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path: root/tvix/eval/docs/build-references.md

Build references in derivations

This document describes how build references are calculated in Tvix. Build references are used to determine which store paths should be available to a builder during the execution of a build (i.e. the full build closure of a derivation).

String contexts in C++ Nix

In C++ Nix, each string value in the evaluator carries an optional so-called "string context".

These contexts are themselves a list of strings that take one of the following formats:

  1. !<output_name>!<drv_path>

    This format describes a build reference to a specific output of a derivation.

  2. =<drv_path>

    This format is used for a special case where a derivation attribute directly refers to a derivation path (e.g. by accessing .drvPath on a derivation).

    Note: In C++ Nix this case is quite special and actually requires a store-database query during evaluation.

  3. <path> - a non-descript store path input, usually a plain source file (e.g. from something like src = ./. or src = ./foo.txt).

    In the case of unsafeDiscardOutputDependency this is used to pass a raw derivation file, but not pull in its outputs.

Lets introduce names for these (in the same order) to make them easier to reference below:

enum BuildReference {
    /// !<output_name>!<drv_path>
    SingleOutput(OutputName, DrvPath),

    /// =<drv_path>
    DrvClosure(DrvPath),

    /// <path>
    Path(StorePath),
}

String contexts are, broadly speaking, created whenever a string is the result of a computation (e.g. string interpolation) that used a computed path or derivation in any way.

Note: This explicitly does not include simply writing a literal string containing a store path (whether valid or not). That is only permitted through the storePath builtin.

Derivation inputs

Based on the data above, the fields inputDrvs and inputSrcs of derivations are populated in builtins.derivationStrict (the function which builtins.derivation, which isn't actually a builtin, wraps).

inputDrvs is represented by a map of derivation paths to the set of their outputs that were referenced by the context.

TODO: What happens if the set is empty? Somebody claimed this means all outputs.

inputSrcs is represented by a set of paths.

These are populated by the above references as follows:

  • SingleOutput entries are merged into inputDrvs
  • Path entries are inserted into inputSrcs
  • DrvClosure leads to a special store computation (computeFSClosure), which finds all paths referenced by the derivation and then inserts all of them into the fields as above (derivations with all their outputs)

This is then serialised in the derivation and passed down the pipe.

Builtins interfacing with contexts

C++ Nix has several builtins that interface directly with string contexts:

  • unsafeDiscardStringContext: throws away a string's string context (if present)

  • hasContext: returns true/false depending on whether the string has context

  • unsafeDiscardOutputDependency: drops dependencies on the outputs of a .drv in the context, passing only the literal .drv itself

    Note: This is only used for special test-cases in nixpkgs, and deprecated Nix commands like nix-push.

  • getContext: returns the string context in serialised form as a Nix attribute set

  • appendContext: adds a given string context to the string in the same format as returned by getContext

Most of the string manipulation operations will propagate the context to the result based on their parameters' contexts.

Placeholders

C++ Nix has builtins.placeholder, which given the name of an output (e.g. out) creates a hashed string representation of that output name. If that string is used anywhere in input attributes, the builder will replace it with the actual name of the corresponding output of the current derivation.

C++ Nix does not use contexts for this, it blindly creates a rewrite map of these placeholder strings to the names of all outputs, and runs the output replacement logic on all environment variables it creates, attribute files it passes etc.

Tvix & string contexts

In the past, Tvix did not track string contexts in its evaluator at all, see the historical section for more information about that.

Tvix tracks string contexts in every NixString structure via a HashSet<BuildReference> and offers an API to combine the references while keeping the exact internal structure of that data private.

Historical attempt: Persistent reference tracking

We were investigating implementing a system which allows us to drop string contexts in favour of reference scanning derivation attributes.

This means that instead of maintaining and passing around a string context data structure in eval, we maintain a data structure of known paths from the same evaluation elsewhere in Tvix, and scan each derivation attribute against this set of known paths when instantiating derivations.

We believed we could take the stance that the system of string contexts as implemented in C++ Nix is likely an implementation detail that should not be leaking to the language surface as it does now.

Tracking "known paths"

Every time a Tvix evaluation does something that causes a store interaction, a "known path" is created. On the language surface, this is the result of one of:

  1. Path literals (e.g. src = ./.).
  2. Calls to builtins.derivationStrict yielding a derivation and its output paths.
  3. Calls to builtins.path.

Whenever one of these occurs, some metadata that persists for the duration of one evaluation should be created in Nix. This metadata needs to be available in builtins.derivationStrict, and should be able to respond to these queries:

  1. What is the set of all known paths? (used for e.g. instantiating an Aho-Corasick type string searcher)
  2. What is the type of a path? (derivation path, derivation output, source file)
  3. What are the outputs of a derivation?
  4. What is the derivation of an output?

These queries will need to be asked of the metadata when populating the derivation fields.

Note: Depending on how we implement builtins.placeholder, it might be useful to track created placeholders in this metadata, too.

Context builtins

Context-reading builtins can be implemented in Tvix by adding hasContext and getContext with the appropriate reference-scanning logic. However, we should evaluate how these are used in nixpkgs and whether their uses can be removed.

Context-mutating builtins can be implemented by tracking their effects in the value representation of Tvix, however we should consider not doing this at all.

unsafeDiscardOutputDependency should probably never be used and we should warn or error on it.

unsafeDiscardStringContext is often used as a workaround for avoiding IFD in inconvenient places (e.g. in the TVL depot pipeline generation). This is unnecessary in Tvix. We should evaluate which other uses exist, and act on them appropriately.

The initial danger with diverging here is that we might cause derivation hash discrepancies between Tvix and C++ Nix, which can make initial comparisons of derivations generated by the two systems difficult. If this occurs we need to discuss how to approach it, but initially we will implement the mutating builtins as no-ops.

Why this did not work for us?

Nix has a feature to perform environmental checks of your derivation, e.g. "these derivation outputs should not be referenced in this derivation", this was introduced in Nix 2.2 by https://github.com/NixOS/nix/commit/3cd15c5b1f5a8e6de87d5b7e8cc2f1326b420c88.

Unfortunately, this feature introduced a very unfortunate and critical bug: all usage of this feature with contextful strings will actually force the derivation to depend at least at build time on those specific paths, see https://github.com/NixOS/nix/issues/4629.

For example, if you wanted to disallowedReferences to a package and you used a derivation as a path, you would actually register that derivation as a input derivation of that derivation.

This bug is still unfixed in Nix and it seems that fixing it would require introducing different ways to evaluate Nix derivations to preserve the output path calculation for Nix expressions so far.

All of this would be fine if the bug behavior was uniform in the sense that no one tried to force-workaround it. Since Nixpkgs 23.05, due to https://github.com/NixOS/nixpkgs/pull/211783 this is not true anymore.

If you let nixpkgs be the disjoint union of bootstrapping derivations $A$ and stdenv.mkDerivation-built derivations $B$.

$A$ suffers from the bug and $B$ doesn't by the forced usage of unsafeDiscardStringContext on those special checking fields.

This means that to build hash-compatible $A$ and $B$, we need to distinguish $A$ and $B$. A lot of hacks could be imagined to support this problem.

Let's assume we have a solution to that problem, it means that we are able to detect implicitly when a set of specific fields are unsafeDiscardStringContext-ed.

Thus, we could use that same trick to implement unsafeDiscardStringContext entirely for all fields actually.

Now, to implement unsafeDiscardStringContext in the persistent reference tracking model, you will need to store a disallowed list of strings that should not trigger a reference when we are scanning a derivation parameters.

But assume you have something like:

derivation {
   buildInputs = [
     stdenv.cc
   ];

   disallowedReferences = [ stdenv.cc ];
}

If you unregister naively the stdenv.cc reference, it will silence the fact that it is part of the buildInputs, so you will observe that Nix will fail the derivation during environmental check, but Tvix would silently force remove that reference.

Until proven otherwise, it seems highly difficult to have the fine-grained information to prevent reference tracking of those specific fields. It is not a failure of the persistent reference tracking, it is an unresolved critical bug of Nix that only nixpkgs really workarounded for stdenv.mkDerivation-based derivations.