// file : libbuild2/dyndep.cxx -*- C++ -*- // license : MIT; see accompanying LICENSE file #include #include #include #include #include #include #include using namespace std; using namespace butl; namespace build2 { bool dyndep_rule:: update (tracer& trace, action a, const target& t, timestamp ts) { return update_during_match (trace, a, t, ts); } optional dyndep_rule:: inject_file (tracer& trace, const char* what, action a, target& t, const file& pt, timestamp mt, bool f, bool adhoc, uintptr_t data) { // Even if failing we still use try_match_sync() in order to issue // consistent (with other places) diagnostics (rather than the generic // "not rule to update ..."). // if (!try_match_sync (a, pt).first) { if (!f) return nullopt; diag_record dr; dr << fail << what << ' ' << pt << " not found and no rule to " << "generate it"; if (verb < 4) dr << info << "re-run with --verbose=4 for more information"; } bool r (update (trace, a, pt, mt)); // Add to our prerequisite target list. // t.prerequisite_targets[a].emplace_back (&pt, adhoc, data); return r; } optional dyndep_rule:: inject_existing_file (tracer& trace, const char* what, action a, target& t, const file& pt, timestamp mt, bool f, bool adhoc, uintptr_t data) { if (!try_match_sync (a, pt).first) { if (!f) return nullopt; diag_record dr; dr << fail << what << ' ' << pt << " not found and no rule to " << "generate it"; if (verb < 4) dr << info << "re-run with --verbose=4 for more information"; } recipe_function* const* rf (pt[a].recipe.target ()); if (rf == nullptr || *rf != &noop_action) { fail << what << ' ' << pt << " has non-noop recipe" << info << "consider listing it as static prerequisite of " << t; } bool r (update (trace, a, pt, mt)); // Add to our prerequisite target list. // t.prerequisite_targets[a].emplace_back (&pt, adhoc, data); return r; } void dyndep_rule:: verify_existing_file (tracer&, const char* what, action a, const target& t, const file& pt) { diag_record dr; if (pt.matched (a)) { recipe_function* const* rf (pt[a].recipe.target ()); if (rf == nullptr || *rf != &noop_action) { dr << fail << what << ' ' << pt << " has non-noop recipe"; } } else if (pt.decl == target_decl::real) { dr << fail << what << ' ' << pt << " is explicitly declared as " << "target and may have non-noop recipe"; } if (!dr.empty ()) dr << info << "consider listing it as static prerequisite of " << t; } // Reverse-lookup target type(s) from file name/extension. // // If the list of base target types is specified, then only these types and // those derived from them are considered. Otherwise, any file-based type is // considered but not the file type itself. // small_vector dyndep_rule:: map_extension (const scope& bs, const string& n, const string& e, const target_type* const* tts) { // We will just have to try all of the possible ones, in the "most // likely to match" order. // auto test = [&bs, &n, &e] (const target_type& tt) -> bool { if (tt.default_extension != nullptr) { // Call the extension derivation function. Here we know that it will // only use the target type and name from the target key so we can // pass bogus values for the rest. // target_key tk {&tt, nullptr, nullptr, &n, nullopt}; // This is like prerequisite search. // optional de (tt.default_extension (tk, bs, nullptr, true)); return de && *de == e; } return false; }; small_vector r; if (tts != nullptr) { // @@ What if these types are not known by this project? Maybe this // should just be unified with the below loop? Need to make sure // we don't rely on the order in which they are returned. // for (const target_type* const* p (tts); *p != nullptr; ++p) if (test (**p)) r.push_back (*p); } // Next try target types derived from any of the base types (or file if // there are no base types). // const target_type_map& ttm (bs.root_scope ()->root_extra->target_types); for (auto i (ttm.type_begin ()), e (ttm.type_end ()); i != e; ++i) { const target_type& dt (i->second); if (tts != nullptr) { for (const target_type* const* p (tts); *p != nullptr; ++p) { const target_type& bt (**p); if (dt.is_a (bt)) { if (dt != bt && test (dt)) r.push_back (&dt); break; } } } else { // Anything file-derived but not the file itself. // if (dt.is_a () && dt != file::static_type && test (dt)) r.push_back (&dt); } } return r; } void dyndep_rule:: append_prefix (tracer& trace, prefix_map& m, const target& t, dir_path d) { // If the target directory is a sub-directory of the include directory, // then the prefix is the difference between the two. Otherwise, leave it // empty. // // The idea here is to make this "canonical" setup work auto-magically // (using C/C++ #include's as an example): // // 1. We include all headers with a prefix, e.g., . // // 2. The library target is in the foo/ sub-directory, e.g., /tmp/foo/. // // 3. The poptions variable contains -I/tmp. // dir_path p (t.dir.sub (d) ? t.dir.leaf (d) : dir_path ()); // We use the target's directory as out_base but that doesn't work well // for targets that are stashed in subdirectories. So as a heuristics we // are going to also enter the outer directories of the original prefix. // It is, however, possible, that another directory after this one will // produce one of these outer prefixes as its original prefix in which // case we should override it. // // So we are going to assign the original prefix priority value 0 // (highest) and then increment it for each outer prefix. // auto enter = [&trace, &m] (dir_path p, dir_path d, size_t prio) { auto j (m.lower_bound (p)), e (m.end ()); if (j != e && j->first != p) j = e; if (j == m.end ()) { if (verb >= 4) trace << "new mapping for prefix '" << p << "'\n" << " new mapping to " << d << " priority " << prio; m.emplace (move (p), prefix_value {move (d), prio}); } else if (p.empty ()) { // For prefixless we keep all the entries since for them we have an // extra check (target must be explicitly spelled out in a buildfile). // if (verb >= 4) trace << "additional mapping for prefix '" << p << "'\n" << " new mapping to " << d << " priority " << prio; // Find the position where to insert according to the priority. // For equal priorities we use the insertion order. // do { if (j->second.priority > prio) break; } while (++j != e && j->first == p); m.emplace_hint (j, move (p), prefix_value {move (d), prio}); } else { prefix_value& v (j->second); // We used to reject duplicates but it seems this can be reasonably // expected to work according to the order of, say, -I options. // // Seeing that we normally have more "specific" -I paths first, (so // that we don't pick up installed headers, etc), we ignore it. // if (v.directory == d) { if (v.priority > prio) v.priority = prio; } else if (v.priority <= prio) { if (verb >= 4) trace << "ignoring mapping for prefix '" << p << "'\n" << " existing mapping to " << v.directory << " priority " << v.priority << '\n' << " another mapping to " << d << " priority " << prio; } else { if (verb >= 4) trace << "overriding mapping for prefix '" << p << "'\n" << " existing mapping to " << v.directory << " priority " << v.priority << '\n' << " new mapping to " << d << " priority " << prio; v.directory = move (d); v.priority = prio; } } }; // Enter all outer prefixes, including prefixless. // // The prefixless part is fuzzy but seems to be doing the right thing // ignoring/overriding-wise, at least in cases where one of the competing // include search paths is a subdirectory of another. // for (size_t prio (0);; ++prio) { bool e (p.empty ()); enter ((e ? move (p) : p), (e ? move (d) : d), prio); if (e) break; p = p.directory (); } } bool dyndep_rule::srcout_builder:: next (dir_path&& d) { // Ignore any paths containing '.', '..' components. Allow any directory // separators though (think -I$src_root/foo on Windows). // if (d.absolute () && d.normalized (false)) { // If we have a candidate out_base, see if this is its src_base. // if (prev_ != nullptr) { const dir_path& bp (prev_->src_path ()); if (d.sub (bp)) { if (diff_.empty () || d.leaf (bp) == diff_) { // We've got a pair. // map_.emplace (move (d), prev_->out_path () / diff_); prev_ = nullptr; // Taken. return true; } } // Not a pair. Fall through to consider as out_base. // prev_ = nullptr; } // See if this path is inside a project with an out of source build and is // in the out directory tree. // const scope& bs (ctx_.scopes.find_out (d)); if (bs.root_scope () != nullptr) { if (!bs.out_eq_src ()) { const dir_path& bp (bs.out_path ()); bool e; if ((e = (d == bp)) || d.sub (bp)) { prev_ = &bs; if (e) diff_.clear (); else diff_ = d.leaf (bp); } } } } else prev_ = nullptr; return false; } static pair enter_file_impl ( tracer& trace, const char* what, action a, const scope& bs, const target& t, path& fp, bool cache, bool norm, bool insert, const function& map_extension, const target_type& fallback, const function& get_pfx_map, const dyndep_rule::srcout_map& so_map) { // NOTE: see enter_header() caching logic if changing anyting here with // regards to the target and base scope usage. // Find or maybe insert the target. The directory is only moved from if // insert is true. Note that it must be normalized. // auto find = [&trace, what, &t, &map_extension, &fallback] (dir_path&& d, path&& f, bool insert) -> const file* { // Split the file into its name part and extension. Here we can assume // the name part is a valid filesystem name. // // Note that if the file has no extension, we record an empty extension // rather than NULL (which would signify that the default extension // should be added). // string e (f.extension ()); string n (move (f).string ()); if (!e.empty ()) n.resize (n.size () - e.size () - 1); // One for the dot. // See if this directory is part of any project and if so determine // the target type. // // While at it also determine if this target is from the src or out // tree of said project. // dir_path out; // It's possible the extension-to-target type mapping is ambiguous (for // example, because both C and X-language headers use the same .h // extension). In this case we will first try to find one that matches // an explicit target (similar logic to when insert is false). // small_vector tts; // Note that the path can be in out or src directory and the latter // can be associated with multiple scopes. So strictly speaking we // need to pick one that is "associated" with us. But that is still a // TODO (see scope_map::find() for details) and so for now we just // pick the first one (it's highly unlikely the source file extension // mapping will differ based on the configuration). // { const scope& bs (**t.ctx.scopes.find (d).first); if (const scope* rs = bs.root_scope ()) { if (map_extension != nullptr) tts = map_extension (bs, n, e); if (!bs.out_eq_src () && d.sub (bs.src_path ())) out = out_src (d, *rs); } } // If it is outside any project, or the project doesn't have such an // extension, use the fallback target type. // if (tts.empty ()) { // If the project doesn't "know" this extension then we can't possibly // find an explicit target of this type. // if (!insert) { l6 ([&]{trace << "unknown " << what << ' ' << n << " extension '" << e << "'";}); return nullptr; } tts.push_back (&fallback); } // Find or insert target. // // Note that in case of the target type ambiguity we first try to find // an explicit target that resolves this ambiguity. // const target* r (nullptr); if (!insert || tts.size () > 1) { // Note that we skip any target type-specific searches (like for an // existing file) and go straight for the target object since we need // to find the target explicitly spelled out. // // Also, it doesn't feel like we should be able to resolve an absolute // path with a spelled-out extension to multiple targets. // const target* f (nullptr); for (size_t i (0), m (tts.size ()); i != m; ++i) { const target_type& tt (*tts[i]); if (const target* x = t.ctx.targets.find (tt, d, out, n, e, trace)) { // What would be the harm in reusing a dynamically-inserted target // if there is no buildfile-mentioned one? Probably none (since it // can't be updated) except that it will be racy: sometimes we // will reuse the dynamic, sometimes we will insert a new one. And // we don't like racy. // // Note that we can't only check for real targets and must include // implied ones because pre-entered members of a target group // (e.g., cli.cxx) are implied. // if (x->decl == target_decl::real || x->decl == target_decl::implied) { r = x; break; } else { // Cache the dynamic target corresponding to tts[0] since that's // what we will be inserting (see below). // if (insert && i == 0) f = x; l6 ([&]{trace << "dynamic target with target type " << tt.name;}); } } else l6 ([&]{trace << "no target with target type " << tt.name;}); } // Note: we can't do this because of the in source builds where there // won't be explicit targets for non-generated files. // // This should be harmless, however, since in our world generated file // are spelled-out as explicit targets. And if not, we will still get // an error, just a bit less specific. // #if 0 if (r == nullptr && insert) { f = d / n; if (!e.empty ()) { f += '.'; f += e; } diag_record dr (fail); dr << "ambiguous mapping of " << what ' ' << f << " to target type"; for (const target_type* tt: tts) dr << info << "could be " << tt->name << "{}"; dr << info << "spell-out its target to resolve this ambiguity"; } #endif if (r == nullptr && f != nullptr) r = f; } // @@ OPT: move d, out, n // if (r == nullptr && insert) r = &search (t, *tts[0], d, out, n, &e, nullptr); return static_cast (r); }; // If it's not absolute then it either does not (yet) exist or is a // relative ""-include (see init_args() for details). Reduce the second // case to absolute. // // Note: we now always use absolute path to the translation unit so this // no longer applies. But let's keep it for posterity. // // Also note that we now assume (see cc::compile_rule::enter_header()) a // relative path signifies a generated header. // #if 0 if (f.relative () && rels.relative ()) { // If the relative source path has a directory component, make sure it // matches since ""-include will always start with that (none of the // compilers we support try to normalize this path). Failed that we may // end up searching for a generated header in a random (working) // directory. // const string& fs (f.string ()); const string& ss (rels.string ()); size_t p (path::traits::rfind_separator (ss)); if (p == string::npos || // No directory. (fs.size () > p + 1 && path::traits::compare (fs.c_str (), p, ss.c_str (), p) == 0)) { path t (work / f); // The rels path is relative to work. if (exists (t)) f = move (t); } } #endif const file* pt (nullptr); bool remapped (false); // If relative then it does not exist. // if (fp.relative ()) { // This is probably as often an error as an auto-generated file, so // trace at level 4. // l4 ([&]{trace << "non-existent " << what << " '" << fp << "'";}); if (get_pfx_map != nullptr) { fp.normalize (); // The relative path might still contain '..' (e.g., ../foo.hxx; // presumably ""-include'ed). We don't attempt to support auto- // generated files with such inclusion styles. // if (fp.normalized ()) { const dyndep_rule::prefix_map& pfx_map (get_pfx_map (a, bs, t)); // First try the whole file. Then just the directory. // // @@ Has to be a separate map since the prefix can be the same as // the file name. // // auto i (pfx_map->find (f)); // Find the most qualified prefix of which we are a sub-path. // if (!pfx_map.empty ()) { dir_path d (fp.directory ()); auto p (pfx_map.sup_range (d)); if (p.first != p.second) { // Note that we can only have multiple entries for the // prefixless mapping. // dir_path pd; // Reuse. for (auto i (p.first); i != p.second; ++i) { // Note: value in pfx_map is not necessarily canonical. // pd = i->second.directory; pd.canonicalize (); l4 ([&]{trace << "try prefix '" << d << "' mapped to " << pd;}); // If this is a prefixless mapping, then only use it if we can // resolve it to an existing target (i.e., it is explicitly // spelled out in a buildfile). @@ Hm, I wonder why, it's not // like we can generate any file without an explicit target. // Maybe for diagnostics (i.e., we will actually try to build // something there instead of just saying no mapping). // pt = find (pd / d, fp.leaf (), insert && !i->first.empty ()); if (pt != nullptr) { fp = pd / fp; l4 ([&]{trace << "mapped as auto-generated " << fp;}); break; } else l4 ([&]{trace << "no explicit target in " << pd;}); } } else l4 ([&]{trace << "no prefix map entry for '" << d << "'";}); } else l4 ([&]{trace << "prefix map is empty";}); } } } else { // Normalize the path unless it is already normalized. This is also // where we handle src-out remap which is not needed if cached. // if (!norm) normalize_external (fp, what); if (!cache) { if (!so_map.empty ()) { // Find the most qualified prefix of which we are a sub-path. // auto i (so_map.find_sup (fp)); if (i != so_map.end ()) { // Ok, there is an out tree for this file. Remap to a path from // the out tree and see if there is a target for it. Note that the // value in so_map is not necessarily canonical. // dir_path d (i->second); d /= fp.leaf (i->first).directory (); d.canonicalize (); pt = find (move (d), fp.leaf (), false); // d is not moved from. if (pt != nullptr) { path p (d / fp.leaf ()); l4 ([&]{trace << "remapping " << fp << " to " << p;}); fp = move (p); remapped = true; } } } } if (pt == nullptr) { l6 ([&]{trace << (insert ? "entering " : "finding ") << fp;}); pt = find (fp.directory (), fp.leaf (), insert); } } return make_pair (pt, remapped); } pair dyndep_rule:: enter_file (tracer& trace, const char* what, action a, const scope& bs, target& t, path& fp, bool cache, bool norm, const function& map_ext, const target_type& fallback, const function& pfx_map, const srcout_map& so_map) { return enter_file_impl (trace, what, a, bs, t, fp, cache, norm, true /* insert */, map_ext, fallback, pfx_map, so_map); } pair dyndep_rule:: find_file (tracer& trace, const char* what, action a, const scope& bs, const target& t, path& fp, bool cache, bool norm, const function& map_ext, const target_type& fallback, const function& pfx_map, const srcout_map& so_map) { return enter_file_impl (trace, what, a, bs, t, fp, cache, norm, false /* insert */, map_ext, fallback, pfx_map, so_map); } const file& dyndep_rule:: inject_group_member (action a, const scope& bs, mtime_target& g, path p, const target_type& tt) { path n (p.leaf ()); string e (n.extension ()); // Assume nobody else can insert these members (seems reasonable seeing // that their names are dynamically discovered). // auto l (search_new_locked ( bs.ctx, tt, p.directory (), dir_path (), // Always in out. move (n.make_base ()).string (), &e, &bs)); const file& t (l.first.as ()); // Note: non-const only if have lock. if (l.second) { l.first.group = &g; l.second.unlock (); t.path (move (p)); // Only do this once. } else // Must have been already done (e.g., on previous operation in a // batch). // assert (t.group == &g); // This shouldn't fail since we are the only ones that should be matching // this target. // target_lock tl (lock (a, t)); assert (tl); match_inc_dependents (a, g); match_recipe (tl, group_recipe); return t; } }