lix/src/libstore/store-api.cc
2022-06-08 14:03:46 +02:00

1440 lines
46 KiB
C++

#include "crypto.hh"
#include "fs-accessor.hh"
#include "globals.hh"
#include "derivations.hh"
#include "store-api.hh"
#include "util.hh"
#include "nar-info-disk-cache.hh"
#include "thread-pool.hh"
#include "json.hh"
#include "url.hh"
#include "archive.hh"
#include "callback.hh"
#include "remote-store.hh"
#include <regex>
namespace nix {
bool Store::isInStore(const Path & path) const
{
return isInDir(path, storeDir);
}
std::pair<StorePath, Path> Store::toStorePath(const Path & path) const
{
if (!isInStore(path))
throw Error("path '%1%' is not in the Nix store", path);
Path::size_type slash = path.find('/', storeDir.size() + 1);
if (slash == Path::npos)
return {parseStorePath(path), ""};
else
return {parseStorePath(std::string_view(path).substr(0, slash)), path.substr(slash)};
}
Path Store::followLinksToStore(std::string_view _path) const
{
Path path = absPath(std::string(_path));
while (!isInStore(path)) {
if (!isLink(path)) break;
auto target = readLink(path);
path = absPath(target, dirOf(path));
}
if (!isInStore(path))
throw BadStorePath("path '%1%' is not in the Nix store", path);
return path;
}
StorePath Store::followLinksToStorePath(std::string_view path) const
{
return toStorePath(followLinksToStore(path)).first;
}
/* Store paths have the following form:
<realized-path> = <store>/<h>-<name>
where
<store> = the location of the Nix store, usually /nix/store
<name> = a human readable name for the path, typically obtained
from the name attribute of the derivation, or the name of the
source file from which the store path is created. For derivation
outputs other than the default "out" output, the string "-<id>"
is suffixed to <name>.
<h> = base-32 representation of the first 160 bits of a SHA-256
hash of <s>; the hash part of the store name
<s> = the string "<type>:sha256:<h2>:<store>:<name>";
note that it includes the location of the store as well as the
name to make sure that changes to either of those are reflected
in the hash (e.g. you won't get /nix/store/<h>-name1 and
/nix/store/<h>-name2 with equal hash parts).
<type> = one of:
"text:<r1>:<r2>:...<rN>"
for plain text files written to the store using
addTextToStore(); <r1> ... <rN> are the store paths referenced
by this path, in the form described by <realized-path>
"source:<r1>:<r2>:...:<rN>:self"
for paths copied to the store using addToStore() when recursive
= true and hashAlgo = "sha256". Just like in the text case, we
can have the store paths referenced by the path.
Additionally, we can have an optional :self label to denote self
reference.
"output:<id>"
for either the outputs created by derivations, OR paths copied
to the store using addToStore() with recursive != true or
hashAlgo != "sha256" (in that case "source" is used; it's
silly, but it's done that way for compatibility). <id> is the
name of the output (usually, "out").
<h2> = base-16 representation of a SHA-256 hash of:
if <type> = "text:...":
the string written to the resulting store path
if <type> = "source":
the serialisation of the path from which this store path is
copied, as returned by hashPath()
if <type> = "output:<id>":
for non-fixed derivation outputs:
the derivation (see hashDerivationModulo() in
primops.cc)
for paths copied by addToStore() or produced by fixed-output
derivations:
the string "fixed:out:<rec><algo>:<hash>:", where
<rec> = "r:" for recursive (path) hashes, or "" for flat
(file) hashes
<algo> = "md5", "sha1" or "sha256"
<hash> = base-16 representation of the path or flat hash of
the contents of the path (or expected contents of the
path for fixed-output derivations)
Note that since an output derivation has always type output, while
something added by addToStore can have type output or source depending
on the hash, this means that the same input can be hashed differently
if added to the store via addToStore or via a derivation, in the sha256
recursive case.
It would have been nicer to handle fixed-output derivations under
"source", e.g. have something like "source:<rec><algo>", but we're
stuck with this for now...
The main reason for this way of computing names is to prevent name
collisions (for security). For instance, it shouldn't be feasible
to come up with a derivation whose output path collides with the
path for a copied source. The former would have a <s> starting with
"output:out:", while the latter would have a <s> starting with
"source:".
*/
StorePath Store::makeStorePath(std::string_view type,
std::string_view hash, std::string_view name) const
{
/* e.g., "source:sha256:1abc...:/nix/store:foo.tar.gz" */
auto s = std::string(type) + ":" + std::string(hash)
+ ":" + storeDir + ":" + std::string(name);
auto h = compressHash(hashString(htSHA256, s), 20);
return StorePath(h, name);
}
StorePath Store::makeStorePath(std::string_view type,
const Hash & hash, std::string_view name) const
{
return makeStorePath(type, hash.to_string(Base16, true), name);
}
StorePath Store::makeOutputPath(std::string_view id,
const Hash & hash, std::string_view name) const
{
return makeStorePath("output:" + std::string { id }, hash, outputPathName(name, id));
}
static std::string makeType(
const Store & store,
std::string && type,
const StorePathSet & references,
bool hasSelfReference = false)
{
for (auto & i : references) {
type += ":";
type += store.printStorePath(i);
}
if (hasSelfReference) type += ":self";
return std::move(type);
}
StorePath Store::makeFixedOutputPath(
FileIngestionMethod method,
const Hash & hash,
std::string_view name,
const StorePathSet & references,
bool hasSelfReference) const
{
if (hash.type == htSHA256 && method == FileIngestionMethod::Recursive) {
return makeStorePath(makeType(*this, "source", references, hasSelfReference), hash, name);
} else {
assert(references.empty());
return makeStorePath("output:out",
hashString(htSHA256,
"fixed:out:"
+ makeFileIngestionPrefix(method)
+ hash.to_string(Base16, true) + ":"),
name);
}
}
StorePath Store::makeFixedOutputPathFromCA(std::string_view name, ContentAddress ca,
const StorePathSet & references, bool hasSelfReference) const
{
// New template
return std::visit(overloaded {
[&](const TextHash & th) {
return makeTextPath(name, th.hash, references);
},
[&](const FixedOutputHash & fsh) {
return makeFixedOutputPath(fsh.method, fsh.hash, name, references, hasSelfReference);
}
}, ca);
}
StorePath Store::makeTextPath(std::string_view name, const Hash & hash,
const StorePathSet & references) const
{
assert(hash.type == htSHA256);
/* Stuff the references (if any) into the type. This is a bit
hacky, but we can't put them in `s' since that would be
ambiguous. */
return makeStorePath(makeType(*this, "text", references), hash, name);
}
std::pair<StorePath, Hash> Store::computeStorePathForPath(std::string_view name,
const Path & srcPath, FileIngestionMethod method, HashType hashAlgo, PathFilter & filter) const
{
Hash h = method == FileIngestionMethod::Recursive
? hashPath(hashAlgo, srcPath, filter).first
: hashFile(hashAlgo, srcPath);
return std::make_pair(makeFixedOutputPath(method, h, name), h);
}
StorePath Store::computeStorePathForText(
std::string_view name,
std::string_view s,
const StorePathSet & references) const
{
return makeTextPath(name, hashString(htSHA256, s), references);
}
StorePath Store::addToStore(
std::string_view name,
const Path & _srcPath,
FileIngestionMethod method,
HashType hashAlgo,
PathFilter & filter,
RepairFlag repair,
const StorePathSet & references)
{
Path srcPath(absPath(_srcPath));
auto source = sinkToSource([&](Sink & sink) {
if (method == FileIngestionMethod::Recursive)
dumpPath(srcPath, sink, filter);
else
readFile(srcPath, sink);
});
return addToStoreFromDump(*source, name, method, hashAlgo, repair, references);
}
void Store::addMultipleToStore(
PathsSource & pathsToCopy,
Activity & act,
RepairFlag repair,
CheckSigsFlag checkSigs)
{
std::atomic<size_t> nrDone{0};
std::atomic<size_t> nrFailed{0};
std::atomic<uint64_t> bytesExpected{0};
std::atomic<uint64_t> nrRunning{0};
using PathWithInfo = std::pair<ValidPathInfo, std::unique_ptr<Source>>;
std::map<StorePath, PathWithInfo*> infosMap;
StorePathSet storePathsToAdd;
for (auto & thingToAdd : pathsToCopy) {
infosMap.insert_or_assign(thingToAdd.first.path, &thingToAdd);
storePathsToAdd.insert(thingToAdd.first.path);
}
auto showProgress = [&]() {
act.progress(nrDone, pathsToCopy.size(), nrRunning, nrFailed);
};
ThreadPool pool;
processGraph<StorePath>(pool,
storePathsToAdd,
[&](const StorePath & path) {
auto & [info, source] = *infosMap.at(path);
/* auto storePathForDst = info.storePath; */
/* if (info->ca && info->references.empty()) { */
/* storePathForDst = dstStore.makeFixedOutputPathFromCA(storePath.name(), *info->ca); */
/* if (dstStore.storeDir == srcStore.storeDir) */
/* assert(storePathForDst == storePath); */
/* if (storePathForDst != storePath) */
/* debug("replaced path '%s' to '%s' for substituter '%s'", */
/* srcStore.printStorePath(storePath), */
/* dstStore.printStorePath(storePathForDst), */
/* dstStore.getUri()); */
/* } */
/* pathsMap.insert_or_assign(storePath, storePathForDst); */
if (isValidPath(info.path)) {
nrDone++;
showProgress();
return StorePathSet();
}
bytesExpected += info.narSize;
act.setExpected(actCopyPath, bytesExpected);
return info.references;
},
[&](const StorePath & path) {
checkInterrupt();
auto & [info, source] = *infosMap.at(path);
if (!isValidPath(info.path)) {
MaintainCount<decltype(nrRunning)> mc(nrRunning);
showProgress();
try {
addToStore(info, *source, repair, checkSigs);
} catch (Error &e) {
nrFailed++;
if (!settings.keepGoing)
throw e;
printMsg(lvlError, "could not copy %s: %s", printStorePath(path), e.what());
showProgress();
return;
}
}
nrDone++;
showProgress();
});
}
void Store::addMultipleToStore(
Source & source,
RepairFlag repair,
CheckSigsFlag checkSigs)
{
auto expected = readNum<uint64_t>(source);
for (uint64_t i = 0; i < expected; ++i) {
auto info = ValidPathInfo::read(source, *this, 16);
info.ultimate = false;
addToStore(info, source, repair, checkSigs);
}
}
/*
The aim of this function is to compute in one pass the correct ValidPathInfo for
the files that we are trying to add to the store. To accomplish that in one
pass, given the different kind of inputs that we can take (normal nar archives,
nar archives with non SHA-256 hashes, and flat files), we set up a net of sinks
and aliases. Also, since the dataflow is obfuscated by this, we include here a
graphviz diagram:
digraph graphname {
node [shape=box]
fileSource -> narSink
narSink [style=dashed]
narSink -> unsualHashTee [style = dashed, label = "Recursive && !SHA-256"]
narSink -> narHashSink [style = dashed, label = "else"]
unsualHashTee -> narHashSink
unsualHashTee -> caHashSink
fileSource -> parseSink
parseSink [style=dashed]
parseSink-> fileSink [style = dashed, label = "Flat"]
parseSink -> blank [style = dashed, label = "Recursive"]
fileSink -> caHashSink
}
*/
ValidPathInfo Store::addToStoreSlow(std::string_view name, const Path & srcPath,
FileIngestionMethod method, HashType hashAlgo,
std::optional<Hash> expectedCAHash)
{
HashSink narHashSink { htSHA256 };
HashSink caHashSink { hashAlgo };
/* Note that fileSink and unusualHashTee must be mutually exclusive, since
they both write to caHashSink. Note that that requisite is currently true
because the former is only used in the flat case. */
RetrieveRegularNARSink fileSink { caHashSink };
TeeSink unusualHashTee { narHashSink, caHashSink };
auto & narSink = method == FileIngestionMethod::Recursive && hashAlgo != htSHA256
? static_cast<Sink &>(unusualHashTee)
: narHashSink;
/* Functionally, this means that fileSource will yield the content of
srcPath. The fact that we use scratchpadSink as a temporary buffer here
is an implementation detail. */
auto fileSource = sinkToSource([&](Sink & scratchpadSink) {
dumpPath(srcPath, scratchpadSink);
});
/* tapped provides the same data as fileSource, but we also write all the
information to narSink. */
TeeSource tapped { *fileSource, narSink };
ParseSink blank;
auto & parseSink = method == FileIngestionMethod::Flat
? fileSink
: blank;
/* The information that flows from tapped (besides being replicated in
narSink), is now put in parseSink. */
parseDump(parseSink, tapped);
/* We extract the result of the computation from the sink by calling
finish. */
auto [narHash, narSize] = narHashSink.finish();
auto hash = method == FileIngestionMethod::Recursive && hashAlgo == htSHA256
? narHash
: caHashSink.finish().first;
if (expectedCAHash && expectedCAHash != hash)
throw Error("hash mismatch for '%s'", srcPath);
ValidPathInfo info {
makeFixedOutputPath(method, hash, name),
narHash,
};
info.narSize = narSize;
info.ca = FixedOutputHash { .method = method, .hash = hash };
if (!isValidPath(info.path)) {
auto source = sinkToSource([&](Sink & scratchpadSink) {
dumpPath(srcPath, scratchpadSink);
});
addToStore(info, *source);
}
return info;
}
StringSet StoreConfig::getDefaultSystemFeatures()
{
auto res = settings.systemFeatures.get();
if (settings.isExperimentalFeatureEnabled(Xp::CaDerivations))
res.insert("ca-derivations");
if (settings.isExperimentalFeatureEnabled(Xp::RecursiveNix))
res.insert("recursive-nix");
return res;
}
Store::Store(const Params & params)
: StoreConfig(params)
, state({(size_t) pathInfoCacheSize})
{
}
std::string Store::getUri()
{
return "";
}
bool Store::PathInfoCacheValue::isKnownNow()
{
std::chrono::duration ttl = didExist()
? std::chrono::seconds(settings.ttlPositiveNarInfoCache)
: std::chrono::seconds(settings.ttlNegativeNarInfoCache);
return std::chrono::steady_clock::now() < time_point + ttl;
}
std::map<std::string, std::optional<StorePath>> Store::queryPartialDerivationOutputMap(const StorePath & path)
{
std::map<std::string, std::optional<StorePath>> outputs;
auto drv = readInvalidDerivation(path);
for (auto& [outputName, output] : drv.outputsAndOptPaths(*this)) {
outputs.emplace(outputName, output.second);
}
return outputs;
}
OutputPathMap Store::queryDerivationOutputMap(const StorePath & path) {
auto resp = queryPartialDerivationOutputMap(path);
OutputPathMap result;
for (auto & [outName, optOutPath] : resp) {
if (!optOutPath)
throw Error("output '%s' of derivation '%s' has no store path mapped to it", outName, printStorePath(path));
result.insert_or_assign(outName, *optOutPath);
}
return result;
}
StorePathSet Store::queryDerivationOutputs(const StorePath & path)
{
auto outputMap = this->queryDerivationOutputMap(path);
StorePathSet outputPaths;
for (auto & i: outputMap) {
outputPaths.emplace(std::move(i.second));
}
return outputPaths;
}
bool Store::isValidPath(const StorePath & storePath)
{
{
auto state_(state.lock());
auto res = state_->pathInfoCache.get(std::string(storePath.to_string()));
if (res && res->isKnownNow()) {
stats.narInfoReadAverted++;
return res->didExist();
}
}
if (diskCache) {
auto res = diskCache->lookupNarInfo(getUri(), std::string(storePath.hashPart()));
if (res.first != NarInfoDiskCache::oUnknown) {
stats.narInfoReadAverted++;
auto state_(state.lock());
state_->pathInfoCache.upsert(std::string(storePath.to_string()),
res.first == NarInfoDiskCache::oInvalid ? PathInfoCacheValue{} : PathInfoCacheValue { .value = res.second });
return res.first == NarInfoDiskCache::oValid;
}
}
bool valid = isValidPathUncached(storePath);
if (diskCache && !valid)
// FIXME: handle valid = true case.
diskCache->upsertNarInfo(getUri(), std::string(storePath.hashPart()), 0);
return valid;
}
/* Default implementation for stores that only implement
queryPathInfoUncached(). */
bool Store::isValidPathUncached(const StorePath & path)
{
try {
queryPathInfo(path);
return true;
} catch (InvalidPath &) {
return false;
}
}
ref<const ValidPathInfo> Store::queryPathInfo(const StorePath & storePath)
{
std::promise<ref<const ValidPathInfo>> promise;
queryPathInfo(storePath,
{[&](std::future<ref<const ValidPathInfo>> result) {
try {
promise.set_value(result.get());
} catch (...) {
promise.set_exception(std::current_exception());
}
}});
return promise.get_future().get();
}
static bool goodStorePath(const StorePath & expected, const StorePath & actual)
{
return
expected.hashPart() == actual.hashPart()
&& (expected.name() == Store::MissingName || expected.name() == actual.name());
}
void Store::queryPathInfo(const StorePath & storePath,
Callback<ref<const ValidPathInfo>> callback) noexcept
{
auto hashPart = std::string(storePath.hashPart());
try {
{
auto res = state.lock()->pathInfoCache.get(std::string(storePath.to_string()));
if (res && res->isKnownNow()) {
stats.narInfoReadAverted++;
if (!res->didExist())
throw InvalidPath("path '%s' is not valid", printStorePath(storePath));
return callback(ref<const ValidPathInfo>(res->value));
}
}
if (diskCache) {
auto res = diskCache->lookupNarInfo(getUri(), hashPart);
if (res.first != NarInfoDiskCache::oUnknown) {
stats.narInfoReadAverted++;
{
auto state_(state.lock());
state_->pathInfoCache.upsert(std::string(storePath.to_string()),
res.first == NarInfoDiskCache::oInvalid ? PathInfoCacheValue{} : PathInfoCacheValue{ .value = res.second });
if (res.first == NarInfoDiskCache::oInvalid ||
!goodStorePath(storePath, res.second->path))
throw InvalidPath("path '%s' is not valid", printStorePath(storePath));
}
return callback(ref<const ValidPathInfo>(res.second));
}
}
} catch (...) { return callback.rethrow(); }
auto callbackPtr = std::make_shared<decltype(callback)>(std::move(callback));
queryPathInfoUncached(storePath,
{[this, storePath, hashPart, callbackPtr](std::future<std::shared_ptr<const ValidPathInfo>> fut) {
try {
auto info = fut.get();
if (diskCache)
diskCache->upsertNarInfo(getUri(), hashPart, info);
{
auto state_(state.lock());
state_->pathInfoCache.upsert(std::string(storePath.to_string()), PathInfoCacheValue { .value = info });
}
if (!info || !goodStorePath(storePath, info->path)) {
stats.narInfoMissing++;
throw InvalidPath("path '%s' is not valid", printStorePath(storePath));
}
(*callbackPtr)(ref<const ValidPathInfo>(info));
} catch (...) { callbackPtr->rethrow(); }
}});
}
void Store::queryRealisation(const DrvOutput & id,
Callback<std::shared_ptr<const Realisation>> callback) noexcept
{
try {
if (diskCache) {
auto [cacheOutcome, maybeCachedRealisation]
= diskCache->lookupRealisation(getUri(), id);
switch (cacheOutcome) {
case NarInfoDiskCache::oValid:
debug("Returning a cached realisation for %s", id.to_string());
callback(maybeCachedRealisation);
return;
case NarInfoDiskCache::oInvalid:
debug(
"Returning a cached missing realisation for %s",
id.to_string());
callback(nullptr);
return;
case NarInfoDiskCache::oUnknown:
break;
}
}
} catch (...) {
return callback.rethrow();
}
auto callbackPtr
= std::make_shared<decltype(callback)>(std::move(callback));
queryRealisationUncached(
id,
{ [this, id, callbackPtr](
std::future<std::shared_ptr<const Realisation>> fut) {
try {
auto info = fut.get();
if (diskCache) {
if (info)
diskCache->upsertRealisation(getUri(), *info);
else
diskCache->upsertAbsentRealisation(getUri(), id);
}
(*callbackPtr)(std::shared_ptr<const Realisation>(info));
} catch (...) {
callbackPtr->rethrow();
}
} });
}
std::shared_ptr<const Realisation> Store::queryRealisation(const DrvOutput & id)
{
using RealPtr = std::shared_ptr<const Realisation>;
std::promise<RealPtr> promise;
queryRealisation(id,
{[&](std::future<RealPtr> result) {
try {
promise.set_value(result.get());
} catch (...) {
promise.set_exception(std::current_exception());
}
}});
return promise.get_future().get();
}
void Store::substitutePaths(const StorePathSet & paths)
{
std::vector<DerivedPath> paths2;
for (auto & path : paths)
if (!path.isDerivation())
paths2.push_back(DerivedPath::Opaque{path});
uint64_t downloadSize, narSize;
StorePathSet willBuild, willSubstitute, unknown;
queryMissing(paths2,
willBuild, willSubstitute, unknown, downloadSize, narSize);
if (!willSubstitute.empty())
try {
std::vector<DerivedPath> subs;
for (auto & p : willSubstitute) subs.push_back(DerivedPath::Opaque{p});
buildPaths(subs);
} catch (Error & e) {
logWarning(e.info());
}
}
StorePathSet Store::queryValidPaths(const StorePathSet & paths, SubstituteFlag maybeSubstitute)
{
struct State
{
size_t left;
StorePathSet valid;
std::exception_ptr exc;
};
Sync<State> state_(State{paths.size(), StorePathSet()});
std::condition_variable wakeup;
ThreadPool pool;
auto doQuery = [&](const Path & path) {
checkInterrupt();
queryPathInfo(parseStorePath(path), {[path, this, &state_, &wakeup](std::future<ref<const ValidPathInfo>> fut) {
auto state(state_.lock());
try {
auto info = fut.get();
state->valid.insert(parseStorePath(path));
} catch (InvalidPath &) {
} catch (...) {
state->exc = std::current_exception();
}
assert(state->left);
if (!--state->left)
wakeup.notify_one();
}});
};
for (auto & path : paths)
pool.enqueue(std::bind(doQuery, printStorePath(path))); // FIXME
pool.process();
while (true) {
auto state(state_.lock());
if (!state->left) {
if (state->exc) std::rethrow_exception(state->exc);
return std::move(state->valid);
}
state.wait(wakeup);
}
}
/* Return a string accepted by decodeValidPathInfo() that
registers the specified paths as valid. Note: it's the
responsibility of the caller to provide a closure. */
std::string Store::makeValidityRegistration(const StorePathSet & paths,
bool showDerivers, bool showHash)
{
std::string s = "";
for (auto & i : paths) {
s += printStorePath(i) + "\n";
auto info = queryPathInfo(i);
if (showHash) {
s += info->narHash.to_string(Base16, false) + "\n";
s += (format("%1%\n") % info->narSize).str();
}
auto deriver = showDerivers && info->deriver ? printStorePath(*info->deriver) : "";
s += deriver + "\n";
s += (format("%1%\n") % info->references.size()).str();
for (auto & j : info->references)
s += printStorePath(j) + "\n";
}
return s;
}
StorePathSet Store::exportReferences(const StorePathSet & storePaths, const StorePathSet & inputPaths)
{
StorePathSet paths;
for (auto & storePath : storePaths) {
if (!inputPaths.count(storePath))
throw BuildError("cannot export references of path '%s' because it is not in the input closure of the derivation", printStorePath(storePath));
computeFSClosure({storePath}, paths);
}
/* If there are derivations in the graph, then include their
outputs as well. This is useful if you want to do things
like passing all build-time dependencies of some path to a
derivation that builds a NixOS DVD image. */
auto paths2 = paths;
for (auto & j : paths2) {
if (j.isDerivation()) {
Derivation drv = derivationFromPath(j);
for (auto & k : drv.outputsAndOptPaths(*this)) {
if (!k.second.second)
/* FIXME: I am confused why we are calling
`computeFSClosure` on the output path, rather than
derivation itself. That doesn't seem right to me, so I
won't try to implemented this for CA derivations. */
throw UnimplementedError("exportReferences on CA derivations is not yet implemented");
computeFSClosure(*k.second.second, paths);
}
}
}
return paths;
}
void Store::pathInfoToJSON(JSONPlaceholder & jsonOut, const StorePathSet & storePaths,
bool includeImpureInfo, bool showClosureSize,
Base hashBase,
AllowInvalidFlag allowInvalid)
{
auto jsonList = jsonOut.list();
for (auto & storePath : storePaths) {
auto jsonPath = jsonList.object();
try {
auto info = queryPathInfo(storePath);
jsonPath.attr("path", printStorePath(info->path));
jsonPath
.attr("narHash", info->narHash.to_string(hashBase, true))
.attr("narSize", info->narSize);
{
auto jsonRefs = jsonPath.list("references");
for (auto & ref : info->references)
jsonRefs.elem(printStorePath(ref));
}
if (info->ca)
jsonPath.attr("ca", renderContentAddress(info->ca));
std::pair<uint64_t, uint64_t> closureSizes;
if (showClosureSize) {
closureSizes = getClosureSize(info->path);
jsonPath.attr("closureSize", closureSizes.first);
}
if (includeImpureInfo) {
if (info->deriver)
jsonPath.attr("deriver", printStorePath(*info->deriver));
if (info->registrationTime)
jsonPath.attr("registrationTime", info->registrationTime);
if (info->ultimate)
jsonPath.attr("ultimate", info->ultimate);
if (!info->sigs.empty()) {
auto jsonSigs = jsonPath.list("signatures");
for (auto & sig : info->sigs)
jsonSigs.elem(sig);
}
auto narInfo = std::dynamic_pointer_cast<const NarInfo>(
std::shared_ptr<const ValidPathInfo>(info));
if (narInfo) {
if (!narInfo->url.empty())
jsonPath.attr("url", narInfo->url);
if (narInfo->fileHash)
jsonPath.attr("downloadHash", narInfo->fileHash->to_string(hashBase, true));
if (narInfo->fileSize)
jsonPath.attr("downloadSize", narInfo->fileSize);
if (showClosureSize)
jsonPath.attr("closureDownloadSize", closureSizes.second);
}
}
} catch (InvalidPath &) {
jsonPath.attr("path", printStorePath(storePath));
jsonPath.attr("valid", false);
}
}
}
std::pair<uint64_t, uint64_t> Store::getClosureSize(const StorePath & storePath)
{
uint64_t totalNarSize = 0, totalDownloadSize = 0;
StorePathSet closure;
computeFSClosure(storePath, closure, false, false);
for (auto & p : closure) {
auto info = queryPathInfo(p);
totalNarSize += info->narSize;
auto narInfo = std::dynamic_pointer_cast<const NarInfo>(
std::shared_ptr<const ValidPathInfo>(info));
if (narInfo)
totalDownloadSize += narInfo->fileSize;
}
return {totalNarSize, totalDownloadSize};
}
const Store::Stats & Store::getStats()
{
{
auto state_(state.lock());
stats.pathInfoCacheSize = state_->pathInfoCache.size();
}
return stats;
}
static std::string makeCopyPathMessage(
std::string_view srcUri,
std::string_view dstUri,
std::string_view storePath)
{
return srcUri == "local" || srcUri == "daemon"
? fmt("copying path '%s' to '%s'", storePath, dstUri)
: dstUri == "local" || dstUri == "daemon"
? fmt("copying path '%s' from '%s'", storePath, srcUri)
: fmt("copying path '%s' from '%s' to '%s'", storePath, srcUri, dstUri);
}
void copyStorePath(
Store & srcStore,
Store & dstStore,
const StorePath & storePath,
RepairFlag repair,
CheckSigsFlag checkSigs)
{
auto srcUri = srcStore.getUri();
auto dstUri = dstStore.getUri();
auto storePathS = srcStore.printStorePath(storePath);
Activity act(*logger, lvlInfo, actCopyPath,
makeCopyPathMessage(srcUri, dstUri, storePathS),
{storePathS, srcUri, dstUri});
PushActivity pact(act.id);
auto info = srcStore.queryPathInfo(storePath);
uint64_t total = 0;
// recompute store path on the chance dstStore does it differently
if (info->ca && info->references.empty()) {
auto info2 = make_ref<ValidPathInfo>(*info);
info2->path = dstStore.makeFixedOutputPathFromCA(info->path.name(), *info->ca);
if (dstStore.storeDir == srcStore.storeDir)
assert(info->path == info2->path);
info = info2;
}
if (info->ultimate) {
auto info2 = make_ref<ValidPathInfo>(*info);
info2->ultimate = false;
info = info2;
}
auto source = sinkToSource([&](Sink & sink) {
LambdaSink progressSink([&](std::string_view data) {
total += data.size();
act.progress(total, info->narSize);
});
TeeSink tee { sink, progressSink };
srcStore.narFromPath(storePath, tee);
}, [&]() {
throw EndOfFile("NAR for '%s' fetched from '%s' is incomplete", srcStore.printStorePath(storePath), srcStore.getUri());
});
dstStore.addToStore(*info, *source, repair, checkSigs);
}
std::map<StorePath, StorePath> copyPaths(
Store & srcStore,
Store & dstStore,
const RealisedPath::Set & paths,
RepairFlag repair,
CheckSigsFlag checkSigs,
SubstituteFlag substitute)
{
StorePathSet storePaths;
std::set<Realisation> toplevelRealisations;
for (auto & path : paths) {
storePaths.insert(path.path());
if (auto realisation = std::get_if<Realisation>(&path.raw)) {
settings.requireExperimentalFeature(Xp::CaDerivations);
toplevelRealisations.insert(*realisation);
}
}
auto pathsMap = copyPaths(srcStore, dstStore, storePaths, repair, checkSigs, substitute);
ThreadPool pool;
try {
// Copy the realisation closure
processGraph<Realisation>(
pool, Realisation::closure(srcStore, toplevelRealisations),
[&](const Realisation & current) -> std::set<Realisation> {
std::set<Realisation> children;
for (const auto & [drvOutput, _] : current.dependentRealisations) {
auto currentChild = srcStore.queryRealisation(drvOutput);
if (!currentChild)
throw Error(
"incomplete realisation closure: '%s' is a "
"dependency of '%s' but isn't registered",
drvOutput.to_string(), current.id.to_string());
children.insert(*currentChild);
}
return children;
},
[&](const Realisation& current) -> void {
dstStore.registerDrvOutput(current, checkSigs);
});
} catch (MissingExperimentalFeature & e) {
// Don't fail if the remote doesn't support CA derivations is it might
// not be within our control to change that, and we might still want
// to at least copy the output paths.
if (e.missingFeature == Xp::CaDerivations)
ignoreException();
else
throw;
}
return pathsMap;
}
std::map<StorePath, StorePath> copyPaths(
Store & srcStore,
Store & dstStore,
const StorePathSet & storePaths,
RepairFlag repair,
CheckSigsFlag checkSigs,
SubstituteFlag substitute)
{
auto valid = dstStore.queryValidPaths(storePaths, substitute);
StorePathSet missing;
for (auto & path : storePaths)
if (!valid.count(path)) missing.insert(path);
Activity act(*logger, lvlInfo, actCopyPaths, fmt("copying %d paths", missing.size()));
// In the general case, `addMultipleToStore` requires a sorted list of
// store paths to add, so sort them right now
auto sortedMissing = srcStore.topoSortPaths(missing);
std::reverse(sortedMissing.begin(), sortedMissing.end());
std::map<StorePath, StorePath> pathsMap;
for (auto & path : storePaths)
pathsMap.insert_or_assign(path, path);
Store::PathsSource pathsToCopy;
for (auto & missingPath : sortedMissing) {
auto info = srcStore.queryPathInfo(missingPath);
auto source = sinkToSource([&](Sink & sink) {
// We can reasonably assume that the copy will happen whenever we
// read the path, so log something about that at that point
auto srcUri = srcStore.getUri();
auto dstUri = dstStore.getUri();
auto storePathS = srcStore.printStorePath(missingPath);
Activity act(*logger, lvlInfo, actCopyPath,
makeCopyPathMessage(srcUri, dstUri, storePathS),
{storePathS, srcUri, dstUri});
PushActivity pact(act.id);
srcStore.narFromPath(missingPath, sink);
});
pathsToCopy.push_back(std::pair{*info, std::move(source)});
}
dstStore.addMultipleToStore(pathsToCopy, act, repair, checkSigs);
return pathsMap;
}
void copyClosure(
Store & srcStore,
Store & dstStore,
const RealisedPath::Set & paths,
RepairFlag repair,
CheckSigsFlag checkSigs,
SubstituteFlag substitute)
{
if (&srcStore == &dstStore) return;
RealisedPath::Set closure;
RealisedPath::closure(srcStore, paths, closure);
copyPaths(srcStore, dstStore, closure, repair, checkSigs, substitute);
}
void copyClosure(
Store & srcStore,
Store & dstStore,
const StorePathSet & storePaths,
RepairFlag repair,
CheckSigsFlag checkSigs,
SubstituteFlag substitute)
{
if (&srcStore == &dstStore) return;
StorePathSet closure;
srcStore.computeFSClosure(storePaths, closure);
copyPaths(srcStore, dstStore, closure, repair, checkSigs, substitute);
}
std::optional<ValidPathInfo> decodeValidPathInfo(const Store & store, std::istream & str, std::optional<HashResult> hashGiven)
{
std::string path;
getline(str, path);
if (str.eof()) { return {}; }
if (!hashGiven) {
std::string s;
getline(str, s);
auto narHash = Hash::parseAny(s, htSHA256);
getline(str, s);
auto narSize = string2Int<uint64_t>(s);
if (!narSize) throw Error("number expected");
hashGiven = { narHash, *narSize };
}
ValidPathInfo info(store.parseStorePath(path), hashGiven->first);
info.narSize = hashGiven->second;
std::string deriver;
getline(str, deriver);
if (deriver != "") info.deriver = store.parseStorePath(deriver);
std::string s;
getline(str, s);
auto n = string2Int<int>(s);
if (!n) throw Error("number expected");
while ((*n)--) {
getline(str, s);
info.references.insert(store.parseStorePath(s));
}
if (!str || str.eof()) throw Error("missing input");
return std::optional<ValidPathInfo>(std::move(info));
}
std::string Store::showPaths(const StorePathSet & paths)
{
std::string s;
for (auto & i : paths) {
if (s.size() != 0) s += ", ";
s += "'" + printStorePath(i) + "'";
}
return s;
}
std::string showPaths(const PathSet & paths)
{
return concatStringsSep(", ", quoteStrings(paths));
}
std::string ValidPathInfo::fingerprint(const Store & store) const
{
if (narSize == 0)
throw Error("cannot calculate fingerprint of path '%s' because its size is not known",
store.printStorePath(path));
return
"1;" + store.printStorePath(path) + ";"
+ narHash.to_string(Base32, true) + ";"
+ std::to_string(narSize) + ";"
+ concatStringsSep(",", store.printStorePathSet(references));
}
void ValidPathInfo::sign(const Store & store, const SecretKey & secretKey)
{
sigs.insert(secretKey.signDetached(fingerprint(store)));
}
bool ValidPathInfo::isContentAddressed(const Store & store) const
{
if (! ca) return false;
auto caPath = std::visit(overloaded {
[&](const TextHash & th) {
return store.makeTextPath(path.name(), th.hash, references);
},
[&](const FixedOutputHash & fsh) {
auto refs = references;
bool hasSelfReference = false;
if (refs.count(path)) {
hasSelfReference = true;
refs.erase(path);
}
return store.makeFixedOutputPath(fsh.method, fsh.hash, path.name(), refs, hasSelfReference);
}
}, *ca);
bool res = caPath == path;
if (!res)
printError("warning: path '%s' claims to be content-addressed but isn't", store.printStorePath(path));
return res;
}
size_t ValidPathInfo::checkSignatures(const Store & store, const PublicKeys & publicKeys) const
{
if (isContentAddressed(store)) return maxSigs;
size_t good = 0;
for (auto & sig : sigs)
if (checkSignature(store, publicKeys, sig))
good++;
return good;
}
bool ValidPathInfo::checkSignature(const Store & store, const PublicKeys & publicKeys, const std::string & sig) const
{
return verifyDetached(fingerprint(store), sig, publicKeys);
}
Strings ValidPathInfo::shortRefs() const
{
Strings refs;
for (auto & r : references)
refs.push_back(std::string(r.to_string()));
return refs;
}
Derivation Store::derivationFromPath(const StorePath & drvPath)
{
ensurePath(drvPath);
return readDerivation(drvPath);
}
Derivation readDerivationCommon(Store& store, const StorePath& drvPath, bool requireValidPath)
{
auto accessor = store.getFSAccessor();
try {
return parseDerivation(store,
accessor->readFile(store.printStorePath(drvPath), requireValidPath),
Derivation::nameFromPath(drvPath));
} catch (FormatError & e) {
throw Error("error parsing derivation '%s': %s", store.printStorePath(drvPath), e.msg());
}
}
Derivation Store::readDerivation(const StorePath & drvPath)
{ return readDerivationCommon(*this, drvPath, true); }
Derivation Store::readInvalidDerivation(const StorePath & drvPath)
{ return readDerivationCommon(*this, drvPath, false); }
}
#include "local-store.hh"
#include "uds-remote-store.hh"
namespace nix {
/* Split URI into protocol+hierarchy part and its parameter set. */
std::pair<std::string, Store::Params> splitUriAndParams(const std::string & uri_)
{
auto uri(uri_);
Store::Params params;
auto q = uri.find('?');
if (q != std::string::npos) {
params = decodeQuery(uri.substr(q + 1));
uri = uri_.substr(0, q);
}
return {uri, params};
}
static bool isNonUriPath(const std::string & spec) {
return
// is not a URL
spec.find("://") == std::string::npos
// Has at least one path separator, and so isn't a single word that
// might be special like "auto"
&& spec.find("/") != std::string::npos;
}
std::shared_ptr<Store> openFromNonUri(const std::string & uri, const Store::Params & params)
{
if (uri == "" || uri == "auto") {
auto stateDir = getOr(params, "state", settings.nixStateDir);
if (access(stateDir.c_str(), R_OK | W_OK) == 0)
return std::make_shared<LocalStore>(params);
else if (pathExists(settings.nixDaemonSocketFile))
return std::make_shared<UDSRemoteStore>(params);
else
return std::make_shared<LocalStore>(params);
} else if (uri == "daemon") {
return std::make_shared<UDSRemoteStore>(params);
} else if (uri == "local") {
return std::make_shared<LocalStore>(params);
} else if (isNonUriPath(uri)) {
Store::Params params2 = params;
params2["root"] = absPath(uri);
return std::make_shared<LocalStore>(params2);
} else {
return nullptr;
}
}
// The `parseURL` function supports both IPv6 URIs as defined in
// RFC2732, but also pure addresses. The latter one is needed here to
// connect to a remote store via SSH (it's possible to do e.g. `ssh root@::1`).
//
// This function now ensures that a usable connection string is available:
// * If the store to be opened is not an SSH store, nothing will be done.
// * If the URL looks like `root@[::1]` (which is allowed by the URL parser and probably
// needed to pass further flags), it
// will be transformed into `root@::1` for SSH (same for `[::1]` -> `::1`).
// * If the URL looks like `root@::1` it will be left as-is.
// * In any other case, the string will be left as-is.
static std::string extractConnStr(const std::string &proto, const std::string &connStr)
{
if (proto.rfind("ssh") != std::string::npos) {
std::smatch result;
std::regex v6AddrRegex("^((.*)@)?\\[(.*)\\]$");
if (std::regex_match(connStr, result, v6AddrRegex)) {
if (result[1].matched) {
return result.str(1) + result.str(3);
}
return result.str(3);
}
}
return connStr;
}
ref<Store> openStore(const std::string & uri_,
const Store::Params & extraParams)
{
auto params = extraParams;
try {
auto parsedUri = parseURL(uri_);
params.insert(parsedUri.query.begin(), parsedUri.query.end());
auto baseURI = extractConnStr(
parsedUri.scheme,
parsedUri.authority.value_or("") + parsedUri.path
);
for (auto implem : *Implementations::registered) {
if (implem.uriSchemes.count(parsedUri.scheme)) {
auto store = implem.create(parsedUri.scheme, baseURI, params);
if (store) {
store->init();
store->warnUnknownSettings();
return ref<Store>(store);
}
}
}
}
catch (BadURL &) {
auto [uri, uriParams] = splitUriAndParams(uri_);
params.insert(uriParams.begin(), uriParams.end());
if (auto store = openFromNonUri(uri, params)) {
store->warnUnknownSettings();
return ref<Store>(store);
}
}
throw Error("don't know how to open Nix store '%s'", uri_);
}
std::list<ref<Store>> getDefaultSubstituters()
{
static auto stores([]() {
std::list<ref<Store>> stores;
StringSet done;
auto addStore = [&](const std::string & uri) {
if (!done.insert(uri).second) return;
try {
stores.push_back(openStore(uri));
} catch (Error & e) {
logWarning(e.info());
}
};
for (auto uri : settings.substituters.get())
addStore(uri);
stores.sort([](ref<Store> & a, ref<Store> & b) {
return a->priority < b->priority;
});
return stores;
} ());
return stores;
}
std::vector<StoreFactory> * Implementations::registered = 0;
}