diff options
author | Boris Kolpackov <boris@codesynthesis.com> | 2015-07-21 15:51:54 +0200 |
---|---|---|
committer | Boris Kolpackov <boris@codesynthesis.com> | 2015-07-21 15:51:54 +0200 |
commit | 4be404cd8b7f4c7b450364defea92cd02e9b7a62 (patch) | |
tree | f8f0aac622dfd9d30d1900b958ecea9505265502 /build/algorithm.cxx | |
parent | 10604d850510e46b2ee625548abe5eb9a1172a0d (diff) |
Improve nested operations support
The idea is this: we need to be able to override "conditional, inner
for outer" recipes with the "unconditional inner" ones. Here is the
concrete scenario: we have {update, test} action and the lib{} target
that is both mentioned as a prerequisite of ./ and exe{}, which is a
test. At first, we want to ignore lib{} when reached as a prerequisite
of ./. But then we get to it via exe{} (which is a test and thus should
be updated). At this point we should override the recipe for lib{} with
the one that would update it rather than ignore.
Diffstat (limited to 'build/algorithm.cxx')
-rw-r--r-- | build/algorithm.cxx | 165 |
1 files changed, 89 insertions, 76 deletions
diff --git a/build/algorithm.cxx b/build/algorithm.cxx index 290bfa5..c9dcbfe 100644 --- a/build/algorithm.cxx +++ b/build/algorithm.cxx @@ -41,10 +41,10 @@ namespace build return create_new_target (pk); } - pair<const rule*, match_result> + match_result_impl match_impl (action a, target& t, bool apply) { - pair<const rule*, match_result> r (nullptr, nullptr); + match_result_impl r; // Clear the resolved targets list before calling match(). The rule // is free to, say, resize() this list in match() (provided that it @@ -52,75 +52,90 @@ namespace build // t.prerequisite_targets.clear (); - size_t oi (a.operation () - 1); // Operation index in rule_map. - scope& bs (t.base_scope ()); - - for (auto tt (&t.type ()); - tt != nullptr && !t.recipe (a); - tt = tt->base) + // If this is a nested operation, first try the outer operation. + // This allows a rule to implement a "precise match", that is, + // both inner and outer operations match. + // + for (operation_id oo (a.outer_operation ()), io (a.operation ()), + o (oo != 0 ? oo : io); o != 0; o = (oo != 0 ? io : 0)) { - // Search scopes outwards, stopping at the project root. + // Adjust action for recipe: on the first iteration we want it + // {inner, outer} (which is the same as 'a') while on the second + // -- {inner, 0}. Note that {inner, 0} is the same or "stronger" + // (i.e., overrides; see action::operator<()) than 'a'. This + // allows "unconditional inner" to override "inner for outer" + // recipes. // - for (const scope* s (&bs); - s != nullptr; - s = s->root () ? global_scope : s->parent_scope ()) - { - const rule_map& om (s->rules); + action ra (a.meta_operation (), io, o != oo ? 0 : oo); - if (om.size () <= oi) - continue; // No entry for this operation id. + size_t oi (o - 1); // Operation index in rule_map. + scope& bs (t.base_scope ()); - const target_type_rule_map& ttm (om[oi]); + for (auto tt (&t.type ()); + tt != nullptr && !t.recipe (ra); + tt = tt->base) + { + // Search scopes outwards, stopping at the project root. + // + for (const scope* s (&bs); + s != nullptr; + s = s->root () ? global_scope : s->parent_scope ()) + { + const rule_map& om (s->rules); - if (ttm.empty ()) - continue; // Empty map for this operation id. + if (om.size () <= oi) + continue; // No entry for this operation id. - auto i (ttm.find (tt->id)); + const target_type_rule_map& ttm (om[oi]); - if (i == ttm.end () || i->second.empty ()) - continue; // No rules registered for this target type. + if (ttm.empty ()) + continue; // Empty map for this operation id. - const auto& rules (i->second); // Hint map. + auto i (ttm.find (tt->id)); - // @@ TODO - // - // Different rules can be used for different operations (update - // vs test is a good example). So, at some point, we will probably - // have to support a list of hints or even an operation-hint map - // (e.g., 'hint=cxx test=foo' if cxx supports the test operation - // but we want the foo rule instead). This is also the place where - // the '{build clean}=cxx' construct (which we currently do not - // support) can come handy. - // - // Also, ignore the hint (that is most likely ment for a different - // operation) if this is a unique match. - // - string hint; - auto rs (rules.size () == 1 - ? make_pair (rules.begin (), rules.end ()) - : rules.find_prefix (hint)); + if (i == ttm.end () || i->second.empty ()) + continue; // No rules registered for this target type. - for (auto i (rs.first); i != rs.second; ++i) - { - const string& n (i->first); - const rule& ru (i->second); + const auto& rules (i->second); // Hint map. - match_result m; - { - auto g ( - make_exception_guard ( - [](action a, target& t, const string& n) - { - info << "while matching rule " << n << " to " - << diag_do (a, t); - }, - a, t, n)); - - m = ru.match (a, t, hint); - } + // @@ TODO + // + // Different rules can be used for different operations (update + // vs test is a good example). So, at some point, we will probably + // have to support a list of hints or even an operation-hint map + // (e.g., 'hint=cxx test=foo' if cxx supports the test operation + // but we want the foo rule instead). This is also the place where + // the '{build clean}=cxx' construct (which we currently do not + // support) can come handy. + // + // Also, ignore the hint (that is most likely ment for a different + // operation) if this is a unique match. + // + string hint; + auto rs (rules.size () == 1 + ? make_pair (rules.begin (), rules.end ()) + : rules.find_prefix (hint)); - if (m) + for (auto i (rs.first); i != rs.second; ++i) { + const string& n (i->first); + const rule& ru (i->second); + + match_result m; + { + auto g ( + make_exception_guard ( + [](action a, target& t, const string& n) + { + info << "while matching rule " << n << " to " + << diag_do (a, t); + }, + ra, t, n)); + + if (!(m = ru.match (ra, t, hint))) + continue; + } + // Do the ambiguity test. // bool ambig (false); @@ -132,7 +147,6 @@ namespace build const string& n1 (i->first); const rule& ru1 (i->second); - match_result m1; { auto g ( make_exception_guard ( @@ -141,22 +155,20 @@ namespace build info << "while matching rule " << n1 << " to " << diag_do (a, t); }, - a, t, n1)); + ra, t, n1)); - m1 = ru1.match (a, t, hint); + if (!ru1.match (ra, t, hint)) + continue; } - if (m1) + if (!ambig) { - if (!ambig) - { - dr << fail << "multiple rules matching " << diag_doing (a, t) - << info << "rule " << n << " matches"; - ambig = true; - } - - dr << info << "rule " << n1 << " also matches"; + dr << fail << "multiple rules matching " << diag_doing (ra, t) + << info << "rule " << n << " matches"; + ambig = true; } + + dr << info << "rule " << n1 << " also matches"; } if (!ambig) @@ -170,14 +182,15 @@ namespace build info << "while applying rule " << n << " to " << diag_do (a, t); }, - a, t, n)); + ra, t, n)); - t.recipe (a, ru.apply (a, t, m)); + t.recipe (ra, ru.apply (ra, t, m)); } else { - r.first = &ru; - r.second = m; + r.ra = ra; + r.ru = &ru; + r.mr = m; } return r; @@ -208,7 +221,7 @@ namespace build // if (!g.recipe (a)) { - auto p (match_impl (a, g, false)); + auto mir (match_impl (a, g, false)); r = g.group_members (a); if (r.members != nullptr) @@ -217,7 +230,7 @@ namespace build // That didn't help, so apply the rule and go to the building // phase. // - g.recipe (a, p.first->apply (a, g, p.second)); + g.recipe (mir.ra, mir.ru->apply (mir.ra, g, mir.mr)); } // Note that we use execute_direct() rather than execute() here to |