// file : libbuild2/functions-name.cxx -*- C++ -*- // license : MIT; see accompanying LICENSE file #include #include #include #include #include using namespace std; namespace build2 { extern bool functions_sort_flags (optional); // functions-builtin.cxx // Convert name to target'ish name (see below for the 'ish part). Return // raw/unprocessed data in case this is an unknown target type (or called // out of scope). See scope::find_target_type() for details. Allow out- // qualified names (out is discarded). // static pair> to_target_type (const scope* s, name& n, const name& o = name ()) { if (n.pair && !o.directory ()) fail << "name pair in names"; return s != nullptr ? s->find_target_type (n, location ()) : pair> {nullptr, nullopt}; } static pair> to_target_name (const scope* s, name&& n, const name& o = name ()) { auto rp (to_target_type (s, n, o)); if (rp.first != nullptr) n.type = rp.first->name; if (n.value.empty () && (n.type == "dir" || n.type == "fsdir")) { n.value = n.dir.leaf ().string (); n.dir.make_directory (); } return make_pair (move (n), move (rp.second)); } const target& to_target (const scope& s, name&& n, name&& o, bool in_recipe, const location& loc) { // Note: help the user out and search in both out and src like a // prerequisite. // if (const target* r = search_existing (n, s, o.dir)) return *r; // Inside recipes we don't treat `{}` as special so a literal target name // will have no type and won't be found, which is confusing as hell. // bool typed (n.typed ()); diag_record dr (fail (loc)); dr << "target " << (n.pair ? names {move (n), move (o)} : names {move (n)}) << " not found"; if (in_recipe && !typed) dr << info << "wrap it in ([names] ...) if this is literal target name " << "specified inside recipe"; dr << endf; } const target& to_target (const scope& s, names&& ns, bool in_recipe, const location& loc) { assert (ns.size () == (ns[0].pair ? 2 : 1)); name o; return to_target (s, move (ns[0]), move (ns[0].pair ? ns[1] : o), in_recipe, loc); } static bool is_a (const scope* s, name&& n, const name& o, names&& t) { if (s == nullptr) fail << "name.is_a() called out of scope"; string tts (convert (move (t))); const target_type* tt (s->find_target_type (tts)); if (tt == nullptr) fail << "unknown target type " << tts; const target_type* ntt (to_target_type (s, n, o).first); if (ntt == nullptr) { // If this is an imported target and the target type is unknown, then // it cannot possibly match one of the known types. We handle it like // this instead of failing because the later failure (e.g., as a // result of this target listed as prerequisite) will have more // accurate diagnostics. See also filter() below. // if (n.proj) return false; fail << "unknown target type " << n.type << " in " << n; } return ntt->is_a (*tt); } static names filter (const scope* s, names ns, names ts, bool out) { if (s == nullptr) fail << "name." << (out ? "filter_out" : "filter") << "() called out of scope"; small_vector tts; for (const name& n: ts) { if (!n.simple ()) fail << "invalid target type name " << n; if (n.pair) fail << "pair in target type name " << n; const target_type* tt (s->find_target_type (n.value)); if (tt == nullptr) fail << "unknown target type " << n.value; tts.push_back (tt); } names r; for (auto i (ns.begin ()); i != ns.end (); ++i) { name& n (*i); bool p (n.pair); // to_target_type() splits the name into the target name and extension. // While we could try to reconstitute it with combine_name(), there are // murky corner cases (see the default_extension argument) which won't // be easy to handle. So let's just make a copy. Looking at the // implementation of scope::find_target_type(), we can optimize for the // (common) typed case by only copying the type. // name c (n.typed () ? name (n.type, "") : n); const target_type* ntt (to_target_type (s, c, p ? *++i : name ()).first); if (ntt == nullptr) { // If this is an imported target and the target type is unknown, then // it cannot possibly match one of the known types. We handle it like // this instead of failing because the later failure (e.g., as a // result of this target listed as prerequisite) will have more // accurate diagnostics. See also is_a() above. // if (!n.proj) fail << "unknown target type " << n.type << " in " << n; } if (ntt != nullptr ? (find_if (tts.begin (), tts.end (), [ntt] (const target_type* tt) { return ntt->is_a (*tt); }) != tts.end ()) != out : out) { r.push_back (move (n)); if (p) r.push_back (move (*i)); } } return r; } void name_functions (function_map& m) { // These functions treat a name as a target/prerequisite name. // // While on one hand it feels like calling them target.name(), etc., would // have been more appropriate, on the other hand they can also be called // on prerequisite names. They also won't always return the same result as // if we were interrogating an actual target (e.g., the directory may be // relative). Plus we now have functions that can only be called on // targets (see functions-target.cxx). // function_family f (m, "name"); // Note: let's leave this undocumented for now since it's not often needed // and is a can of worms. // // Note that we must handle NULL values (relied upon by the parser // to provide conversion semantics consistent with untyped values). // f["string"] += [](name* n) { return n != nullptr ? to_string (move (*n)) : string (); }; // $name() // // Return the name of a target (or a list of names for a list of targets). // f["name"] += [](const scope* s, name n) { return to_target_name (s, move (n)).first.value; }; f["name"] += [](const scope* s, names ns) { small_vector r; for (auto i (ns.begin ()); i != ns.end (); ++i) { name& n (*i); r.push_back ( to_target_name (s, move (n), n.pair ? *++i : name ()).first.value); } if (r.size () == 1) return value (move (r[0])); return value (strings (make_move_iterator (r.begin ()), make_move_iterator (r.end ()))); }; // $extension() // // Return the extension of a target. // // Note that this function returns `null` if the extension is unspecified // (default) and empty string if it's specified as no extension. // f["extension"] += [](const scope* s, name n) { return to_target_name (s, move (n)).second; }; f["extension"] += [](const scope* s, names ns) { // Note: can't do multiple due to NULL semantics. // auto i (ns.begin ()); name& n (*i); const name& o (n.pair ? *++i : name ()); if (++i != ns.end ()) fail << "invalid name value: multiple names"; // Like in convert(). return to_target_name (s, move (n), o).second; }; // $directory() // // Return the directory of a target (or a list of directories for a list // of targets). // f["directory"] += [](const scope* s, name n) { return to_target_name (s, move (n)).first.dir; }; f["directory"] += [](const scope* s, names ns) { small_vector r; for (auto i (ns.begin ()); i != ns.end (); ++i) { name& n (*i); r.push_back ( to_target_name (s, move (n), n.pair ? *++i : name ()).first.dir); } if (r.size () == 1) return value (move (r[0])); return value (dir_paths (make_move_iterator (r.begin ()), make_move_iterator (r.end ()))); }; // $target_type() // // Return the target type name of a target (or a list of target type names // for a list of targets). // f["target_type"] += [](const scope* s, name n) { return to_target_name (s, move (n)).first.type; }; f["target_type"] += [](const scope* s, names ns) { small_vector r; for (auto i (ns.begin ()); i != ns.end (); ++i) { name& n (*i); r.push_back ( to_target_name (s, move (n), n.pair ? *++i : name ()).first.type); } if (r.size () == 1) return value (move (r[0])); return value (strings (make_move_iterator (r.begin ()), make_move_iterator (r.end ()))); }; // $project() // // Return the project of a target or `null` if not project-qualified. // f["project"] += [](const scope* s, name n) { return to_target_name (s, move (n)).first.proj; }; f["project"] += [](const scope* s, names ns) { // Note: can't do multiple due to NULL semantics. // auto i (ns.begin ()); name& n (*i); const name& o (n.pair ? *++i : name ()); if (++i != ns.end ()) fail << "invalid name value: multiple names"; // Like in convert(). return to_target_name (s, move (n), o).first.proj; }; // $is_a(, ) // // Return true if the 's target type is-a . Note that // this is a dynamic type check that takes into account target type // inheritance. // f["is_a"] += [](const scope* s, name n, names t) { return is_a (s, move (n), name (), move (t)); }; f["is_a"] += [](const scope* s, names ns, names t) { auto i (ns.begin ()); name& n (*i); const name& o (n.pair ? *++i : name ()); if (++i != ns.end ()) fail << "invalid name value: multiple names"; // Like in convert(). return is_a (s, move (n), o, move (t)); }; // $filter(, ) // $filter_out(, ) // // Return names with target types which are-a (`filter`) or not are-a // (`filter_out`) one of . See `$is_a()` for background. // f["filter"] += [](const scope* s, names ns, names ts) { return filter (s, move (ns), move (ts), false /* out */); }; f["filter_out"] += [](const scope* s, names ns, names ts) { return filter (s, move (ns), move (ts), true /* out */); }; // $size() // // Return the number of elements in the sequence. // f["size"] += [] (names ns) { size_t n (0); for (auto i (ns.begin ()); i != ns.end (); ++i) { ++n; if (i->pair && !(++i)->directory ()) fail << "name pair in names"; } return n; }; // $sort([, ]) // // Sort names in ascending order. // // The following flags are supported: // // dedup - in addition to sorting also remove duplicates // f["sort"] += [] (names ns, optional fs) { //@@ TODO: shouldn't we do this in a pair-aware manner? sort (ns.begin (), ns.end ()); if (functions_sort_flags (move (fs))) ns.erase (unique (ns.begin (), ns.end ()), ns.end ()); return ns; }; // $find(, ) // // Return true if the name sequence contains the specified name. // f["find"] += [](names vs, names v) { //@@ TODO: shouldn't we do this in a pair-aware manner? return find (vs.begin (), vs.end (), convert (move (v))) != vs.end (); }; // $find_index(, ) // // Return the index of the first element in the name sequence that is // equal to the specified name or `$size(names)` if none is found. // f["find_index"] += [](names vs, names v) { //@@ TODO: shouldn't we do this in a pair-aware manner? auto i (find (vs.begin (), vs.end (), convert (move (v)))); return i != vs.end () ? i - vs.begin () : vs.size (); }; // Name-specific overloads from builtins. // function_family fb (m, "builtin"); // Note that while we should normally handle NULL values (relied upon by // the parser to provide concatenation semantics consistent with untyped // values), the result will unlikely be what the user expected. So for now // we keep it a bit tighter. // fb[".concat"] += [](dir_path d, name n) { d /= n.dir; n.dir = move (d); return n; }; } }