//! Implements `builtins.derivation`, the core of what makes Nix build packages.
use nix_compat::derivation::{Derivation, Output};
use nix_compat::nixhash;
use std::cell::RefCell;
use std::collections::{btree_map, BTreeSet};
use std::rc::Rc;
use tvix_eval::builtin_macros::builtins;
use tvix_eval::generators::{self, emit_warning_kind, GenCo};
use tvix_eval::{
AddContext, CatchableErrorKind, CoercionKind, ErrorKind, NixAttrs, NixList, Value, WarningKind,
};
use crate::errors::Error;
use crate::known_paths::{KnownPaths, PathKind, PathName};
// Constants used for strangely named fields in derivation inputs.
const STRUCTURED_ATTRS: &str = "__structuredAttrs";
const IGNORE_NULLS: &str = "__ignoreNulls";
/// Helper function for populating the `drv.outputs` field from a
/// manually specified set of outputs, instead of the default
/// `outputs`.
async fn populate_outputs(
co: &GenCo,
drv: &mut Derivation,
outputs: NixList,
) -> Result<(), ErrorKind> {
// Remove the original default `out` output.
drv.outputs.clear();
for output in outputs {
let output_name = generators::request_force(co, output)
.await
.to_str()
.context("determining output name")?;
if drv
.outputs
.insert(output_name.as_str().into(), Default::default())
.is_some()
{
return Err(Error::DuplicateOutput(output_name.as_str().into()).into());
}
}
Ok(())
}
/// Populate the inputs of a derivation from the build references
/// found when scanning the derivation's parameters.
fn populate_inputs<I: IntoIterator<Item = PathName>>(
drv: &mut Derivation,
known_paths: &KnownPaths,
references: I,
) {
for reference in references.into_iter() {
let reference = &known_paths[&reference];
match &reference.kind {
PathKind::Plain => {
drv.input_sources.insert(reference.path.clone());
}
PathKind::Output { name, derivation } => {
match drv.input_derivations.entry(derivation.clone()) {
btree_map::Entry::Vacant(entry) => {
entry.insert(BTreeSet::from([name.clone()]));
}
btree_map::Entry::Occupied(mut entry) => {
entry.get_mut().insert(name.clone());
}
}
}
PathKind::Derivation { output_names } => {
match drv.input_derivations.entry(reference.path.clone()) {
btree_map::Entry::Vacant(entry) => {
entry.insert(output_names.clone());
}
btree_map::Entry::Occupied(mut entry) => {
entry.get_mut().extend(output_names.clone().into_iter());
}
}
}
}
}
}
/// Populate the output configuration of a derivation based on the
/// parameters passed to the call, configuring a fixed-output derivation output
/// if necessary.
///
/// This function handles all possible combinations of the
/// parameters, including invalid ones.
///
/// Due to the support for SRI hashes, and how these are passed along to
/// builtins.derivation, outputHash and outputHashAlgo can have values which
/// need to be further modified before constructing the Derivation struct.
///
/// If outputHashAlgo is an SRI hash, outputHashAlgo must either be an empty
/// string, or the hash algorithm as specified in the (single) SRI (entry).
/// SRI strings with multiple hash algorithms are not supported.
///
/// In case an SRI string was used, the (single) fixed output is populated
/// with the hash algo name, and the hash digest is populated with the
/// (lowercase) hex encoding of the digest.
///
/// These values are only rewritten for the outputs, not what's passed to env.
fn handle_fixed_output(
drv: &mut Derivation,
hash_str: Option<String>, // in nix: outputHash
hash_algo_str: Option<String>, // in nix: outputHashAlgo
hash_mode_str: Option<String>, // in nix: outputHashmode
) -> Result<(), ErrorKind> {
// If outputHash is provided, ensure hash_algo_str is compatible.
// If outputHash is not provided, do nothing.
if let Some(hash_str) = hash_str {
// treat an empty algo as None
let hash_algo_str = match hash_algo_str {
Some(s) if s.is_empty() => None,
Some(s) => Some(s),
None => None,
};
// construct a NixHash.
let nixhash = nixhash::from_str(&hash_str, hash_algo_str.as_deref())
.map_err(Error::InvalidOutputHash)?;
// construct the fixed output.
drv.outputs.insert(
"out".to_string(),
Output {
path: "".to_string(),
ca_hash: match hash_mode_str.as_deref() {
None | Some("flat") => Some(nixhash::CAHash::Flat(nixhash)),
Some("recursive") => Some(nixhash::CAHash::Nar(nixhash)),
Some(other) => return Err(Error::InvalidOutputHashMode(other.to_string()))?,
},
},
);
}
Ok(())
}
/// Handles derivation parameters which are not just forwarded to
/// the environment. The return value indicates whether the
/// parameter should be included in the environment.
async fn handle_derivation_parameters(
drv: &mut Derivation,
co: &GenCo,
name: &str,
value: &Value,
val_str: &str,
) -> Result<Result<bool, CatchableErrorKind>, ErrorKind> {
match name {
IGNORE_NULLS => return Ok(Ok(false)),
// Command line arguments to the builder.
"args" => {
let args = value.to_list()?;
for arg in args {
match strong_coerce_to_string(co, arg).await? {
Err(cek) => return Ok(Err(cek)),
Ok(s) => drv.arguments.push(s),
}
}
// The arguments do not appear in the environment.
return Ok(Ok(false));
}
// Explicitly specified drv outputs (instead of default [ "out" ])
"outputs" => {
let outputs = value
.to_list()
.context("looking at the `outputs` parameter of the derivation")?;
populate_outputs(co, drv, outputs).await?;
}
"builder" => {
drv.builder = val_str.to_string();
}
"system" => {
drv.system = val_str.to_string();
}
_ => {}
}
Ok(Ok(true))
}
async fn strong_coerce_to_string(
co: &GenCo,
val: Value,
) -> Result<Result<String, CatchableErrorKind>, ErrorKind> {
let val = generators::request_force(co, val).await;
match generators::request_string_coerce(co, val, CoercionKind::Strong).await {
Err(cek) => Ok(Err(cek)),
Ok(val_str) => Ok(Ok(val_str.as_str().to_string())),
}
}
#[builtins(state = "Rc<RefCell<KnownPaths>>")]
mod derivation_builtins {
use super::*;
use nix_compat::store_path::hash_placeholder;
use tvix_eval::generators::Gen;
#[builtin("placeholder")]
async fn builtin_placeholder(co: GenCo, input: Value) -> Result<Value, ErrorKind> {
let placeholder = hash_placeholder(
input
.to_str()
.context("looking at output name in builtins.placeholder")?
.as_str(),
);
Ok(placeholder.into())
}
/// Strictly construct a Nix derivation from the supplied arguments.
///
/// This is considered an internal function, users usually want to
/// use the higher-level `builtins.derivation` instead.
#[builtin("derivationStrict")]
async fn builtin_derivation_strict(
state: Rc<RefCell<KnownPaths>>,
co: GenCo,
input: Value,
) -> Result<Value, ErrorKind> {
let input = input.to_attrs()?;
let name = generators::request_force(&co, input.select_required("name")?.clone())
.await
.to_str()
.context("determining derivation name")?;
if name.is_empty() {
return Err(ErrorKind::Abort("derivation has empty name".to_string()));
}
// Check whether attributes should be passed as a JSON file.
// TODO: the JSON serialisation has to happen here.
if let Some(sa) = input.select(STRUCTURED_ATTRS) {
if generators::request_force(&co, sa.clone()).await.as_bool()? {
return Err(ErrorKind::NotImplemented(STRUCTURED_ATTRS));
}
}
// Check whether null attributes should be ignored or passed through.
let ignore_nulls = match input.select(IGNORE_NULLS) {
Some(b) => generators::request_force(&co, b.clone()).await.as_bool()?,
None => false,
};
let mut drv = Derivation::default();
drv.outputs.insert("out".to_string(), Default::default());
async fn select_string(
co: &GenCo,
attrs: &NixAttrs,
key: &str,
) -> Result<Result<Option<String>, CatchableErrorKind>, ErrorKind> {
if let Some(attr) = attrs.select(key) {
match strong_coerce_to_string(co, attr.clone()).await? {
Err(cek) => return Ok(Err(cek)),
Ok(str) => return Ok(Ok(Some(str))),
}
}
Ok(Ok(None))
}
for (name, value) in input.clone().into_iter_sorted() {
let value = generators::request_force(&co, value).await;
if ignore_nulls && matches!(value, Value::Null) {
continue;
}
match strong_coerce_to_string(&co, value.clone()).await? {
Err(cek) => return Ok(Value::Catchable(cek)),
Ok(val_str) => {
// handle_derivation_parameters tells us whether the
// argument should be added to the environment; continue
// to the next one otherwise
match handle_derivation_parameters(
&mut drv,
&co,
name.as_str(),
&value,
&val_str,
)
.await?
{
Err(cek) => return Ok(Value::Catchable(cek)),
Ok(false) => continue,
_ => (),
}
// Most of these are also added to the builder's environment in "raw" form.
if drv
.environment
.insert(name.as_str().to_string(), val_str.into())
.is_some()
{
return Err(Error::DuplicateEnvVar(name.as_str().to_string()).into());
}
}
}
}
// Configure fixed-output derivations if required.
{
let output_hash = match select_string(&co, &input, "outputHash")
.await
.context("evaluating the `outputHash` parameter")?
{
Err(cek) => return Ok(Value::Catchable(cek)),
Ok(s) => s,
};
let output_hash_algo = match select_string(&co, &input, "outputHashAlgo")
.await
.context("evaluating the `outputHashAlgo` parameter")?
{
Err(cek) => return Ok(Value::Catchable(cek)),
Ok(s) => s,
};
let output_hash_mode = match select_string(&co, &input, "outputHashMode")
.await
.context("evaluating the `outputHashMode` parameter")?
{
Err(cek) => return Ok(Value::Catchable(cek)),
Ok(s) => s,
};
handle_fixed_output(&mut drv, output_hash, output_hash_algo, output_hash_mode)?;
}
// Scan references in relevant attributes to detect any build-references.
let references = {
let state = state.borrow();
if state.is_empty() {
// skip reference scanning, create an empty result
Default::default()
} else {
let mut refscan = state.reference_scanner();
drv.arguments.iter().for_each(|s| refscan.scan(s));
drv.environment.values().for_each(|s| refscan.scan(s));
refscan.scan(&drv.builder);
refscan.finalise()
}
};
// Each output name needs to exist in the environment, at this
// point initialised as an empty string because that is the
// way of Golang ;)
for output in drv.outputs.keys() {
if drv
.environment
.insert(output.to_string(), String::new().into())
.is_some()
{
emit_warning_kind(&co, WarningKind::ShadowedOutput(output.to_string())).await;
}
}
let mut known_paths = state.borrow_mut();
populate_inputs(&mut drv, &known_paths, references);
// At this point, derivation fields are fully populated from
// eval data structures.
drv.validate(false).map_err(Error::InvalidDerivation)?;
// Calculate the derivation_or_fod_hash for the current derivation.
// This one is still intermediate (so not added to known_paths)
let derivation_or_fod_hash_tmp =
drv.derivation_or_fod_hash(|drv| known_paths.get_hash_derivation_modulo(drv));
// Mutate the Derivation struct and set output paths
drv.calculate_output_paths(&name, &derivation_or_fod_hash_tmp)
.map_err(Error::InvalidDerivation)?;
let derivation_path = drv
.calculate_derivation_path(&name)
.map_err(Error::InvalidDerivation)?;
// recompute the hash derivation modulo and add to known_paths
let derivation_or_fod_hash_final =
drv.derivation_or_fod_hash(|drv| known_paths.get_hash_derivation_modulo(drv));
known_paths.add_hash_derivation_modulo(
derivation_path.to_absolute_path(),
&derivation_or_fod_hash_final,
);
// mark all the new paths as known
let output_names: Vec<String> = drv.outputs.keys().map(Clone::clone).collect();
known_paths.drv(derivation_path.to_absolute_path(), &output_names);
for (output_name, output) in &drv.outputs {
known_paths.output(
&output.path,
output_name,
derivation_path.to_absolute_path(),
);
}
let mut new_attrs: Vec<(String, String)> = drv
.outputs
.into_iter()
.map(|(name, output)| (name, output.path))
.collect();
new_attrs.push(("drvPath".to_string(), derivation_path.to_absolute_path()));
Ok(Value::Attrs(Box::new(NixAttrs::from_iter(
new_attrs.into_iter(),
))))
}
#[builtin("toFile")]
async fn builtin_to_file(
state: Rc<RefCell<KnownPaths>>,
co: GenCo,
name: Value,
content: Value,
) -> Result<Value, ErrorKind> {
let name = name
.to_str()
.context("evaluating the `name` parameter of builtins.toFile")?;
let content = content
.to_str()
.context("evaluating the `content` parameter of builtins.toFile")?;
let mut refscan = state.borrow().reference_scanner();
refscan.scan(content.as_str());
let refs = {
let paths = state.borrow();
refscan
.finalise()
.into_iter()
.map(|path| paths[&path].path.to_string())
.collect::<Vec<_>>()
};
// TODO: fail on derivation references (only "plain" is allowed here)
let path = nix_compat::store_path::build_text_path(name.as_str(), content.as_str(), refs)
.map_err(|_e| {
nix_compat::derivation::DerivationError::InvalidOutputName(
name.as_str().to_string(),
)
})
.map_err(Error::InvalidDerivation)?
.to_absolute_path();
state.borrow_mut().plain(&path);
// TODO: actually persist the file in the store at that path ...
Ok(Value::String(path.into()))
}
}
pub use derivation_builtins::builtins as derivation_builtins;
#[cfg(test)]
mod tests {
use crate::known_paths::KnownPaths;
use nix_compat::store_path::hash_placeholder;
use std::{cell::RefCell, rc::Rc};
use test_case::test_case;
use tvix_eval::EvaluationResult;
/// evaluates a given nix expression and returns the result.
/// Takes care of setting up the evaluator so it knows about the
// `derivation` builtin.
fn eval(str: &str) -> EvaluationResult {
let mut eval = tvix_eval::Evaluation::new_impure(str, None);
let known_paths: Rc<RefCell<KnownPaths>> = Default::default();
eval.builtins
.extend(crate::derivation::derivation_builtins(known_paths));
// Add the actual `builtins.derivation` from compiled Nix code
eval.src_builtins
.push(("derivation", include_str!("derivation.nix")));
// run the evaluation itself.
eval.evaluate()
}
#[test]
fn derivation() {
let result = eval(
r#"(derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux";}).outPath"#,
);
assert!(result.errors.is_empty(), "expect evaluation to succeed");
let value = result.value.expect("must be some");
match value {
tvix_eval::Value::String(s) => {
assert_eq!(
"/nix/store/xpcvxsx5sw4rbq666blz6sxqlmsqphmr-foo",
s.as_str()
);
}
_ => panic!("unexpected value type: {:?}", value),
}
}
/// a derivation with an empty name is an error.
#[test]
fn derivation_empty_name_fail() {
let result = eval(
r#"(derivation { name = ""; builder = "/bin/sh"; system = "x86_64-linux";}).outPath"#,
);
assert!(!result.errors.is_empty(), "expect evaluation to fail");
}
/// construct some calls to builtins.derivation and compare produced output
/// paths.
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/17wgs52s7kcamcyin4ja58njkf91ipq8-foo"; "r:sha256")]
#[test_case(r#"(builtins.derivation { name = "foo2"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/gi0p8vd635vpk1nq029cz3aa3jkhar5k-foo2"; "r:sha256 other name")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha1"; outputHash = "sha1-VUCRC+16gU5lcrLYHlPSUyx0Y/Q="; }).outPath"#, "/nix/store/p5sammmhpa84ama7ymkbgwwzrilva24x-foo"; "r:sha1")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "md5"; outputHash = "md5-07BzhNET7exJ6qYjitX/AA=="; }).outPath"#, "/nix/store/gmmxgpy1jrzs86r5y05wy6wiy2m15xgi-foo"; "r:md5")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha512"; outputHash = "sha512-DPkYCnZKuoY6Z7bXLwkYvBMcZ3JkLLLc5aNPCnAvlHDdwr8SXBIZixmVwjPDS0r9NGxUojNMNQqUilG26LTmtg=="; }).outPath"#, "/nix/store/lfi2bfyyap88y45mfdwi4j99gkaxaj19-foo"; "r:sha512")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "4374173a8cbe88de152b609f96f46e958bcf65762017474eec5a05ec2bd61530"; }).outPath"#, "/nix/store/17wgs52s7kcamcyin4ja58njkf91ipq8-foo"; "r:sha256 base16")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "0c0msqmyq1asxi74f5r0frjwz2wmdvs9d7v05caxx25yihx1fx23"; }).outPath"#, "/nix/store/17wgs52s7kcamcyin4ja58njkf91ipq8-foo"; "r:sha256 nixbase32")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/17wgs52s7kcamcyin4ja58njkf91ipq8-foo"; "r:sha256 base64")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "sha256-fgIr3TyFGDAXP5+qoAaiMKDg/a1MlT6Fv/S/DaA24S8="; }).outPath"#, "/nix/store/xm1l9dx4zgycv9qdhcqqvji1z88z534b-foo"; "r:sha256 base64 nopad")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "flat"; outputHashAlgo = "sha256"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/q4pkwkxdib797fhk22p0k3g1q32jmxvf-foo"; "sha256")]
#[test_case(r#"(builtins.derivation { name = "foo2"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "flat"; outputHashAlgo = "sha256"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/znw17xlmx9r6gw8izjkqxkl6s28sza4l-foo2"; "sha256 other name")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "flat"; outputHashAlgo = "sha1"; outputHash = "sha1-VUCRC+16gU5lcrLYHlPSUyx0Y/Q="; }).outPath"#, "/nix/store/zgpnjjmga53d8srp8chh3m9fn7nnbdv6-foo"; "sha1")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "flat"; outputHashAlgo = "md5"; outputHash = "md5-07BzhNET7exJ6qYjitX/AA=="; }).outPath"#, "/nix/store/jfhcwnq1852ccy9ad9nakybp2wadngnd-foo"; "md5")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "flat"; outputHashAlgo = "sha512"; outputHash = "sha512-DPkYCnZKuoY6Z7bXLwkYvBMcZ3JkLLLc5aNPCnAvlHDdwr8SXBIZixmVwjPDS0r9NGxUojNMNQqUilG26LTmtg=="; }).outPath"#, "/nix/store/as736rr116ian9qzg457f96j52ki8bm3-foo"; "sha512")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/17wgs52s7kcamcyin4ja58njkf91ipq8-foo"; "r:sha256 outputHashAlgo omitted")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#, "/nix/store/q4pkwkxdib797fhk22p0k3g1q32jmxvf-foo"; "r:sha256 outputHashAlgo and outputHashMode omitted")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; }).outPath"#, "/nix/store/xpcvxsx5sw4rbq666blz6sxqlmsqphmr-foo"; "outputHash* omitted")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; outputs = ["foo" "bar"]; system = "x86_64-linux"; }).outPath"#, "/nix/store/hkwdinvz2jpzgnjy9lv34d2zxvclj4s3-foo-foo"; "multiple outputs")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; args = ["--foo" "42" "--bar"]; system = "x86_64-linux"; }).outPath"#, "/nix/store/365gi78n2z7vwc1bvgb98k0a9cqfp6as-foo"; "args")]
#[test_case(r#"
let
bar = builtins.derivation {
name = "bar";
builder = ":";
system = ":";
outputHash = "08813cbee9903c62be4c5027726a418a300da4500b2d369d3af9286f4815ceba";
outputHashAlgo = "sha256";
outputHashMode = "recursive";
};
in
(builtins.derivation {
name = "foo";
builder = ":";
system = ":";
inherit bar;
}).outPath
"#, "/nix/store/5vyvcwah9l9kf07d52rcgdk70g2f4y13-foo"; "full")]
fn test_outpath(code: &str, expected_path: &str) {
let value = eval(code).value.expect("must succeed");
match value {
tvix_eval::Value::String(s) => {
assert_eq!(expected_path, s.as_str());
}
_ => panic!("unexpected value type: {:?}", value),
}
}
/// construct some calls to builtins.derivation that should be rejected
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha256"; outputHash = "sha256-00"; }).outPath"#; "invalid outputhash")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; system = "x86_64-linux"; outputHashMode = "recursive"; outputHashAlgo = "sha1"; outputHash = "sha256-Q3QXOoy+iN4VK2CflvRulYvPZXYgF0dO7FoF7CvWFTA="; }).outPath"#; "sha1 and sha256")]
#[test_case(r#"(builtins.derivation { name = "foo"; builder = "/bin/sh"; outputs = ["foo" "foo"]; system = "x86_64-linux"; }).outPath"#; "duplicate output names")]
fn test_outpath_invalid(code: &str) {
let resp = eval(code);
assert!(resp.value.is_none(), "Value should be None");
assert!(
!resp.errors.is_empty(),
"There should have been some errors"
);
}
#[test]
fn builtins_placeholder_hashes() {
assert_eq!(
hash_placeholder("out").as_str(),
"/1rz4g4znpzjwh1xymhjpm42vipw92pr73vdgl6xs1hycac8kf2n9"
);
assert_eq!(
hash_placeholder("").as_str(),
"/171rf4jhx57xqz3p7swniwkig249cif71pa08p80mgaf0mqz5bmr"
);
}
}