%glr-parser %define api.pure %locations %define parse.error verbose %defines /* %no-lines */ %parse-param { void * scanner } %parse-param { nix::ParseData * data } %lex-param { void * scanner } %lex-param { nix::ParseData * data } %expect 1 %expect-rr 1 %code requires { #ifndef BISON_HEADER #define BISON_HEADER #include #include "util.hh" #include "users.hh" #include "nixexpr.hh" #include "eval.hh" #include "eval-settings.hh" #include "globals.hh" namespace nix { struct ParseData { EvalState & state; SymbolTable & symbols; Expr * result; SourcePath basePath; PosTable::Origin origin; std::optional error; }; struct ParserFormals { std::vector formals; bool ellipsis = false; }; } // using C a struct allows us to avoid having to define the special // members that using string_view here would implicitly delete. struct StringToken { const char * p; size_t l; bool hasIndentation; operator std::string_view() const { return {p, l}; } }; #define YY_DECL int yylex \ (YYSTYPE * yylval_param, YYLTYPE * yylloc_param, yyscan_t yyscanner, nix::ParseData * data) #endif } %{ #include "parser-tab.hh" #include "lexer-tab.hh" YY_DECL; using namespace nix; namespace nix { static void dupAttr(const EvalState & state, const AttrPath & attrPath, const PosIdx pos, const PosIdx prevPos) { throw ParseError({ .msg = hintfmt("attribute '%1%' already defined at %2%", showAttrPath(state.symbols, attrPath), state.positions[prevPos]), .errPos = state.positions[pos] }); } static void dupAttr(const EvalState & state, Symbol attr, const PosIdx pos, const PosIdx prevPos) { throw ParseError({ .msg = hintfmt("attribute '%1%' already defined at %2%", state.symbols[attr], state.positions[prevPos]), .errPos = state.positions[pos] }); } static void addAttr(ExprAttrs * attrs, AttrPath && attrPath, Expr * e, const PosIdx pos, const nix::EvalState & state) { AttrPath::iterator i; // All attrpaths have at least one attr assert(!attrPath.empty()); // Checking attrPath validity. // =========================== for (i = attrPath.begin(); i + 1 < attrPath.end(); i++) { if (i->symbol) { ExprAttrs::AttrDefs::iterator j = attrs->attrs.find(i->symbol); if (j != attrs->attrs.end()) { if (!j->second.inherited) { ExprAttrs * attrs2 = dynamic_cast(j->second.e); if (!attrs2) dupAttr(state, attrPath, pos, j->second.pos); attrs = attrs2; } else dupAttr(state, attrPath, pos, j->second.pos); } else { ExprAttrs * nested = new ExprAttrs; attrs->attrs[i->symbol] = ExprAttrs::AttrDef(nested, pos); attrs = nested; } } else { ExprAttrs *nested = new ExprAttrs; attrs->dynamicAttrs.push_back(ExprAttrs::DynamicAttrDef(i->expr, nested, pos)); attrs = nested; } } // Expr insertion. // ========================== if (i->symbol) { ExprAttrs::AttrDefs::iterator j = attrs->attrs.find(i->symbol); if (j != attrs->attrs.end()) { // This attr path is already defined. However, if both // e and the expr pointed by the attr path are two attribute sets, // we want to merge them. // Otherwise, throw an error. auto ae = dynamic_cast(e); auto jAttrs = dynamic_cast(j->second.e); if (jAttrs && ae) { for (auto & ad : ae->attrs) { auto j2 = jAttrs->attrs.find(ad.first); if (j2 != jAttrs->attrs.end()) // Attr already defined in iAttrs, error. dupAttr(state, ad.first, j2->second.pos, ad.second.pos); jAttrs->attrs.emplace(ad.first, ad.second); } jAttrs->dynamicAttrs.insert(jAttrs->dynamicAttrs.end(), ae->dynamicAttrs.begin(), ae->dynamicAttrs.end()); } else { dupAttr(state, attrPath, pos, j->second.pos); } } else { // This attr path is not defined. Let's create it. attrs->attrs.emplace(i->symbol, ExprAttrs::AttrDef(e, pos)); e->setName(i->symbol); } } else { attrs->dynamicAttrs.push_back(ExprAttrs::DynamicAttrDef(i->expr, e, pos)); } } static Formals * toFormals(ParseData & data, ParserFormals * formals, PosIdx pos = noPos, Symbol arg = {}) { std::sort(formals->formals.begin(), formals->formals.end(), [] (const auto & a, const auto & b) { return std::tie(a.name, a.pos) < std::tie(b.name, b.pos); }); std::optional> duplicate; for (size_t i = 0; i + 1 < formals->formals.size(); i++) { if (formals->formals[i].name != formals->formals[i + 1].name) continue; std::pair thisDup{formals->formals[i].name, formals->formals[i + 1].pos}; duplicate = std::min(thisDup, duplicate.value_or(thisDup)); } if (duplicate) throw ParseError({ .msg = hintfmt("duplicate formal function argument '%1%'", data.symbols[duplicate->first]), .errPos = data.state.positions[duplicate->second] }); Formals result; result.ellipsis = formals->ellipsis; result.formals = std::move(formals->formals); if (arg && result.has(arg)) throw ParseError({ .msg = hintfmt("duplicate formal function argument '%1%'", data.symbols[arg]), .errPos = data.state.positions[pos] }); delete formals; return new Formals(std::move(result)); } static Expr * stripIndentation(const PosIdx pos, SymbolTable & symbols, std::vector>> && es) { if (es.empty()) return new ExprString(""); /* Figure out the minimum indentation. Note that by design whitespace-only final lines are not taken into account. (So the " " in "\n ''" is ignored, but the " " in "\n foo''" is.) */ bool atStartOfLine = true; /* = seen only whitespace in the current line */ size_t minIndent = 1000000; size_t curIndent = 0; for (auto & [i_pos, i] : es) { auto * str = std::get_if(&i); if (!str || !str->hasIndentation) { /* Anti-quotations and escaped characters end the current start-of-line whitespace. */ if (atStartOfLine) { atStartOfLine = false; if (curIndent < minIndent) minIndent = curIndent; } continue; } for (size_t j = 0; j < str->l; ++j) { if (atStartOfLine) { if (str->p[j] == ' ') curIndent++; else if (str->p[j] == '\n') { /* Empty line, doesn't influence minimum indentation. */ curIndent = 0; } else { atStartOfLine = false; if (curIndent < minIndent) minIndent = curIndent; } } else if (str->p[j] == '\n') { atStartOfLine = true; curIndent = 0; } } } /* Strip spaces from each line. */ auto * es2 = new std::vector>; atStartOfLine = true; size_t curDropped = 0; size_t n = es.size(); auto i = es.begin(); const auto trimExpr = [&] (Expr * e) { atStartOfLine = false; curDropped = 0; es2->emplace_back(i->first, e); }; const auto trimString = [&] (const StringToken & t) { std::string s2; for (size_t j = 0; j < t.l; ++j) { if (atStartOfLine) { if (t.p[j] == ' ') { if (curDropped++ >= minIndent) s2 += t.p[j]; } else if (t.p[j] == '\n') { curDropped = 0; s2 += t.p[j]; } else { atStartOfLine = false; curDropped = 0; s2 += t.p[j]; } } else { s2 += t.p[j]; if (t.p[j] == '\n') atStartOfLine = true; } } /* Remove the last line if it is empty and consists only of spaces. */ if (n == 1) { std::string::size_type p = s2.find_last_of('\n'); if (p != std::string::npos && s2.find_first_not_of(' ', p + 1) == std::string::npos) s2 = std::string(s2, 0, p + 1); } es2->emplace_back(i->first, new ExprString(std::move(s2))); }; for (; i != es.end(); ++i, --n) { std::visit(overloaded { trimExpr, trimString }, i->second); } /* If this is a single string, then don't do a concatenation. */ if (es2->size() == 1 && dynamic_cast((*es2)[0].second)) { auto *const result = (*es2)[0].second; delete es2; return result; } return new ExprConcatStrings(pos, true, es2); } static inline PosIdx makeCurPos(const YYLTYPE & loc, ParseData * data) { return data->state.positions.add(data->origin, loc.first_line, loc.first_column); } #define CUR_POS makeCurPos(*yylocp, data) } void yyerror(YYLTYPE * loc, yyscan_t scanner, ParseData * data, const char * error) { data->error = { .msg = hintfmt(error), .errPos = data->state.positions[makeCurPos(*loc, data)] }; } %} %union { // !!! We're probably leaking stuff here. nix::Expr * e; nix::ExprList * list; nix::ExprAttrs * attrs; nix::ParserFormals * formals; nix::Formal * formal; nix::NixInt n; nix::NixFloat nf; StringToken id; // !!! -> Symbol StringToken path; StringToken uri; StringToken str; std::vector * attrNames; std::vector> * string_parts; std::vector>> * ind_string_parts; } %type start expr expr_function expr_if expr_op %type expr_select expr_simple expr_app %type expr_list %type binds %type formals %type formal %type attrs attrpath %type string_parts_interpolated %type ind_string_parts %type path_start string_parts string_attr %type attr %token ID %token STR IND_STR %token INT %token FLOAT %token PATH HPATH SPATH PATH_END %token URI %token IF THEN ELSE ASSERT WITH LET IN REC INHERIT EQ NEQ AND OR IMPL OR_KW %token DOLLAR_CURLY /* == ${ */ %token IND_STRING_OPEN IND_STRING_CLOSE %token ELLIPSIS %right IMPL %left OR %left AND %nonassoc EQ NEQ %nonassoc '<' '>' LEQ GEQ %right UPDATE %left NOT %left '+' '-' %left '*' '/' %right CONCAT %nonassoc '?' %nonassoc NEGATE %% start: expr { data->result = $1; }; expr: expr_function; expr_function : ID ':' expr_function { $$ = new ExprLambda(CUR_POS, data->symbols.create($1), 0, $3); } | '{' formals '}' ':' expr_function { $$ = new ExprLambda(CUR_POS, toFormals(*data, $2), $5); } | '{' formals '}' '@' ID ':' expr_function { auto arg = data->symbols.create($5); $$ = new ExprLambda(CUR_POS, arg, toFormals(*data, $2, CUR_POS, arg), $7); } | ID '@' '{' formals '}' ':' expr_function { auto arg = data->symbols.create($1); $$ = new ExprLambda(CUR_POS, arg, toFormals(*data, $4, CUR_POS, arg), $7); } | ASSERT expr ';' expr_function { $$ = new ExprAssert(CUR_POS, $2, $4); } | WITH expr ';' expr_function { $$ = new ExprWith(CUR_POS, $2, $4); } | LET binds IN expr_function { if (!$2->dynamicAttrs.empty()) throw ParseError({ .msg = hintfmt("dynamic attributes not allowed in let"), .errPos = data->state.positions[CUR_POS] }); $$ = new ExprLet($2, $4); } | expr_if ; expr_if : IF expr THEN expr ELSE expr { $$ = new ExprIf(CUR_POS, $2, $4, $6); } | expr_op ; expr_op : '!' expr_op %prec NOT { $$ = new ExprOpNot($2); } | '-' expr_op %prec NEGATE { $$ = new ExprCall(CUR_POS, new ExprVar(data->symbols.create("__sub")), {new ExprInt(0), $2}); } | expr_op EQ expr_op { $$ = new ExprOpEq($1, $3); } | expr_op NEQ expr_op { $$ = new ExprOpNEq($1, $3); } | expr_op '<' expr_op { $$ = new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__lessThan")), {$1, $3}); } | expr_op LEQ expr_op { $$ = new ExprOpNot(new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__lessThan")), {$3, $1})); } | expr_op '>' expr_op { $$ = new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__lessThan")), {$3, $1}); } | expr_op GEQ expr_op { $$ = new ExprOpNot(new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__lessThan")), {$1, $3})); } | expr_op AND expr_op { $$ = new ExprOpAnd(makeCurPos(@2, data), $1, $3); } | expr_op OR expr_op { $$ = new ExprOpOr(makeCurPos(@2, data), $1, $3); } | expr_op IMPL expr_op { $$ = new ExprOpImpl(makeCurPos(@2, data), $1, $3); } | expr_op UPDATE expr_op { $$ = new ExprOpUpdate(makeCurPos(@2, data), $1, $3); } | expr_op '?' attrpath { $$ = new ExprOpHasAttr($1, std::move(*$3)); delete $3; } | expr_op '+' expr_op { $$ = new ExprConcatStrings(makeCurPos(@2, data), false, new std::vector >({{makeCurPos(@1, data), $1}, {makeCurPos(@3, data), $3}})); } | expr_op '-' expr_op { $$ = new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__sub")), {$1, $3}); } | expr_op '*' expr_op { $$ = new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__mul")), {$1, $3}); } | expr_op '/' expr_op { $$ = new ExprCall(makeCurPos(@2, data), new ExprVar(data->symbols.create("__div")), {$1, $3}); } | expr_op CONCAT expr_op { $$ = new ExprOpConcatLists(makeCurPos(@2, data), $1, $3); } | expr_app ; expr_app : expr_app expr_select { if (auto e2 = dynamic_cast($1)) { e2->args.push_back($2); $$ = $1; } else $$ = new ExprCall(CUR_POS, $1, {$2}); } | expr_select ; expr_select : expr_simple '.' attrpath { $$ = new ExprSelect(CUR_POS, $1, std::move(*$3), nullptr); delete $3; } | expr_simple '.' attrpath OR_KW expr_select { $$ = new ExprSelect(CUR_POS, $1, std::move(*$3), $5); delete $3; } | /* Backwards compatibility: because Nixpkgs has a rarely used function named ‘or’, allow stuff like ‘map or [...]’. */ expr_simple OR_KW { $$ = new ExprCall(CUR_POS, $1, {new ExprVar(CUR_POS, data->symbols.create("or"))}); } | expr_simple ; expr_simple : ID { std::string_view s = "__curPos"; if ($1.l == s.size() && strncmp($1.p, s.data(), s.size()) == 0) $$ = new ExprPos(CUR_POS); else $$ = new ExprVar(CUR_POS, data->symbols.create($1)); } | INT { $$ = new ExprInt($1); } | FLOAT { $$ = new ExprFloat($1); } | '"' string_parts '"' { $$ = $2; } | IND_STRING_OPEN ind_string_parts IND_STRING_CLOSE { $$ = stripIndentation(CUR_POS, data->symbols, std::move(*$2)); delete $2; } | path_start PATH_END | path_start string_parts_interpolated PATH_END { $2->insert($2->begin(), {makeCurPos(@1, data), $1}); $$ = new ExprConcatStrings(CUR_POS, false, $2); } | SPATH { std::string path($1.p + 1, $1.l - 2); $$ = new ExprCall(CUR_POS, new ExprVar(data->symbols.create("__findFile")), {new ExprVar(data->symbols.create("__nixPath")), new ExprString(std::move(path))}); } | URI { static bool noURLLiterals = experimentalFeatureSettings.isEnabled(Xp::NoUrlLiterals); if (noURLLiterals) throw ParseError({ .msg = hintfmt("URL literals are disabled"), .errPos = data->state.positions[CUR_POS] }); $$ = new ExprString(std::string($1)); } | '(' expr ')' { $$ = $2; } /* Let expressions `let {..., body = ...}' are just desugared into `(rec {..., body = ...}).body'. */ | LET '{' binds '}' { $3->recursive = true; $$ = new ExprSelect(noPos, $3, data->symbols.create("body")); } | REC '{' binds '}' { $3->recursive = true; $$ = $3; } | '{' binds '}' { $$ = $2; } | '[' expr_list ']' { $$ = $2; } ; string_parts : STR { $$ = new ExprString(std::string($1)); } | string_parts_interpolated { $$ = new ExprConcatStrings(CUR_POS, true, $1); } | { $$ = new ExprString(""); } ; string_parts_interpolated : string_parts_interpolated STR { $$ = $1; $1->emplace_back(makeCurPos(@2, data), new ExprString(std::string($2))); } | string_parts_interpolated DOLLAR_CURLY expr '}' { $$ = $1; $1->emplace_back(makeCurPos(@2, data), $3); } | DOLLAR_CURLY expr '}' { $$ = new std::vector>; $$->emplace_back(makeCurPos(@1, data), $2); } | STR DOLLAR_CURLY expr '}' { $$ = new std::vector>; $$->emplace_back(makeCurPos(@1, data), new ExprString(std::string($1))); $$->emplace_back(makeCurPos(@2, data), $3); } ; path_start : PATH { Path path(absPath({$1.p, $1.l}, data->basePath.path.abs())); /* add back in the trailing '/' to the first segment */ if ($1.p[$1.l-1] == '/' && $1.l > 1) path += "/"; $$ = new ExprPath(ref(data->state.rootFS), std::move(path)); } | HPATH { if (evalSettings.pureEval) { throw Error( "the path '%s' can not be resolved in pure mode", std::string_view($1.p, $1.l) ); } Path path(getHome() + std::string($1.p + 1, $1.l - 1)); $$ = new ExprPath(ref(data->state.rootFS), std::move(path)); } ; ind_string_parts : ind_string_parts IND_STR { $$ = $1; $1->emplace_back(makeCurPos(@2, data), $2); } | ind_string_parts DOLLAR_CURLY expr '}' { $$ = $1; $1->emplace_back(makeCurPos(@2, data), $3); } | { $$ = new std::vector>>; } ; binds : binds attrpath '=' expr ';' { $$ = $1; addAttr($$, std::move(*$2), $4, makeCurPos(@2, data), data->state); delete $2; } | binds INHERIT attrs ';' { $$ = $1; for (auto & i : *$3) { if ($$->attrs.find(i.symbol) != $$->attrs.end()) dupAttr(data->state, i.symbol, makeCurPos(@3, data), $$->attrs[i.symbol].pos); auto pos = makeCurPos(@3, data); $$->attrs.emplace(i.symbol, ExprAttrs::AttrDef(new ExprVar(CUR_POS, i.symbol), pos, true)); } delete $3; } | binds INHERIT '(' expr ')' attrs ';' { $$ = $1; /* !!! Should ensure sharing of the expression in $4. */ for (auto & i : *$6) { if ($$->attrs.find(i.symbol) != $$->attrs.end()) dupAttr(data->state, i.symbol, makeCurPos(@6, data), $$->attrs[i.symbol].pos); $$->attrs.emplace(i.symbol, ExprAttrs::AttrDef(new ExprSelect(CUR_POS, $4, i.symbol), makeCurPos(@6, data))); } delete $6; } | { $$ = new ExprAttrs(makeCurPos(@0, data)); } ; attrs : attrs attr { $$ = $1; $1->push_back(AttrName(data->symbols.create($2))); } | attrs string_attr { $$ = $1; ExprString * str = dynamic_cast($2); if (str) { $$->push_back(AttrName(data->symbols.create(str->s))); delete str; } else throw ParseError({ .msg = hintfmt("dynamic attributes not allowed in inherit"), .errPos = data->state.positions[makeCurPos(@2, data)] }); } | { $$ = new AttrPath; } ; attrpath : attrpath '.' attr { $$ = $1; $1->push_back(AttrName(data->symbols.create($3))); } | attrpath '.' string_attr { $$ = $1; ExprString * str = dynamic_cast($3); if (str) { $$->push_back(AttrName(data->symbols.create(str->s))); delete str; } else $$->push_back(AttrName($3)); } | attr { $$ = new std::vector; $$->push_back(AttrName(data->symbols.create($1))); } | string_attr { $$ = new std::vector; ExprString *str = dynamic_cast($1); if (str) { $$->push_back(AttrName(data->symbols.create(str->s))); delete str; } else $$->push_back(AttrName($1)); } ; attr : ID | OR_KW { $$ = {"or", 2}; } ; string_attr : '"' string_parts '"' { $$ = $2; } | DOLLAR_CURLY expr '}' { $$ = $2; } ; expr_list : expr_list expr_select { $$ = $1; $1->elems.push_back($2); /* !!! dangerous */ } | { $$ = new ExprList; } ; formals : formal ',' formals { $$ = $3; $$->formals.emplace_back(*$1); delete $1; } | formal { $$ = new ParserFormals; $$->formals.emplace_back(*$1); $$->ellipsis = false; delete $1; } | { $$ = new ParserFormals; $$->ellipsis = false; } | ELLIPSIS { $$ = new ParserFormals; $$->ellipsis = true; } ; formal : ID { $$ = new Formal{CUR_POS, data->symbols.create($1), 0}; } | ID '?' expr { $$ = new Formal{CUR_POS, data->symbols.create($1), $3}; } ; %% #include #include #include #include #include "eval.hh" #include "filetransfer.hh" #include "tarball.hh" #include "store-api.hh" #include "flake/flake.hh" #include "fs-input-accessor.hh" #include "memory-input-accessor.hh" namespace nix { unsigned long Expr::nrExprs = 0; Expr * EvalState::parse( char * text, size_t length, Pos::Origin origin, const SourcePath & basePath, std::shared_ptr & staticEnv) { yyscan_t scanner; ParseData data { .state = *this, .symbols = symbols, .basePath = basePath, .origin = {origin}, }; yylex_init(&scanner); yy_scan_buffer(text, length, scanner); int res = yyparse(scanner, &data); yylex_destroy(scanner); if (res) throw ParseError(data.error.value()); data.result->bindVars(*this, staticEnv); return data.result; } SourcePath resolveExprPath(SourcePath path) { unsigned int followCount = 0, maxFollow = 1024; /* If `path' is a symlink, follow it. This is so that relative path references work. */ while (!path.path.isRoot()) { // Basic cycle/depth limit to avoid infinite loops. if (++followCount >= maxFollow) throw Error("too many symbolic links encountered while traversing the path '%s'", path); auto p = path.parent().resolveSymlinks() + path.baseName(); if (p.lstat().type != InputAccessor::tSymlink) break; path = {path.accessor, CanonPath(p.readLink(), path.path.parent().value_or(CanonPath::root))}; } /* If `path' refers to a directory, append `/default.nix'. */ if (path.resolveSymlinks().lstat().type == InputAccessor::tDirectory) return path + "default.nix"; return path; } Expr * EvalState::parseExprFromFile(const SourcePath & path) { return parseExprFromFile(path, staticBaseEnv); } Expr * EvalState::parseExprFromFile(const SourcePath & path, std::shared_ptr & staticEnv) { auto buffer = path.resolveSymlinks().readFile(); // readFile hopefully have left some extra space for terminators buffer.append("\0\0", 2); return parse(buffer.data(), buffer.size(), Pos::Origin(path), path.parent(), staticEnv); } Expr * EvalState::parseExprFromString(std::string s_, const SourcePath & basePath, std::shared_ptr & staticEnv) { auto s = make_ref(std::move(s_)); s->append("\0\0", 2); return parse(s->data(), s->size(), Pos::String{.source = s}, basePath, staticEnv); } Expr * EvalState::parseExprFromString(std::string s, const SourcePath & basePath) { return parseExprFromString(std::move(s), basePath, staticBaseEnv); } Expr * EvalState::parseStdin() { //Activity act(*logger, lvlTalkative, "parsing standard input"); auto buffer = drainFD(0); // drainFD should have left some extra space for terminators buffer.append("\0\0", 2); auto s = make_ref(std::move(buffer)); return parse(s->data(), s->size(), Pos::Stdin{.source = s}, rootPath(CanonPath::fromCwd()), staticBaseEnv); } SourcePath EvalState::findFile(const std::string_view path) { return findFile(searchPath, path); } SourcePath EvalState::findFile(const SearchPath & searchPath, const std::string_view path, const PosIdx pos) { for (auto & i : searchPath.elements) { auto suffixOpt = i.prefix.suffixIfPotentialMatch(path); if (!suffixOpt) continue; auto suffix = *suffixOpt; auto rOpt = resolveSearchPathPath(i.path); if (!rOpt) continue; auto r = *rOpt; Path res = suffix == "" ? r : concatStrings(r, "/", suffix); if (pathExists(res)) return rootPath(CanonPath(canonPath(res))); } if (hasPrefix(path, "nix/")) return {corepkgsFS, CanonPath(path.substr(3))}; debugThrow(ThrownError({ .msg = hintfmt(evalSettings.pureEval ? "cannot look up '<%s>' in pure evaluation mode (use '--impure' to override)" : "file '%s' was not found in the Nix search path (add it using $NIX_PATH or -I)", path), .errPos = positions[pos] }), 0, 0); } std::optional EvalState::resolveSearchPathPath(const SearchPath::Path & value0, bool initAccessControl) { auto & value = value0.s; auto i = searchPathResolved.find(value); if (i != searchPathResolved.end()) return i->second; std::optional res; if (EvalSettings::isPseudoUrl(value)) { try { auto storePath = fetchers::downloadTarball( store, EvalSettings::resolvePseudoUrl(value), "source", false).storePath; res = { store->toRealPath(storePath) }; } catch (FileTransferError & e) { logWarning({ .msg = hintfmt("Nix search path entry '%1%' cannot be downloaded, ignoring", value) }); } } else if (hasPrefix(value, "flake:")) { experimentalFeatureSettings.require(Xp::Flakes); auto flakeRef = parseFlakeRef(value.substr(6), {}, true, false); debug("fetching flake search path element '%s''", value); auto storePath = flakeRef.resolve(store).fetchTree(store).first; res = { store->toRealPath(storePath) }; } else { auto path = absPath(value); /* Allow access to paths in the search path. */ if (initAccessControl) { allowPath(path); if (store->isInStore(path)) { try { StorePathSet closure; store->computeFSClosure(store->toStorePath(path).first, closure); for (auto & p : closure) allowPath(p); } catch (InvalidPath &) { } } } if (pathExists(path)) res = { path }; else { logWarning({ .msg = hintfmt("Nix search path entry '%1%' does not exist, ignoring", value) }); res = std::nullopt; } } if (res) debug("resolved search path element '%s' to '%s'", value, *res); else debug("failed to resolve search path element '%s'", value); searchPathResolved.emplace(value, res); return res; } }