lix/src/libstore/derivations.hh
2022-03-31 16:12:25 +02:00

325 lines
11 KiB
C++

#pragma once
#include "path.hh"
#include "types.hh"
#include "hash.hh"
#include "content-address.hh"
#include "repair-flag.hh"
#include "sync.hh"
#include <map>
#include <variant>
namespace nix {
/* Abstract syntax of derivations. */
/* The traditional non-fixed-output derivation type. */
struct DerivationOutputInputAddressed
{
StorePath path;
};
/* Fixed-output derivations, whose output paths are content addressed
according to that fixed output. */
struct DerivationOutputCAFixed
{
FixedOutputHash hash; /* hash used for expected hash computation */
StorePath path(const Store & store, std::string_view drvName, std::string_view outputName) const;
};
/* Floating-output derivations, whose output paths are content addressed, but
not fixed, and so are dynamically calculated from whatever the output ends
up being. */
struct DerivationOutputCAFloating
{
/* information used for expected hash computation */
FileIngestionMethod method;
HashType hashType;
};
/* Input-addressed output which depends on a (CA) derivation whose hash isn't
* known yet.
*/
struct DerivationOutputDeferred {};
/* Impure output which is moved to a content-addressed location (like
CAFloating) but isn't registered as a realization.
*/
struct DerivationOutputImpure
{
/* information used for expected hash computation */
FileIngestionMethod method;
HashType hashType;
};
typedef std::variant<
DerivationOutputInputAddressed,
DerivationOutputCAFixed,
DerivationOutputCAFloating,
DerivationOutputDeferred,
DerivationOutputImpure
> _DerivationOutputRaw;
struct DerivationOutput : _DerivationOutputRaw
{
using Raw = _DerivationOutputRaw;
using Raw::Raw;
using InputAddressed = DerivationOutputInputAddressed;
using CAFixed = DerivationOutputCAFixed;
using CAFloating = DerivationOutputCAFloating;
using Deferred = DerivationOutputDeferred;
using Impure = DerivationOutputImpure;
/* Note, when you use this function you should make sure that you're passing
the right derivation name. When in doubt, you should use the safer
interface provided by BasicDerivation::outputsAndOptPaths */
std::optional<StorePath> path(const Store & store, std::string_view drvName, std::string_view outputName) const;
inline const Raw & raw() const {
return static_cast<const Raw &>(*this);
}
};
typedef std::map<std::string, DerivationOutput> DerivationOutputs;
/* These are analogues to the previous DerivationOutputs data type, but they
also contains, for each output, the (optional) store path in which it would
be written. To calculate values of these types, see the corresponding
functions in BasicDerivation */
typedef std::map<std::string, std::pair<DerivationOutput, std::optional<StorePath>>>
DerivationOutputsAndOptPaths;
/* For inputs that are sub-derivations, we specify exactly which
output IDs we are interested in. */
typedef std::map<StorePath, StringSet> DerivationInputs;
struct DerivationType_InputAddressed {
bool deferred;
};
struct DerivationType_ContentAddressed {
bool sandboxed;
bool fixed;
};
struct DerivationType_Impure {
};
typedef std::variant<
DerivationType_InputAddressed,
DerivationType_ContentAddressed,
DerivationType_Impure
> _DerivationTypeRaw;
struct DerivationType : _DerivationTypeRaw {
using Raw = _DerivationTypeRaw;
using Raw::Raw;
using InputAddressed = DerivationType_InputAddressed;
using ContentAddressed = DerivationType_ContentAddressed;
using Impure = DerivationType_Impure;
/* Do the outputs of the derivation have paths calculated from their content,
or from the derivation itself? */
bool isCA() const;
/* Is the content of the outputs fixed a-priori via a hash? Never true for
non-CA derivations. */
bool isFixed() const;
/* Whether the derivation is fully sandboxed. If false, the
sandbox is opened up, e.g. the derivation has access to the
network. Note that whether or not we actually sandbox the
derivation is controlled separately. Always true for non-CA
derivations. */
bool isSandboxed() const;
/* Whether the derivation is expected to produce the same result
every time, and therefore it only needs to be built once. This
is only false for derivations that have the attribute '__impure
= true'. */
bool isPure() const;
/* Does the derivation knows its own output paths?
Only true when there's no floating-ca derivation involved in the
closure, or if fixed output.
*/
bool hasKnownOutputPaths() const;
inline const Raw & raw() const {
return static_cast<const Raw &>(*this);
}
};
struct BasicDerivation
{
DerivationOutputs outputs; /* keyed on symbolic IDs */
StorePathSet inputSrcs; /* inputs that are sources */
std::string platform;
Path builder;
Strings args;
StringPairs env;
std::string name;
BasicDerivation() = default;
virtual ~BasicDerivation() { };
bool isBuiltin() const;
/* Return true iff this is a fixed-output derivation. */
DerivationType type() const;
/* Return the output names of a derivation. */
StringSet outputNames() const;
/* Calculates the maps that contains all the DerivationOutputs, but
augmented with knowledge of the Store paths they would be written
into. */
DerivationOutputsAndOptPaths outputsAndOptPaths(const Store & store) const;
static std::string_view nameFromPath(const StorePath & storePath);
};
struct Derivation : BasicDerivation
{
DerivationInputs inputDrvs; /* inputs that are sub-derivations */
/* Print a derivation. */
std::string unparse(const Store & store, bool maskOutputs,
std::map<std::string, StringSet> * actualInputs = nullptr) const;
/* Return the underlying basic derivation but with these changes:
1. Input drvs are emptied, but the outputs of them that were used are
added directly to input sources.
2. Input placeholders are replaced with realized input store paths. */
std::optional<BasicDerivation> tryResolve(Store & store) const;
/* Like the above, but instead of querying the Nix database for
realisations, uses a given mapping from input derivation paths
+ output names to actual output store paths. */
std::optional<BasicDerivation> tryResolve(
Store & store,
const std::map<std::pair<StorePath, std::string>, StorePath> & inputDrvOutputs) const;
Derivation() = default;
Derivation(const BasicDerivation & bd) : BasicDerivation(bd) { }
Derivation(BasicDerivation && bd) : BasicDerivation(std::move(bd)) { }
};
class Store;
/* Write a derivation to the Nix store, and return its path. */
StorePath writeDerivation(Store & store,
const Derivation & drv,
RepairFlag repair = NoRepair,
bool readOnly = false);
/* Read a derivation from a file. */
Derivation parseDerivation(const Store & store, std::string && s, std::string_view name);
// FIXME: remove
bool isDerivation(const std::string & fileName);
/* Calculate the name that will be used for the store path for this
output.
This is usually <drv-name>-<output-name>, but is just <drv-name> when
the output name is "out". */
std::string outputPathName(std::string_view drvName, std::string_view outputName);
// The hashes modulo of a derivation.
//
// Each output is given a hash, although in practice only the content-addressed
// derivations (fixed-output or not) will have a different hash for each
// output.
struct DrvHash {
std::map<std::string, Hash> hashes;
enum struct Kind : bool {
// Statically determined derivations.
// This hash will be directly used to compute the output paths
Regular,
// Floating-output derivations (and their reverse dependencies).
Deferred,
};
Kind kind;
};
void operator |= (DrvHash::Kind & self, const DrvHash::Kind & other) noexcept;
/* Returns hashes with the details of fixed-output subderivations
expunged.
A fixed-output derivation is a derivation whose outputs have a
specified content hash and hash algorithm. (Currently they must have
exactly one output (`out'), which is specified using the `outputHash'
and `outputHashAlgo' attributes, but the algorithm doesn't assume
this.) We don't want changes to such derivations to propagate upwards
through the dependency graph, changing output paths everywhere.
For instance, if we change the url in a call to the `fetchurl'
function, we do not want to rebuild everything depending on it---after
all, (the hash of) the file being downloaded is unchanged. So the
*output paths* should not change. On the other hand, the *derivation
paths* should change to reflect the new dependency graph.
For fixed-output derivations, this returns a map from the name of
each output to its hash, unique up to the output's contents.
For regular derivations, it returns a single hash of the derivation
ATerm, after subderivations have been likewise expunged from that
derivation.
*/
DrvHash hashDerivationModulo(Store & store, const Derivation & drv, bool maskOutputs);
/*
Return a map associating each output to a hash that uniquely identifies its
derivation (modulo the self-references).
FIXME: what is the Hash in this map?
*/
std::map<std::string, Hash> staticOutputHashes(Store & store, const Derivation & drv);
/* Memoisation of hashDerivationModulo(). */
typedef std::map<StorePath, DrvHash> DrvHashes;
// FIXME: global, though at least thread-safe.
extern Sync<DrvHashes> drvHashes;
bool wantOutput(const std::string & output, const std::set<std::string> & wanted);
struct Source;
struct Sink;
Source & readDerivation(Source & in, const Store & store, BasicDerivation & drv, std::string_view name);
void writeDerivation(Sink & out, const Store & store, const BasicDerivation & drv);
/* This creates an opaque and almost certainly unique string
deterministically from the output name.
It is used as a placeholder to allow derivations to refer to their
own outputs without needing to use the hash of a derivation in
itself, making the hash near-impossible to calculate. */
std::string hashPlaceholder(const std::string_view outputName);
/* This creates an opaque and almost certainly unique string
deterministically from a derivation path and output name.
It is used as a placeholder to allow derivations to refer to
content-addressed paths whose content --- and thus the path
themselves --- isn't yet known. This occurs when a derivation has a
dependency which is a CA derivation. */
std::string downstreamPlaceholder(const Store & store, const StorePath & drvPath, std::string_view outputName);
extern const Hash impureOutputHash;
}