
if err.is_none() {
if let Some(path) = find_in_dirs(&filename, working_set, &cwd, LIB_DIRS_ENV) {
if let Ok(contents) = std::fs::read(&path) {
// Change currently parsed directory
let prev_currently_parsed_cwd = if let Some(parent) = path.parent() {
let prev = working_set.currently_parsed_cwd.clone();
working_set.currently_parsed_cwd = Some(parent.into());
prev
} 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, err) = parse(
working_set,
path.file_name().and_then(|x| x.to_str()),
&contents,
scoped,
expand_aliases_denylist,
);
// Restore the currently parsed directory back
working_set.currently_parsed_cwd = prev_currently_parsed_cwd;
if err.is_some() {
// Unsuccessful parse of file
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(&spans[1..]),
ty: Type::Any,
custom_completion: None,
}]),
// Return the file parse error
err,
);
} else {
// 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.add_positional(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,
}]),
None,
);
}
}
} else {
error = error.or(Some(ParseError::SourcedFileNotFound(filename, spans[1])));
}
} else {
return (garbage_pipeline(spans), Some(ParseError::NonUtf8(spans[1])));
}
}
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: span(spans),
ty: Type::Any,
custom_completion: None,
}]),
error,
);
}
}
(
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: source statement unparseable".into(),
span(spans),
)),
)
}
#[cfg(feature = "plugin")]
pub fn parse_register(
working_set: &mut StateWorkingSet,
spans: &[Span],
expand_aliases_denylist: &[usize],
) -> (Pipeline, Option<ParseError>) {
use nu_plugin::{get_signature, PluginDeclaration};
use nu_protocol::{engine::Stack, Signature};
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" {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Wrong call name for parse plugin function".into(),
span(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", &Type::Any) {
None => {
return (
garbage_pipeline(spans),
Some(ParseError::UnknownState(
"internal error: Register declaration not found".into(),
span(spans),
)),
)
}
Some(decl_id) => {
let ParsedInternalCall {
call,
error: mut err,
output,
} = parse_internal_call(
working_set,
spans[0],
&spans[1..],
decl_id,
expand_aliases_denylist,
);
let decl = working_set.get_decl(decl_id);
let call_span = span(spans);
err = check_call(call_span, &decl.signature(), &call).or(err);
if err.is_some() || call.has_flag("help") {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: output,
custom_completion: None,
}]),
err,
);
}
(call, call_span)
}
};
// Extracting the required arguments from the call and keeping them together in a tuple
// The ? operator is not used because the error has to be kept to be printed in the shell
// For that reason the values are kept in a result that will be passed at the end of this call
let arguments = call
.positional_nth(0)
.map(|expr| {
let name_expr = working_set.get_span_contents(expr.span);
let (name, err) = unescape_unquote_string(name_expr, expr.span);
if let Some(err) = err {
Err(err)
} else {
let path = if let Some(p) = find_in_dirs(&name, working_set, &cwd, PLUGIN_DIRS_ENV)
{
p
} else {
return Err(ParseError::RegisteredFileNotFound(name, expr.span));
};
if path.exists() & path.is_file() {
Ok(path)
} else {
Err(ParseError::RegisteredFileNotFound(
format!("{:?}", path),
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::<Signature>(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) => {
return (
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Any,
custom_completion: None,
}]),
Some(err),
);
}
},
};
// 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 stack = Stack::new();
let current_envs =
nu_engine::env::env_to_strings(working_set.permanent_state, &stack).unwrap_or_default();
let error = match signature {
Some(signature) => arguments.and_then(|path| {
// restrict plugin file name starts with `nu_plugin_`
let f_name = path
.file_name()
.map(|s| s.to_string_lossy().starts_with("nu_plugin_"));
if let Some(true) = f_name {
signature.map(|signature| {
let plugin_decl = PluginDeclaration::new(path, signature, shell);
working_set.add_decl(Box::new(plugin_decl));
working_set.mark_plugins_file_dirty();
})
} else {
Ok(())
}
}),
None => arguments.and_then(|path| {
// restrict plugin file name starts with `nu_plugin_`
let f_name = path
.file_name()
.map(|s| s.to_string_lossy().starts_with("nu_plugin_"));
if let Some(true) = f_name {
get_signature(path.as_path(), &shell, &current_envs)
.map_err(|err| {
ParseError::LabeledError(
"Error getting signatures".into(),
err.to_string(),
spans[0],
)
})
.map(|signatures| {
for signature in signatures {
// create plugin command declaration (need struct impl Command)
// store declaration in working set
let plugin_decl =
PluginDeclaration::new(path.clone(), signature, shell.clone());
working_set.add_decl(Box::new(plugin_decl));
}
working_set.mark_plugins_file_dirty();
})
} else {
Ok(())
}
}),
}
.err();
(
Pipeline::from_vec(vec![Expression {
expr: Expr::Call(call),
span: call_span,
ty: Type::Nothing,
custom_completion: None,
}]),
error,
)
}
/// 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, NU_LIB_DIRS is checked.
/// If there is a relative path in NU_LIB_DIRS, 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_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.as_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
}
}
}
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