// file : libbuild2/target.cxx -*- C++ -*- // license : MIT; see accompanying LICENSE file #include #include // strcmp() #include #include #include #include #include #include using namespace std; using namespace butl; namespace build2 { // target_type // bool target_type:: is_a (const char* n) const { for (const target_type* b (this); b != nullptr; b = b->base) if (strcmp (b->name, n) == 0) return true; return false; } // target_key // void target_key:: as_name (names& r) const { string v; if (!name->empty ()) { v = *name; // @@ TMP: see also other calls to combine_name() -- need to fix. // target::combine_name (v, ext, false /* @@ TMP: what to do? */); } else assert (!ext || ext->empty ()); // Unspecified or none. r.emplace_back (*dir, type->name, move (v)); if (!out->empty ()) { r.back ().pair = '@'; r.emplace_back (*out); } } // target_state // static const char* const target_state_[] = { "", // Absent/invalid (see target_state for details). "unknown", "unchanged", "postponed", "busy", "changed", "failed", "group" }; string to_string (target_state ts) { return target_state_[static_cast (ts)]; } // target // target:: ~target () { } const string& target:: ext (string v) { ulock l (ctx.targets.mutex_); // Once the extension is set, it is immutable. However, it is possible // that someone has already "branded" this target with a different // extension. // optional& e (*ext_); if (!e) e = move (v); else if (*e != v) { string o (*e); l.unlock (); fail << "conflicting extensions '" << o << "' and '" << v << "' " << "for target " << *this; } return *e; } group_view target:: group_members (action) const { // Not a group or doesn't expose its members. // return group_view {nullptr, 0}; } const scope& target:: base_scope_impl () const { // If this target is from the src tree, use its out directory to find // the scope. // const scope& s (ctx.scopes.find_out (out_dir ())); // Cache unless we are in the load phase. // if (ctx.phase != run_phase::load) { const scope* e (nullptr); if (!base_scope_.compare_exchange_strong ( e, &s, memory_order_release, memory_order_consume)) assert (e == &s); } return s; } pair target:: lookup_original (const variable& var, lookup_limit limit, const scope* bs, bool locked) const { pair r (lookup_type (), 0); ++r.second; { auto p (vars.lookup (var)); if (p.first != nullptr) r.first = lookup_type (*p.first, p.second, vars); } const target* g1 (nullptr); const target* g2 (nullptr); if (!r.first) { ++r.second; // While we went back to not treating the first member as a group for // variable lookup, let's keep this logic in case one day we end up with // a separate ad hoc group target. // #if 0 // In case of an ad hoc group, we may have to look in two groups. // if ((g1 = group) != nullptr) { auto p (g1->vars.lookup (var)); if (p.first != nullptr) r.first = lookup_type (*p.first, p.second, g1->vars); else { if ((g2 = g1->group) != nullptr) { auto p (g2->vars.lookup (var)); if (p.first != nullptr) r.first = lookup_type (*p.first, p.second, g2->vars); } } } #else // Skip looking up in the ad hoc group, which is semantically the // first/primary member. // const target* g (group); // Atomic. if ((g1 = g == nullptr ? nullptr : g->adhoc_group () ? static_cast (g->group) : g)) { auto p (g1->vars.lookup (var)); if (p.first != nullptr) r.first = lookup_type (*p.first, p.second, g1->vars); } #endif } // Delegate to scope's lookup_original(). // if (!r.first) { if (limit != lookup_limit::target) { auto key = [locked] (const target* t) { return locked ? t->key_locked () : t->key (); }; target_key tk (key (this)); target_key g1k (g1 != nullptr ? key (g1) : target_key {}); target_key g2k (g2 != nullptr ? key (g2) : target_key {}); if (bs == nullptr) bs = &base_scope (); auto p (bs->lookup_original (var, &tk, g1 != nullptr ? &g1k : nullptr, g2 != nullptr ? &g2k : nullptr, limit)); r.first = move (p.first); r.second = r.first ? r.second + p.second : p.second; } else r.second = size_t (~0); } return r; } value& target:: append (const variable& var, const scope* bs) { // Note: see also prerequisite::append() if changing anything here. // Note that here we want the original value without any overrides // applied. // auto l (lookup_original (var, bs).first); if (l.defined () && l.belongs (*this)) // Existing var in this target. return vars.modify (l); // Ok since this is original. value& r (assign (var)); // NULL. if (l.defined ()) r = *l; // Copy value (and type) from the outer scope. return r; } value& target:: append_locked (const variable& var, const scope* bs) { auto l (lookup_original (var, bs, true /* locked */).first); if (l.defined () && l.belongs (*this)) // Existing var in this target. return vars.modify (l); // Ok since this is original. value& r (assign (var)); // NULL. if (l.defined ()) r = *l; // Copy value (and type) from the outer scope. return r; } pair target::opstate:: lookup_original (const variable& var, lookup_limit limit) const { pair r (lookup_type (), 0); ++r.second; { auto p (vars.lookup (var)); if (p.first != nullptr) r.first = lookup_type (*p.first, p.second, vars); } // Delegate to target's lookup_original(). // if (!r.first) { auto p (target_->lookup_original (var, limit)); r.first = move (p.first); r.second = r.first ? r.second + p.second : p.second; } return r; } optional target:: split_name (string& v, const location& loc) { assert (!v.empty ()); // Normally, we treat the rightmost dot as an extension separator (but see // find_extension() for the exact semantics) and if none exists, then we // assume the extension is not specified. There are, however, special // cases that override this rule: // // - We treat triple dots as the "chosen extension separator" (used to // resolve ambiguity as to which dot is the separator, for example, // libfoo...u.a). If they are trailing triple dots, then this signifies // the "unspecified (default) extension" (used when the extension in the // name is not "ours", for example, cxx{foo.test...} for foo.test.cxx) // Having multiple triple dots is illegal. // // - Otherwise, we treat a single trailing dot as the "specified no // - extension". // // - Finally, double dots are used as an escape sequence to make sure the // dot is not treated as an extension separator (or as special by any of // the above rules, for example, libfoo.u..a). In case of trailing // double dots, we naturally assume there is no default extension. // // An odd number of dots other than one or three is illegal. This means, // in particular, that it's impossible to specify a base/extension pair // where either the base ends with a dot or the extension begins with one // (or both). We are ok with that. // // Dot-only sequences are illegal. Note though, that dir{.} and dir{..} // are handled ad hoc outside this function and are valid. // Note that we cannot unescape dots in-place before we validate the name // since it can be required for diagnostics. Thus, the plan is as follows: // // - Iterate right to left, searching for the extension dot, validating // the name, and checking if any dots are escaped. // // - Split the name. // // - Unescape the dots in the name and/or extension, if required. // Search for an extension dot, validate the name, and check for escape // sequences. // optional edp; // Extension dot position. size_t edn (0); // Extension dot representation lenght (1 or 3). bool escaped (false); bool dot_only (true); size_t n (v.size ()); // Iterate right to left until the beginning of the string or a directory // separator is encountered. // // At the end of the loop p will point to the beginning of the leaf. // size_t p (n - 1); for (;; --p) { char c (v[p]); if (c == '.') { // Find the first dot in the sequence. // size_t i (p); for (; i != 0 && v[i - 1] == '.'; --i) ; size_t sn (p - i + 1); // Sequence length. if (sn == 3) // Triple dots? { if (edp && edn == 3) fail (loc) << "multiple triple dots in target name '" << v << "'"; edp = i; edn = 3; } else if (sn == 1) // Single dot? { if (!edp) { edp = i; edn = 1; } } else if (sn % 2 == 0) // Escape sequence? escaped = true; else fail (loc) << "invalid dot sequence in target name '" << v << "'"; p = i; // Position to the first dot in the sequence. } else if (path::traits_type::is_separator (c)) { // Position to the beginning of the leaf and bail out. // ++p; break; } else dot_only = false; if (p == 0) break; } if (dot_only) fail (loc) << "invalid target name '" << v << "'"; // The leading dot cannot be an extension dot. Thus, the leading triple // dots are invalid and the leading single dot is not considered as such. // if (edp && *edp == p) { if (edn == 3) fail (loc) << "leading triple dots in target name '" << v << "'"; edp = nullopt; } // Split the name. // optional r; if (edp) { if (*edp != n - edn) // Non-trailing dot? r = string (v, *edp + edn); else if (edn == 1) // Trailing single dot? r = string (); //else if (edn == 3) // Trailing triple dots? // r = nullopt; v.resize (*edp); } else if (v.back () == '.') // Trailing escaped dot? r = string (); if (!escaped) return r; // Unescape the dots. // auto unescape = [] (string& s, size_t b = 0) { size_t n (s.size ()); for (size_t i (b); i != n; ++i) { if (s[i] == '.') { // Find the end of the dot sequence. // size_t j (i + 1); for (; j != n && s[j] == '.'; ++j) ; size_t sn (j - i); // Sequence length. // Multiple dots can only represent an escape sequence now. // if (sn != 1) { assert (sn % 2 == 0); size_t dn (sn / 2); // Number of dots to remove. s.erase (i + dn, dn); i += dn - 1; // Position to the last dot in the sequence. n -= dn; // Adjust string size counter. } } } }; unescape (v, p); if (r) unescape (*r); return r; } // Escape the name according to the rules described in split_name(). The // idea is that we should be able to roundtrip things. // // Note though, that multiple representations can end up with the same // name, for example libfoo.u..a and libfoo...u.a. We will always resolve // ambiguity with the triple dot and only escape those dots that otherwise // can be misinterpreted (dot sequences, etc). // void target:: combine_name (string& v, const optional& e, bool de) { // Escape all dot sequences since they can be misinterpreted as escape // sequences and return true if the result contains an unescaped dot that // can potentially be considered an extension dot. // // In the name mode only consider the basename, escape the trailing dot // (since it can be misinterpreted as the 'no extension' case), and don't // treat the basename leading dot as the potential extension dot. // auto escape = [] (string& s, bool name) -> bool { if (s.empty ()) return false; bool r (false); size_t n (s.size ()); // Iterate right to left until the beginning of the string or a // directory separator is encountered. // for (size_t p (n - 1);; --p) { char c (s[p]); if (c == '.') { // Find the first dot in the sequence. // size_t i (p); for (; i != 0 && s[i - 1] == '.'; --i) ; size_t sn (p - i + 1); // Sequence length. bool esc (sn != 1); // Escape the sequence. bool ext (sn == 1); // An extension dot, potentially. if (name) { if (i == n - 1) esc = true; if (ext && (i == 0 || path::traits_type::is_separator (s[i - 1]))) ext = false; } if (esc) s.insert (p + 1, sn, '.'); // Double them. if (ext) r = true; p = i; // Position to the first dot in the sequence. } else if (path::traits_type::is_separator (c)) { assert (name); break; } if (p == 0) break; } return r; }; bool ed (escape (v, true /* name */)); if (v.back () == '.') // Name had (before escaping) trailing dot. { assert (e && e->empty ()); } else if (e) { // Separate the name and extension with the triple dots if the extension // contains potential extension dots. // string ext (*e); v += escape (ext, false /* name */) ? "..." : "."; v += ext; // Empty or not. } else if (de && ed) v += "..."; } // include() // // See var_include documentation for details on what's going on here. // include_type include_impl (action a, const target& t, const prerequisite& p, const target* m, lookup* rl) { context& ctx (t.ctx); include_type r (include_type::normal); { lookup l (p.vars[ctx.var_include]); if (l.defined ()) { if (l->null) { // @@ TMP (added in 0.16.0). // warn << "null " << *ctx.var_include << " variable value specified " << "for prerequisite " << p << info << "treated as undefined for backwards compatibility" << info << "this warning will become error in the future"; } else { const string& v (cast (*l)); if (v == "false") r = include_type::excluded; else if (v == "true") r = include_type::normal; else if (v == "adhoc") r = include_type::adhoc; else if (v == "posthoc") r = include_type::posthoc; else fail << "invalid " << *ctx.var_include << " variable value '" << v << "' specified for prerequisite " << p; } } } // Handle operation-specific override (see var_include documentation // for details). // lookup l; optional r1; // Absent means something other than true|false. names storage; names_view ns; const variable* ovar (nullptr); if (r != include_type::excluded) { // Instead of going via potentially expensive target::base_scope(), use // the prerequisite's scope; while it may not be the same as the // targets's base scope, they must have the same root scope. // const scope& rs (*p.scope.root_scope ()); ovar = rs.root_extra->operations[ (a.outer () ? ctx.current_outer_oif : ctx.current_inner_oif)->id].ovar; if (ovar != nullptr) { l = p.vars[*ovar]; if (l.defined ()) { if (l->null) fail << "null " << *ovar << " variable value specified for " << "prerequisite " << p; // Maybe we should optimize this for the common cases (bool, path, // name)? But then again we don't expect many such overrides. Plus // will complicate the diagnostics below. // ns = reverse (*l, storage, true /* reduce */); if (ns.size () == 1) { const name& n (ns[0]); if (n.simple ()) { const string& v (n.value); if (v == "false") r1 = false; else if (v == "true") r1 = true; } } if (r1 && !*r1) r = include_type::excluded; } } } // Call the meta-operation override, if any (currently used by dist). // if (r != include_type::normal || l) { if (auto f = ctx.current_mif->include) r = f (a, t, prerequisite_member {p, m}, r, l); } if (l) { if (rl != nullptr) *rl = l; else if (!r1) { // Note: we have to delay this until the meta-operation callback above // had a chance to override it. // fail << "unrecognized " << *ovar << " variable value '" << ns << "' specified for prerequisite " << p; } } return r; } // target_set // const target* target_set:: find (const target_key& k, tracer& trace) const { bool load (ctx.phase == run_phase::load); slock sl (mutex_, defer_lock); if (!load) sl.lock (); map_type::const_iterator i (map_.find (k)); if (i == map_.end ()) return nullptr; const target& t (*i->second); optional& ext (i->first.ext); if (ext != k.ext) { ulock ul; // Keep locked for trace. if (k.ext) { // To update the extension we have to re-lock for exclusive access. // Between us releasing the shared lock and acquiring unique the // extension could change and possibly a new target that matches the // key could be inserted. In this case we simply re-run find (). // Naturally, can't happen during load. // if (!load) { sl.unlock (); ul = ulock (mutex_); if (ext) // Someone set the extension. { ul.unlock (); return find (k, trace); } } } l5 ([&]{ diag_record r (trace); r << "assuming target "; to_stream (r.os, target_key {&t.type (), &t.dir, &t.out, &t.name, ext}, stream_verb_max); // Always print the extension. r << " is the same as the one with "; if (!k.ext) r << "unspecified extension"; else if (k.ext->empty ()) r << "no extension"; else r << "extension " << *k.ext; }); if (k.ext) ext = k.ext; } return &t; } pair target_set:: insert_locked (const target_type& tt, dir_path dir, dir_path out, string name, optional ext, target_decl decl, tracer& trace, bool skip_find, bool need_lock) { target_key tk {&tt, &dir, &out, &name, move (ext)}; target* t (skip_find ? nullptr : const_cast (find (tk, trace))); if (t == nullptr) { // We sometimes call insert() even if we expect to find an existing // target in order to keep the same code (see cc/search_library()). // assert (ctx.phase != run_phase::execute); optional e ( tt.fixed_extension != nullptr ? string (tt.fixed_extension (tk, nullptr /* root scope */)) : move (tk.ext)); t = tt.factory (ctx, tt, move (dir), move (out), move (name)); // Re-lock for exclusive access. In the meantime, someone could have // inserted this target so emplace() below could return false, in which // case we proceed pretty much like find() except already under the // exclusive lock. // ulock ul (mutex_, defer_lock); if (ctx.phase != run_phase::load || need_lock) ul.lock (); auto p (map_.emplace (target_key {&tt, &t->dir, &t->out, &t->name, e}, unique_ptr (t))); map_type::iterator i (p.first); if (p.second) { #if 0 { size_t n (map_.bucket_count ()); if (n > buckets_) { text << "target_set buckets: " << buckets_ << " -> " << n << " (" << map_.size () << ")"; buckets_ = n; } } #endif t->ext_ = &i->first.ext; t->decl = decl; t->state.inner.target_ = t; t->state.outer.target_ = t; t->state.inner.vars.target_ = t; t->state.outer.vars.target_ = t; if (ctx.phase != run_phase::load && !need_lock) ul.unlock (); return pair (*t, move (ul)); } // The "tail" of find(). // t = i->second.get (); optional& ext (i->first.ext); if (ext != e) { l5 ([&]{ diag_record r (trace); r << "assuming target "; to_stream ( r.os, target_key {&t->type (), &t->dir, &t->out, &t->name, ext}, stream_verb_max); // Always print the extension. r << " is the same as the one with "; if (!e) r << "unspecified extension"; else if (e->empty ()) r << "no extension"; else r << "extension " << *e; }); if (e) ext = e; } // Fall through (continue as if the first find() returned this target). } // Without resorting to something like atomic we can only upgrade the // declaration to real (which is expected to only happen during the load // phase). // if (decl == target_decl::real) { assert (ctx.phase == run_phase::load); if (t->decl != target_decl::real) t->decl = decl; } return pair (*t, ulock ()); } static const optional unknown_ext ("?"); bool to_stream (ostream& os, const target_key& k, optional osv, bool name_only) { // Note: similar code in print_diag_impl(vector). stream_verbosity sv (osv ? *osv : stream_verb (os)); uint16_t dv (sv.path); uint16_t ev (sv.extension); // If the name is empty, then we want to print the last component of the // directory inside {}, e.g., dir{bar/}, not bar/dir{}. // bool n (!k.name->empty ()); const target_type& tt (*k.type); dir_path rds; // Storage. if (!name_only) { // Note: relative() returns empty for './'. // if (dv < 1) rds = relative (*k.dir); const dir_path& rd (dv < 1 ? rds : *k.dir); // Relative. const dir_path& pd (n ? rd : rd.directory ()); // Parent. if (!pd.empty ()) { if (dv < 1) os << diag_relative (pd); else to_stream (os, pd, true /* representation */); } os << tt.name << '{'; } if (n) { const optional* ext (nullptr); // NULL or present. // If the extension derivation functions are NULL, then it means this // target type doesn't use extensions. // if (tt.fixed_extension != nullptr || tt.default_extension != nullptr) { // For verbosity level 0 we don't print the extension. For 1 we print // it if there is one. For 2 we print 'foo.?' if it hasn't yet been // assigned and 'foo.' if it is assigned as "no extension" (empty). // if (ev > 0 && (ev > 1 || (k.ext && !k.ext->empty ()))) { ext = k.ext ? &k.ext : &unknown_ext; } } else assert (!k.ext || k.ext->empty ()); // Unspecified or none. // Escape dots in the name/extension to resolve potential ambiguity. // if (k.name->find ('.') == string::npos && (ext == nullptr || (*ext)->find ('.') == string::npos)) { os << *k.name; if (ext != nullptr) os << '.' << **ext; } else { string n (*k.name); target::combine_name (n, ext != nullptr ? *ext : nullopt_string, false /* default_extension */); os << n; } } else { if (name_only && dv < 1) // Already done if !name_only. rds = relative (*k.dir); const dir_path& rd (dv < 1 ? rds : *k.dir); to_stream (os, rd.empty () ? dir_path (".") : rd.leaf (), true /* representation */); } if (!name_only) { os << '}'; // If this target is from src, print its out. // if (!k.out->empty ()) { if (dv < 1) { // Don't print '@./'. // const string& o (diag_relative (*k.out, false)); if (!o.empty ()) os << '@' << o; } else os << '@' << *k.out; } } return n; // Regular if we had the name. } ostream& operator<< (ostream& os, const target_key& k) { if (auto p = k.type->print) p (os, k, false /* name_only */); else to_stream (os, k, stream_verb (os)); return os; } // mtime_target // timestamp mtime_target:: mtime () const { // Figure out from which target we should get the value. // const mtime_target* t (this); switch (ctx.phase) { case run_phase::load: break; case run_phase::match: { // Similar logic to target::matched(). // const opstate& s (state[action () /* inner */]); // Note: use acquire for group_state(). // size_t c (s.task_count.load (memory_order_acquire)); size_t b (ctx.count_base ()); // Note: cannot do (c - b)! if (!(c == (b + offset_applied) || c == (b + offset_executed) || (c >= (b + offset_busy) && s.match_extra.cur_options_.load (memory_order_relaxed) != 0))) break; } // Fall through. case run_phase::execute: { if (group_state (action () /* inner */)) t = &group->as (); break; } } return timestamp (duration (t->mtime_.load (memory_order_consume))); } // path_target // const string* path_target:: derive_extension (bool search, const char* de) { // See also search_existing_file() if updating anything here. // Should be no default extension if searching. // assert (!search || de == nullptr); // The target should use extensions and they should not be fixed. // assert (de == nullptr || type ().default_extension != nullptr); if (const string* p = ext ()) // Note that returning by reference is now MT-safe since once the // extension is specified, it is immutable. // return p; else { optional e; // If the target type has the default extension function then try that // first. The reason for preferring it over what's been provided by the // caller is that this function will often use the 'extension' variable // which the user can use to override extensions. But since we pass the // provided default extension, the target type can override this logic // (see the exe{} target type for a use case). // if (auto f = type ().default_extension) e = f (key (), base_scope (), de, search); if (!e) { if (de != nullptr) e = de; else { if (search) return nullptr; fail << "no default extension for target " << *this << endf; } } return &ext (move (*e)); } } const path& path_target:: derive_path (const char* de, const char* np, const char* ns, const char* ee) { return derive_path_with_extension (derive_extension (de), np, ns, ee); } const path& path_target:: derive_path_with_extension (const string& e, const char* np, const char* ns, const char* ee) { path_type p (dir); if (np == nullptr || np[0] == '\0') p /= name; else { p /= np; p += name; } if (ns != nullptr) p += ns; return derive_path_with_extension (move (p), e, ee); } const path& path_target:: derive_path (path_type p, const char* de, const char* ee) { return derive_path_with_extension (move (p), derive_extension (de), ee); } const path& path_target:: derive_path_with_extension (path_type p, const string& e, const char* ee) { if (!e.empty ()) { p += '.'; p += e; } if (ee != nullptr) { p += '.'; p += ee; } return path (move (p)); } // Search functions. // const target* target_search (context& ctx, const target*, const prerequisite_key& pk) { // The default behavior is to look for an existing target in the // prerequisite's directory scope. // return search_existing_target (ctx, pk, true /* out_only */); } const target* file_search (context& ctx, const target* t, const prerequisite_key& pk) { // First see if there is an existing target in the out or src tree. // if (const target* e = search_existing_target (ctx, pk, false /* out_only */)) return e; // Then look for an existing file in the src tree. // return t != nullptr ? search_existing_file (ctx, pk) : nullptr; } extern const char target_extension_none_[] = ""; const char* target_extension_none (const target_key& k, const scope* s) { return target_extension_fix (k, s); } const char* target_extension_must (const target_key& tk, const scope*) { if (!tk.ext) fail << tk.type->name << " target " << tk << " must include extension"; return tk.ext->c_str (); } bool target_print_0_ext_verb (ostream& os, const target_key& k, bool no) { stream_verbosity sv (stream_verb (os)); if (sv.extension == 1) sv.extension = 0; // Remap 1 to 0. return to_stream (os, k, sv, no); } bool target_print_1_ext_verb (ostream& os, const target_key& k, bool no) { stream_verbosity sv (stream_verb (os)); if (sv.extension == 0) sv.extension = 1; // Remap 0 to 1. return to_stream (os, k, sv, no); } // type info // const target_type target::static_type { "target", nullptr, nullptr, nullptr, nullptr, nullptr, nullptr, &target_search, target_type::flag::none, }; const target_type mtime_target::static_type { "mtime_target", &target::static_type, nullptr, nullptr, nullptr, nullptr, nullptr, &target_search, target_type::flag::none }; const target_type path_target::static_type { "path_target", &mtime_target::static_type, nullptr, nullptr, nullptr, nullptr, nullptr, &target_search, target_type::flag::none }; const target_type file::static_type { "file", &path_target::static_type, &target_factory, &target_extension_none, nullptr, /* default_extension */ nullptr, /* pattern */ &target_print_1_ext_verb, // Print extension even at verbosity level 0. &file_search, target_type::flag::none }; // group // group_view group:: group_members (action a) const { if (members_on == 0) // Not yet discovered. return group_view {nullptr, 0}; // Members discovered during anything other than perform_update are only // good for that operation. For example, we only return the static members // ("representative sample") for perform_configure. // // We also re-discover the members on each update and clean not to // overcomplicate the already twisted adhoc_buildscript_rule::apply() // logic. // if (members_on != ctx.current_on) { if (members_action != perform_update_id || a == perform_update_id || a == perform_clean_id) return group_view {nullptr, 0}; } // Note that we may have no members (e.g., perform_configure and there are // no static members). However, whether std::vector returns a non-NULL // pointer in this case is undefined. // size_t n (members.size ()); return group_view { n != 0 ? members.data () : reinterpret_cast (this), n}; } const target_type group::static_type { "group", &mtime_target::static_type, &target_factory, nullptr, nullptr, nullptr, nullptr, &target_search, // // Note that the dyn_members semantics is used not only to handle // depdb-dyndep --dyn-target, but also pattern rule-static members. // target_type::flag::group | target_type::flag::dyn_members }; // alias // static const target* alias_search (context& ctx, const target* t, const prerequisite_key& pk) { // For an alias we don't want to silently create a target since it will do // nothing and it most likely not what the user intended (but omit this // check when searching for an existing target since presumably a new one // won't be created in this case). // // But, allowing implied aliases seems harmless since all the alias does // is pull its prerequisites. And they are handy to use as metadata // carriers. // // Doesn't feel like an alias in the src tree makes much sense. // const target* e (search_existing_target (ctx, pk, true /* out_only */)); if ((e == nullptr || !(operator>= (e->decl, target_decl::implied))) && t != nullptr) fail << "no explicit target for " << pk; return e; } const target_type alias::static_type { "alias", &target::static_type, &target_factory, nullptr, // Extension not used. nullptr, nullptr, nullptr, &alias_search, target_type::flag::none }; // dir // bool dir:: check_implied (const scope& rs, const dir_path& d) { try { for (const dir_entry& e: dir_iterator (d, dir_iterator::detect_dangling)) { switch (e.type ()) { case entry_type::directory: { if (check_implied (rs, d / path_cast (e.path ()))) return true; break; } case entry_type::regular: { if (e.path () == rs.root_extra->buildfile_file) return true; break; } case entry_type::unknown: { bool sl (e.ltype () == entry_type::symlink); warn << "skipping " << (sl ? "dangling symlink" : "inaccessible entry") << ' ' << d / e.path (); break; } default: break; } } } catch (const system_error& e) { fail << "unable to iterate over " << d << ": " << e << endf; } return false; } prerequisites dir:: collect_implied (const scope& bs) { prerequisites_type r; const dir_path& d (bs.src_path ()); try { for (const dir_entry& e: dir_iterator (d, dir_iterator::detect_dangling)) { if (e.type () == entry_type::directory) { r.push_back ( prerequisite (dir::static_type, dir_path (e.path ().representation ()), // Relative. dir_path (), // In the out tree. string (), nullopt, bs)); } else if (e.type () == entry_type::unknown) { bool sl (e.ltype () == entry_type::symlink); warn << "skipping " << (sl ? "dangling symlink" : "inaccessible entry") << ' ' << d / e.path (); } } } catch (const system_error& e) { fail << "unable to iterate over " << d << ": " << e; } return r; } static const target* dir_search (context& ctx, const target* t, const prerequisite_key& pk) { tracer trace ("dir_search"); // The first step is like in alias_search(): looks for an existing target // (but unlike alias, no implied, think `test/: install=false`). // // Likewise, dir{} in the src tree doesn't make much sense. // const target* e (search_existing_target (ctx, pk, true /* out_only */)); if (e != nullptr && e->decl == target_decl::real) return e; // The search for an existing target can also be done during execute so // none of the below code applied. Note: return implied instead of NULL // (to be consistent with search_new(), for example). // if (t == nullptr) return e; // If not found (or is implied), then try to load the corresponding // buildfile (which would normally define this target). Failed that, see // if we can assume an implied buildfile which would be equivalent to: // // ./: */ // const scope& s (*pk.scope); const dir_path& d (*pk.tk.dir); // Note: this code is a custom version of parser::parse_include(). // Calculate the new out_base. If the directory is absolute then we assume // it is already normalized. // dir_path out_base (d.relative () ? (s.out_path () / d).normalize () : d); // In our world modifications to the scope structure during search & match // should be "pure append" in the sense that they should not affect any // existing targets that have already been searched & matched. // // A straightforward way to enforce this is to not allow any existing // targets to be inside any newly created scopes (except, perhaps for the // directory target itself which we know hasn't been searched yet). This, // however, is not that straightforward to implement: we would need to // keep a directory prefix map for all the targets (e.g., in target_set). // Also, a buildfile could load from a directory that is not a // subdirectory of out_base. So for now we just assume that this is so. // And so it is. // bool retest (false); assert (ctx.phase == run_phase::match); { // Switch the phase to load. // phase_switch ps (ctx, run_phase::load); // This is subtle: while we were fussing around another thread may have // loaded the buildfile. So re-test now that we are in an exclusive // phase. // if (e == nullptr) e = search_existing_target (ctx, pk, true); if (e != nullptr && e->decl == target_decl::real) retest = true; else { // Ok, no luck, switch the scope. // // Note that we don't need to do anything for the project's // environment: source_once() will take care of it itself and // search_implied() is not affected. // pair sp ( switch_scope (*s.rw ().root_scope (), out_base)); if (sp.second != nullptr) // Ignore scopes out of any project. { scope& base (sp.first); scope& root (*sp.second); const dir_path& src_base (base.src_path ()); path bf (src_base / root.root_extra->buildfile_file); if (exists (bf)) { l5 ([&]{trace << "loading buildfile " << bf << " for " << pk;}); retest = source_once (root, base, bf); } else if (exists (src_base)) { e = dir::search_implied (base, pk, trace); retest = (e != nullptr); } } } } assert (ctx.phase == run_phase::match); // If we loaded/implied the buildfile, examine the target again. // if (retest) { if (e == nullptr) e = search_existing_target (ctx, pk, true); if (e != nullptr && e->decl == target_decl::real) return e; } fail << "no explicit target for " << pk << endf; } static bool dir_pattern (const target_type&, const scope&, string& v, optional&, const location&, bool r) { // Add/strip trailing directory separator unless already there. // bool d (path::traits_type::is_separator (v.back ())); if (r) { assert (d); v.resize (v.size () - 1); } else if (!d) { v += path::traits_type::directory_separator; return true; } return false; } const target_type dir::static_type { "dir", &alias::static_type, &target_factory, nullptr, // Extension not used. nullptr, &dir_pattern, nullptr, &dir_search, target_type::flag::none }; const target_type fsdir::static_type { "fsdir", &target::static_type, &target_factory, nullptr, // Extension not used. nullptr, &dir_pattern, nullptr, &target_search, target_type::flag::none }; static optional exe_target_extension (const target_key&, const scope&, const char* e, bool search) { // If we are searching for an executable that is not a target, then use // the host machine executable extension. Otherwise, if this is a target, // then we expect the rule to supply the target machine extension. But if // it doesn't, then fallback to no extension (e.g., a script). // return string (!search ? (e != nullptr ? e : "") : #ifdef _WIN32 "exe" #else "" #endif ); } #ifdef _WIN32 static bool exe_target_pattern (const target_type&, const scope&, string& v, optional& e, const location& l, bool r) { if (r) { assert (e); e = nullopt; } else { e = target::split_name (v, l); if (!e) { e = "exe"; return true; } } return false; } #endif const target_type exe::static_type { "exe", &file::static_type, &target_factory, nullptr, /* fixed_extension */ &exe_target_extension, #ifdef _WIN32 &exe_target_pattern, #else nullptr, #endif nullptr, &file_search, // Note: can also be a script in src. target_type::flag::none }; static const char* buildfile_target_extension (const target_key& tk, const scope* root) { // If the name is the special 'buildfile', then there is no extension, // otherwise it is 'build' (or 'build2file' and 'build2' in the // alternative naming scheme). // Let's try hard not to need the root scope by trusting the extensions // we were given. // // BTW, one way to get rid of all this root scope complication is to // always require explicit extension specification for buildfiles. Since // they are hardly ever mentioned explicitly, this should probably be ok. // if (tk.ext) return tk.ext->c_str (); if (root == nullptr) { // The same login as in target::root_scope(). // // Note: we are guaranteed the scope is never NULL for prerequisites // (where out/dir could be relative and none of this will work). // // @@ CTX TODO #if 0 root = scopes.find (tk.out->empty () ? *tk.dir : *tk.out).root_scope (); #endif if (root == nullptr || root->root_extra == nullptr) fail << "unable to determine extension for buildfile target " << tk; } return *tk.name == root->root_extra->buildfile_file.string () ? "" : root->root_extra->build_ext.c_str (); } static bool buildfile_target_pattern (const target_type&, const scope& base, string& v, optional& e, const location& l, bool r) { if (r) { assert (e); e = nullopt; } else { e = target::split_name (v, l); if (!e) { const scope* root (base.root_scope ()); if (root == nullptr || root->root_extra == nullptr) fail (l) << "unable to determine extension for buildfile pattern"; if (v != root->root_extra->buildfile_file.string ()) { e = root->root_extra->build_ext; return true; } } } return false; } const target_type buildfile::static_type { "buildfile", &file::static_type, &target_factory, &buildfile_target_extension, nullptr, /* default_extension */ &buildfile_target_pattern, nullptr, &file_search, target_type::flag::none }; static const char* buildscript_target_extension (const target_key& tk, const scope*) { // If the name is special 'buildscript', then there is no extension, // otherwise it is .buildscript. // return *tk.name == "buildscript" ? "" : "buildscript"; } static bool buildscript_target_pattern (const target_type&, const scope&, string& v, optional& e, const location& l, bool r) { if (r) { assert (e); e = nullopt; } else { e = target::split_name (v, l); if (!e && v != "buildscript") { e = "buildscript"; return true; } } return false; } const target_type buildscript::static_type { "buildscript", &file::static_type, &target_factory, &buildscript_target_extension, nullptr, /* default_extension */ &buildscript_target_pattern, nullptr, &file_search, target_type::flag::none }; const target_type doc::static_type { "doc", &file::static_type, &target_factory, &target_extension_none, // Same as file (no extension). nullptr, /* default_extension */ nullptr, /* pattern */ // Same as file. &target_print_1_ext_verb, // Same as file. &file_search, target_type::flag::none }; const target_type legal::static_type { "legal", &doc::static_type, &target_factory, &target_extension_none, // Same as file (no extension). nullptr, /* default_extension */ nullptr, /* pattern */ // Same as file. &target_print_1_ext_verb, // Same as file. &file_search, target_type::flag::none }; const target_type man::static_type { "man", &doc::static_type, &target_factory, &target_extension_must, // Should be specified explicitly. nullptr, /* default_extension */ nullptr, &target_print_1_ext_verb, // Print extension even at verbosity level 0. &file_search, target_type::flag::none }; extern const char man1_ext[] = "1"; // VC14 rejects constexpr. const target_type man1::static_type { "man1", &man::static_type, &target_factory, &target_extension_fix, nullptr, /* default_extension */ &target_pattern_fix, &target_print_0_ext_verb, // Fixed extension, no use printing. &file_search, target_type::flag::none }; static const char* manifest_target_extension (const target_key& tk, const scope*) { // If the name is special 'manifest', then there is no extension, // otherwise it is .manifest. // return *tk.name == "manifest" ? "" : "manifest"; } static bool manifest_target_pattern (const target_type&, const scope&, string& v, optional& e, const location& l, bool r) { if (r) { assert (e); e = nullopt; } else { e = target::split_name (v, l); if (!e && v != "manifest") { e = "manifest"; return true; } } return false; } const target_type manifest::static_type { "manifest", &doc::static_type, &target_factory, &manifest_target_extension, nullptr, /* default_extension */ &manifest_target_pattern, nullptr, &file_search, target_type::flag::none }; }