// file : mod/mod-build-task.cxx -*- C++ -*- // license : MIT; see accompanying LICENSE file #include #include #include #include #include #include #include #include #include // thread_local #include #include #include #include // nullfd #include #include #include #include #include #include #include #include #include #include #include // send_notification_email() #include #include using namespace std; using namespace butl; using namespace bbot; using namespace brep::cli; using namespace odb::core; static thread_local mt19937 rand_gen (random_device {} ()); // The challenge (nonce) is randomly generated for every build task if brep is // configured to authenticate bbot agents. // // Nonce generator must guarantee a probabilistically insignificant chance // of repeating a previously generated value. The common approach is to use // counters or random number generators (alone or in combination), that // produce values of the sufficient length. 64-bit non-repeating and // 512-bit random numbers are considered to be more than sufficient for // most practical purposes. // // We will produce the challenge as the sha256sum of the 512-bit random // number and the 64-bit current timestamp combination. The latter is // not really a non-repeating counter and can't be used alone. However // adding it is a good and cheap uniqueness improvement. // // Note that since generating a challenge is not exactly cheap/fast, we will // generate it in advance for every task request, out of the database // transaction, and will cache it if it turns out that it wasn't used (no // package configuration to (re-)build, etc). // static thread_local optional challenge; // Generate a random number in the specified range (max value is included). // static inline size_t rand (size_t min_val, size_t max_val) { // Note that size_t is not whitelisted as a type the // uniform_int_distribution class template can be instantiated with. // return min_val == max_val ? min_val : static_cast ( uniform_int_distribution ( static_cast (min_val), static_cast (max_val)) (rand_gen)); } brep::build_task:: build_task (const tenant_service_map& tsm) : tenant_service_map_ (tsm) { } // While currently the user-defined copy constructor is not required (we don't // need to deep copy nullptr's), it is a good idea to keep the placeholder // ready for less trivial cases. // brep::build_task:: build_task (const build_task& r, const tenant_service_map& tsm) : database_module (r), build_config_module (r), options_ (r.initialized_ ? r.options_ : nullptr), tenant_service_map_ (tsm) { } void brep::build_task:: init (scanner& s) { HANDLER_DIAG; options_ = make_shared ( s, unknown_mode::fail, unknown_mode::fail); if (options_->build_config_specified ()) { // Verify that build-alt-*-rebuild-{start,stop} are both either specified // or not. // auto bad_alt = [&fail] (const char* what) { fail << "build-alt-" << what << "-rebuild-start and build-alt-" << what << "-rebuild-stop configuration options must both be either " << "specified or not"; }; if (options_->build_alt_soft_rebuild_start_specified () != options_->build_alt_soft_rebuild_stop_specified ()) bad_alt ("soft"); if (options_->build_alt_hard_rebuild_start_specified () != options_->build_alt_hard_rebuild_stop_specified ()) bad_alt ("hard"); database_module::init (*options_, options_->build_db_retry ()); // Check that the database 'build' schema matches the current one. It's // enough to perform the check in just a single module implementation // (more details in the comment in package_search::init()). // const string ds ("build"); if (schema_catalog::current_version (*build_db_, ds) != build_db_->schema_version (ds)) fail << "database 'build' schema differs from the current one (module " << BREP_VERSION_ID << ")"; build_config_module::init (*options_); } if (options_->root ().empty ()) options_->root (dir_path ("/")); } // Skip tenants with the freshly queued packages from the consideration (see // tenant::queued_timestamp for the details on the service notifications race // prevention). // template static inline query package_query (bool custom_bot, brep::params::build_task& params, interactive_mode imode, uint64_t queued_expiration_ns) { using namespace brep; using query = query; query q (!query::build_tenant::archived); if (custom_bot) { // Note that we could potentially only query the packages which refer to // this custom bot key in one of their build configurations. For that we // would need to additionally join the current query tables with the bot // fingerprint-containing build_package_bot_keys and // build_package_config_bot_keys tables and use the SELECT DISTINCT // clause. The problem is that we also use the ORDER BY clause and in this // case PostgreSQL requires all the ORDER BY clause expressions to also be // present in the SELECT DISTINCT clause and fails with the 'for SELECT // DISTINCT, ORDER BY expressions must appear in select list' error if // that's not the case. Also note that in the ODB-generated code the // 'build_package.project::TEXT' expression in the SELECT DISTINCT clause // (see the CITEXT type mapping for details in libbrep/common.hxx) would // not match the 'build_package.name' expression in the ORDER BY clause // and so we will end up with the mentioned error. One (hackish) way to // fix that would be to add a dummy member of the string type for the // build_package.name column. This all sounds quite hairy at the moment // and it also feels that this can potentially pessimize querying the // packages built with the default bots only. Thus let's keep it simple // for now and filter packages by the bot fingerprint at the program // level. // q = q && (query::build_package::custom_bot.is_null () || query::build_package::custom_bot); } else q = q && (query::build_package::custom_bot.is_null () || !query::build_package::custom_bot); // Filter by repositories canonical names (if requested). // const strings& rp (params.repository ()); if (!rp.empty ()) q = q && query::build_repository::id.canonical_name.in_range (rp.begin (), rp.end ()); // If the interactive mode is false or true, then filter out the respective // packages. // switch (imode) { case interactive_mode::false_: { q = q && query::build_tenant::interactive.is_null (); break; } case interactive_mode::true_: { q = q && query::build_tenant::interactive.is_not_null (); break; } case interactive_mode::both: break; } return q && (query::build_tenant::queued_timestamp.is_null () || query::build_tenant::queued_timestamp < queued_expiration_ns); } bool brep::build_task:: handle (request& rq, response& rs) { HANDLER_DIAG; if (build_db_ == nullptr) throw invalid_request (501, "not implemented"); params::build_task params; try { // Note that we expect the task request manifest to be posted and so // consider parameters from the URL only. // name_value_scanner s (rq.parameters (0 /* limit */, true /* url_only */)); params = params::build_task (s, unknown_mode::fail, unknown_mode::fail); } catch (const cli::exception& e) { throw invalid_request (400, e.what ()); } task_request_manifest tqm; try { // We fully cache the request content to be able to retry the request // handling if odb::recoverable is thrown (see database-module.cxx for // details). // size_t limit (options_->build_task_request_max_size ()); manifest_parser p (rq.content (limit, limit), "task_request_manifest"); tqm = task_request_manifest (p); } catch (const manifest_parsing& e) { throw invalid_request (400, e.what ()); } // Obtain the agent's public key fingerprint if requested. If the // fingerprint is requested but is not present in the request, then respond // with 401 HTTP code (unauthorized). If a key with the specified // fingerprint is not present in the build bot agent keys directory, then // assume that this is a custom build bot. // // Note that if the agent authentication is not configured (the agent keys // directory is not specified), then the bot can never be custom and its // fingerprint is ignored, if present. // optional agent_fp; bool custom_bot (false); if (bot_agent_key_map_ != nullptr) { if (!tqm.fingerprint) throw invalid_request (401, "unauthorized"); agent_fp = move (tqm.fingerprint); custom_bot = (bot_agent_key_map_->find (*agent_fp) == bot_agent_key_map_->end ()); } // The resulting task manifest and the related build, package, and // configuration objects. Note that the latter 3 are only meaningful if the // the task manifest is present. // task_response_manifest task_response; shared_ptr task_build; shared_ptr task_package; const build_package_config* task_config; auto serialize_task_response_manifest = [&task_response, &rs] () { // @@ Probably it would be a good idea to also send some cache control // headers to avoid caching by HTTP proxies. That would require // extension of the web::response interface. // manifest_serializer s (rs.content (200, "text/manifest;charset=utf-8"), "task_response_manifest"); task_response.serialize (s); }; interactive_mode imode (tqm.effective_interactive_mode ()); // Restict the interactive mode (specified by the task request manifest) if // the interactive parameter is specified and is other than "both". If // values specified by the parameter and manifest are incompatible (false vs // true), then just bail out responding with the manifest with an empty // session. // if (params.interactive () != interactive_mode::both) { if (imode != interactive_mode::both) { if (params.interactive () != imode) { serialize_task_response_manifest (); return true; } } else imode = params.interactive (); // Can only change both to true or false. } // Map build target configurations to machines that are capable of building // them. The first matching machine is selected for each configuration. // struct config_machine { const build_target_config* config; machine_header_manifest* machine; }; using config_machines = map; config_machines conf_machines; for (const build_target_config& c: *target_conf_) { for (machine_header_manifest& m: tqm.machines) { if (m.effective_role () == machine_role::build) try { // The same story as in exclude() from build-target-config.cxx. // if (path_match (dash_components_to_path (m.name), dash_components_to_path (c.machine_pattern), dir_path () /* start */, path_match_flags::match_absent)) { conf_machines.emplace (build_target_config_id {c.target, c.name}, config_machine {&c, &m}); break; } } catch (const invalid_path&) {} } } // Collect the auxiliary configurations/machines available for the build. // struct auxiliary_config_machine { string config; const machine_header_manifest* machine; }; vector auxiliary_config_machines; for (const machine_header_manifest& m: tqm.machines) { if (m.effective_role () == machine_role::auxiliary) { // Derive the auxiliary configuration name by stripping the first // (architecture) component from the machine name. // size_t p (m.name.find ('-')); if (p == string::npos || p == 0 || p == m.name.size () - 1) throw invalid_request (400, (string ("no ") + (p == 0 ? "architecture" : "OS") + " component in machine name '" + m.name + "'")); auxiliary_config_machines.push_back ( auxiliary_config_machine {string (m.name, p + 1), &m}); } } // Acquire the database connection for the subsequent transactions. // // Note that we will release it prior to any potentially time-consuming // operations (such as HTTP requests) and re-acquire it again afterwards, // if required. // connection_ptr conn (build_db_->connection ()); // Perform some housekeeping first. // // Notify a tenant-associated third-party service about the unloaded CI // request, if present. // { const tenant_service_build_unloaded* tsu (nullptr); transaction tr (conn->begin ()); using query = query; // Pick the unloaded tenant with the earliest loaded timestamp, skipping // those which were already picked recently. // shared_ptr t ( build_db_->query_one ( (!query::archived && query::unloaded_timestamp.is_not_null () && (query::unloaded_timestamp + "<= EXTRACT (EPOCH FROM NOW()) * 1000000000 - " + query::unloaded_notify_interval)) + "ORDER BY" + query::unloaded_timestamp + "LIMIT 1")); if (t != nullptr && t->service) { auto i (tenant_service_map_.find (t->service->type)); if (i != tenant_service_map_.end ()) { tsu = dynamic_cast ( i->second.get ()); if (tsu != nullptr) { // If we ought to call the // tenant_service_build_unloaded::build_unloaded() callback, then // set the package tenant's loaded timestamp to the current time to // prevent the notifications race. // t->unloaded_timestamp = system_clock::now (); build_db_->update (t); } } } tr.commit (); if (tsu != nullptr) { // Release the database connection since the build_unloaded() // notification can potentially be time-consuming (e.g., it may perform // an HTTP request). // conn.reset (); if (auto f = tsu->build_unloaded (move (*t->service), log_writer_)) { conn = build_db_->connection (); update_tenant_service_state (conn, t->id, f); } } } // Go through package build configurations until we find one that has no // build target configuration present in the database, or is in the building // state but expired (collectively called unbuilt). If such a target // configuration is found then put it into the building state, set the // current timestamp and respond with the task for building this package // configuration. // // While trying to find a non-built package configuration we will also // collect the list of the built configurations which it's time to // rebuild. So if no unbuilt package configuration is found, we will pickup // one to rebuild. The rebuild preference is given in the following order: // the greater force state, the greater overall status, the lower timestamp. // if (!conf_machines.empty ()) { vector> rebuilds; // Create the task response manifest. Must be called inside the build db // transaction. // auto task = [this] (const build& b, const build_package& p, const build_package_config& pc, small_vector&& tests, vector&& ams, optional&& interactive, const config_machine& cm) -> task_response_manifest { uint64_t ts ( chrono::duration_cast ( b.timestamp.time_since_epoch ()).count ()); string session (b.tenant + '/' + b.package_name.string () + '/' + b.package_version.string () + '/' + b.target.string () + '/' + b.target_config_name + '/' + b.package_config_name + '/' + b.toolchain_name + '/' + b.toolchain_version.string () + '/' + to_string (ts)); string tenant (tenant_dir (options_->root (), b.tenant).string ()); string result_url (options_->host () + tenant + "?build-result"); assert (transaction::has_current ()); assert (p.internal ()); // The package is expected to be buildable. shared_ptr r (p.internal_repository.load ()); strings fps; if (r->certificate_fingerprint) fps.emplace_back (move (*r->certificate_fingerprint)); const package_name& pn (p.id.name); bool module_pkg (pn.string ().compare (0, 10, "libbuild2-") == 0); // Note that the auxiliary environment is crafted by the bbot agent // after the auxiliary machines are booted. // task_manifest task (pn, p.version, move (r->location), move (fps), p.requirements, move (tests), b.dependency_checksum, cm.machine->name, move (ams), cm.config->target, cm.config->environment, nullopt /* auxiliary_environment */, cm.config->args, pc.arguments, belongs (*cm.config, module_pkg ? "build2" : "host"), cm.config->warning_regexes, move (interactive), b.worker_checksum); // Collect the build artifacts upload URLs, skipping those which are // excluded with the upload-*-exclude configuration options. // vector upload_urls; for (const auto& ud: options_->upload_data ()) { const string& t (ud.first); auto exclude = [&t] (const multimap& mm, const string& v) { auto range (mm.equal_range (t)); for (auto i (range.first); i != range.second; ++i) { if (i->second == v) return true; } return false; }; if (!exclude (options_->upload_toolchain_exclude (), b.toolchain_name) && !exclude (options_->upload_repository_exclude (), r->canonical_name)) { upload_urls.emplace_back (options_->host () + tenant + "?upload=" + t, t); } } return task_response_manifest (move (session), b.agent_challenge, move (result_url), move (upload_urls), b.agent_checksum, move (task)); }; // Calculate the build/rebuild (building/built state) and the `queued` // notifications expiration time for package configurations. // timestamp now (system_clock::now ()); auto expiration = [&now] (size_t timeout) -> timestamp { return now - chrono::seconds (timeout); }; auto expiration_ns = [&expiration] (size_t timeout) -> uint64_t { return chrono::duration_cast ( expiration (timeout).time_since_epoch ()).count (); }; uint64_t normal_result_expiration_ns ( expiration_ns (options_->build_result_timeout ())); uint64_t forced_result_expiration_ns ( expiration_ns (options_->build_forced_rebuild_timeout ())); timestamp forced_rebuild_expiration ( expiration (options_->build_forced_rebuild_timeout ())); uint64_t queued_expiration_ns ( expiration_ns (options_->build_queued_timeout ())); // Calculate the soft/hard rebuild expiration time, based on the // respective build-{soft,hard}-rebuild-timeout and // build-alt-{soft,hard}-rebuild-{start,stop,timeout} configuration // options. // // If normal_timeout is zero, then return timestamp_unknown to indicate // 'never expire'. Note that this value is less than any build timestamp // value, including timestamp_nonexistent. // // NOTE: there is a similar code in monitor/monitor.cxx. // auto build_expiration = [&now] ( const optional>& alt_interval, optional alt_timeout, size_t normal_timeout) { if (normal_timeout == 0) return timestamp_unknown; timestamp r; chrono::seconds nt (normal_timeout); if (alt_interval) { const duration& start (alt_interval->first); const duration& stop (alt_interval->second); duration dt (daytime (now)); // Note that if the stop time is less than the start time then the // interval extends through the midnight. // bool use_alt_timeout (start <= stop ? dt >= start && dt < stop : dt >= start || dt < stop); // If we out of the alternative rebuild timeout interval, then fall // back to using the normal rebuild timeout. // if (use_alt_timeout) { // Calculate the alternative timeout, unless it is specified // explicitly. // duration t; if (!alt_timeout) { t = start <= stop ? (stop - start) : ((24h - start) + stop); // If the normal rebuild timeout is greater than 24 hours, then // increase the default alternative timeout by (normal - 24h) (see // build-alt-soft-rebuild-timeout configuration option for // details). // if (nt > 24h) t += nt - 24h; } else t = chrono::seconds (*alt_timeout); r = now - t; } } return r != timestamp_nonexistent ? r : (now - nt); }; timestamp soft_rebuild_expiration ( build_expiration ( (options_->build_alt_soft_rebuild_start_specified () ? make_pair (options_->build_alt_soft_rebuild_start (), options_->build_alt_soft_rebuild_stop ()) : optional> ()), (options_->build_alt_soft_rebuild_timeout_specified () ? options_->build_alt_soft_rebuild_timeout () : optional ()), options_->build_soft_rebuild_timeout ())); timestamp hard_rebuild_expiration ( build_expiration ( (options_->build_alt_hard_rebuild_start_specified () ? make_pair (options_->build_alt_hard_rebuild_start (), options_->build_alt_hard_rebuild_stop ()) : optional> ()), (options_->build_alt_hard_rebuild_timeout_specified () ? options_->build_alt_hard_rebuild_timeout () : optional ()), options_->build_hard_rebuild_timeout ())); // Convert butl::standard_version type to brep::version. // brep::version toolchain_version (tqm.toolchain_version.string ()); string& toolchain_name (tqm.toolchain_name); // Prepare the buildable package prepared query. // // Note that the number of packages can be large and so, in order not to // hold locks for too long, we will restrict the number of packages being // queried in a single transaction. To achieve this we will iterate through // packages using the OFFSET/LIMIT pair and sort the query result. // // Note that this approach can result in missing some packages or // iterating multiple times over some of them. However there is nothing // harmful in that: updates are infrequent and missed packages will be // picked up on the next request. // // Also note that we disregard the request tenant and operate on the whole // set of the packages and builds. In future we may add support for // building packages for a specific tenant. // using pkg_query = query; using prep_pkg_query = prepared_query; pkg_query pq (package_query (custom_bot, params, imode, queued_expiration_ns)); // Transform (in-place) the interactive login information into the actual // login command, if specified in the manifest and the transformation // regexes are specified in the configuration. // if (tqm.interactive_login && options_->build_interactive_login_specified ()) { optional lc; string l (tqm.agent + ' ' + *tqm.interactive_login); // Use the first matching regex for the transformation. // for (const pair& rf: options_->build_interactive_login ()) { pair r (regex_replace_match (l, rf.first, rf.second)); if (r.second) { lc = move (r.first); break; } } if (!lc) throw invalid_request (400, "unable to match login info '" + l + '\''); tqm.interactive_login = move (lc); } // In the random package ordering mode iterate over the packages list by // starting from the random offset and wrapping around when reaching the // end. // // Note, however, that since there can be some packages which are already // built for all configurations and are not archived yet, picking an // unbuilt package this way may not work as desired. Think of the // following case with 5 packages in 3 non-archived tenants: // // 0: A - unbuilt, tenant 1 // 1: B - built, tenant 2 // 2: C - built, tenant 2 // 3: D - built, tenant 2 // 4: E - unbuilt, tenant 3 // // If we just pick a random starting offset in the [0, 4] range, then we // will build A package with probability 0.2 and E with probability 0.8. // // To fix that we will only try to build a package from a tenant that the // random starting offset refers to. Failed that, we will randomly pick // new starting offset and retry. To make sure we don't retry indefinitely // when there are no more packages to build (and also for the sake of // optimization; see below), we will track positions of packages which we // (unsuccessfully) have already tried to build and skip them while // generating the random starting offsets and while iterating over // packages. // // Also note that since we iterate over packages in chunks, each queried // in a separate transaction, the number of packages may potentially // increase or decrease while iterating over them. Thus, to keep things // consistent, we may need to update our tried positions tracking state // accordingly (not to cycle, not to refer to an entry out of the list // boundaries, etc). Generally, regardless whether the number of packages // has changed or not, the offsets and position statuses may now refer to // some different packages. The only sensible thing we can do in such // cases (without trying to detect this situation and restart from // scratch) is to serve the request and issue some build task, if // possible. // bool random (options_->build_package_order () == build_order::random); size_t start_offset (0); // List of "tried to build" package statuses. True entries denote // positions of packages which we have tried to build. Initially all // entries are false. // vector tried_positions; // Number of false entries in the above vector. Used merely as an // optimization to bail out. // size_t untried_positions_count (0); // Return a random position of a package that we have not yet tried to // build, if present, and nullopt otherwise. // auto rand_position = [&tried_positions, &untried_positions_count] () -> optional { assert (untried_positions_count <= tried_positions.size ()); if (untried_positions_count == 0) return nullopt; size_t r; while (tried_positions[r = rand (0, tried_positions.size () - 1)]) ; return r; }; // Mark the package at specified position as tried to build. Assume that // it is not yet been tried to build. // auto position_tried = [&tried_positions, &untried_positions_count] (size_t i) { assert (i < tried_positions.size () && !tried_positions[i] && untried_positions_count != 0); tried_positions[i] = true; --untried_positions_count; }; // Resize the tried positions list and update the untried positions // counter accordingly if the package number has changed. // // For simplicity, assume that packages are added/removed to/from the end // of the list. Note that misguessing in such a rare cases are possible // but not harmful (see above for the reasoning). // auto resize_tried_positions = [&tried_positions, &untried_positions_count] (size_t n) { if (n > tried_positions.size ()) // Packages added? { untried_positions_count += n - tried_positions.size (); tried_positions.resize (n, false); } else if (n < tried_positions.size ()) // Packages removed? { for (size_t i (n); i != tried_positions.size (); ++i) { if (!tried_positions[i]) { assert (untried_positions_count != 0); --untried_positions_count; } } tried_positions.resize (n); } else { // Not supposed to be called if the number of packages didn't change. // assert (false); } }; if (random) { using query = query; query q (package_query (custom_bot, params, imode, queued_expiration_ns)); if (conn == nullptr) conn = build_db_->connection (); transaction t (conn->begin ()); // If there are any non-archived interactive build tenants, then the // chosen randomization approach doesn't really work since interactive // tenants must be preferred over non-interactive ones, which is // achieved by proper ordering of the package query result (see below). // Thus, we just disable randomization if there are any interactive // tenants. // // But shouldn't we randomize the order between packages in multiple // interactive tenants? Given that such a tenant may only contain a // single package and can only be built in a single configuration that // is probably not important. However, we may assume that the // randomization still happens naturally due to the random nature of the // tenant id, which is used as a primary sorting criteria (see below). // size_t interactive_package_count ( build_db_->query_value ( q && query::build_tenant::interactive.is_not_null ())); if (interactive_package_count == 0) { untried_positions_count = build_db_->query_value (q); } else random = false; t.commit (); if (untried_positions_count != 0) { tried_positions.resize (untried_positions_count, false); optional so (rand_position ()); assert (so); // Wouldn't be here otherwise. start_offset = *so; } } if (!random || !tried_positions.empty ()) { // Specify the portion. // size_t offset (start_offset); size_t limit (50); pq += "ORDER BY"; // If the interactive mode is both, then order the packages so that ones // from the interactive build tenants appear first. // if (imode == interactive_mode::both) pq += pkg_query::build_tenant::interactive + "NULLS LAST,"; pq += pkg_query::build_package::id.tenant + "," + pkg_query::build_package::id.name + order_by_version (pkg_query::build_package::id.version, false) + "OFFSET" + pkg_query::_ref (offset) + "LIMIT" + pkg_query::_ref (limit); if (conn == nullptr) conn = build_db_->connection (); prep_pkg_query pkg_prep_query ( conn->prepare_query ( "mod-build-task-package-query", pq)); // Prepare the build prepared query. // // Note that we can not query the database for configurations that a // package was not built with, as the database contains only those build // configurations that have already been acted upon (initially empty). // // This is why we query the database for configurations that should not // be built (in the built state, or in the building state and not // expired). Having such a list we will select the first build // configuration that is not in the list (if available) for the // response. // using bld_query = query; using prep_bld_query = prepared_query; package_id id; string pkg_config; bld_query sq (false); for (const auto& cm: conf_machines) sq = sq || (bld_query::id.target == cm.first.target && bld_query::id.target_config_name == cm.first.config); bld_query bq ( equal (bld_query::id.package, id) && bld_query::id.package_config_name == bld_query::_ref (pkg_config) && sq && bld_query::id.toolchain_name == toolchain_name && compare_version_eq (bld_query::id.toolchain_version, canonical_version (toolchain_version), true /* revision */) && (bld_query::state == "built" || (bld_query::state == "building" && ((bld_query::force == "forcing" && bld_query::timestamp > forced_result_expiration_ns) || (bld_query::force != "forcing" && // Unforced or forced. bld_query::timestamp > normal_result_expiration_ns))))); prep_bld_query bld_prep_query ( conn->prepare_query ("mod-build-task-build-query", bq)); // Return true if a package needs to be rebuilt. // auto needs_rebuild = [&forced_rebuild_expiration, &soft_rebuild_expiration, &hard_rebuild_expiration] (const build& b) { assert (b.state == build_state::built); return (b.force == force_state::forced && b.timestamp <= forced_rebuild_expiration) || b.soft_timestamp <= soft_rebuild_expiration || b.hard_timestamp <= hard_rebuild_expiration; }; // Convert a build to the hard rebuild, resetting the agent checksum. // // Note that since the checksums are hierarchical, the agent checksum // reset will trigger resets of the "subordinate" checksums up to the // dependency checksum and so the package will be rebuilt. // // Also note that we keep the previous build task result and status // intact since we may still need to revert the build into the built // state if the task execution is interrupted. // auto convert_to_hard = [] (const shared_ptr& b) { b->agent_checksum = nullopt; }; // Return SHA256 checksum of the controller logic and the configuration // target, environment, arguments, and warning-detecting regular // expressions. // auto controller_checksum = [] (const build_target_config& c) { sha256 cs ("1"); // Hash the logic version. cs.append (c.target.string ()); cs.append (c.environment ? *c.environment : ""); for (const string& a: c.args) cs.append (a); for (const string& re: c.warning_regexes) cs.append (re); return string (cs.string ()); }; // Return the machine id as a machine checksum. // // Note that we don't include auxiliary machine ids into this checksum // since a different machine will most likely get picked for a pattern. // And we view all auxiliary machines that match a pattern as equal for // testing purposes (in other words, pattern is not the way to get // coverage). // auto machine_checksum = [] (const machine_header_manifest& m) { return m.id; }; // Tenant that the start offset refers to. // optional start_tenant; // If the build task is created and the tenant of the being built // package has a third-party service state associated with it, then // check if the tenant_service_build_building and/or // tenant_service_build_queued callbacks are registered for the type of // the associated service. If they are, then stash the state, the build // object, and the callback pointers for the subsequent service // notifications. // // Also, if the tenant_service_build_queued callback is registered, then // create, persist, and stash the queued build objects for all the // unbuilt by the current toolchain and not yet queued configurations of // the package the build task is created for and calculate the hints. // Note that for the task build, we need to make sure that the // third-party service receives the `queued` notification prior to the // `building` notification (see mod/tenant-service.hxx for valid // transitions). The `queued` notification is assumed to be already sent // for the build if the respective object exists and any of the // following is true for it: // // - It is in the queued state (initial_state is build_state::queued). // // - It is a user-forced rebuild of an incomplete build // (rebuild_forced_build is true). // // - It is a rebuild of an interrupted rebuild (rebuild_forced_build is // true). // const tenant_service_build_building* tsb (nullptr); const tenant_service_build_queued* tsq (nullptr); optional>> tss; vector qbs; tenant_service_base::build_hints bhs; optional initial_state; bool rebuild_forced_build (false); bool rebuild_interrupted_rebuild (false); // Create, persist, and return the queued build objects for all the // unbuilt by the current toolchain and not yet queued configurations of // the specified package. // // Note that the build object argument is only used for the toolchain // information retrieval. Also note that the package constraints section // is expected to be loaded. // auto queue_builds = [this] (const build_package& p, const build& b) { assert (p.constraints_section.loaded ()); // Query the existing build ids and stash them into the set. // set existing_builds; using query = query; query q (query::build::id.package == p.id && query::build::id.toolchain_name == b.toolchain_name && compare_version_eq (query::build::id.toolchain_version, b.id.toolchain_version, true /* revision */)); for (build_id& id: build_db_->query (q)) existing_builds.emplace (move (id)); // Go through all the potential package builds and queue those which // are not in the existing builds set. // vector r; for (const build_package_config& pc: p.configs) { for (const build_target_config& tc: *target_conf_) { if (!exclude (pc, p.builds, p.constraints, tc)) { build_id id (p.id, tc.target, tc.name, pc.name, b.toolchain_name, b.toolchain_version); if (existing_builds.find (id) == existing_builds.end ()) { r.emplace_back (move (id.package.tenant), move (id.package.name), p.version, move (id.target), move (id.target_config_name), move (id.package_config_name), move (id.toolchain_name), b.toolchain_version); // @@ TODO Persist the whole vector of builds with a single // operation if/when bulk operations support is added // for objects with containers. // build_db_->persist (r.back ()); } } } } return r; }; auto build_hints = [this] (const build_package& p) { buildable_package_count tpc ( build_db_->query_value ( query::build_tenant::id == p.id.tenant)); return tenant_service_base::build_hints {tpc == 1, p.configs.size () == 1}; }; // Collect the auxiliary machines required for testing of the specified // package configuration and the external test packages, if present for // the specified target configuration (task_auxiliary_machines), // together with the auxiliary machines information that needs to be // persisted in the database as a part of the build object // (build_auxiliary_machines, which is parallel to // task_auxiliary_machines). While at it collect the involved test // dependencies. Return nullopt if any auxiliary configuration patterns // may not be resolved to the auxiliary machines (no matching // configuration, auxiliary machines RAM limit is exceeded, etc). // // Note that if the same auxiliary environment name is used for multiple // packages (for example, for the main and tests packages or for the // tests and examples packages, etc), then a shared auxiliary machine is // used for all these packages. In this case all the respective // configuration patterns must match the configuration derived from this // machine name. If they don't, then return nullopt. The thinking here // is that on the next task request a machine whose derived // configuration matches all the patterns can potentially be picked. // struct collect_auxiliaries_result { vector task_auxiliary_machines; vector build_auxiliary_machines; small_vector tests; }; auto collect_auxiliaries = [&tqm, &auxiliary_config_machines, this] (const shared_ptr& p, const build_package_config& pc, const build_target_config& tc) -> optional { // The list of the picked build auxiliary machines together with the // environment names they have been picked for. // vector> picked_machines; // Try to randomly pick the auxiliary machine that matches the // specified pattern and which can be supplied with the minimum // required RAM, if specified. Return false if such a machine is not // available. If a machine is already picked for the specified // environment name, then return true if the machine's configuration // matches the specified pattern and false otherwise. // auto pick_machine = [&tqm, &picked_machines, used_ram = uint64_t (0), available_machines = auxiliary_config_machines] (const build_auxiliary& ba) mutable -> bool { vector ams; // Indexes of the available matching machines. optional ar (tqm.auxiliary_ram); // If the machine configuration name pattern (which is legal) or any // of the machine configuration names (illegal) are invalid paths, // then we assume we cannot pick the machine. // try { // The same story as in exclude() from build-target-config.cxx. // auto match = [pattern = dash_components_to_path (ba.config)] (const string& config) { return path_match (dash_components_to_path (config), pattern, dir_path () /* start */, path_match_flags::match_absent); }; // Check if a machine is already picked for the specified // environment name. // for (const auto& m: picked_machines) { if (m.second == ba.environment_name) return match (m.first.config); } // Collect the matching machines from the list of the available // machines and bail out if there are none. // for (size_t i (0); i != available_machines.size (); ++i) { const auxiliary_config_machine& m (available_machines[i]); optional mr (m.machine->ram_minimum); if (match (m.config) && (!mr || !ar || used_ram + *mr <= *ar)) ams.push_back (i); } if (ams.empty ()) return false; } catch (const invalid_path&) { return false; } // Pick the matching machine randomly. // size_t i (ams[rand (0, ams.size () - 1)]); auxiliary_config_machine& cm (available_machines[i]); // Bump the used RAM. // if (optional r = cm.machine->ram_minimum) used_ram += *r; // Move out the picked machine from the available machines list. // picked_machines.emplace_back (move (cm), ba.environment_name); available_machines.erase (available_machines.begin () + i); return true; }; // Collect auxiliary machines for the main package build configuration. // for (const build_auxiliary& ba: pc.effective_auxiliaries (p->auxiliaries)) { if (!pick_machine (ba)) return nullopt; // No matched auxiliary machine. } // Collect the test packages and the auxiliary machines for their // default build configurations. Exclude external test packages which // exclude the current target configuration. // small_vector tests; if (!p->requirements_tests_section.loaded ()) build_db_->load (*p, p->requirements_tests_section); for (const build_test_dependency& td: p->tests) { // Don't exclude unresolved external tests. // // Note that this may result in the build task failure. However, // silently excluding such tests could end up with missed software // bugs which feels much worse. // if (td.package != nullptr) { shared_ptr tp (td.package.load ()); // Try to use the test package configuration named the same as the // current configuration of the main package. If there is no such // a configuration, then fallback to using the default // configuration (which must exist). If the selected test package // configuration excludes the current target configuration, then // exclude this external test package from the build task. // // Note that potentially the selected test package configuration // may contain some (bpkg) arguments associated, but we currently // don't provide build bot worker with such information. This, // however, is probably too far fetched so let's keep it simple // for now. // const build_package_config* tpc (find (pc.name, tp->configs)); if (tpc == nullptr) { tpc = find ("default", tp->configs); assert (tpc != nullptr); // Must always be present. } // Use the `all` class as a least restrictive default underlying // build class set. Note that we should only apply the explicit // build restrictions to the external test packages (think about // the `builds: all` and `builds: -windows` manifest values for // the primary and external test packages, respectively). // build_db_->load (*tp, tp->constraints_section); if (exclude (*tpc, tp->builds, tp->constraints, tc, nullptr /* reason */, true /* default_all_ucs */)) continue; build_db_->load (*tp, tp->auxiliaries_section); for (const build_auxiliary& ba: tpc->effective_auxiliaries (tp->auxiliaries)) { if (!pick_machine (ba)) return nullopt; // No matched auxiliary machine. } } tests.emplace_back (td.name, td.type, td.buildtime, td.constraint, td.enable, td.reflect); } vector tms; vector bms; if (size_t n = picked_machines.size ()) { tms.reserve (n); bms.reserve (n); for (pair& pm: picked_machines) { const machine_header_manifest& m (*pm.first.machine); tms.push_back (auxiliary_machine {m.name, move (pm.second)}); bms.push_back (build_machine {m.name, m.summary}); } } return collect_auxiliaries_result { move (tms), move (bms), move (tests)}; }; if (agent_fp && !challenge) try { auto print_args = [&trace, this] (const char* args[], size_t n) { l2 ([&]{trace << process_args {args, n};}); }; openssl os (print_args, nullfd, path ("-"), 2, process_env (options_->openssl (), options_->openssl_envvar ()), "rand", options_->openssl_option (), 64); vector nonce (os.in.read_binary ()); os.in.close (); if (!os.wait () || nonce.size () != 64) fail << "unable to generate nonce"; uint64_t t (chrono::duration_cast ( now.time_since_epoch ()).count ()); sha256 cs (nonce.data (), nonce.size ()); cs.append (&t, sizeof (t)); challenge = cs.string (); } catch (const system_error& e) { fail << "unable to generate nonce: " << e; } // While at it, collect the aborted for various reasons builds // (interactive builds in multiple configurations, builds with too many // auxiliary machines, etc) to send the notification emails at the end // of the request handling. // struct aborted_build { shared_ptr b; shared_ptr p; const build_package_config* pc; const char* what; }; vector aborted_builds; // Note: is only used for crafting of the notification email subjects. // bool unforced (true); for (bool done (false); !task_response.task && !done; ) { transaction tr (conn->begin ()); // We need to be careful in the random package ordering mode not to // miss the end after having wrapped around. // done = (start_offset != 0 && offset < start_offset && offset + limit >= start_offset); if (done) limit = start_offset - offset; // Query (and cache) buildable packages. // auto packages (pkg_prep_query.execute ()); size_t chunk_size (packages.size ()); size_t next_offset (offset + chunk_size); // If we are in the random package ordering mode, then also check if // the package number has changed and, if that's the case, resize the // tried positions list accordingly. // if (random && (next_offset > tried_positions.size () || (next_offset < tried_positions.size () && chunk_size < limit))) { resize_tried_positions (next_offset); } // Bail out if there is nothing left, unless we need to wrap around in // the random package ordering mode. // if (chunk_size == 0) { tr.commit (); if (start_offset != 0 && offset >= start_offset) offset = 0; else done = true; continue; } size_t position (offset); // Current package position. offset = next_offset; // Iterate over packages until we find one that needs building or have // to bail out in the random package ordering mode for some reason (no // more untried positions, need to restart, etc). // // Note that it is not uncommon for the sequentially examined packages // to belong to the same tenant (single tenant mode, etc). Thus, we // will cache the loaded tenant objects. // shared_ptr t; for (auto& bp: packages) { shared_ptr& p (bp.package); id = p->id; // Reset the tenant cache if the current package belongs to a // different tenant. // if (t != nullptr && t->id != id.tenant) t = nullptr; // If we are in the random package ordering mode, then cache the // tenant the start offset refers to, if not cached yet, and check // if we are still iterating over packages from this tenant // otherwise. If the latter is not the case, then restart from a new // random untried offset, if present, and bail out otherwise. // if (random) { if (!start_tenant) { start_tenant = id.tenant; } else if (*start_tenant != id.tenant) { if (optional so = rand_position ()) { start_offset = *so; offset = start_offset; start_tenant = nullopt; limit = 50; done = false; } else done = true; break; } size_t pos (position++); // Should have been resized, if required. // assert (pos < tried_positions.size ()); // Skip the position if it has already been tried. // if (tried_positions[pos]) continue; position_tried (pos); } // Note that a request to interactively build a package in multiple // configurations is most likely a mistake than a deliberate choice. // Thus, for the interactive tenant let's check if the package can // be built in multiple configurations. If that's the case then we // will put all the potential builds into the aborted state and // continue iterating looking for another package. Otherwise, just // proceed for this package normally. // // It also feels like a good idea to archive an interactive tenant // after a build object is created for it, regardless if the build // task is issued or not. This way we make sure that an interactive // build is never performed multiple times for such a tenant for any // reason (multiple toolchains, buildtab change, etc). Note that the // build result will still be accepted for an archived build. // if (bp.interactive) { // Note that the tenant can be archived via some other package on // some previous iteration. Skip the package if that's the case. // // Also note that if bp.archived is false, then we need to // (re-)load the tenant object to re-check the archived flag. // if (!bp.archived) { if (t == nullptr) t = build_db_->load (id.tenant); bp.archived = t->archived; } if (bp.archived) continue; assert (t != nullptr); // Wouldn't be here otherwise. // Collect the potential build configurations as all combinations // of the tenant's packages build configurations and the // non-excluded (by the packages) build target // configurations. Note that here we ignore the machines from the // task request. // struct build_config { shared_ptr p; const build_package_config* pc; const build_target_config* tc; }; small_vector build_configs; // Note that we don't bother creating a prepared query here, since // its highly unlikely to encounter multiple interactive tenants // per task request. Given that we archive such tenants // immediately, as a common case there will be none. // pkg_query pq (pkg_query::build_tenant::id == id.tenant); for (auto& tp: build_db_->query (pq)) { shared_ptr& p (tp.package); build_db_->load (*p, p->constraints_section); for (build_package_config& pc: p->configs) { for (const auto& tc: *target_conf_) { if (!exclude (pc, p->builds, p->constraints, tc)) build_configs.push_back (build_config {p, &pc, &tc}); } } } // If multiple build configurations are collected, then abort all // the potential builds and continue iterating over the packages. // if (build_configs.size () > 1) { // Abort the builds. // for (build_config& c: build_configs) { shared_ptr& p (c.p); const string& pc (c.pc->name); const build_target_config& tc (*c.tc); build_id bid (p->id, tc.target, tc.name, pc, toolchain_name, toolchain_version); // Can there be any existing builds for such a tenant? Doesn't // seem so, unless due to some manual intervention into the // database. Anyway, let's just leave such a build alone. // shared_ptr b (build_db_->find (bid)); if (b == nullptr) { b = make_shared (move (bid.package.tenant), move (bid.package.name), p->version, move (bid.target), move (bid.target_config_name), move (bid.package_config_name), move (bid.toolchain_name), toolchain_version, result_status::abort, operation_results ({ operation_result { "configure", result_status::abort, "error: multiple configurations " "for interactive build\n"}}), build_machine { "brep", "build task module"}); build_db_->persist (b); // Schedule the build notification email. // aborted_builds.push_back (aborted_build { move (b), move (p), c.pc, "build"}); } } // Archive the tenant. // t->archived = true; build_db_->update (t); continue; // Skip the package. } } // If true, then the package is (being) built for some // configurations. // // Note that since we only query the built and forced rebuild // objects there can be false negatives. // bool package_built (false); build_db_->load (*p, p->bot_keys_section); for (const build_package_config& pc: p->configs) { // If this is a custom bot, then skip this configuration if it // doesn't contain this bot's public key in its custom bot keys // list. Otherwise (this is a default bot), skip this // configuration if its custom bot keys list is not empty. // { const build_package_bot_keys& bks ( pc.effective_bot_keys (p->bot_keys)); if (custom_bot) { assert (agent_fp); // Wouldn't be here otherwise. if (find_if ( bks.begin (), bks.end (), [&agent_fp] (const lazy_shared_ptr& k) { return k.object_id ().fingerprint == *agent_fp; }) == bks.end ()) { continue; } } else { if (!bks.empty ()) continue; } } pkg_config = pc.name; // Iterate through the built configurations and erase them from the // build configuration map. All those configurations that remained // can be built. We will take the first one, if present. // // Also save the built configurations for which it's time to be // rebuilt. // config_machines configs (conf_machines); // Make copy for this pkg. auto pkg_builds (bld_prep_query.execute ()); if (!package_built && !pkg_builds.empty ()) package_built = true; for (auto i (pkg_builds.begin ()); i != pkg_builds.end (); ++i) { auto j ( configs.find (build_target_config_id { i->id.target, i->id.target_config_name})); // Outdated configurations are already excluded with the // database query. // assert (j != configs.end ()); configs.erase (j); if (i->state == build_state::built) { assert (i->force != force_state::forcing); if (needs_rebuild (*i)) rebuilds.emplace_back (i.load ()); } } if (!configs.empty ()) { // Find the first build configuration that is not excluded by // the package configuration and for which all the requested // auxiliary machines can be provided. // const config_machine* cm (nullptr); optional aux; if (!p->constraints_section.loaded ()) build_db_->load (*p, p->constraints_section); for (auto i (configs.begin ()), e (configs.end ()); i != e; ++i) { cm = &i->second; const build_target_config& tc (*cm->config); if (!exclude (pc, p->builds, p->constraints, tc)) { if (!p->auxiliaries_section.loaded ()) build_db_->load (*p, p->auxiliaries_section); if ((aux = collect_auxiliaries (p, pc, tc))) break; } } if (aux) { machine_header_manifest& mh (*cm->machine); build_id bid (move (id), cm->config->target, cm->config->name, move (pkg_config), move (toolchain_name), toolchain_version); shared_ptr b (build_db_->find (bid)); // Move the interactive build login information into the build // object, if the package to be built interactively. // optional login (bp.interactive ? move (tqm.interactive_login) : nullopt); // If build configuration doesn't exist then create the new // one and persist. Otherwise put it into the building state, // refresh the timestamp and update. // if (b == nullptr) { b = make_shared (move (bid.package.tenant), move (bid.package.name), p->version, move (bid.target), move (bid.target_config_name), move (bid.package_config_name), move (bid.toolchain_name), move (toolchain_version), move (login), move (agent_fp), move (challenge), build_machine { mh.name, move (mh.summary)}, move (aux->build_auxiliary_machines), controller_checksum (*cm->config), machine_checksum (*cm->machine)); challenge = nullopt; build_db_->persist (b); } else { // The build configuration is in the building or queued // state. // // Note that in both the building and built cases we keep // the status intact to be able to compare it with the final // one in the result request handling in order to decide if // to send the notification email or to revert it to the // built state if interrupted. The same is true for the // forced flag (in the sense that we don't set the force // state to unforced). // assert (b->state != build_state::built); initial_state = b->state; b->state = build_state::building; b->interactive = move (login); unforced = (b->force == force_state::unforced); // Switch the force state not to reissue the task after the // forced rebuild timeout. Note that the result handler will // still recognize that the rebuild was forced. // if (b->force == force_state::forcing) { b->force = force_state::forced; rebuild_forced_build = true; } b->agent_fingerprint = move (agent_fp); b->agent_challenge = move (challenge); challenge = nullopt; b->machine = build_machine {mh.name, move (mh.summary)}; // Mark the section as loaded, so auxiliary_machines are // updated. // b->auxiliary_machines_section.load (); b->auxiliary_machines = move (aux->build_auxiliary_machines); string ccs (controller_checksum (*cm->config)); string mcs (machine_checksum (*cm->machine)); // Issue the hard rebuild if it is forced or the // configuration or machine has changed. // if (b->hard_timestamp <= hard_rebuild_expiration || b->force == force_state::forced || b->controller_checksum != ccs || b->machine_checksum != mcs) convert_to_hard (b); b->controller_checksum = move (ccs); b->machine_checksum = move (mcs); b->timestamp = system_clock::now (); build_db_->update (b); } if (t == nullptr) t = build_db_->load (b->tenant); // Archive an interactive tenant. // if (bp.interactive) { t->archived = true; build_db_->update (t); } // Finally, stash the service notification information, if // present, and prepare the task response manifest. // if (t->service) { auto i (tenant_service_map_.find (t->service->type)); if (i != tenant_service_map_.end ()) { const tenant_service_base* s (i->second.get ()); tsb = dynamic_cast (s); tsq = dynamic_cast (s); if (tsq != nullptr) { qbs = queue_builds (*p, *b); // If we ought to call the // tenant_service_build_queued::build_queued() callback, // then also set the package tenant's queued timestamp // to the current time to prevent the notifications race // (see tenant::queued_timestamp for details). // if (!qbs.empty () || !initial_state || (*initial_state != build_state::queued && !rebuild_forced_build)) { bhs = build_hints (*p); t->queued_timestamp = system_clock::now (); build_db_->update (t); } } if (tsb != nullptr || tsq != nullptr) tss = make_pair (*t->service, b); } } task_response = task (*b, *p, pc, move (aux->tests), move (aux->task_auxiliary_machines), move (bp.interactive), *cm); task_build = move (b); task_package = move (p); task_config = &pc; package_built = true; break; // Bail out from the package configurations loop. } } } // If the task manifest is prepared, then bail out from the package // loop, commit the transaction and respond. Otherwise, stash the // build toolchain into the tenant, unless it is already stashed or // the current package already has some configurations (being) // built. // if (!task_response.task) { // Note that since there can be false negatives for the // package_built flag (see above), there can be redundant tenant // queries which, however, seems harmless (query uses the primary // key and the object memory footprint is small). // if (!package_built) { if (t == nullptr) t = build_db_->load (p->id.tenant); if (!t->toolchain) { t->toolchain = build_toolchain {toolchain_name, toolchain_version}; build_db_->update (t); } } } else break; } tr.commit (); } // If we don't have an unbuilt package, then let's see if we have a // build configuration to rebuild. // if (!task_response.task && !rebuilds.empty ()) { // Sort the configuration rebuild list with the following sort // priority: // // 1: force state // 2: overall status // 3: timestamp (less is preferred) // auto cmp = [] (const shared_ptr& x, const shared_ptr& y) { if (x->force != y->force) return x->force > y->force; // Forced goes first. assert (x->status && y->status); // Both built. if (x->status != y->status) return x->status > y->status; // Larger status goes first. // Older build completion goes first. // // Note that a completed build can have the state change timestamp // (timestamp member) newer than the completion timestamp // (soft_timestamp member) if the build was interrupted. // return x->soft_timestamp < y->soft_timestamp; }; sort (rebuilds.begin (), rebuilds.end (), cmp); // Pick the first build configuration from the ordered list. // // Note that the configurations and packages may not match the // required criteria anymore (as we have committed the database // transactions that were used to collect this data) so we recheck. If // we find one that matches then put it into the building state, // refresh the timestamp and update. Note that we don't amend the // status and the force state to have them available in the result // request handling (see above). // for (auto& b: rebuilds) { try { transaction t (conn->begin ()); b = build_db_->find (b->id); if (b != nullptr && b->state == build_state::built && needs_rebuild (*b)) { auto i (conf_machines.find ( build_target_config_id { b->target, b->target_config_name})); // Only actual package configurations are loaded (see above). // assert (i != conf_machines.end ()); const config_machine& cm (i->second); // Rebuild the package configuration if still present, is // buildable, doesn't exclude the target configuration, can be // provided with all the requested auxiliary machines, and // matches the request's interactive mode. // // Note that while change of the latter seems rather far fetched, // let's check it for good measure. // shared_ptr p ( build_db_->find (b->id.package)); shared_ptr t ( p != nullptr ? build_db_->load (p->id.tenant) : nullptr); build_package_config* pc (p != nullptr ? find (b->package_config_name, p->configs) : nullptr); if (pc != nullptr && p->buildable && (imode == interactive_mode::both || (t->interactive.has_value () == (imode == interactive_mode::true_)))) { const build_target_config& tc (*cm.config); build_db_->load (*p, p->constraints_section); if (exclude (*pc, p->builds, p->constraints, tc)) continue; build_db_->load (*p, p->auxiliaries_section); if (optional aux = collect_auxiliaries (p, *pc, tc)) { assert (b->status); initial_state = build_state::built; rebuild_interrupted_rebuild = (b->timestamp > b->soft_timestamp); b->state = build_state::building; // Save the interactive build login information into the // build object, if the package to be built interactively. // // Can't move from, as may need it on the next iteration. // b->interactive = t->interactive ? tqm.interactive_login : nullopt; unforced = (b->force == force_state::unforced); b->agent_fingerprint = move (agent_fp); b->agent_challenge = move (challenge); challenge = nullopt; const machine_header_manifest& mh (*cm.machine); b->machine = build_machine {mh.name, mh.summary}; // Mark the section as loaded, so auxiliary_machines are // updated. // b->auxiliary_machines_section.load (); b->auxiliary_machines = move (aux->build_auxiliary_machines); // Issue the hard rebuild if the timeout expired, rebuild is // forced, or the configuration or machine has changed. // // Note that we never reset the build status (see above for // the reasoning). // string ccs (controller_checksum (*cm.config)); string mcs (machine_checksum (*cm.machine)); if (b->hard_timestamp <= hard_rebuild_expiration || b->force == force_state::forced || b->controller_checksum != ccs || b->machine_checksum != mcs) convert_to_hard (b); b->controller_checksum = move (ccs); b->machine_checksum = move (mcs); b->timestamp = system_clock::now (); build_db_->update (b); // Stash the service notification information, if present, // and prepare the task response manifest. // if (t->service) { auto i (tenant_service_map_.find (t->service->type)); if (i != tenant_service_map_.end ()) { const tenant_service_base* s (i->second.get ()); tsb = dynamic_cast (s); tsq = dynamic_cast (s); bhs = build_hints (*p); if (tsq != nullptr) { qbs = queue_builds (*p, *b); // If we ought to call the // tenant_service_build_queued::build_queued() // callback, then also set the package tenant's queued // timestamp to the current time to prevent the // notifications race (see tenant::queued_timestamp // for details). // if (!qbs.empty () || !rebuild_interrupted_rebuild) { t->queued_timestamp = system_clock::now (); build_db_->update (t); } } if (tsb != nullptr || tsq != nullptr) tss = make_pair (move (*t->service), b); } } task_response = task (*b, *p, *pc, move (aux->tests), move (aux->task_auxiliary_machines), move (t->interactive), cm); task_build = move (b); task_package = move (p); task_config = pc; } } } t.commit (); } catch (const odb::deadlock&) { // Just try with the next rebuild. But first, restore the agent's // fingerprint and challenge and reset the task manifest and the // session that we may have prepared. // if (task_build != nullptr) b = move (task_build); assert (b != nullptr); // Wouldn't be here otherwise. agent_fp = move (b->agent_fingerprint); challenge = move (b->agent_challenge); task_response = task_response_manifest (); } // If the task manifest is prepared, then bail out from the package // configuration rebuilds loop and respond. // if (task_response.task) break; } } // If the tenant-associated third-party service needs to be notified // about the queued builds, then call the // tenant_service_build_queued::build_queued() callback function and // update the service state, if requested. // if (tsq != nullptr) { assert (tss); // Wouldn't be here otherwise. tenant_service& ss (tss->first); // If the task build has no initial state (is just created), then // temporarily move it into the list of the queued builds until the // `queued` notification is delivered. Afterwards, restore it so that // the `building` notification can also be sent. // build& b (*tss->second); bool restore_build (false); if (!initial_state) { qbs.push_back (move (b)); restore_build = true; } if (!qbs.empty ()) { // Release the database connection since the build_queued() // notification can potentially be time-consuming (e.g., it may // perform an HTTP request). // conn.reset (); if (auto f = tsq->build_queued (ss, qbs, nullopt /* initial_state */, bhs, log_writer_)) { conn = build_db_->connection (); if (optional data = update_tenant_service_state (conn, qbs.back ().tenant, f)) ss.data = move (data); } } // Send the `queued` notification for the task build, unless it is // already sent, and update the service state, if requested. // if (initial_state && *initial_state != build_state::queued && !rebuild_interrupted_rebuild && !rebuild_forced_build) { qbs.clear (); qbs.push_back (move (b)); restore_build = true; // Release the database connection since the build_queued() // notification can potentially be time-consuming (e.g., it may // perform an HTTP request). // conn.reset (); if (auto f = tsq->build_queued (ss, qbs, initial_state, bhs, log_writer_)) { conn = build_db_->connection (); if (optional data = update_tenant_service_state (conn, qbs.back ().tenant, f)) ss.data = move (data); } } if (restore_build) b = move (qbs.back ()); } // If a third-party service needs to be notified about the package // build, then call the tenant_service_build_built::build_building() // callback function and, if requested, update the tenant-associated // service state. // if (tsb != nullptr) { assert (tss); // Wouldn't be here otherwise. tenant_service& ss (tss->first); const build& b (*tss->second); // Release the database connection since the build_building() // notification can potentially be time-consuming (e.g., it may // perform an HTTP request). // conn.reset (); if (auto f = tsb->build_building (ss, b, log_writer_)) { conn = build_db_->connection (); if (optional data = update_tenant_service_state (conn, b.tenant, f)) ss.data = move (data); } } // If the task manifest is prepared, then check that the number of the // build auxiliary machines is less than 10. If that's not the case, // then turn the build into the built state with the abort status. // if (task_response.task && task_response.task->auxiliary_machines.size () > 9) { // Respond with the no-task manifest. // task_response = task_response_manifest (); // If the package tenant has a third-party service state associated // with it, then check if the tenant_service_build_built callback is // registered for the type of the associated service. If it is, then // stash the state, the build object, and the callback pointer for the // subsequent service `built` notification. // const tenant_service_build_built* tsb (nullptr); optional>> tss; { if (conn == nullptr) conn = build_db_->connection (); transaction t (conn->begin ()); shared_ptr b (build_db_->find (task_build->id)); // For good measure, check that the build object is in the building // state and has not been updated. // if (b->state == build_state::building && b->timestamp == task_build->timestamp) { b->state = build_state::built; b->status = result_status::abort; b->force = force_state::unforced; // Cleanup the interactive build login information. // b->interactive = nullopt; // Cleanup the authentication data. // b->agent_fingerprint = nullopt; b->agent_challenge = nullopt; b->timestamp = system_clock::now (); b->soft_timestamp = b->timestamp; b->hard_timestamp = b->soft_timestamp; // Mark the section as loaded, so results are updated. // b->results_section.load (); b->results = operation_results ({ operation_result { "configure", result_status::abort, "error: not more than 9 auxiliary machines are allowed"}}); b->agent_checksum = nullopt; b->worker_checksum = nullopt; b->dependency_checksum = nullopt; build_db_->update (b); // Schedule the `built` notification, if the // tenant_service_build_built callback is registered for the // tenant. // shared_ptr t ( build_db_->load (b->tenant)); if (t->service) { auto i (tenant_service_map_.find (t->service->type)); if (i != tenant_service_map_.end ()) { tsb = dynamic_cast ( i->second.get ()); // If required, stash the service notification information. // if (tsb != nullptr) tss = make_pair (move (*t->service), b); } } // Schedule the build notification email. // aborted_builds.push_back ( aborted_build {move (b), move (task_package), task_config, unforced ? "build" : "rebuild"}); } t.commit (); } // If a third-party service needs to be notified about the built // package, then call the tenant_service_build_built::build_built() // callback function and update the service state, if requested. // if (tsb != nullptr) { assert (tss); // Wouldn't be here otherwise. tenant_service& ss (tss->first); const build& b (*tss->second); // Release the database connection since the build_built() // notification can potentially be time-consuming (e.g., it may // perform an HTTP request). // conn.reset (); if (auto f = tsb->build_built (ss, b, log_writer_)) { conn = build_db_->connection (); if (optional data = update_tenant_service_state (conn, b.tenant, f)) ss.data = move (data); } } } // Send notification emails for all the aborted builds. // for (const aborted_build& ab: aborted_builds) { if (conn == nullptr) conn = build_db_->connection (); send_notification_email (*options_, conn, *ab.b, *ab.p, *ab.pc, ab.what, error, verb_ >= 2 ? &trace : nullptr); } } } // Release the database connection as soon as possible. // conn.reset (); serialize_task_response_manifest (); return true; }