//! This module constructs a [Derivation] by parsing its [ATerm][] //! serialization. //! //! [ATerm]: http://program-transformation.org/Tools/ATermFormat.html use nom::bytes::complete::tag; use nom::character::complete::char as nomchar; use nom::combinator::{all_consuming, map_res}; use nom::multi::{separated_list0, separated_list1}; use nom::sequence::{delimited, preceded, separated_pair, terminated, tuple}; use std::collections::{btree_map, BTreeMap, BTreeSet}; use thiserror; use crate::derivation::parse_error::{into_nomerror, ErrorKind, NomError, NomResult}; use crate::derivation::{write, CAHash, Derivation, Output}; use crate::store_path::{self, StorePath}; use crate::{aterm, nixhash}; #[derive(Debug, thiserror::Error)] pub enum Error { #[error("parsing error: {0}")] Parser(NomError), #[error("premature EOF")] Incomplete, #[error("validation error: {0}")] Validation(super::DerivationError), } pub(crate) fn parse(i: &[u8]) -> Result> { match all_consuming(parse_derivation)(i) { Ok((rest, derivation)) => { // this shouldn't happen, as all_consuming shouldn't return. debug_assert!(rest.is_empty()); // invoke validate derivation.validate(true).map_err(Error::Validation)?; Ok(derivation) } Err(nom::Err::Incomplete(_)) => Err(Error::Incomplete), Err(nom::Err::Error(e) | nom::Err::Failure(e)) => Err(Error::Parser(e)), } } /// Consume a string containing the algo, and optionally a `r:` /// prefix, and a digest (bytes), return a [CAHash::Nar] or [CAHash::Flat]. fn from_algo_and_mode_and_digest>( algo_and_mode: &str, digest: B, ) -> crate::nixhash::NixHashResult { Ok(match algo_and_mode.strip_prefix("r:") { Some(algo) => nixhash::CAHash::Nar(nixhash::from_algo_and_digest( algo.try_into()?, digest.as_ref(), )?), None => nixhash::CAHash::Flat(nixhash::from_algo_and_digest( algo_and_mode.try_into()?, digest.as_ref(), )?), }) } /// Parse one output in ATerm. This is 4 string fields inside parans: /// output name, output path, algo (and mode), digest. /// Returns the output name and [Output] struct. fn parse_output(i: &[u8]) -> NomResult<&[u8], (String, Output)> { delimited( nomchar('('), map_res( |i| { tuple(( terminated(aterm::parse_string_field, nomchar(',')), terminated(aterm::parse_string_field, nomchar(',')), terminated(aterm::parse_string_field, nomchar(',')), aterm::parse_bytes_field, ))(i) .map_err(into_nomerror) }, |(output_name, output_path, algo_and_mode, encoded_digest)| { // convert these 4 fields into an [Output]. let ca_hash_res = { if algo_and_mode.is_empty() && encoded_digest.is_empty() { None } else { match data_encoding::HEXLOWER.decode(&encoded_digest) { Ok(digest) => { Some(from_algo_and_mode_and_digest(&algo_and_mode, digest)) } Err(e) => Some(Err(nixhash::Error::InvalidBase64Encoding(e))), } } } .transpose(); match ca_hash_res { Ok(hash_with_mode) => Ok(( output_name, Output { // TODO: Check if allowing empty paths here actually makes sense // or we should make this code stricter. path: if output_path.is_empty() { None } else { Some(string_to_store_path(i, &output_path)?) }, ca_hash: hash_with_mode, }, )), Err(e) => Err(nom::Err::Failure(NomError { input: i, code: ErrorKind::NixHashError(e), })), } }, ), nomchar(')'), )(i) } /// Parse multiple outputs in ATerm. This is a list of things acccepted by /// parse_output, and takes care of turning the (String, Output) returned from /// it to a BTreeMap. /// We don't use parse_kv here, as it's dealing with 2-tuples, and these are /// 4-tuples. fn parse_outputs(i: &[u8]) -> NomResult<&[u8], BTreeMap> { let res = delimited( nomchar('['), separated_list1(tag(","), parse_output), nomchar(']'), )(i); match res { Ok((rst, outputs_lst)) => { let mut outputs = BTreeMap::default(); for (output_name, output) in outputs_lst.into_iter() { if outputs.contains_key(&output_name) { return Err(nom::Err::Failure(NomError { input: i, code: ErrorKind::DuplicateMapKey(output_name.to_string()), })); } outputs.insert(output_name, output); } Ok((rst, outputs)) } // pass regular parse errors along Err(e) => Err(e), } } fn parse_input_derivations( i: &[u8], ) -> NomResult<&[u8], BTreeMap, BTreeSet>> { let (i, input_derivations_list) = parse_kv(aterm::parse_string_list)(i)?; // This is a HashMap of drv paths to a list of output names. let mut input_derivations: BTreeMap, BTreeSet<_>> = BTreeMap::new(); for (input_derivation, output_names) in input_derivations_list { let mut new_output_names = BTreeSet::new(); for output_name in output_names.into_iter() { if new_output_names.contains(&output_name) { return Err(nom::Err::Failure(NomError { input: i, code: ErrorKind::DuplicateInputDerivationOutputName( input_derivation.to_string(), output_name.to_string(), ), })); } new_output_names.insert(output_name); } let input_derivation = string_to_store_path(i, input_derivation.as_str())?; input_derivations.insert(input_derivation, new_output_names); } Ok((i, input_derivations)) } fn parse_input_sources(i: &[u8]) -> NomResult<&[u8], BTreeSet>> { let (i, input_sources_lst) = aterm::parse_string_list(i).map_err(into_nomerror)?; let mut input_sources: BTreeSet<_> = BTreeSet::new(); for input_source in input_sources_lst.into_iter() { let input_source = string_to_store_path(i, input_source.as_str())?; if input_sources.contains(&input_source) { return Err(nom::Err::Failure(NomError { input: i, code: ErrorKind::DuplicateInputSource(input_source.to_owned()), })); } else { input_sources.insert(input_source); } } Ok((i, input_sources)) } fn string_to_store_path<'a, 'i, S>( i: &'i [u8], path_str: &'a str, ) -> Result, nom::Err>> where S: std::cmp::Eq + std::fmt::Display + std::clone::Clone + std::ops::Deref + std::convert::From<&'a str>, { let path = StorePath::from_absolute_path(path_str.as_bytes()).map_err(|e: store_path::Error| { nom::Err::Failure(NomError { input: i, code: e.into(), }) })?; #[cfg(debug_assertions)] assert_eq!(path_str, path.to_absolute_path()); Ok(path) } pub fn parse_derivation(i: &[u8]) -> NomResult<&[u8], Derivation> { use nom::Parser; preceded( tag(write::DERIVATION_PREFIX), delimited( // inside parens nomchar('('), // tuple requires all errors to be of the same type, so we need to be a // bit verbose here wrapping generic IResult into [NomATermResult]. tuple(( // parse outputs terminated(parse_outputs, nomchar(',')), // // parse input derivations terminated(parse_input_derivations, nomchar(',')), // // parse input sources terminated(parse_input_sources, nomchar(',')), // // parse system |i| terminated(aterm::parse_string_field, nomchar(','))(i).map_err(into_nomerror), // // parse builder |i| terminated(aterm::parse_string_field, nomchar(','))(i).map_err(into_nomerror), // // parse arguments |i| terminated(aterm::parse_string_list, nomchar(','))(i).map_err(into_nomerror), // parse environment parse_kv(aterm::parse_bytes_field), )), nomchar(')'), ) .map( |( outputs, input_derivations, input_sources, system, builder, arguments, environment, )| { Derivation { arguments, builder, environment, input_derivations, input_sources, outputs, system, } }, ), )(i) } /// Parse a list of key/value pairs into a BTreeMap. /// The parser for the values can be passed in. /// In terms of ATerm, this is just a 2-tuple, /// but we have the additional restriction that the first element needs to be /// unique across all tuples. pub(crate) fn parse_kv<'a, V, VF>( vf: VF, ) -> impl FnMut(&'a [u8]) -> NomResult<&'a [u8], BTreeMap> + 'static where VF: FnMut(&'a [u8]) -> nom::IResult<&'a [u8], V, nom::error::Error<&'a [u8]>> + Clone + 'static, { move |i| // inside brackets delimited( nomchar('['), |ii| { let res = separated_list0( nomchar(','), // inside parens delimited( nomchar('('), separated_pair( aterm::parse_string_field, nomchar(','), vf.clone(), ), nomchar(')'), ), )(ii).map_err(into_nomerror); match res { Ok((rest, pairs)) => { let mut kvs: BTreeMap = BTreeMap::new(); for (k, v) in pairs.into_iter() { // collect the 2-tuple to a BTreeMap, // and fail if the key was already seen before. match kvs.entry(k) { btree_map::Entry::Vacant(e) => { e.insert(v); }, btree_map::Entry::Occupied(e) => { return Err(nom::Err::Failure(NomError { input: i, code: ErrorKind::DuplicateMapKey(e.key().clone()), })); } } } Ok((rest, kvs)) } Err(e) => Err(e), } }, nomchar(']'), )(i) } #[cfg(test)] mod tests { use crate::store_path::StorePathRef; use std::collections::{BTreeMap, BTreeSet}; use crate::{ derivation::{ parse_error::ErrorKind, parser::from_algo_and_mode_and_digest, CAHash, NixHash, Output, }, store_path::StorePath, }; use bstr::{BString, ByteSlice}; use hex_literal::hex; use lazy_static::lazy_static; use rstest::rstest; const DIGEST_SHA256: [u8; 32] = hex!("a5ce9c155ed09397614646c9717fc7cd94b1023d7b76b618d409e4fefd6e9d39"); lazy_static! { pub static ref NIXHASH_SHA256: NixHash = NixHash::Sha256(DIGEST_SHA256); static ref EXP_MULTI_OUTPUTS: BTreeMap = { let mut b = BTreeMap::new(); b.insert( "lib".to_string(), Output { path: Some( StorePath::from_bytes( b"2vixb94v0hy2xc6p7mbnxxcyc095yyia-has-multi-out-lib", ) .unwrap(), ), ca_hash: None, }, ); b.insert( "out".to_string(), Output { path: Some( StorePath::from_bytes( b"55lwldka5nyxa08wnvlizyqw02ihy8ic-has-multi-out".as_bytes(), ) .unwrap(), ), ca_hash: None, }, ); b }; static ref EXP_AB_MAP: BTreeMap = { let mut b = BTreeMap::new(); b.insert("a".to_string(), b"1".into()); b.insert("b".to_string(), b"2".into()); b }; static ref EXP_INPUT_DERIVATIONS_SIMPLE: BTreeMap, BTreeSet> = { let mut b = BTreeMap::new(); b.insert( StorePath::from_bytes(b"8bjm87p310sb7r2r0sg4xrynlvg86j8k-hello-2.12.1.tar.gz.drv") .unwrap(), { let mut output_names = BTreeSet::new(); output_names.insert("out".to_string()); output_names }, ); b.insert( StorePath::from_bytes(b"p3jc8aw45dza6h52v81j7lk69khckmcj-bash-5.2-p15.drv") .unwrap(), { let mut output_names = BTreeSet::new(); output_names.insert("out".to_string()); output_names.insert("lib".to_string()); output_names }, ); b }; static ref EXP_INPUT_DERIVATIONS_SIMPLE_ATERM: String = { format!( "[(\"{0}\",[\"out\"]),(\"{1}\",[\"out\",\"lib\"])]", "/nix/store/8bjm87p310sb7r2r0sg4xrynlvg86j8k-hello-2.12.1.tar.gz.drv", "/nix/store/p3jc8aw45dza6h52v81j7lk69khckmcj-bash-5.2-p15.drv" ) }; static ref EXP_INPUT_SOURCES_SIMPLE: BTreeSet = { let mut b = BTreeSet::new(); b.insert("/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-has-multi-out".to_string()); b.insert("/nix/store/2vixb94v0hy2xc6p7mbnxxcyc095yyia-has-multi-out-lib".to_string()); b }; } /// Ensure parsing KVs works #[rstest] #[case::empty(b"[]", &BTreeMap::new(), b"")] #[case::simple(b"[(\"a\",\"1\"),(\"b\",\"2\")]", &EXP_AB_MAP, b"")] fn parse_kv( #[case] input: &'static [u8], #[case] expected: &BTreeMap, #[case] exp_rest: &[u8], ) { let (rest, parsed) = super::parse_kv(crate::aterm::parse_bytes_field)(input).expect("must parse"); assert_eq!(exp_rest, rest, "expected remainder"); assert_eq!(*expected, parsed); } /// Ensures the kv parser complains about duplicate map keys #[test] fn parse_kv_fail_dup_keys() { let input: &'static [u8] = b"[(\"a\",\"1\"),(\"a\",\"2\")]"; let e = super::parse_kv(crate::aterm::parse_bytes_field)(input).expect_err("must fail"); match e { nom::Err::Failure(e) => { assert_eq!(ErrorKind::DuplicateMapKey("a".to_string()), e.code); } _ => panic!("unexpected error"), } } /// Ensure parsing input derivations works. #[rstest] #[case::empty(b"[]", &BTreeMap::new())] #[case::simple(EXP_INPUT_DERIVATIONS_SIMPLE_ATERM.as_bytes(), &EXP_INPUT_DERIVATIONS_SIMPLE)] fn parse_input_derivations( #[case] input: &'static [u8], #[case] expected: &BTreeMap, BTreeSet>, ) { let (rest, parsed) = super::parse_input_derivations(input).expect("must parse"); assert_eq!(expected, &parsed, "parsed mismatch"); assert!(rest.is_empty(), "rest must be empty"); } /// Ensures the input derivation parser complains about duplicate output names #[test] fn parse_input_derivations_fail_dup_output_names() { let input_str = format!( "[(\"{0}\",[\"out\"]),(\"{1}\",[\"out\",\"out\"])]", "/nix/store/8bjm87p310sb7r2r0sg4xrynlvg86j8k-hello-2.12.1.tar.gz.drv", "/nix/store/p3jc8aw45dza6h52v81j7lk69khckmcj-bash-5.2-p15.drv" ); let e = super::parse_input_derivations(input_str.as_bytes()).expect_err("must fail"); match e { nom::Err::Failure(e) => { assert_eq!( ErrorKind::DuplicateInputDerivationOutputName( "/nix/store/p3jc8aw45dza6h52v81j7lk69khckmcj-bash-5.2-p15.drv".to_string(), "out".to_string() ), e.code ); } _ => panic!("unexpected error"), } } /// Ensure parsing input sources works #[rstest] #[case::empty(b"[]", &BTreeSet::new())] #[case::simple(b"[\"/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-has-multi-out\",\"/nix/store/2vixb94v0hy2xc6p7mbnxxcyc095yyia-has-multi-out-lib\"]", &EXP_INPUT_SOURCES_SIMPLE)] fn parse_input_sources(#[case] input: &'static [u8], #[case] expected: &BTreeSet) { let (rest, parsed) = super::parse_input_sources(input).expect("must parse"); assert_eq!( expected, &parsed .iter() .map(StorePath::to_absolute_path) .collect::>(), "parsed mismatch" ); assert!(rest.is_empty(), "rest must be empty"); } /// Ensures the input sources parser complains about duplicate input sources #[test] fn parse_input_sources_fail_dup_keys() { let input: &'static [u8] = b"[\"/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-foo\",\"/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-foo\"]"; let e = super::parse_input_sources(input).expect_err("must fail"); match e { nom::Err::Failure(e) => { assert_eq!( ErrorKind::DuplicateInputSource( StorePathRef::from_absolute_path( "/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-foo".as_bytes() ) .unwrap() .to_owned() ), e.code ); } _ => panic!("unexpected error"), } } #[rstest] #[case::simple( br#"("out","/nix/store/5vyvcwah9l9kf07d52rcgdk70g2f4y13-foo","","")"#, ("out".to_string(), Output { path: Some( StorePathRef::from_absolute_path("/nix/store/5vyvcwah9l9kf07d52rcgdk70g2f4y13-foo".as_bytes()).unwrap().to_owned()), ca_hash: None }) )] #[case::fod( br#"("out","/nix/store/4q0pg5zpfmznxscq3avycvf9xdvx50n3-bar","r:sha256","08813cbee9903c62be4c5027726a418a300da4500b2d369d3af9286f4815ceba")"#, ("out".to_string(), Output { path: Some( StorePathRef::from_absolute_path( "/nix/store/4q0pg5zpfmznxscq3avycvf9xdvx50n3-bar".as_bytes()).unwrap().to_owned()), ca_hash: Some(from_algo_and_mode_and_digest("r:sha256", data_encoding::HEXLOWER.decode(b"08813cbee9903c62be4c5027726a418a300da4500b2d369d3af9286f4815ceba").unwrap() ).unwrap()), }) )] fn parse_output(#[case] input: &[u8], #[case] expected: (String, Output)) { let (rest, parsed) = super::parse_output(input).expect("must parse"); assert!(rest.is_empty()); assert_eq!(expected, parsed); } #[rstest] #[case::multi_out( br#"[("lib","/nix/store/2vixb94v0hy2xc6p7mbnxxcyc095yyia-has-multi-out-lib","",""),("out","/nix/store/55lwldka5nyxa08wnvlizyqw02ihy8ic-has-multi-out","","")]"#, &EXP_MULTI_OUTPUTS )] fn parse_outputs(#[case] input: &[u8], #[case] expected: &BTreeMap) { let (rest, parsed) = super::parse_outputs(input).expect("must parse"); assert!(rest.is_empty()); assert_eq!(*expected, parsed); } #[rstest] #[case::sha256_flat("sha256", &DIGEST_SHA256, CAHash::Flat(NIXHASH_SHA256.clone()))] #[case::sha256_recursive("r:sha256", &DIGEST_SHA256, CAHash::Nar(NIXHASH_SHA256.clone()))] fn test_from_algo_and_mode_and_digest( #[case] algo_and_mode: &str, #[case] digest: &[u8], #[case] expected: CAHash, ) { assert_eq!( expected, from_algo_and_mode_and_digest(algo_and_mode, digest).unwrap() ); } #[test] fn from_algo_and_mode_and_digest_failure() { assert!(from_algo_and_mode_and_digest("r:sha256", []).is_err()); assert!(from_algo_and_mode_and_digest("ha256", DIGEST_SHA256).is_err()); } }