tvl-depot/tvix/eval/src/builtins/mod.rs

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//! This module implements the builtins exposed in the Nix language.
//!
//! See //tvix/eval/docs/builtins.md for a some context on the
//! available builtins in Nix.
use std::cmp::{self, Ordering};
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
use std::collections::{BTreeMap, HashSet};
use std::path::PathBuf;
use builtin_macros::builtins;
use regex::Regex;
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
use crate::arithmetic_op;
use crate::value::BuiltinArgument;
use crate::warnings::WarningKind;
use crate::{
errors::{ErrorKind, EvalResult},
value::{Builtin, CoercionKind, NixAttrs, NixList, NixString, Value},
vm::VM,
};
use self::versions::{VersionPart, VersionPartsIter};
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
mod versions;
#[cfg(feature = "impure")]
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
mod impure;
#[cfg(feature = "impure")]
pub use impure::impure_builtins;
// we set TVIX_CURRENT_SYSTEM in build.rs
pub const CURRENT_PLATFORM: &str = env!("TVIX_CURRENT_SYSTEM");
/// Coerce a Nix Value to a plain path, e.g. in order to access the
/// file it points to via either `builtins.toPath` or an impure
/// builtin. This coercion can _never_ be performed in a Nix program
/// without using builtins (i.e. the trick `path: /. + path` to
/// convert from a string to a path wouldn't hit this code).
pub fn coerce_value_to_path(v: &Value, vm: &mut VM) -> Result<PathBuf, ErrorKind> {
let value = v.force(vm)?;
match &*value {
Value::Thunk(t) => coerce_value_to_path(&t.value(), vm),
Value::Path(p) => Ok(p.clone()),
_ => value
.coerce_to_string(CoercionKind::Weak, vm)
.map(|s| PathBuf::from(s.as_str()))
.and_then(|path| {
if path.is_absolute() {
Ok(path)
} else {
Err(ErrorKind::NotAnAbsolutePath(path))
}
}),
}
}
#[builtins]
mod pure_builtins {
use std::collections::VecDeque;
use super::*;
#[builtin("abort")]
fn builtin_abort(_vm: &mut VM, message: Value) -> Result<Value, ErrorKind> {
Err(ErrorKind::Abort(message.to_str()?.to_string()))
}
#[builtin("add")]
fn builtin_add(vm: &mut VM, #[lazy] x: Value, #[lazy] y: Value) -> Result<Value, ErrorKind> {
arithmetic_op!(&*x.force(vm)?, &*y.force(vm)?, +)
}
#[builtin("all")]
fn builtin_all(vm: &mut VM, pred: Value, list: Value) -> Result<Value, ErrorKind> {
for value in list.to_list()?.into_iter() {
let pred_result = vm.call_with(&pred, [value])?;
if !pred_result.force(vm)?.as_bool()? {
return Ok(Value::Bool(false));
}
}
Ok(Value::Bool(true))
}
#[builtin("any")]
fn builtin_any(vm: &mut VM, pred: Value, list: Value) -> Result<Value, ErrorKind> {
for value in list.to_list()?.into_iter() {
let pred_result = vm.call_with(&pred, [value])?;
if pred_result.force(vm)?.as_bool()? {
return Ok(Value::Bool(true));
}
}
Ok(Value::Bool(false))
}
#[builtin("attrNames")]
fn builtin_attr_names(_: &mut VM, set: Value) -> Result<Value, ErrorKind> {
let xs = set.to_attrs()?;
let mut output = Vec::with_capacity(xs.len());
for (key, _val) in xs.iter() {
output.push(Value::String(key.clone()));
}
Ok(Value::List(NixList::construct(output.len(), output)))
}
#[builtin("attrValues")]
fn builtin_attr_values(_: &mut VM, set: Value) -> Result<Value, ErrorKind> {
let xs = set.to_attrs()?;
let mut output = Vec::with_capacity(xs.len());
for (_key, val) in xs.iter() {
output.push(val.clone());
}
Ok(Value::List(NixList::construct(output.len(), output)))
}
#[builtin("baseNameOf")]
fn builtin_base_name_of(vm: &mut VM, s: Value) -> Result<Value, ErrorKind> {
let s = s.coerce_to_string(CoercionKind::Weak, vm)?;
let result: String = s.rsplit_once('/').map(|(_, x)| x).unwrap_or(&s).into();
Ok(result.into())
}
#[builtin("bitAnd")]
fn builtin_bit_and(_: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(x.as_int()? & y.as_int()?))
}
#[builtin("bitOr")]
fn builtin_bit_or(_: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(x.as_int()? | y.as_int()?))
}
#[builtin("bitXor")]
fn builtin_bit_xor(_: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(x.as_int()? ^ y.as_int()?))
}
#[builtin("catAttrs")]
fn builtin_cat_attrs(vm: &mut VM, key: Value, list: Value) -> Result<Value, ErrorKind> {
let key = key.to_str()?;
let list = list.to_list()?;
let mut output = vec![];
for item in list.into_iter() {
let set = item.force(vm)?.to_attrs()?;
if let Some(value) = set.select(key.as_str()) {
output.push(value.clone());
}
}
Ok(Value::List(NixList::construct(output.len(), output)))
}
#[builtin("ceil")]
fn builtin_ceil(_: &mut VM, double: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(double.as_float()?.ceil() as i64))
}
#[builtin("compareVersions")]
fn builtin_compare_versions(_: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
let s1 = x.to_str()?;
let s1 = VersionPartsIter::new_for_cmp(s1.as_str());
let s2 = y.to_str()?;
let s2 = VersionPartsIter::new_for_cmp(s2.as_str());
match s1.cmp(s2) {
std::cmp::Ordering::Less => Ok(Value::Integer(-1)),
std::cmp::Ordering::Equal => Ok(Value::Integer(0)),
std::cmp::Ordering::Greater => Ok(Value::Integer(1)),
}
}
#[builtin("concatLists")]
fn builtin_concat_lists(vm: &mut VM, lists: Value) -> Result<Value, ErrorKind> {
let list = lists.to_list()?;
let lists = list
.into_iter()
.map(|elem| {
let value = elem.force(vm)?;
value.to_list()
})
.collect::<Result<Vec<NixList>, ErrorKind>>()?;
Ok(Value::List(NixList::from(
lists.into_iter().flatten().collect::<imbl::Vector<Value>>(),
)))
}
#[builtin("concatMap")]
fn builtin_concat_map(vm: &mut VM, f: Value, list: Value) -> Result<Value, ErrorKind> {
let list = list.to_list()?;
let mut res = imbl::Vector::new();
for val in list {
res.extend(vm.call_with(&f, [val])?.force(vm)?.to_list()?);
}
Ok(Value::List(res.into()))
}
#[builtin("concatStringsSep")]
fn builtin_concat_strings_sep(
vm: &mut VM,
separator: Value,
list: Value,
) -> Result<Value, ErrorKind> {
let separator = separator.to_str()?;
let list = list.to_list()?;
let mut res = String::new();
for (i, val) in list.into_iter().enumerate() {
if i != 0 {
res.push_str(&separator);
}
res.push_str(&val.force(vm)?.coerce_to_string(CoercionKind::Weak, vm)?);
}
Ok(res.into())
}
#[builtin("deepSeq")]
fn builtin_deep_seq(vm: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
x.deep_force(vm, &mut Default::default())?;
Ok(y)
}
#[builtin("div")]
fn builtin_div(vm: &mut VM, #[lazy] x: Value, #[lazy] y: Value) -> Result<Value, ErrorKind> {
arithmetic_op!(&*x.force(vm)?, &*y.force(vm)?, /)
}
#[builtin("dirOf")]
fn builtin_dir_of(vm: &mut VM, s: Value) -> Result<Value, ErrorKind> {
let str = s.coerce_to_string(CoercionKind::Weak, vm)?;
let result = str
.rsplit_once('/')
.map(|(x, _)| match x {
"" => "/",
_ => x,
})
.unwrap_or(".");
if s.is_path() {
Ok(Value::Path(result.into()))
} else {
Ok(result.into())
}
}
#[builtin("elem")]
fn builtin_elem(vm: &mut VM, x: Value, xs: Value) -> Result<Value, ErrorKind> {
for val in xs.to_list()? {
if vm.nix_eq(val, x.clone(), true)? {
return Ok(true.into());
}
}
Ok(false.into())
}
#[builtin("elemAt")]
fn builtin_elem_at(_: &mut VM, xs: Value, i: Value) -> Result<Value, ErrorKind> {
let xs = xs.to_list()?;
let i = i.as_int()?;
if i < 0 {
Err(ErrorKind::IndexOutOfBounds { index: i })
} else {
match xs.get(i as usize) {
Some(x) => Ok(x.clone()),
None => Err(ErrorKind::IndexOutOfBounds { index: i }),
}
}
}
#[builtin("filter")]
fn builtin_filter(vm: &mut VM, pred: Value, list: Value) -> Result<Value, ErrorKind> {
let list: NixList = list.to_list()?;
list.into_iter()
.filter_map(|elem| {
let result = match vm.call_with(&pred, [elem.clone()]) {
Err(err) => return Some(Err(err)),
Ok(result) => result,
};
// Must be assigned to a local to avoid a borrowcheck
// failure related to the ForceResult destructor.
let result = match result.force(vm) {
Err(err) => Some(Err(vm.error(err))),
Ok(value) => match value.as_bool() {
Ok(true) => Some(Ok(elem)),
Ok(false) => None,
Err(err) => Some(Err(vm.error(err))),
},
};
result
})
.collect::<Result<imbl::Vector<Value>, _>>()
.map(|list| Value::List(NixList::from(list)))
.map_err(Into::into)
}
#[builtin("floor")]
fn builtin_floor(_: &mut VM, double: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(double.as_float()?.floor() as i64))
}
#[builtin("foldl'")]
fn builtin_foldl(
vm: &mut VM,
op: Value,
#[lazy] mut nul: Value,
list: Value,
) -> Result<Value, ErrorKind> {
let list = list.to_list()?;
for val in list {
nul = vm.call_with(&op, [nul, val])?;
nul.force(vm)?;
}
Ok(nul)
}
#[builtin("functionArgs")]
fn builtin_function_args(_: &mut VM, f: Value) -> Result<Value, ErrorKind> {
let lambda = &f.as_closure()?.lambda();
let formals = if let Some(formals) = &lambda.formals {
formals
} else {
return Ok(Value::attrs(NixAttrs::empty()));
};
Ok(Value::attrs(NixAttrs::from_iter(
formals.arguments.iter().map(|(k, v)| (k.clone(), (*v))),
)))
}
#[builtin("fromJSON")]
fn builtin_from_json(_: &mut VM, json: Value) -> Result<Value, ErrorKind> {
let json_str = json.to_str()?;
let json: serde_json::Value = serde_json::from_str(&json_str)?;
json.try_into()
}
#[builtin("genericClosure")]
fn builtin_generic_closure(vm: &mut VM, input: Value) -> Result<Value, ErrorKind> {
let attrs = input.to_attrs()?;
// The work set is maintained as a VecDeque because new items
// are popped from the front.
let mut work_set: VecDeque<Value> = attrs
.select_required("startSet")?
.force(vm)?
.to_list()?
.into_iter()
.collect();
let operator = attrs.select_required("operator")?;
let mut res = imbl::Vector::new();
let mut done_keys: Vec<Value> = vec![];
let mut insert_key = |k: Value, vm: &mut VM| -> Result<bool, ErrorKind> {
for existing in &done_keys {
if existing.nix_eq(&k, vm)? {
return Ok(false);
}
}
done_keys.push(k);
Ok(true)
};
while let Some(val) = work_set.pop_front() {
let attrs = val.force(vm)?.to_attrs()?;
let key = attrs.select_required("key")?;
if !insert_key(key.clone(), vm)? {
continue;
}
res.push_back(val.clone());
let op_result = vm.call_with(operator, Some(val))?.force(vm)?.to_list()?;
work_set.extend(op_result.into_iter());
}
Ok(Value::List(NixList::from(res)))
}
#[builtin("genList")]
fn builtin_gen_list(vm: &mut VM, generator: Value, length: Value) -> Result<Value, ErrorKind> {
let len = length.as_int()?;
(0..len)
.map(|i| vm.call_with(&generator, [i.into()]))
.collect::<Result<imbl::Vector<Value>, _>>()
.map(|list| Value::List(NixList::from(list)))
.map_err(Into::into)
}
#[builtin("getAttr")]
fn builtin_get_attr(_: &mut VM, key: Value, set: Value) -> Result<Value, ErrorKind> {
let k = key.to_str()?;
let xs = set.to_attrs()?;
match xs.select(k.as_str()) {
Some(x) => Ok(x.clone()),
None => Err(ErrorKind::AttributeNotFound {
name: k.to_string(),
}),
}
}
#[builtin("groupBy")]
fn builtin_group_by(vm: &mut VM, f: Value, list: Value) -> Result<Value, ErrorKind> {
let mut res: BTreeMap<NixString, imbl::Vector<Value>> = BTreeMap::new();
for val in list.to_list()? {
let key = vm.call_with(&f, [val.clone()])?.force(vm)?.to_str()?;
res.entry(key)
.or_insert_with(imbl::Vector::new)
.push_back(val);
}
Ok(Value::attrs(NixAttrs::from_iter(
res.into_iter()
.map(|(k, v)| (k, Value::List(NixList::from(v)))),
)))
}
#[builtin("hasAttr")]
fn builtin_has_attr(_: &mut VM, key: Value, set: Value) -> Result<Value, ErrorKind> {
let k = key.to_str()?;
let xs = set.to_attrs()?;
Ok(Value::Bool(xs.contains(k.as_str())))
}
#[builtin("head")]
fn builtin_head(_: &mut VM, list: Value) -> Result<Value, ErrorKind> {
match list.to_list()?.get(0) {
Some(x) => Ok(x.clone()),
None => Err(ErrorKind::IndexOutOfBounds { index: 0 }),
}
}
#[builtin("intersectAttrs")]
fn builtin_intersect_attrs(_: &mut VM, x: Value, y: Value) -> Result<Value, ErrorKind> {
let attrs1 = x.to_attrs()?;
let attrs2 = y.to_attrs()?;
let res = attrs2.iter().filter_map(|(k, v)| {
if attrs1.contains(k) {
Some((k.clone(), v.clone()))
} else {
None
}
});
Ok(Value::attrs(NixAttrs::from_iter(res)))
}
// For `is*` predicates we force manually, as Value::force also unwraps any Thunks
#[builtin("isAttrs")]
fn builtin_is_attrs(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Attrs(_))))
}
#[builtin("isBool")]
fn builtin_is_bool(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Bool(_))))
}
#[builtin("isFloat")]
fn builtin_is_float(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Float(_))))
}
#[builtin("isFunction")]
fn builtin_is_function(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(
*value,
Value::Closure(_) | Value::Builtin(_)
)))
}
#[builtin("isInt")]
fn builtin_is_int(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Integer(_))))
}
#[builtin("isList")]
fn builtin_is_list(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::List(_))))
}
#[builtin("isNull")]
fn builtin_is_null(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Null)))
}
#[builtin("isPath")]
fn builtin_is_path(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::Path(_))))
}
#[builtin("isString")]
fn builtin_is_string(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
let value = x.force(vm)?;
Ok(Value::Bool(matches!(*value, Value::String(_))))
}
#[builtin("length")]
fn builtin_length(_: &mut VM, list: Value) -> Result<Value, ErrorKind> {
Ok(Value::Integer(list.to_list()?.len() as i64))
}
#[builtin("lessThan")]
fn builtin_less_than(
vm: &mut VM,
#[lazy] x: Value,
#[lazy] y: Value,
) -> Result<Value, ErrorKind> {
Ok(Value::Bool(matches!(
x.force(vm)?.nix_cmp(&*y.force(vm)?, vm)?,
Some(Ordering::Less)
)))
}
#[builtin("listToAttrs")]
fn builtin_list_to_attrs(vm: &mut VM, list: Value) -> Result<Value, ErrorKind> {
let list = list.to_list()?;
let mut map = BTreeMap::new();
for val in list {
let attrs = val.force(vm)?.to_attrs()?;
let name = attrs.select_required("name")?.force(vm)?.to_str()?;
let value = attrs.select_required("value")?.clone();
// Map entries earlier in the list take precedence over entries later in the list
map.entry(name).or_insert(value);
}
Ok(Value::attrs(NixAttrs::from_iter(map.into_iter())))
}
#[builtin("map")]
fn builtin_map(vm: &mut VM, f: Value, list: Value) -> Result<Value, ErrorKind> {
let list: NixList = list.to_list()?;
list.into_iter()
.map(|val| vm.call_with(&f, [val]))
.collect::<Result<imbl::Vector<Value>, _>>()
.map(|list| Value::List(NixList::from(list)))
.map_err(Into::into)
}
#[builtin("mapAttrs")]
fn builtin_map_attrs(vm: &mut VM, f: Value, attrs: Value) -> Result<Value, ErrorKind> {
let attrs = attrs.to_attrs()?;
let res =
attrs
.as_ref()
.into_iter()
.flat_map(|(key, value)| -> EvalResult<(NixString, Value)> {
let value = vm.call_with(&f, [key.clone().into(), value.clone()])?;
Ok((key.to_owned(), value))
});
Ok(Value::attrs(NixAttrs::from_iter(res)))
}
#[builtin("match")]
fn builtin_match(_: &mut VM, regex: Value, str: Value) -> Result<Value, ErrorKind> {
let s = str.to_str()?;
let re = regex.to_str()?;
let re: Regex = Regex::new(&format!("^{}$", re.as_str())).unwrap();
match re.captures(&s) {
Some(caps) => Ok(caps
.iter()
.skip(1)
.map(|grp| grp.map(|g| Value::from(g.as_str())).unwrap_or(Value::Null))
.collect::<Vec<Value>>()
.into()),
None => Ok(Value::Null),
}
}
#[builtin("mul")]
fn builtin_mul(vm: &mut VM, #[lazy] x: Value, #[lazy] y: Value) -> Result<Value, ErrorKind> {
arithmetic_op!(&*x.force(vm)?, &*y.force(vm)?, *)
}
#[builtin("parseDrvName")]
fn builtin_parse_drv_name(_vm: &mut VM, s: Value) -> Result<Value, ErrorKind> {
// This replicates cppnix's (mis?)handling of codepoints
// above U+007f following 0x2d ('-')
let s = s.to_str()?;
let slice: &[u8] = s.as_str().as_ref();
let (name, dash_and_version) = slice.split_at(
slice
.windows(2)
.enumerate()
.find_map(|x| match x {
(idx, [b'-', c1]) if !c1.is_ascii_alphabetic() => Some(idx),
_ => None,
})
.unwrap_or(slice.len()),
);
let version = dash_and_version
.split_first()
.map(|x| core::str::from_utf8(x.1))
.unwrap_or(Ok(""))?;
Ok(Value::attrs(NixAttrs::from_iter(
[("name", core::str::from_utf8(name)?), ("version", version)].into_iter(),
)))
}
#[builtin("partition")]
fn builtin_partition(vm: &mut VM, pred: Value, list: Value) -> Result<Value, ErrorKind> {
let mut right: Vec<Value> = vec![];
let mut wrong: Vec<Value> = vec![];
let list: NixList = list.to_list()?;
for elem in list {
let result = vm.call_with(&pred, [elem.clone()])?;
if result.force(vm)?.as_bool()? {
right.push(elem);
} else {
wrong.push(elem);
};
}
let res = [("right", right), ("wrong", wrong)];
Ok(Value::attrs(NixAttrs::from_iter(res.into_iter())))
}
#[builtin("removeAttrs")]
fn builtin_remove_attrs(_: &mut VM, attrs: Value, keys: Value) -> Result<Value, ErrorKind> {
let attrs = attrs.to_attrs()?;
let keys = keys
.to_list()?
.into_iter()
.map(|v| v.to_str())
.collect::<Result<HashSet<_>, _>>()?;
let res = attrs.iter().filter_map(|(k, v)| {
if !keys.contains(k) {
Some((k.clone(), v.clone()))
} else {
None
}
});
Ok(Value::attrs(NixAttrs::from_iter(res)))
}
#[builtin("replaceStrings")]
fn builtin_replace_strings(
vm: &mut VM,
from: Value,
to: Value,
s: Value,
) -> Result<Value, ErrorKind> {
let from = from.to_list()?;
from.force_elements(vm)?;
let to = to.to_list()?;
to.force_elements(vm)?;
let string = s.to_str()?;
let mut res = String::new();
let mut i: usize = 0;
let mut empty_string_replace = false;
// This can't be implemented using Rust's string.replace() as
// well as a map because we need to handle errors with results
// as well as "reset" the iterator to zero for the replacement
// everytime there's a successful match.
// Also, Rust's string.replace allocates a new string
// on every call which is not preferable.
'outer: while i < string.len() {
// Try a match in all the from strings
for elem in std::iter::zip(from.iter(), to.iter()) {
let from = elem.0.to_str()?;
let to = elem.1.to_str()?;
if i + from.len() >= string.len() {
continue;
}
// We already applied a from->to with an empty from
// transformation.
// Let's skip it so that we don't loop infinitely
if empty_string_replace && from.as_str().is_empty() {
continue;
}
// if we match the `from` string, let's replace
if &string[i..i + from.len()] == from.as_str() {
res += &to;
i += from.len();
// remember if we applied the empty from->to
empty_string_replace = from.as_str().is_empty();
continue 'outer;
}
}
// If we don't match any `from`, we simply add a character
res += &string[i..i + 1];
i += 1;
// Since we didn't apply anything transformation,
// we reset the empty string replacement
empty_string_replace = false;
}
// Special case when the string is empty or at the string's end
// and one of the from is also empty
for elem in std::iter::zip(from.iter(), to.iter()) {
let from = elem.0.to_str()?;
let to = elem.1.to_str()?;
if from.as_str().is_empty() {
res += &to;
break;
}
}
Ok(Value::String(res.into()))
}
#[builtin("seq")]
fn builtin_seq(_: &mut VM, _x: Value, y: Value) -> Result<Value, ErrorKind> {
// The builtin calling infra has already forced both args for us, so
// we just return the second and ignore the first
Ok(y)
}
#[builtin("split")]
fn builtin_split(_: &mut VM, regex: Value, str: Value) -> Result<Value, ErrorKind> {
let s = str.to_str()?;
let text = s.as_str();
let re = regex.to_str()?;
let re: Regex = Regex::new(re.as_str()).unwrap();
let mut capture_locations = re.capture_locations();
let num_captures = capture_locations.len();
let mut ret = imbl::Vector::new();
let mut pos = 0;
while let Some(thematch) = re.captures_read_at(&mut capture_locations, text, pos) {
// push the unmatched characters preceding the match
ret.push_back(Value::from(&text[pos..thematch.start()]));
// Push a list with one element for each capture
// group in the regex, containing the characters
// matched by that capture group, or null if no match.
// We skip capture 0; it represents the whole match.
let v: imbl::Vector<Value> = (1..num_captures)
.map(|i| capture_locations.get(i))
.map(|o| {
o.map(|(start, end)| Value::from(&text[start..end]))
.unwrap_or(Value::Null)
})
.collect();
ret.push_back(Value::List(NixList::from(v)));
pos = thematch.end();
}
// push the unmatched characters following the last match
ret.push_back(Value::from(&text[pos..]));
Ok(Value::List(NixList::from(ret)))
}
#[builtin("sort")]
fn builtin_sort(vm: &mut VM, comparator: Value, list: Value) -> Result<Value, ErrorKind> {
// TODO: the bound on the sort function in
// `imbl::Vector::sort_by` is `Fn(...)`, which means that we can
// not use the mutable VM inside of its closure, hence the
// dance via `Vec`. I think this is just an unnecessarily
// restrictive bound in `im`, not a functional requirement.
let mut list = list.to_list()?.into_iter().collect::<Vec<_>>();
// Used to let errors "escape" from the sorting closure. If anything
// ends up setting an error, it is returned from this function.
let mut error: Option<ErrorKind> = None;
list.sort_by(|lhs, rhs| {
let result = vm
.call_with(&comparator, [lhs.clone(), rhs.clone()])
.map_err(|err| ErrorKind::ThunkForce(Box::new(err)))
.and_then(|v| v.force(vm)?.as_bool());
match (&error, result) {
// The contained closure only returns a "less
// than?"-boolean, no way to yield "equal".
(None, Ok(true)) => Ordering::Less,
(None, Ok(false)) => Ordering::Greater,
// Closest thing to short-circuiting out if an error was
// thrown.
(Some(_), _) => Ordering::Equal,
// Propagate the error if one was encountered.
(_, Err(e)) => {
error = Some(e);
Ordering::Equal
}
}
});
match error {
#[allow(deprecated)] // imbl::Vector usage prevented by its API
None => Ok(Value::List(NixList::from_vec(list))),
Some(e) => Err(e),
}
}
#[builtin("splitVersion")]
fn builtin_split_version(_: &mut VM, s: Value) -> Result<Value, ErrorKind> {
let s = s.to_str()?;
let s = VersionPartsIter::new(s.as_str());
let parts = s
.map(|s| {
Value::String(match s {
VersionPart::Number(n) => n.into(),
VersionPart::Word(w) => w.into(),
})
})
.collect::<Vec<Value>>();
Ok(Value::List(NixList::construct(parts.len(), parts)))
}
#[builtin("stringLength")]
fn builtin_string_length(vm: &mut VM, #[lazy] s: Value) -> Result<Value, ErrorKind> {
// also forces the value
let s = s.coerce_to_string(CoercionKind::Weak, vm)?;
Ok(Value::Integer(s.as_str().len() as i64))
}
#[builtin("sub")]
fn builtin_sub(vm: &mut VM, #[lazy] x: Value, #[lazy] y: Value) -> Result<Value, ErrorKind> {
arithmetic_op!(&*x.force(vm)?, &*y.force(vm)?, -)
}
#[builtin("substring")]
fn builtin_substring(
_: &mut VM,
start: Value,
len: Value,
s: Value,
) -> Result<Value, ErrorKind> {
let beg = start.as_int()?;
let len = len.as_int()?;
let x = s.to_str()?;
if beg < 0 {
return Err(ErrorKind::IndexOutOfBounds { index: beg });
}
let beg = beg as usize;
// Nix doesn't assert that the length argument is
// non-negative when the starting index is GTE the
// string's length.
if beg >= x.as_str().len() {
return Ok(Value::String("".into()));
}
if len < 0 {
return Err(ErrorKind::NegativeLength { length: len });
}
let len = len as usize;
let end = cmp::min(beg + len, x.as_str().len());
Ok(Value::String(x.as_str()[beg..end].into()))
}
#[builtin("tail")]
fn builtin_tail(_: &mut VM, list: Value) -> Result<Value, ErrorKind> {
let xs = list.to_list()?;
if xs.len() == 0 {
Err(ErrorKind::TailEmptyList)
} else {
let output = xs.into_iter().skip(1).collect::<Vec<_>>();
Ok(Value::List(NixList::construct(output.len(), output)))
}
}
#[builtin("throw")]
fn builtin_throw(_: &mut VM, message: Value) -> Result<Value, ErrorKind> {
Err(ErrorKind::Throw(message.to_str()?.to_string()))
}
#[builtin("toString")]
fn builtin_to_string(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
// coerce_to_string forces for us
x.coerce_to_string(CoercionKind::Strong, vm)
.map(Value::String)
}
#[builtin("placeholder")]
fn builtin_placeholder(vm: &mut VM, #[lazy] _: Value) -> Result<Value, ErrorKind> {
// TODO(amjoseph)
vm.emit_warning(WarningKind::NotImplemented("builtins.placeholder"));
Ok("<builtins.placeholder-is-not-implemented-in-tvix-yet>".into())
}
#[builtin("trace")]
fn builtin_trace(_: &mut VM, message: Value, value: Value) -> Result<Value, ErrorKind> {
// TODO(grfn): `trace` should be pluggable and capturable, probably via a method on
// the VM
println!("trace: {} :: {}", message, message.type_of());
Ok(value)
}
#[builtin("toPath")]
fn builtin_to_path(vm: &mut VM, #[lazy] s: Value) -> Result<Value, ErrorKind> {
let path: Value = crate::value::canon_path(coerce_value_to_path(&s, vm)?).into();
Ok(path.coerce_to_string(CoercionKind::Weak, vm)?.into())
}
#[builtin("tryEval")]
fn builtin_try_eval(vm: &mut VM, #[lazy] e: Value) -> Result<Value, ErrorKind> {
let res = match e.force(vm) {
Ok(value) => [("value", (*value).clone()), ("success", true.into())],
Err(e) if e.is_catchable() => [("value", false.into()), ("success", false.into())],
Err(e) => return Err(e),
};
Ok(Value::attrs(NixAttrs::from_iter(res.into_iter())))
}
#[builtin("typeOf")]
fn builtin_type_of(vm: &mut VM, #[lazy] x: Value) -> Result<Value, ErrorKind> {
// We force manually here because it also unwraps the Thunk
// representation, if any.
// TODO(sterni): it'd be nice if we didn't have to worry about this
let value = x.force(vm)?;
Ok(Value::String(value.type_of().into()))
}
}
pub(crate) fn builtin_tuple(builtin: Builtin) -> (&'static str, Value) {
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
(builtin.name(), Value::Builtin(builtin))
}
/// The set of standard pure builtins in Nix, mostly concerned with
/// data structure manipulation (string, attrs, list, etc. functions).
pub fn pure_builtins() -> Vec<(&'static str, Value)> {
let mut result = pure_builtins::builtins()
.into_iter()
.map(builtin_tuple)
.collect::<Vec<_>>();
// Pure-value builtins
result.push(("nixVersion", Value::String("2.3-compat-tvix-0.1".into())));
result.push(("langVersion", Value::Integer(6)));
result.push(("null", Value::Null));
result.push(("true", Value::Bool(true)));
result.push(("false", Value::Bool(false)));
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
result.push((
"currentSystem",
crate::systems::llvm_triple_to_nix_double(CURRENT_PLATFORM).into(),
));
result
}
/// Placeholder builtins that technically have a function which we do
/// not yet implement, but which is also not easily observable from
/// within a pure evaluation context.
///
/// These are used as a crutch to make progress on nixpkgs evaluation.
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
pub fn placeholders() -> Vec<(&'static str, Value)> {
let ph = vec![
Builtin::new(
"addErrorContext",
&[
BuiltinArgument {
strict: false,
name: "context",
},
BuiltinArgument {
strict: false,
name: "value",
},
],
None,
|mut args: Vec<Value>, vm: &mut VM| {
vm.emit_warning(WarningKind::NotImplemented("builtins.addErrorContext"));
Ok(args.pop().unwrap())
},
),
Builtin::new(
"unsafeDiscardStringContext",
&[BuiltinArgument {
strict: true,
name: "s",
}],
None,
|mut args: Vec<Value>, vm: &mut VM| {
vm.emit_warning(WarningKind::NotImplemented(
"builtins.unsafeDiscardStringContext",
));
Ok(args.pop().unwrap())
},
),
Builtin::new(
"unsafeGetAttrPos",
&[
BuiltinArgument {
strict: true,
name: "name",
},
BuiltinArgument {
strict: true,
name: "attrset",
},
],
None,
|mut args: Vec<Value>, vm: &mut VM| {
vm.emit_warning(WarningKind::NotImplemented("builtins.unsafeGetAttrsPos"));
let _attrset = args.pop().unwrap().to_attrs();
let _name = args.pop().unwrap().to_str();
let res = [
("line", 42.into()),
("col", 42.into()),
("file", Value::Path("/deep/thought".into())),
];
Ok(Value::attrs(NixAttrs::from_iter(res.into_iter())))
},
),
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
];
refactor(tvix/eval): streamline construction of globals/builtins Previously the construction of globals (a compiler-only concept) and builtins (a (now) user-facing API) was intermingled between multiple different modules, and kind of difficult to understand. The complexity of this had grown in large part due to the implementation of `builtins.import`, which required the notorious "knot-tying" trick using Rc::new_cyclic (see cl/7097) for constructing the set of globals. As part of the new `Evaluation` API users should have the ability to bring their own builtins, and control explicitly whether or not impure builtins are available (regardless of whether they're compiled in or not). To streamline the construction and allow the new API features to work, this commit restructures things by making these changes: 1. The `tvix_eval::builtins` module is now only responsible for exporting sets of builtins. It no longer has any knowledge of whether or not certain sets (e.g. only pure, or pure+impure) are enabled, and it has no control over which builtins are globally available (this is now handled in the compiler). 2. The compiler module is now responsible for both constructing the final attribute set of builtins from the set of builtins supplied by a user, as well as for populating its globals (that is identifiers which are available at the top-level scope). 3. The `Evaluation` API now carries a `builtins` field which is populated with the pure builtins by default, and can be extended by users. 4. The `import` feature has been moved into the compiler, as a special case. In general, builtins no longer have the ability to reference the "fix point" of the globals set. This should not change any functionality, and in fact preserves minor differences between Tvix/Nix that we already had (such as `builtins.builtins` not existing). Change-Id: Icdf5dd50eb81eb9260d89269d6e08b1e67811a2c Reviewed-on: https://cl.tvl.fyi/c/depot/+/7738 Reviewed-by: sterni <sternenseemann@systemli.org> Autosubmit: tazjin <tazjin@tvl.su> Tested-by: BuildkiteCI Reviewed-by: flokli <flokli@flokli.de>
2023-01-03 20:30:49 +01:00
ph.into_iter().map(builtin_tuple).collect()
}