%glr-parser %pure-parser %locations %error-verbose %defines /* %no-lines */ %parse-param { yyscan_t scanner } %parse-param { ParseData * data } %lex-param { yyscan_t scanner } %{ /* Newer versions of Bison copy the declarations below to parser-tab.hh, which sucks bigtime since lexer.l doesn't want that stuff. So allow it to be excluded. */ #ifndef BISON_HEADER_HACK #define BISON_HEADER_HACK #include #include #include #include "aterm.hh" #include "util.hh" #include "parser-tab.hh" #include "lexer-tab.hh" #define YYSTYPE YYSTYPE // workaround a bug in Bison 2.4 #include "nixexpr.hh" #include "nixexpr-ast.hh" using namespace nix; namespace nix { struct ParseData { Expr result; Path basePath; Path path; string error; }; static string showAttrPath(ATermList attrPath) { string s; for (ATermIterator i(attrPath); i; ++i) { if (!s.empty()) s += '.'; s += aterm2String(*i); } return s; } struct Tree { Expr leaf; ATerm pos; bool recursive; typedef std::map Children; Children children; Tree() { leaf = 0; recursive = true; } }; static ATermList buildAttrs(const Tree & t, ATermList & nonrec) { ATermList res = ATempty; for (Tree::Children::const_reverse_iterator i = t.children.rbegin(); i != t.children.rend(); ++i) if (!i->second.recursive) nonrec = ATinsert(nonrec, makeBind(i->first, i->second.leaf, i->second.pos)); else res = ATinsert(res, i->second.leaf ? makeBind(i->first, i->second.leaf, i->second.pos) : makeBind(i->first, makeAttrs(buildAttrs(i->second, nonrec)), makeNoPos())); return res; } static Expr fixAttrs(bool recursive, ATermList as) { Tree attrs; /* This ATermMap is needed to ensure that the `leaf' fields in the Tree nodes are not garbage collected. */ ATermMap gcRoots; for (ATermIterator i(as); i; ++i) { ATermList names, attrPath; Expr src, e; ATerm name, pos; if (matchInherit(*i, src, names, pos)) { bool fromScope = matchScope(src); for (ATermIterator j(names); j; ++j) { if (attrs.children.find(*j) != attrs.children.end()) throw ParseError(format("duplicate definition of attribute `%1%' at %2%") % showAttrPath(ATmakeList1(*j)) % showPos(pos)); Tree & t(attrs.children[*j]); Expr leaf = fromScope ? makeVar(*j) : makeSelect(src, *j); gcRoots.set(leaf, leaf); t.leaf = leaf; t.pos = pos; if (recursive && fromScope) t.recursive = false; } } else if (matchBindAttrPath(*i, attrPath, e, pos)) { Tree * t(&attrs); for (ATermIterator j(attrPath); j; ) { name = *j; ++j; if (t->leaf) throw ParseError(format("attribute set containing `%1%' at %2% already defined at %3%") % showAttrPath(attrPath) % showPos(pos) % showPos (t->pos)); t = &(t->children[name]); } if (t->leaf) throw ParseError(format("duplicate definition of attribute `%1%' at %2% and %3%") % showAttrPath(attrPath) % showPos(pos) % showPos (t->pos)); if (!t->children.empty()) throw ParseError(format("duplicate definition of attribute `%1%' at %2%") % showAttrPath(attrPath) % showPos(pos)); t->leaf = e; t->pos = pos; } else abort(); /* can't happen */ } ATermList nonrec = ATempty; ATermList rec = buildAttrs(attrs, nonrec); return recursive ? makeRec(rec, nonrec) : makeAttrs(rec); } static void checkPatternVars(ATerm pos, ATermMap & map, Pattern pat) { ATerm name; ATermList formals; Pattern pat1, pat2; ATermBool ellipsis; if (matchVarPat(pat, name)) { if (map.get(name)) throw ParseError(format("duplicate formal function argument `%1%' at %2%") % aterm2String(name) % showPos(pos)); map.set(name, name); } else if (matchAttrsPat(pat, formals, ellipsis)) { for (ATermIterator i(formals); i; ++i) { ATerm d1; if (!matchFormal(*i, name, d1)) abort(); if (map.get(name)) throw ParseError(format("duplicate formal function argument `%1%' at %2%") % aterm2String(name) % showPos(pos)); map.set(name, name); } } else if (matchAtPat(pat, pat1, pat2)) { checkPatternVars(pos, map, pat1); checkPatternVars(pos, map, pat2); } else abort(); } static void checkPatternVars(ATerm pos, Pattern pat) { ATermMap map; checkPatternVars(pos, map, pat); } static Expr stripIndentation(ATermList es) { if (es == ATempty) return makeStr(""); /* 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 */ unsigned int minIndent = 1000000; unsigned int curIndent = 0; ATerm e; for (ATermIterator i(es); i; ++i) { if (!matchIndStr(*i, e)) { /* Anti-quotations end the current start-of-line whitespace. */ if (atStartOfLine) { atStartOfLine = false; if (curIndent < minIndent) minIndent = curIndent; } continue; } string s = aterm2String(e); for (unsigned int j = 0; j < s.size(); ++j) { if (atStartOfLine) { if (s[j] == ' ') curIndent++; else if (s[j] == '\n') { /* Empty line, doesn't influence minimum indentation. */ curIndent = 0; } else { atStartOfLine = false; if (curIndent < minIndent) minIndent = curIndent; } } else if (s[j] == '\n') { atStartOfLine = true; curIndent = 0; } } } /* Strip spaces from each line. */ ATermList es2 = ATempty; atStartOfLine = true; unsigned int curDropped = 0; unsigned int n = ATgetLength(es); for (ATermIterator i(es); i; ++i, --n) { if (!matchIndStr(*i, e)) { atStartOfLine = false; curDropped = 0; es2 = ATinsert(es2, *i); continue; } string s = aterm2String(e); string s2; for (unsigned int j = 0; j < s.size(); ++j) { if (atStartOfLine) { if (s[j] == ' ') { if (curDropped++ >= minIndent) s2 += s[j]; } else if (s[j] == '\n') { curDropped = 0; s2 += s[j]; } else { atStartOfLine = false; curDropped = 0; s2 += s[j]; } } else { s2 += s[j]; if (s[j] == '\n') atStartOfLine = true; } } /* Remove the last line if it is empty and consists only of spaces. */ if (n == 1) { string::size_type p = s2.find_last_of('\n'); if (p != string::npos && s2.find_first_not_of(' ', p + 1) == string::npos) s2 = string(s2, 0, p + 1); } es2 = ATinsert(es2, makeStr(s2)); } return makeConcatStrings(ATreverse(es2)); } void backToString(yyscan_t scanner); void backToIndString(yyscan_t scanner); static Pos makeCurPos(YYLTYPE * loc, ParseData * data) { return makePos(toATerm(data->path), 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 = (format("%1%, at `%2%':%3%:%4%") % error % data->path % loc->first_line % loc->first_column).str(); } /* Make sure that the parse stack is scanned by the ATerm garbage collector. */ static void * mallocAndProtect(size_t size) { void * p = malloc(size); if (p) ATprotectMemory(p, size); return p; } static void freeAndUnprotect(void * p) { ATunprotectMemory(p); free(p); } #define YYMALLOC mallocAndProtect #define YYFREE freeAndUnprotect #endif %} %union { ATerm t; ATermList ts; struct { ATermList formals; bool ellipsis; } formals; } %type start expr expr_function expr_if expr_op %type expr_app expr_select expr_simple bind inheritsrc formal %type pattern pattern2 %type binds ids attrpath expr_list string_parts ind_string_parts %type formals %token ID INT STR IND_STR PATH URI %token IF THEN ELSE ASSERT WITH LET IN REC INHERIT EQ NEQ AND OR IMPL %token DOLLAR_CURLY /* == ${ */ %token IND_STRING_OPEN IND_STRING_CLOSE %token ELLIPSIS %nonassoc IMPL %left OR %left AND %nonassoc EQ NEQ %right UPDATE %left NEG %left '+' %right CONCAT %nonassoc '?' %nonassoc '~' %% start: expr { data->result = $1; }; expr: expr_function; expr_function : pattern ':' expr_function { checkPatternVars(CUR_POS, $1); $$ = makeFunction($1, $3, CUR_POS); } | ASSERT expr ';' expr_function { $$ = makeAssert($2, $4, CUR_POS); } | WITH expr ';' expr_function { $$ = makeWith($2, $4, CUR_POS); } | LET binds IN expr_function { $$ = makeSelect(fixAttrs(true, ATinsert($2, makeBindAttrPath(ATmakeList1(toATerm("")), $4, CUR_POS))), toATerm("")); } | expr_if ; expr_if : IF expr THEN expr ELSE expr { $$ = makeIf($2, $4, $6); } | expr_op ; expr_op : '!' expr_op %prec NEG { $$ = makeOpNot($2); } | expr_op EQ expr_op { $$ = makeOpEq($1, $3); } | expr_op NEQ expr_op { $$ = makeOpNEq($1, $3); } | expr_op AND expr_op { $$ = makeOpAnd($1, $3); } | expr_op OR expr_op { $$ = makeOpOr($1, $3); } | expr_op IMPL expr_op { $$ = makeOpImpl($1, $3); } | expr_op UPDATE expr_op { $$ = makeOpUpdate($1, $3); } | expr_op '~' expr_op { $$ = makeSubPath($1, $3); } | expr_op '?' ID { $$ = makeOpHasAttr($1, $3); } | expr_op '+' expr_op { $$ = makeOpPlus($1, $3); } | expr_op CONCAT expr_op { $$ = makeOpConcat($1, $3); } | expr_app ; expr_app : expr_app expr_select { $$ = makeCall($1, $2); } | expr_select { $$ = $1; } ; expr_select : expr_select '.' ID { $$ = makeSelect($1, $3); } | expr_simple { $$ = $1; } ; expr_simple : ID { $$ = makeVar($1); } | INT { $$ = makeInt(ATgetInt((ATermInt) $1)); } | '"' string_parts '"' { /* For efficiency, and to simplify parse trees a bit. */ if ($2 == ATempty) $$ = makeStr(toATerm(""), ATempty); else if (ATgetNext($2) == ATempty) $$ = ATgetFirst($2); else $$ = makeConcatStrings(ATreverse($2)); } | IND_STRING_OPEN ind_string_parts IND_STRING_CLOSE { $$ = stripIndentation(ATreverse($2)); } | PATH { $$ = makePath(toATerm(absPath(aterm2String($1), data->basePath))); } | URI { $$ = makeStr($1, ATempty); } | '(' expr ')' { $$ = $2; } /* Let expressions `let {..., body = ...}' are just desugared into `(rec {..., body = ...}).body'. */ | LET '{' binds '}' { $$ = makeSelect(fixAttrs(true, $3), toATerm("body")); } | REC '{' binds '}' { $$ = fixAttrs(true, $3); } | '{' binds '}' { $$ = fixAttrs(false, $2); } | '[' expr_list ']' { $$ = makeList(ATreverse($2)); } ; string_parts : string_parts STR { $$ = ATinsert($1, $2); } | string_parts DOLLAR_CURLY expr '}' { backToString(scanner); $$ = ATinsert($1, $3); } | { $$ = ATempty; } ; ind_string_parts : ind_string_parts IND_STR { $$ = ATinsert($1, $2); } | ind_string_parts DOLLAR_CURLY expr '}' { backToIndString(scanner); $$ = ATinsert($1, $3); } | { $$ = ATempty; } ; pattern : pattern2 '@' pattern { $$ = makeAtPat($1, $3); } | pattern2 ; pattern2 : ID { $$ = makeVarPat($1); } | '{' formals '}' { $$ = makeAttrsPat($2.formals, $2.ellipsis ? eTrue : eFalse); } ; binds : binds bind { $$ = ATinsert($1, $2); } | { $$ = ATempty; } ; bind : attrpath '=' expr ';' { $$ = makeBindAttrPath(ATreverse($1), $3, CUR_POS); } | INHERIT inheritsrc ids ';' { $$ = makeInherit($2, $3, CUR_POS); } ; inheritsrc : '(' expr ')' { $$ = $2; } | { $$ = makeScope(); } ; ids: ids ID { $$ = ATinsert($1, $2); } | { $$ = ATempty; }; attrpath : attrpath '.' ID { $$ = ATinsert($1, $3); } | ID { $$ = ATmakeList1($1); } ; expr_list : expr_list expr_select { $$ = ATinsert($1, $2); } | { $$ = ATempty; } ; formals : formal ',' formals /* !!! right recursive */ { $$.formals = ATinsert($3.formals, $1); $$.ellipsis = $3.ellipsis; } | formal { $$.formals = ATinsert(ATempty, $1); $$.ellipsis = false; } | { $$.formals = ATempty; $$.ellipsis = false; } | ELLIPSIS { $$.formals = ATempty; $$.ellipsis = true; } ; formal : ID { $$ = makeFormal($1, makeNoDefaultValue()); } | ID '?' expr { $$ = makeFormal($1, makeDefaultValue($3)); } ; %% #include "eval.hh" #include #include #include #include namespace nix { static Expr parse(EvalState & state, const char * text, const Path & path, const Path & basePath) { yyscan_t scanner; ParseData data; data.basePath = basePath; data.path = path; yylex_init(&scanner); yy_scan_string(text, scanner); int res = yyparse(scanner, &data); yylex_destroy(scanner); if (res) throw ParseError(data.error); try { checkVarDefs(state.primOps, data.result); } catch (Error & e) { throw ParseError(format("%1%, in `%2%'") % e.msg() % path); } return data.result; } Expr parseExprFromFile(EvalState & state, Path path) { assert(path[0] == '/'); #if 0 /* Perhaps this is already an imploded parse tree? */ Expr e = ATreadFromNamedFile(path.c_str()); if (e) return e; #endif /* If `path' is a symlink, follow it. This is so that relative path references work. */ struct stat st; while (true) { if (lstat(path.c_str(), &st)) throw SysError(format("getting status of `%1%'") % path); if (!S_ISLNK(st.st_mode)) break; path = absPath(readLink(path), dirOf(path)); } /* If `path' refers to a directory, append `/default.nix'. */ if (stat(path.c_str(), &st)) throw SysError(format("getting status of `%1%'") % path); if (S_ISDIR(st.st_mode)) path = canonPath(path + "/default.nix"); /* Read and parse the input file. */ return parse(state, readFile(path).c_str(), path, dirOf(path)); } Expr parseExprFromString(EvalState & state, const string & s, const Path & basePath) { return parse(state, s.c_str(), "(string)", basePath); } }