#include "derivations.hh" #include "downstream-placeholder.hh" #include "store-api.hh" #include "globals.hh" #include "types.hh" #include "util.hh" #include "split.hh" #include "common-protocol.hh" #include "common-protocol-impl.hh" #include #include #include "strings-inline.hh" namespace nix { std::optional DerivationOutput::path(const StoreDirConfig & store, std::string_view drvName, OutputNameView outputName) const { return std::visit(overloaded { [](const DerivationOutput::InputAddressed & doi) -> std::optional { return { doi.path }; }, [&](const DerivationOutput::CAFixed & dof) -> std::optional { return { dof.path(store, drvName, outputName) }; }, [](const DerivationOutput::CAFloating & dof) -> std::optional { return std::nullopt; }, [](const DerivationOutput::Deferred &) -> std::optional { return std::nullopt; }, [](const DerivationOutput::Impure &) -> std::optional { return std::nullopt; }, }, raw); } StorePath DerivationOutput::CAFixed::path(const StoreDirConfig & store, std::string_view drvName, OutputNameView outputName) const { return store.makeFixedOutputPathFromCA( outputPathName(drvName, outputName), ContentAddressWithReferences::withoutRefs(ca)); } bool DerivationType::isCA() const { /* Normally we do the full `std::visit` to make sure we have exhaustively handled all variants, but so long as there is a variant called `ContentAddressed`, it must be the only one for which `isCA` is true for this to make sense!. */ return std::visit(overloaded { [](const InputAddressed & ia) { return false; }, [](const ContentAddressed & ca) { return true; }, [](const Impure &) { return true; }, }, raw); } bool DerivationType::isFixed() const { return std::visit(overloaded { [](const InputAddressed & ia) { return false; }, [](const ContentAddressed & ca) { return ca.fixed; }, [](const Impure &) { return false; }, }, raw); } bool DerivationType::hasKnownOutputPaths() const { return std::visit(overloaded { [](const InputAddressed & ia) { return !ia.deferred; }, [](const ContentAddressed & ca) { return ca.fixed; }, [](const Impure &) { return false; }, }, raw); } bool DerivationType::isSandboxed() const { return std::visit(overloaded { [](const InputAddressed & ia) { return true; }, [](const ContentAddressed & ca) { return ca.sandboxed; }, [](const Impure &) { return false; }, }, raw); } bool DerivationType::isImpure() const { return std::visit(overloaded { [](const InputAddressed & ia) { return false; }, [](const ContentAddressed & ca) { return false; }, [](const Impure &) { return true; }, }, raw); } bool BasicDerivation::isBuiltin() const { return builder.substr(0, 8) == "builtin:"; } StorePath writeDerivation(Store & store, const Derivation & drv, RepairFlag repair, bool readOnly) { auto references = drv.inputSrcs; for (auto & i : drv.inputDrvs.map) references.insert(i.first); /* Note that the outputs of a derivation are *not* references (that can be missing (of course) and should not necessarily be held during a garbage collection). */ auto suffix = std::string(drv.name) + drvExtension; auto contents = drv.unparse(store, false); return readOnly || settings.readOnlyMode ? store.makeFixedOutputPathFromCA(suffix, TextInfo { .hash = hashString(HashAlgorithm::SHA256, contents), .references = std::move(references), }) : ({ StringSource s { contents }; store.addToStoreFromDump(s, suffix, FileSerialisationMethod::Flat, ContentAddressMethod::Raw::Text, HashAlgorithm::SHA256, references, repair); }); } namespace { /** * This mimics std::istream to some extent. We use this much smaller implementation * instead of plain istreams because the sentry object overhead is too high. */ struct StringViewStream { std::string_view remaining; int peek() const { return remaining.empty() ? EOF : remaining[0]; } int get() { if (remaining.empty()) return EOF; char c = remaining[0]; remaining.remove_prefix(1); return c; } }; constexpr struct Escapes { char map[256]; constexpr Escapes() { for (int i = 0; i < 256; i++) map[i] = (char) (unsigned char) i; map[(int) (unsigned char) 'n'] = '\n'; map[(int) (unsigned char) 'r'] = '\r'; map[(int) (unsigned char) 't'] = '\t'; } char operator[](char c) const { return map[(unsigned char) c]; } } escapes; } /* Read string `s' from stream `str'. */ static void expect(StringViewStream & str, std::string_view s) { if (!str.remaining.starts_with(s)) throw FormatError("expected string '%1%'", s); str.remaining.remove_prefix(s.size()); } /* Read a C-style string from stream `str'. */ static BackedStringView parseString(StringViewStream & str) { expect(str, "\""); auto c = str.remaining.begin(), end = str.remaining.end(); bool escaped = false; for (; c != end && *c != '"'; c++) { if (*c == '\\') { c++; if (c == end) throw FormatError("unterminated string in derivation"); escaped = true; } } const auto contentLen = c - str.remaining.begin(); const auto content = str.remaining.substr(0, contentLen); str.remaining.remove_prefix(contentLen + 1); if (!escaped) return content; std::string res; res.reserve(content.size()); for (c = content.begin(), end = content.end(); c != end; c++) if (*c == '\\') { c++; res += escapes[*c]; } else res += *c; return res; } static void validatePath(std::string_view s) { if (s.size() == 0 || s[0] != '/') throw FormatError("bad path '%1%' in derivation", s); } static BackedStringView parsePath(StringViewStream & str) { auto s = parseString(str); validatePath(*s); return s; } static bool endOfList(StringViewStream & str) { if (str.peek() == ',') { str.get(); return false; } if (str.peek() == ']') { str.get(); return true; } return false; } static StringSet parseStrings(StringViewStream & str, bool arePaths) { StringSet res; expect(str, "["); while (!endOfList(str)) res.insert((arePaths ? parsePath(str) : parseString(str)).toOwned()); return res; } static DerivationOutput parseDerivationOutput( const StoreDirConfig & store, std::string_view pathS, std::string_view hashAlgoStr, std::string_view hashS, const ExperimentalFeatureSettings & xpSettings) { if (hashAlgoStr != "") { ContentAddressMethod method = ContentAddressMethod::parsePrefix(hashAlgoStr); if (method == ContentAddressMethod::Raw::Text) xpSettings.require(Xp::DynamicDerivations); const auto hashAlgo = parseHashAlgo(hashAlgoStr); if (hashS == "impure") { xpSettings.require(Xp::ImpureDerivations); if (pathS != "") throw FormatError("impure derivation output should not specify output path"); return DerivationOutput::Impure { .method = std::move(method), .hashAlgo = std::move(hashAlgo), }; } else if (hashS != "") { validatePath(pathS); auto hash = Hash::parseNonSRIUnprefixed(hashS, hashAlgo); return DerivationOutput::CAFixed { .ca = ContentAddress { .method = std::move(method), .hash = std::move(hash), }, }; } else { xpSettings.require(Xp::CaDerivations); if (pathS != "") throw FormatError("content-addressed derivation output should not specify output path"); return DerivationOutput::CAFloating { .method = std::move(method), .hashAlgo = std::move(hashAlgo), }; } } else { if (pathS == "") { return DerivationOutput::Deferred { }; } validatePath(pathS); return DerivationOutput::InputAddressed { .path = store.parseStorePath(pathS), }; } } static DerivationOutput parseDerivationOutput( const StoreDirConfig & store, StringViewStream & str, const ExperimentalFeatureSettings & xpSettings = experimentalFeatureSettings) { expect(str, ","); const auto pathS = parseString(str); expect(str, ","); const auto hashAlgo = parseString(str); expect(str, ","); const auto hash = parseString(str); expect(str, ")"); return parseDerivationOutput(store, *pathS, *hashAlgo, *hash, xpSettings); } /** * All ATerm Derivation format versions currently known. * * Unknown versions are rejected at the parsing stage. */ enum struct DerivationATermVersion { /** * Older unversioned form */ Traditional, /** * Newer versioned form; only this version so far. */ DynamicDerivations, }; static DerivedPathMap::ChildNode parseDerivedPathMapNode( const StoreDirConfig & store, StringViewStream & str, DerivationATermVersion version) { DerivedPathMap::ChildNode node; auto parseNonDynamic = [&]() { node.value = parseStrings(str, false); }; // Older derivation should never use new form, but newer // derivaiton can use old form. switch (version) { case DerivationATermVersion::Traditional: parseNonDynamic(); break; case DerivationATermVersion::DynamicDerivations: switch (str.peek()) { case '[': parseNonDynamic(); break; case '(': expect(str, "("); node.value = parseStrings(str, false); expect(str, ",["); while (!endOfList(str)) { expect(str, "("); auto outputName = parseString(str).toOwned(); expect(str, ","); node.childMap.insert_or_assign(outputName, parseDerivedPathMapNode(store, str, version)); expect(str, ")"); } expect(str, ")"); break; default: throw FormatError("invalid inputDrvs entry in derivation"); } break; default: // invalid format, not a parse error but internal error assert(false); } return node; } Derivation parseDerivation( const StoreDirConfig & store, std::string && s, std::string_view name, const ExperimentalFeatureSettings & xpSettings) { Derivation drv; drv.name = name; StringViewStream str{s}; expect(str, "D"); DerivationATermVersion version; switch (str.peek()) { case 'e': expect(str, "erive("); version = DerivationATermVersion::Traditional; break; case 'r': { expect(str, "rvWithVersion("); auto versionS = parseString(str); if (*versionS == "xp-dyn-drv") { // Only verison we have so far version = DerivationATermVersion::DynamicDerivations; xpSettings.require(Xp::DynamicDerivations); } else { throw FormatError("Unknown derivation ATerm format version '%s'", *versionS); } expect(str, ","); break; } default: throw Error("derivation does not start with 'Derive' or 'DrvWithVersion'"); } /* Parse the list of outputs. */ expect(str, "["); while (!endOfList(str)) { expect(str, "("); std::string id = parseString(str).toOwned(); auto output = parseDerivationOutput(store, str, xpSettings); drv.outputs.emplace(std::move(id), std::move(output)); } /* Parse the list of input derivations. */ expect(str, ",["); while (!endOfList(str)) { expect(str, "("); auto drvPath = parsePath(str); expect(str, ","); drv.inputDrvs.map.insert_or_assign(store.parseStorePath(*drvPath), parseDerivedPathMapNode(store, str, version)); expect(str, ")"); } expect(str, ","); drv.inputSrcs = store.parseStorePathSet(parseStrings(str, true)); expect(str, ","); drv.platform = parseString(str).toOwned(); expect(str, ","); drv.builder = parseString(str).toOwned(); /* Parse the builder arguments. */ expect(str, ",["); while (!endOfList(str)) drv.args.push_back(parseString(str).toOwned()); /* Parse the environment variables. */ expect(str, ",["); while (!endOfList(str)) { expect(str, "("); auto name = parseString(str).toOwned(); expect(str, ","); auto value = parseString(str).toOwned(); expect(str, ")"); drv.env.insert_or_assign(std::move(name), std::move(value)); } expect(str, ")"); return drv; } /** * Print a derivation string literal to an `std::string`. * * This syntax does not generalize to the expression language, which needs to * escape `$`. * * @param res Where to print to * @param s Which logical string to print */ static void printString(std::string & res, std::string_view s) { boost::container::small_vector buffer; buffer.reserve(s.size() * 2 + 2); char * buf = buffer.data(); char * p = buf; *p++ = '"'; for (auto c : s) if (c == '\"' || c == '\\') { *p++ = '\\'; *p++ = c; } else if (c == '\n') { *p++ = '\\'; *p++ = 'n'; } else if (c == '\r') { *p++ = '\\'; *p++ = 'r'; } else if (c == '\t') { *p++ = '\\'; *p++ = 't'; } else *p++ = c; *p++ = '"'; res.append(buf, p - buf); } static void printUnquotedString(std::string & res, std::string_view s) { res += '"'; res.append(s); res += '"'; } template static void printStrings(std::string & res, ForwardIterator i, ForwardIterator j) { res += '['; bool first = true; for ( ; i != j; ++i) { if (first) first = false; else res += ','; printString(res, *i); } res += ']'; } template static void printUnquotedStrings(std::string & res, ForwardIterator i, ForwardIterator j) { res += '['; bool first = true; for ( ; i != j; ++i) { if (first) first = false; else res += ','; printUnquotedString(res, *i); } res += ']'; } static void unparseDerivedPathMapNode(const StoreDirConfig & store, std::string & s, const DerivedPathMap::ChildNode & node) { s += ','; if (node.childMap.empty()) { printUnquotedStrings(s, node.value.begin(), node.value.end()); } else { s += "("; printUnquotedStrings(s, node.value.begin(), node.value.end()); s += ",["; bool first = true; for (auto & [outputName, childNode] : node.childMap) { if (first) first = false; else s += ','; s += '('; printUnquotedString(s, outputName); unparseDerivedPathMapNode(store, s, childNode); s += ')'; } s += "])"; } } /** * Does the derivation have a dependency on the output of a dynamic * derivation? * * In other words, does it on the output of derivation that is itself an * ouput of a derivation? This corresponds to a dependency that is an * inductive derived path with more than one layer of * `DerivedPath::Built`. */ static bool hasDynamicDrvDep(const Derivation & drv) { return std::find_if( drv.inputDrvs.map.begin(), drv.inputDrvs.map.end(), [](auto & kv) { return !kv.second.childMap.empty(); }) != drv.inputDrvs.map.end(); } std::string Derivation::unparse(const StoreDirConfig & store, bool maskOutputs, DerivedPathMap::ChildNode::Map * actualInputs) const { std::string s; s.reserve(65536); /* Use older unversioned form if possible, for wider compat. Use newer form only if we need it, which we do for `Xp::DynamicDerivations`. */ if (hasDynamicDrvDep(*this)) { s += "DrvWithVersion("; // Only version we have so far printUnquotedString(s, "xp-dyn-drv"); s += ","; } else { s += "Derive("; } bool first = true; s += "["; for (auto & i : outputs) { if (first) first = false; else s += ','; s += '('; printUnquotedString(s, i.first); std::visit(overloaded { [&](const DerivationOutput::InputAddressed & doi) { s += ','; printUnquotedString(s, maskOutputs ? "" : store.printStorePath(doi.path)); s += ','; printUnquotedString(s, ""); s += ','; printUnquotedString(s, ""); }, [&](const DerivationOutput::CAFixed & dof) { s += ','; printUnquotedString(s, maskOutputs ? "" : store.printStorePath(dof.path(store, name, i.first))); s += ','; printUnquotedString(s, dof.ca.printMethodAlgo()); s += ','; printUnquotedString(s, dof.ca.hash.to_string(HashFormat::Base16, false)); }, [&](const DerivationOutput::CAFloating & dof) { s += ','; printUnquotedString(s, ""); s += ','; printUnquotedString(s, std::string { dof.method.renderPrefix() } + printHashAlgo(dof.hashAlgo)); s += ','; printUnquotedString(s, ""); }, [&](const DerivationOutput::Deferred &) { s += ','; printUnquotedString(s, ""); s += ','; printUnquotedString(s, ""); s += ','; printUnquotedString(s, ""); }, [&](const DerivationOutput::Impure & doi) { // FIXME s += ','; printUnquotedString(s, ""); s += ','; printUnquotedString(s, std::string { doi.method.renderPrefix() } + printHashAlgo(doi.hashAlgo)); s += ','; printUnquotedString(s, "impure"); } }, i.second.raw); s += ')'; } s += "],["; first = true; if (actualInputs) { for (auto & [drvHashModulo, childMap] : *actualInputs) { if (first) first = false; else s += ','; s += '('; printUnquotedString(s, drvHashModulo); unparseDerivedPathMapNode(store, s, childMap); s += ')'; } } else { for (auto & [drvPath, childMap] : inputDrvs.map) { if (first) first = false; else s += ','; s += '('; printUnquotedString(s, store.printStorePath(drvPath)); unparseDerivedPathMapNode(store, s, childMap); s += ')'; } } s += "],"; auto paths = store.printStorePathSet(inputSrcs); // FIXME: slow printUnquotedStrings(s, paths.begin(), paths.end()); s += ','; printUnquotedString(s, platform); s += ','; printString(s, builder); s += ','; printStrings(s, args.begin(), args.end()); s += ",["; first = true; for (auto & i : env) { if (first) first = false; else s += ','; s += '('; printString(s, i.first); s += ','; printString(s, maskOutputs && outputs.count(i.first) ? "" : i.second); s += ')'; } s += "])"; return s; } // FIXME: remove bool isDerivation(std::string_view fileName) { return hasSuffix(fileName, drvExtension); } std::string outputPathName(std::string_view drvName, OutputNameView outputName) { std::string res { drvName }; if (outputName != "out") { res += "-"; res += outputName; } return res; } DerivationType BasicDerivation::type() const { std::set inputAddressedOutputs, fixedCAOutputs, floatingCAOutputs, deferredIAOutputs, impureOutputs; std::optional floatingHashAlgo; for (auto & i : outputs) { std::visit(overloaded { [&](const DerivationOutput::InputAddressed &) { inputAddressedOutputs.insert(i.first); }, [&](const DerivationOutput::CAFixed &) { fixedCAOutputs.insert(i.first); }, [&](const DerivationOutput::CAFloating & dof) { floatingCAOutputs.insert(i.first); if (!floatingHashAlgo) { floatingHashAlgo = dof.hashAlgo; } else { if (*floatingHashAlgo != dof.hashAlgo) throw Error("all floating outputs must use the same hash algorithm"); } }, [&](const DerivationOutput::Deferred &) { deferredIAOutputs.insert(i.first); }, [&](const DerivationOutput::Impure &) { impureOutputs.insert(i.first); }, }, i.second.raw); } if (inputAddressedOutputs.empty() && fixedCAOutputs.empty() && floatingCAOutputs.empty() && deferredIAOutputs.empty() && impureOutputs.empty()) throw Error("must have at least one output"); if (!inputAddressedOutputs.empty() && fixedCAOutputs.empty() && floatingCAOutputs.empty() && deferredIAOutputs.empty() && impureOutputs.empty()) return DerivationType::InputAddressed { .deferred = false, }; if (inputAddressedOutputs.empty() && !fixedCAOutputs.empty() && floatingCAOutputs.empty() && deferredIAOutputs.empty() && impureOutputs.empty()) { if (fixedCAOutputs.size() > 1) // FIXME: Experimental feature? throw Error("only one fixed output is allowed for now"); if (*fixedCAOutputs.begin() != "out") throw Error("single fixed output must be named \"out\""); return DerivationType::ContentAddressed { .sandboxed = false, .fixed = true, }; } if (inputAddressedOutputs.empty() && fixedCAOutputs.empty() && !floatingCAOutputs.empty() && deferredIAOutputs.empty() && impureOutputs.empty()) return DerivationType::ContentAddressed { .sandboxed = true, .fixed = false, }; if (inputAddressedOutputs.empty() && fixedCAOutputs.empty() && floatingCAOutputs.empty() && !deferredIAOutputs.empty() && impureOutputs.empty()) return DerivationType::InputAddressed { .deferred = true, }; if (inputAddressedOutputs.empty() && fixedCAOutputs.empty() && floatingCAOutputs.empty() && deferredIAOutputs.empty() && !impureOutputs.empty()) return DerivationType::Impure { }; throw Error("can't mix derivation output types"); } Sync drvHashes; /* pathDerivationModulo and hashDerivationModulo are mutually recursive */ /* Look up the derivation by value and memoize the `hashDerivationModulo` call. */ static const DrvHash pathDerivationModulo(Store & store, const StorePath & drvPath) { { auto hashes = drvHashes.lock(); auto h = hashes->find(drvPath); if (h != hashes->end()) { return h->second; } } auto h = hashDerivationModulo( store, store.readInvalidDerivation(drvPath), false); // Cache it drvHashes.lock()->insert_or_assign(drvPath, h); return h; } /* See the header for interface details. These are the implementation details. For fixed-output derivations, each hash in the map is not the corresponding output's content hash, but a hash of that hash along with other constant data. The key point is that the value is a pure function of the output's contents, and there are no preimage attacks either spoofing an output's contents for a derivation, or spoofing a derivation for an output's contents. For regular derivations, it looks up each subderivation from its hash and recurs. If the subderivation is also regular, it simply substitutes the derivation path with its hash. If the subderivation is fixed-output, however, it takes each output hash and pretends it is a derivation hash producing a single "out" output. This is so we don't leak the provenance of fixed outputs, reducing pointless cache misses as the build itself won't know this. */ DrvHash hashDerivationModulo(Store & store, const Derivation & drv, bool maskOutputs) { auto type = drv.type(); /* Return a fixed hash for fixed-output derivations. */ if (type.isFixed()) { std::map outputHashes; for (const auto & i : drv.outputs) { auto & dof = std::get(i.second.raw); auto hash = hashString(HashAlgorithm::SHA256, "fixed:out:" + dof.ca.printMethodAlgo() + ":" + dof.ca.hash.to_string(HashFormat::Base16, false) + ":" + store.printStorePath(dof.path(store, drv.name, i.first))); outputHashes.insert_or_assign(i.first, std::move(hash)); } return DrvHash { .hashes = outputHashes, .kind = DrvHash::Kind::Regular, }; } if (type.isImpure()) { std::map outputHashes; for (const auto & [outputName, _] : drv.outputs) outputHashes.insert_or_assign(outputName, impureOutputHash); return DrvHash { .hashes = outputHashes, .kind = DrvHash::Kind::Deferred, }; } auto kind = std::visit(overloaded { [](const DerivationType::InputAddressed & ia) { /* This might be a "pesimistically" deferred output, so we don't "taint" the kind yet. */ return DrvHash::Kind::Regular; }, [](const DerivationType::ContentAddressed & ca) { return ca.fixed ? DrvHash::Kind::Regular : DrvHash::Kind::Deferred; }, [](const DerivationType::Impure &) -> DrvHash::Kind { assert(false); } }, drv.type().raw); DerivedPathMap::ChildNode::Map inputs2; for (auto & [drvPath, node] : drv.inputDrvs.map) { const auto & res = pathDerivationModulo(store, drvPath); if (res.kind == DrvHash::Kind::Deferred) kind = DrvHash::Kind::Deferred; for (auto & outputName : node.value) { const auto h = get(res.hashes, outputName); if (!h) throw Error("no hash for output '%s' of derivation '%s'", outputName, drv.name); inputs2[h->to_string(HashFormat::Base16, false)].value.insert(outputName); } } auto hash = hashString(HashAlgorithm::SHA256, drv.unparse(store, maskOutputs, &inputs2)); std::map outputHashes; for (const auto & [outputName, _] : drv.outputs) { outputHashes.insert_or_assign(outputName, hash); } return DrvHash { .hashes = outputHashes, .kind = kind, }; } std::map staticOutputHashes(Store & store, const Derivation & drv) { return hashDerivationModulo(store, drv, true).hashes; } static DerivationOutput readDerivationOutput(Source & in, const StoreDirConfig & store) { const auto pathS = readString(in); const auto hashAlgo = readString(in); const auto hash = readString(in); return parseDerivationOutput(store, pathS, hashAlgo, hash, experimentalFeatureSettings); } StringSet BasicDerivation::outputNames() const { StringSet names; for (auto & i : outputs) names.insert(i.first); return names; } DerivationOutputsAndOptPaths BasicDerivation::outputsAndOptPaths(const StoreDirConfig & store) const { DerivationOutputsAndOptPaths outsAndOptPaths; for (auto & [outputName, output] : outputs) outsAndOptPaths.insert(std::make_pair( outputName, std::make_pair(output, output.path(store, name, outputName)) ) ); return outsAndOptPaths; } std::string_view BasicDerivation::nameFromPath(const StorePath & drvPath) { drvPath.requireDerivation(); auto nameWithSuffix = drvPath.name(); nameWithSuffix.remove_suffix(drvExtension.size()); return nameWithSuffix; } Source & readDerivation(Source & in, const StoreDirConfig & store, BasicDerivation & drv, std::string_view name) { drv.name = name; drv.outputs.clear(); auto nr = readNum(in); for (size_t n = 0; n < nr; n++) { auto name = readString(in); auto output = readDerivationOutput(in, store); drv.outputs.emplace(std::move(name), std::move(output)); } drv.inputSrcs = CommonProto::Serialise::read(store, CommonProto::ReadConn { .from = in }); in >> drv.platform >> drv.builder; drv.args = readStrings(in); nr = readNum(in); for (size_t n = 0; n < nr; n++) { auto key = readString(in); auto value = readString(in); drv.env[key] = value; } return in; } void writeDerivation(Sink & out, const StoreDirConfig & store, const BasicDerivation & drv) { out << drv.outputs.size(); for (auto & i : drv.outputs) { out << i.first; std::visit(overloaded { [&](const DerivationOutput::InputAddressed & doi) { out << store.printStorePath(doi.path) << "" << ""; }, [&](const DerivationOutput::CAFixed & dof) { out << store.printStorePath(dof.path(store, drv.name, i.first)) << dof.ca.printMethodAlgo() << dof.ca.hash.to_string(HashFormat::Base16, false); }, [&](const DerivationOutput::CAFloating & dof) { out << "" << (std::string { dof.method.renderPrefix() } + printHashAlgo(dof.hashAlgo)) << ""; }, [&](const DerivationOutput::Deferred &) { out << "" << "" << ""; }, [&](const DerivationOutput::Impure & doi) { out << "" << (std::string { doi.method.renderPrefix() } + printHashAlgo(doi.hashAlgo)) << "impure"; }, }, i.second.raw); } CommonProto::write(store, CommonProto::WriteConn { .to = out }, drv.inputSrcs); out << drv.platform << drv.builder << drv.args; out << drv.env.size(); for (auto & i : drv.env) out << i.first << i.second; } std::string hashPlaceholder(const OutputNameView outputName) { // FIXME: memoize? return "/" + hashString(HashAlgorithm::SHA256, concatStrings("nix-output:", outputName)).to_string(HashFormat::Nix32, false); } static void rewriteDerivation(Store & store, BasicDerivation & drv, const StringMap & rewrites) { debug("Rewriting the derivation"); for (auto & rewrite : rewrites) { debug("rewriting %s as %s", rewrite.first, rewrite.second); } drv.builder = rewriteStrings(drv.builder, rewrites); for (auto & arg : drv.args) { arg = rewriteStrings(arg, rewrites); } StringPairs newEnv; for (auto & envVar : drv.env) { auto envName = rewriteStrings(envVar.first, rewrites); auto envValue = rewriteStrings(envVar.second, rewrites); newEnv.emplace(envName, envValue); } drv.env = newEnv; auto hashModulo = hashDerivationModulo(store, Derivation(drv), true); for (auto & [outputName, output] : drv.outputs) { if (std::holds_alternative(output.raw)) { auto h = get(hashModulo.hashes, outputName); if (!h) throw Error("derivation '%s' output '%s' has no hash (derivations.cc/rewriteDerivation)", drv.name, outputName); auto outPath = store.makeOutputPath(outputName, *h, drv.name); drv.env[outputName] = store.printStorePath(outPath); output = DerivationOutput::InputAddressed { .path = std::move(outPath), }; } } } std::optional Derivation::tryResolve(Store & store, Store * evalStore) const { std::map, StorePath> inputDrvOutputs; std::function::ChildNode &)> accum; accum = [&](auto & inputDrv, auto & node) { for (auto & [outputName, outputPath] : store.queryPartialDerivationOutputMap(inputDrv, evalStore)) { if (outputPath) { inputDrvOutputs.insert_or_assign({inputDrv, outputName}, *outputPath); if (auto p = get(node.childMap, outputName)) accum(*outputPath, *p); } } }; for (auto & [inputDrv, node] : inputDrvs.map) accum(inputDrv, node); return tryResolve(store, inputDrvOutputs); } static bool tryResolveInput( Store & store, StorePathSet & inputSrcs, StringMap & inputRewrites, const DownstreamPlaceholder * placeholderOpt, const StorePath & inputDrv, const DerivedPathMap::ChildNode & inputNode, const std::map, StorePath> & inputDrvOutputs) { auto getOutput = [&](const std::string & outputName) { auto * actualPathOpt = get(inputDrvOutputs, { inputDrv, outputName }); if (!actualPathOpt) warn("output %s of input %s missing, aborting the resolving", outputName, store.printStorePath(inputDrv) ); return actualPathOpt; }; auto getPlaceholder = [&](const std::string & outputName) { return placeholderOpt ? DownstreamPlaceholder::unknownDerivation(*placeholderOpt, outputName) : DownstreamPlaceholder::unknownCaOutput(inputDrv, outputName); }; for (auto & outputName : inputNode.value) { auto actualPathOpt = getOutput(outputName); if (!actualPathOpt) return false; auto actualPath = *actualPathOpt; if (experimentalFeatureSettings.isEnabled(Xp::CaDerivations)) { inputRewrites.emplace( getPlaceholder(outputName).render(), store.printStorePath(actualPath)); } inputSrcs.insert(std::move(actualPath)); } for (auto & [outputName, childNode] : inputNode.childMap) { auto actualPathOpt = getOutput(outputName); if (!actualPathOpt) return false; auto actualPath = *actualPathOpt; auto nextPlaceholder = getPlaceholder(outputName); if (!tryResolveInput(store, inputSrcs, inputRewrites, &nextPlaceholder, actualPath, childNode, inputDrvOutputs)) return false; } return true; } std::optional Derivation::tryResolve( Store & store, const std::map, StorePath> & inputDrvOutputs) const { BasicDerivation resolved { *this }; // Input paths that we'll want to rewrite in the derivation StringMap inputRewrites; for (auto & [inputDrv, inputNode] : inputDrvs.map) if (!tryResolveInput(store, resolved.inputSrcs, inputRewrites, nullptr, inputDrv, inputNode, inputDrvOutputs)) return std::nullopt; rewriteDerivation(store, resolved, inputRewrites); return resolved; } void Derivation::checkInvariants(Store & store, const StorePath & drvPath) const { assert(drvPath.isDerivation()); std::string drvName(drvPath.name()); drvName = drvName.substr(0, drvName.size() - drvExtension.size()); if (drvName != name) { throw Error("Derivation '%s' has name '%s' which does not match its path", store.printStorePath(drvPath), name); } auto envHasRightPath = [&](const StorePath & actual, const std::string & varName) { auto j = env.find(varName); if (j == env.end() || store.parseStorePath(j->second) != actual) throw Error("derivation '%s' has incorrect environment variable '%s', should be '%s'", store.printStorePath(drvPath), varName, store.printStorePath(actual)); }; // Don't need the answer, but do this anyways to assert is proper // combination. The code below is more general and naturally allows // combinations that are currently prohibited. type(); std::optional hashesModulo; for (auto & i : outputs) { std::visit(overloaded { [&](const DerivationOutput::InputAddressed & doia) { if (!hashesModulo) { // somewhat expensive so we do lazily hashesModulo = hashDerivationModulo(store, *this, true); } auto currentOutputHash = get(hashesModulo->hashes, i.first); if (!currentOutputHash) throw Error("derivation '%s' has unexpected output '%s' (local-store / hashesModulo) named '%s'", store.printStorePath(drvPath), store.printStorePath(doia.path), i.first); StorePath recomputed = store.makeOutputPath(i.first, *currentOutputHash, drvName); if (doia.path != recomputed) throw Error("derivation '%s' has incorrect output '%s', should be '%s'", store.printStorePath(drvPath), store.printStorePath(doia.path), store.printStorePath(recomputed)); envHasRightPath(doia.path, i.first); }, [&](const DerivationOutput::CAFixed & dof) { auto path = dof.path(store, drvName, i.first); envHasRightPath(path, i.first); }, [&](const DerivationOutput::CAFloating &) { /* Nothing to check */ }, [&](const DerivationOutput::Deferred &) { /* Nothing to check */ }, [&](const DerivationOutput::Impure &) { /* Nothing to check */ }, }, i.second.raw); } } const Hash impureOutputHash = hashString(HashAlgorithm::SHA256, "impure"); nlohmann::json DerivationOutput::toJSON( const StoreDirConfig & store, std::string_view drvName, OutputNameView outputName) const { nlohmann::json res = nlohmann::json::object(); std::visit(overloaded { [&](const DerivationOutput::InputAddressed & doi) { res["path"] = store.printStorePath(doi.path); }, [&](const DerivationOutput::CAFixed & dof) { res["path"] = store.printStorePath(dof.path(store, drvName, outputName)); res["method"] = std::string { dof.ca.method.render() }; res["hashAlgo"] = printHashAlgo(dof.ca.hash.algo); res["hash"] = dof.ca.hash.to_string(HashFormat::Base16, false); // FIXME print refs? }, [&](const DerivationOutput::CAFloating & dof) { res["method"] = std::string { dof.method.render() }; res["hashAlgo"] = printHashAlgo(dof.hashAlgo); }, [&](const DerivationOutput::Deferred &) {}, [&](const DerivationOutput::Impure & doi) { res["method"] = std::string { doi.method.render() }; res["hashAlgo"] = printHashAlgo(doi.hashAlgo); res["impure"] = true; }, }, raw); return res; } DerivationOutput DerivationOutput::fromJSON( const StoreDirConfig & store, std::string_view drvName, OutputNameView outputName, const nlohmann::json & _json, const ExperimentalFeatureSettings & xpSettings) { std::set keys; auto & json = getObject(_json); for (const auto & [key, _] : json) keys.insert(key); auto methodAlgo = [&]() -> std::pair { auto & method_ = getString(valueAt(json, "method")); ContentAddressMethod method = ContentAddressMethod::parse(method_); if (method == ContentAddressMethod::Raw::Text) xpSettings.require(Xp::DynamicDerivations); auto & hashAlgo_ = getString(valueAt(json, "hashAlgo")); auto hashAlgo = parseHashAlgo(hashAlgo_); return { std::move(method), std::move(hashAlgo) }; }; if (keys == (std::set { "path" })) { return DerivationOutput::InputAddressed { .path = store.parseStorePath(getString(valueAt(json, "path"))), }; } else if (keys == (std::set { "path", "method", "hashAlgo", "hash" })) { auto [method, hashAlgo] = methodAlgo(); auto dof = DerivationOutput::CAFixed { .ca = ContentAddress { .method = std::move(method), .hash = Hash::parseNonSRIUnprefixed(getString(valueAt(json, "hash")), hashAlgo), }, }; if (dof.path(store, drvName, outputName) != store.parseStorePath(getString(valueAt(json, "path")))) throw Error("Path doesn't match derivation output"); return dof; } else if (keys == (std::set { "method", "hashAlgo" })) { xpSettings.require(Xp::CaDerivations); auto [method, hashAlgo] = methodAlgo(); return DerivationOutput::CAFloating { .method = std::move(method), .hashAlgo = std::move(hashAlgo), }; } else if (keys == (std::set { })) { return DerivationOutput::Deferred {}; } else if (keys == (std::set { "method", "hashAlgo", "impure" })) { xpSettings.require(Xp::ImpureDerivations); auto [method, hashAlgo] = methodAlgo(); return DerivationOutput::Impure { .method = std::move(method), .hashAlgo = hashAlgo, }; } else { throw Error("invalid JSON for derivation output"); } } nlohmann::json Derivation::toJSON(const StoreDirConfig & store) const { nlohmann::json res = nlohmann::json::object(); res["name"] = name; { nlohmann::json & outputsObj = res["outputs"]; outputsObj = nlohmann::json::object(); for (auto & [outputName, output] : outputs) { outputsObj[outputName] = output.toJSON(store, name, outputName); } } { auto& inputsList = res["inputSrcs"]; inputsList = nlohmann::json ::array(); for (auto & input : inputSrcs) inputsList.emplace_back(store.printStorePath(input)); } { std::function::ChildNode &)> doInput; doInput = [&](const auto & inputNode) { auto value = nlohmann::json::object(); value["outputs"] = inputNode.value; { auto next = nlohmann::json::object(); for (auto & [outputId, childNode] : inputNode.childMap) next[outputId] = doInput(childNode); value["dynamicOutputs"] = std::move(next); } return value; }; { auto& inputDrvsObj = res["inputDrvs"]; inputDrvsObj = nlohmann::json::object(); for (auto & [inputDrv, inputNode] : inputDrvs.map) { inputDrvsObj[store.printStorePath(inputDrv)] = doInput(inputNode); } } } res["system"] = platform; res["builder"] = builder; res["args"] = args; res["env"] = env; return res; } Derivation Derivation::fromJSON( const StoreDirConfig & store, const nlohmann::json & _json, const ExperimentalFeatureSettings & xpSettings) { using nlohmann::detail::value_t; Derivation res; auto & json = getObject(_json); res.name = getString(valueAt(json, "name")); try { for (auto & [outputName, output] : getObject(valueAt(json, "outputs"))) { res.outputs.insert_or_assign( outputName, DerivationOutput::fromJSON(store, res.name, outputName, output)); } } catch (Error & e) { e.addTrace({}, "while reading key 'outputs'"); throw; } try { for (auto & input : getArray(valueAt(json, "inputSrcs"))) res.inputSrcs.insert(store.parseStorePath(static_cast(input))); } catch (Error & e) { e.addTrace({}, "while reading key 'inputSrcs'"); throw; } try { std::function::ChildNode(const nlohmann::json &)> doInput; doInput = [&](const auto & _json) { auto & json = getObject(_json); DerivedPathMap::ChildNode node; node.value = getStringSet(valueAt(json, "outputs")); for (auto & [outputId, childNode] : getObject(valueAt(json, "dynamicOutputs"))) { xpSettings.require(Xp::DynamicDerivations); node.childMap[outputId] = doInput(childNode); } return node; }; for (auto & [inputDrvPath, inputOutputs] : getObject(valueAt(json, "inputDrvs"))) res.inputDrvs.map[store.parseStorePath(inputDrvPath)] = doInput(inputOutputs); } catch (Error & e) { e.addTrace({}, "while reading key 'inputDrvs'"); throw; } res.platform = getString(valueAt(json, "system")); res.builder = getString(valueAt(json, "builder")); res.args = getStringList(valueAt(json, "args")); res.env = getStringMap(valueAt(json, "env")); return res; } }