""" BitBake 'RunQueue' implementation Handles preparation and execution of a queue of tasks """ # Copyright (C) 2006-2007 Richard Purdie # # SPDX-License-Identifier: GPL-2.0-only # import copy import os import sys import signal import stat import fcntl import errno import logging import re import bb from bb import msg, data, event from bb import monitordisk import subprocess import pickle from multiprocessing import Process import shlex bblogger = logging.getLogger("BitBake") logger = logging.getLogger("BitBake.RunQueue") __find_sha256__ = re.compile( r'(?i)(?= int(self.skip_maxthread[taskname]): return None stamp = self.stamps[tid] if stamp not in self.rq.build_stamps.values(): return tid if not self.rev_prio_map: self.rev_prio_map = {} for tid in self.rqdata.runtaskentries: self.rev_prio_map[tid] = self.prio_map.index(tid) best = None bestprio = None for tid in buildable: taskname = taskname_from_tid(tid) if taskname in skip_buildable and skip_buildable[taskname] >= int(self.skip_maxthread[taskname]): continue prio = self.rev_prio_map[tid] if bestprio is None or bestprio > prio: stamp = self.stamps[tid] if stamp in self.rq.build_stamps.values(): continue bestprio = prio best = tid return best def next(self): """ Return the id of the task we should build next """ if self.rq.can_start_task(): return self.next_buildable_task() def newbuildable(self, task): self.buildable.append(task) def describe_task(self, taskid): result = 'ID %s' % taskid if self.rev_prio_map: result = result + (' pri %d' % self.rev_prio_map[taskid]) return result def dump_prio(self, comment): bb.debug(3, '%s (most important first):\n%s' % (comment, '\n'.join(['%d. %s' % (index + 1, self.describe_task(taskid)) for index, taskid in enumerate(self.prio_map)]))) class RunQueueSchedulerSpeed(RunQueueScheduler): """ A scheduler optimised for speed. The priority map is sorted by task weight, heavier weighted tasks (tasks needed by the most other tasks) are run first. """ name = "speed" def __init__(self, runqueue, rqdata): """ The priority map is sorted by task weight. """ RunQueueScheduler.__init__(self, runqueue, rqdata) weights = {} for tid in self.rqdata.runtaskentries: weight = self.rqdata.runtaskentries[tid].weight if not weight in weights: weights[weight] = [] weights[weight].append(tid) self.prio_map = [] for weight in sorted(weights): for w in weights[weight]: self.prio_map.append(w) self.prio_map.reverse() class RunQueueSchedulerCompletion(RunQueueSchedulerSpeed): """ A scheduler optimised to complete .bb files as quickly as possible. The priority map is sorted by task weight, but then reordered so once a given .bb file starts to build, it's completed as quickly as possible by running all tasks related to the same .bb file one after the after. This works well where disk space is at a premium and classes like OE's rm_work are in force. """ name = "completion" def __init__(self, runqueue, rqdata): super(RunQueueSchedulerCompletion, self).__init__(runqueue, rqdata) # Extract list of tasks for each recipe, with tasks sorted # ascending from "must run first" (typically do_fetch) to # "runs last" (do_build). The speed scheduler prioritizes # tasks that must run first before the ones that run later; # this is what we depend on here. task_lists = {} for taskid in self.prio_map: fn, taskname = taskid.rsplit(':', 1) task_lists.setdefault(fn, []).append(taskname) # Now unify the different task lists. The strategy is that # common tasks get skipped and new ones get inserted after the # preceeding common one(s) as they are found. Because task # lists should differ only by their number of tasks, but not # the ordering of the common tasks, this should result in a # deterministic result that is a superset of the individual # task ordering. all_tasks = [] for recipe, new_tasks in task_lists.items(): index = 0 old_task = all_tasks[index] if index < len(all_tasks) else None for new_task in new_tasks: if old_task == new_task: # Common task, skip it. This is the fast-path which # avoids a full search. index += 1 old_task = all_tasks[index] if index < len(all_tasks) else None else: try: index = all_tasks.index(new_task) # Already present, just not at the current # place. We re-synchronized by changing the # index so that it matches again. Now # move on to the next existing task. index += 1 old_task = all_tasks[index] if index < len(all_tasks) else None except ValueError: # Not present. Insert before old_task, which # remains the same (but gets shifted back). all_tasks.insert(index, new_task) index += 1 bb.debug(3, 'merged task list: %s' % all_tasks) # Now reverse the order so that tasks that finish the work on one # recipe are considered more imporant (= come first). The ordering # is now so that do_build is most important. all_tasks.reverse() # Group tasks of the same kind before tasks of less important # kinds at the head of the queue (because earlier = lower # priority number = runs earlier), while preserving the # ordering by recipe. If recipe foo is more important than # bar, then the goal is to work on foo's do_populate_sysroot # before bar's do_populate_sysroot and on the more important # tasks of foo before any of the less important tasks in any # other recipe (if those other recipes are more important than # foo). # # All of this only applies when tasks are runable. Explicit # dependencies still override this ordering by priority. # # Here's an example why this priority re-ordering helps with # minimizing disk usage. Consider a recipe foo with a higher # priority than bar where foo DEPENDS on bar. Then the # implicit rule (from base.bbclass) is that foo's do_configure # depends on bar's do_populate_sysroot. This ensures that # bar's do_populate_sysroot gets done first. Normally the # tasks from foo would continue to run once that is done, and # bar only gets completed and cleaned up later. By ordering # bar's task that depend on bar's do_populate_sysroot before foo's # do_configure, that problem gets avoided. task_index = 0 self.dump_prio('original priorities') for task in all_tasks: for index in range(task_index, self.numTasks): taskid = self.prio_map[index] taskname = taskid.rsplit(':', 1)[1] if taskname == task: del self.prio_map[index] self.prio_map.insert(task_index, taskid) task_index += 1 self.dump_prio('completion priorities') class RunTaskEntry(object): def __init__(self): self.depends = set() self.revdeps = set() self.hash = None self.unihash = None self.task = None self.weight = 1 class RunQueueData: """ BitBake Run Queue implementation """ def __init__(self, rq, cooker, cfgData, dataCaches, taskData, targets): self.cooker = cooker self.dataCaches = dataCaches self.taskData = taskData self.targets = targets self.rq = rq self.warn_multi_bb = False self.stampwhitelist = cfgData.getVar("BB_STAMP_WHITELIST") or "" self.multi_provider_whitelist = (cfgData.getVar("MULTI_PROVIDER_WHITELIST") or "").split() self.setscenewhitelist = get_setscene_enforce_whitelist(cfgData) self.setscenewhitelist_checked = False self.setscene_enforce = (cfgData.getVar('BB_SETSCENE_ENFORCE') == "1") self.init_progress_reporter = bb.progress.DummyMultiStageProcessProgressReporter() self.reset() def reset(self): self.runtaskentries = {} def runq_depends_names(self, ids): import re ret = [] for id in ids: nam = os.path.basename(id) nam = re.sub("_[^,]*,", ",", nam) ret.extend([nam]) return ret def get_task_hash(self, tid): return self.runtaskentries[tid].hash def get_task_unihash(self, tid): return self.runtaskentries[tid].unihash def get_user_idstring(self, tid, task_name_suffix = ""): return tid + task_name_suffix def get_short_user_idstring(self, task, task_name_suffix = ""): (mc, fn, taskname, taskfn) = split_tid_mcfn(task) pn = self.dataCaches[mc].pkg_fn[taskfn] taskname = taskname_from_tid(task) + task_name_suffix return "%s:%s" % (pn, taskname) def circular_depchains_handler(self, tasks): """ Some tasks aren't buildable, likely due to circular dependency issues. Identify the circular dependencies and print them in a user readable format. """ from copy import deepcopy valid_chains = [] explored_deps = {} msgs = [] class TooManyLoops(Exception): pass def chain_reorder(chain): """ Reorder a dependency chain so the lowest task id is first """ lowest = 0 new_chain = [] for entry in range(len(chain)): if chain[entry] < chain[lowest]: lowest = entry new_chain.extend(chain[lowest:]) new_chain.extend(chain[:lowest]) return new_chain def chain_compare_equal(chain1, chain2): """ Compare two dependency chains and see if they're the same """ if len(chain1) != len(chain2): return False for index in range(len(chain1)): if chain1[index] != chain2[index]: return False return True def chain_array_contains(chain, chain_array): """ Return True if chain_array contains chain """ for ch in chain_array: if chain_compare_equal(ch, chain): return True return False def find_chains(tid, prev_chain): prev_chain.append(tid) total_deps = [] total_deps.extend(self.runtaskentries[tid].revdeps) for revdep in self.runtaskentries[tid].revdeps: if revdep in prev_chain: idx = prev_chain.index(revdep) # To prevent duplicates, reorder the chain to start with the lowest taskid # and search through an array of those we've already printed chain = prev_chain[idx:] new_chain = chain_reorder(chain) if not chain_array_contains(new_chain, valid_chains): valid_chains.append(new_chain) msgs.append("Dependency loop #%d found:\n" % len(valid_chains)) for dep in new_chain: msgs.append(" Task %s (dependent Tasks %s)\n" % (dep, self.runq_depends_names(self.runtaskentries[dep].depends))) msgs.append("\n") if len(valid_chains) > 10: msgs.append("Aborted dependency loops search after 10 matches.\n") raise TooManyLoops continue scan = False if revdep not in explored_deps: scan = True elif revdep in explored_deps[revdep]: scan = True else: for dep in prev_chain: if dep in explored_deps[revdep]: scan = True if scan: find_chains(revdep, copy.deepcopy(prev_chain)) for dep in explored_deps[revdep]: if dep not in total_deps: total_deps.append(dep) explored_deps[tid] = total_deps try: for task in tasks: find_chains(task, []) except TooManyLoops: pass return msgs def calculate_task_weights(self, endpoints): """ Calculate a number representing the "weight" of each task. Heavier weighted tasks have more dependencies and hence should be executed sooner for maximum speed. This function also sanity checks the task list finding tasks that are not possible to execute due to circular dependencies. """ numTasks = len(self.runtaskentries) weight = {} deps_left = {} task_done = {} for tid in self.runtaskentries: task_done[tid] = False weight[tid] = 1 deps_left[tid] = len(self.runtaskentries[tid].revdeps) for tid in endpoints: weight[tid] = 10 task_done[tid] = True while True: next_points = [] for tid in endpoints: for revdep in self.runtaskentries[tid].depends: weight[revdep] = weight[revdep] + weight[tid] deps_left[revdep] = deps_left[revdep] - 1 if deps_left[revdep] == 0: next_points.append(revdep) task_done[revdep] = True endpoints = next_points if len(next_points) == 0: break # Circular dependency sanity check problem_tasks = [] for tid in self.runtaskentries: if task_done[tid] is False or deps_left[tid] != 0: problem_tasks.append(tid) logger.debug(2, "Task %s is not buildable", tid) logger.debug(2, "(Complete marker was %s and the remaining dependency count was %s)\n", task_done[tid], deps_left[tid]) self.runtaskentries[tid].weight = weight[tid] if problem_tasks: message = "%s unbuildable tasks were found.\n" % len(problem_tasks) message = message + "These are usually caused by circular dependencies and any circular dependency chains found will be printed below. Increase the debug level to see a list of unbuildable tasks.\n\n" message = message + "Identifying dependency loops (this may take a short while)...\n" logger.error(message) msgs = self.circular_depchains_handler(problem_tasks) message = "\n" for msg in msgs: message = message + msg bb.msg.fatal("RunQueue", message) return weight def prepare(self): """ Turn a set of taskData into a RunQueue and compute data needed to optimise the execution order. """ runq_build = {} recursivetasks = {} recursiveitasks = {} recursivetasksselfref = set() taskData = self.taskData found = False for mc in self.taskData: if len(taskData[mc].taskentries) > 0: found = True break if not found: # Nothing to do return 0 self.init_progress_reporter.start() self.init_progress_reporter.next_stage() # Step A - Work out a list of tasks to run # # Taskdata gives us a list of possible providers for every build and run # target ordered by priority. It also gives information on each of those # providers. # # To create the actual list of tasks to execute we fix the list of # providers and then resolve the dependencies into task IDs. This # process is repeated for each type of dependency (tdepends, deptask, # rdeptast, recrdeptask, idepends). def add_build_dependencies(depids, tasknames, depends, mc): for depname in depids: # Won't be in build_targets if ASSUME_PROVIDED if depname not in taskData[mc].build_targets or not taskData[mc].build_targets[depname]: continue depdata = taskData[mc].build_targets[depname][0] if depdata is None: continue for taskname in tasknames: t = depdata + ":" + taskname if t in taskData[mc].taskentries: depends.add(t) def add_runtime_dependencies(depids, tasknames, depends, mc): for depname in depids: if depname not in taskData[mc].run_targets or not taskData[mc].run_targets[depname]: continue depdata = taskData[mc].run_targets[depname][0] if depdata is None: continue for taskname in tasknames: t = depdata + ":" + taskname if t in taskData[mc].taskentries: depends.add(t) def add_mc_dependencies(mc, tid): mcdeps = taskData[mc].get_mcdepends() for dep in mcdeps: mcdependency = dep.split(':') pn = mcdependency[3] frommc = mcdependency[1] mcdep = mcdependency[2] deptask = mcdependency[4] if mc == frommc: fn = taskData[mcdep].build_targets[pn][0] newdep = '%s:%s' % (fn,deptask) taskData[mc].taskentries[tid].tdepends.append(newdep) for mc in taskData: for tid in taskData[mc].taskentries: (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) #runtid = build_tid(mc, fn, taskname) #logger.debug(2, "Processing %s,%s:%s", mc, fn, taskname) depends = set() task_deps = self.dataCaches[mc].task_deps[taskfn] self.runtaskentries[tid] = RunTaskEntry() if fn in taskData[mc].failed_fns: continue # We add multiconfig dependencies before processing internal task deps (tdepends) if 'mcdepends' in task_deps and taskname in task_deps['mcdepends']: add_mc_dependencies(mc, tid) # Resolve task internal dependencies # # e.g. addtask before X after Y for t in taskData[mc].taskentries[tid].tdepends: (depmc, depfn, deptaskname, _) = split_tid_mcfn(t) depends.add(build_tid(depmc, depfn, deptaskname)) # Resolve 'deptask' dependencies # # e.g. do_sometask[deptask] = "do_someothertask" # (makes sure sometask runs after someothertask of all DEPENDS) if 'deptask' in task_deps and taskname in task_deps['deptask']: tasknames = task_deps['deptask'][taskname].split() add_build_dependencies(taskData[mc].depids[taskfn], tasknames, depends, mc) # Resolve 'rdeptask' dependencies # # e.g. do_sometask[rdeptask] = "do_someothertask" # (makes sure sometask runs after someothertask of all RDEPENDS) if 'rdeptask' in task_deps and taskname in task_deps['rdeptask']: tasknames = task_deps['rdeptask'][taskname].split() add_runtime_dependencies(taskData[mc].rdepids[taskfn], tasknames, depends, mc) # Resolve inter-task dependencies # # e.g. do_sometask[depends] = "targetname:do_someothertask" # (makes sure sometask runs after targetname's someothertask) idepends = taskData[mc].taskentries[tid].idepends for (depname, idependtask) in idepends: if depname in taskData[mc].build_targets and taskData[mc].build_targets[depname] and not depname in taskData[mc].failed_deps: # Won't be in build_targets if ASSUME_PROVIDED depdata = taskData[mc].build_targets[depname][0] if depdata is not None: t = depdata + ":" + idependtask depends.add(t) if t not in taskData[mc].taskentries: bb.msg.fatal("RunQueue", "Task %s in %s depends upon non-existent task %s in %s" % (taskname, fn, idependtask, depdata)) irdepends = taskData[mc].taskentries[tid].irdepends for (depname, idependtask) in irdepends: if depname in taskData[mc].run_targets: # Won't be in run_targets if ASSUME_PROVIDED if not taskData[mc].run_targets[depname]: continue depdata = taskData[mc].run_targets[depname][0] if depdata is not None: t = depdata + ":" + idependtask depends.add(t) if t not in taskData[mc].taskentries: bb.msg.fatal("RunQueue", "Task %s in %s rdepends upon non-existent task %s in %s" % (taskname, fn, idependtask, depdata)) # Resolve recursive 'recrdeptask' dependencies (Part A) # # e.g. do_sometask[recrdeptask] = "do_someothertask" # (makes sure sometask runs after someothertask of all DEPENDS, RDEPENDS and intertask dependencies, recursively) # We cover the recursive part of the dependencies below if 'recrdeptask' in task_deps and taskname in task_deps['recrdeptask']: tasknames = task_deps['recrdeptask'][taskname].split() recursivetasks[tid] = tasknames add_build_dependencies(taskData[mc].depids[taskfn], tasknames, depends, mc) add_runtime_dependencies(taskData[mc].rdepids[taskfn], tasknames, depends, mc) if taskname in tasknames: recursivetasksselfref.add(tid) if 'recideptask' in task_deps and taskname in task_deps['recideptask']: recursiveitasks[tid] = [] for t in task_deps['recideptask'][taskname].split(): newdep = build_tid(mc, fn, t) recursiveitasks[tid].append(newdep) self.runtaskentries[tid].depends = depends # Remove all self references self.runtaskentries[tid].depends.discard(tid) #self.dump_data() self.init_progress_reporter.next_stage() # Resolve recursive 'recrdeptask' dependencies (Part B) # # e.g. do_sometask[recrdeptask] = "do_someothertask" # (makes sure sometask runs after someothertask of all DEPENDS, RDEPENDS and intertask dependencies, recursively) # We need to do this separately since we need all of runtaskentries[*].depends to be complete before this is processed # Generating/interating recursive lists of dependencies is painful and potentially slow # Precompute recursive task dependencies here by: # a) create a temp list of reverse dependencies (revdeps) # b) walk up the ends of the chains (when a given task no longer has dependencies i.e. len(deps) == 0) # c) combine the total list of dependencies in cumulativedeps # d) optimise by pre-truncating 'task' off the items in cumulativedeps (keeps items in sets lower) revdeps = {} deps = {} cumulativedeps = {} for tid in self.runtaskentries: deps[tid] = set(self.runtaskentries[tid].depends) revdeps[tid] = set() cumulativedeps[tid] = set() # Generate a temp list of reverse dependencies for tid in self.runtaskentries: for dep in self.runtaskentries[tid].depends: revdeps[dep].add(tid) # Find the dependency chain endpoints endpoints = set() for tid in self.runtaskentries: if len(deps[tid]) == 0: endpoints.add(tid) # Iterate the chains collating dependencies while endpoints: next = set() for tid in endpoints: for dep in revdeps[tid]: cumulativedeps[dep].add(fn_from_tid(tid)) cumulativedeps[dep].update(cumulativedeps[tid]) if tid in deps[dep]: deps[dep].remove(tid) if len(deps[dep]) == 0: next.add(dep) endpoints = next #for tid in deps: # if len(deps[tid]) != 0: # bb.warn("Sanity test failure, dependencies left for %s (%s)" % (tid, deps[tid])) # Loop here since recrdeptasks can depend upon other recrdeptasks and we have to # resolve these recursively until we aren't adding any further extra dependencies extradeps = True while extradeps: extradeps = 0 for tid in recursivetasks: tasknames = recursivetasks[tid] totaldeps = set(self.runtaskentries[tid].depends) if tid in recursiveitasks: totaldeps.update(recursiveitasks[tid]) for dep in recursiveitasks[tid]: if dep not in self.runtaskentries: continue totaldeps.update(self.runtaskentries[dep].depends) deps = set() for dep in totaldeps: if dep in cumulativedeps: deps.update(cumulativedeps[dep]) for t in deps: for taskname in tasknames: newtid = t + ":" + taskname if newtid == tid: continue if newtid in self.runtaskentries and newtid not in self.runtaskentries[tid].depends: extradeps += 1 self.runtaskentries[tid].depends.add(newtid) # Handle recursive tasks which depend upon other recursive tasks deps = set() for dep in self.runtaskentries[tid].depends.intersection(recursivetasks): deps.update(self.runtaskentries[dep].depends.difference(self.runtaskentries[tid].depends)) for newtid in deps: for taskname in tasknames: if not newtid.endswith(":" + taskname): continue if newtid in self.runtaskentries: extradeps += 1 self.runtaskentries[tid].depends.add(newtid) bb.debug(1, "Added %s recursive dependencies in this loop" % extradeps) # Remove recrdeptask circular references so that do_a[recrdeptask] = "do_a do_b" can work for tid in recursivetasksselfref: self.runtaskentries[tid].depends.difference_update(recursivetasksselfref) self.init_progress_reporter.next_stage() #self.dump_data() # Step B - Mark all active tasks # # Start with the tasks we were asked to run and mark all dependencies # as active too. If the task is to be 'forced', clear its stamp. Once # all active tasks are marked, prune the ones we don't need. logger.verbose("Marking Active Tasks") def mark_active(tid, depth): """ Mark an item as active along with its depends (calls itself recursively) """ if tid in runq_build: return runq_build[tid] = 1 depends = self.runtaskentries[tid].depends for depend in depends: mark_active(depend, depth+1) self.target_tids = [] for (mc, target, task, fn) in self.targets: if target not in taskData[mc].build_targets or not taskData[mc].build_targets[target]: continue if target in taskData[mc].failed_deps: continue parents = False if task.endswith('-'): parents = True task = task[:-1] if fn in taskData[mc].failed_fns: continue # fn already has mc prefix tid = fn + ":" + task self.target_tids.append(tid) if tid not in taskData[mc].taskentries: import difflib tasks = [] for x in taskData[mc].taskentries: if x.startswith(fn + ":"): tasks.append(taskname_from_tid(x)) close_matches = difflib.get_close_matches(task, tasks, cutoff=0.7) if close_matches: extra = ". Close matches:\n %s" % "\n ".join(close_matches) else: extra = "" bb.msg.fatal("RunQueue", "Task %s does not exist for target %s (%s)%s" % (task, target, tid, extra)) # For tasks called "XXXX-", ony run their dependencies if parents: for i in self.runtaskentries[tid].depends: mark_active(i, 1) else: mark_active(tid, 1) self.init_progress_reporter.next_stage() # Step C - Prune all inactive tasks # # Once all active tasks are marked, prune the ones we don't need. delcount = {} for tid in list(self.runtaskentries.keys()): if tid not in runq_build: delcount[tid] = self.runtaskentries[tid] del self.runtaskentries[tid] # Handle --runall if self.cooker.configuration.runall: # re-run the mark_active and then drop unused tasks from new list runq_build = {} for task in self.cooker.configuration.runall: runall_tids = set() for tid in list(self.runtaskentries): wanttid = fn_from_tid(tid) + ":do_%s" % task if wanttid in delcount: self.runtaskentries[wanttid] = delcount[wanttid] if wanttid in self.runtaskentries: runall_tids.add(wanttid) for tid in list(runall_tids): mark_active(tid,1) for tid in list(self.runtaskentries.keys()): if tid not in runq_build: delcount[tid] = self.runtaskentries[tid] del self.runtaskentries[tid] if len(self.runtaskentries) == 0: bb.msg.fatal("RunQueue", "Could not find any tasks with the tasknames %s to run within the recipes of the taskgraphs of the targets %s" % (str(self.cooker.configuration.runall), str(self.targets))) self.init_progress_reporter.next_stage() # Handle runonly if self.cooker.configuration.runonly: # re-run the mark_active and then drop unused tasks from new list runq_build = {} for task in self.cooker.configuration.runonly: runonly_tids = { k: v for k, v in self.runtaskentries.items() if taskname_from_tid(k) == "do_%s" % task } for tid in list(runonly_tids): mark_active(tid,1) for tid in list(self.runtaskentries.keys()): if tid not in runq_build: delcount[tid] = self.runtaskentries[tid] del self.runtaskentries[tid] if len(self.runtaskentries) == 0: bb.msg.fatal("RunQueue", "Could not find any tasks with the tasknames %s to run within the taskgraphs of the targets %s" % (str(self.cooker.configuration.runonly), str(self.targets))) # # Step D - Sanity checks and computation # # Check to make sure we still have tasks to run if len(self.runtaskentries) == 0: if not taskData[''].abort: bb.msg.fatal("RunQueue", "All buildable tasks have been run but the build is incomplete (--continue mode). Errors for the tasks that failed will have been printed above.") else: bb.msg.fatal("RunQueue", "No active tasks and not in --continue mode?! Please report this bug.") logger.verbose("Pruned %s inactive tasks, %s left", len(delcount), len(self.runtaskentries)) logger.verbose("Assign Weightings") self.init_progress_reporter.next_stage() # Generate a list of reverse dependencies to ease future calculations for tid in self.runtaskentries: for dep in self.runtaskentries[tid].depends: self.runtaskentries[dep].revdeps.add(tid) self.init_progress_reporter.next_stage() # Identify tasks at the end of dependency chains # Error on circular dependency loops (length two) endpoints = [] for tid in self.runtaskentries: revdeps = self.runtaskentries[tid].revdeps if len(revdeps) == 0: endpoints.append(tid) for dep in revdeps: if dep in self.runtaskentries[tid].depends: bb.msg.fatal("RunQueue", "Task %s has circular dependency on %s" % (tid, dep)) logger.verbose("Compute totals (have %s endpoint(s))", len(endpoints)) self.init_progress_reporter.next_stage() # Calculate task weights # Check of higher length circular dependencies self.runq_weight = self.calculate_task_weights(endpoints) self.init_progress_reporter.next_stage() # Sanity Check - Check for multiple tasks building the same provider for mc in self.dataCaches: prov_list = {} seen_fn = [] for tid in self.runtaskentries: (tidmc, fn, taskname, taskfn) = split_tid_mcfn(tid) if taskfn in seen_fn: continue if mc != tidmc: continue seen_fn.append(taskfn) for prov in self.dataCaches[mc].fn_provides[taskfn]: if prov not in prov_list: prov_list[prov] = [taskfn] elif taskfn not in prov_list[prov]: prov_list[prov].append(taskfn) for prov in prov_list: if len(prov_list[prov]) < 2: continue if prov in self.multi_provider_whitelist: continue seen_pn = [] # If two versions of the same PN are being built its fatal, we don't support it. for fn in prov_list[prov]: pn = self.dataCaches[mc].pkg_fn[fn] if pn not in seen_pn: seen_pn.append(pn) else: bb.fatal("Multiple versions of %s are due to be built (%s). Only one version of a given PN should be built in any given build. You likely need to set PREFERRED_VERSION_%s to select the correct version or don't depend on multiple versions." % (pn, " ".join(prov_list[prov]), pn)) msg = "Multiple .bb files are due to be built which each provide %s:\n %s" % (prov, "\n ".join(prov_list[prov])) # # Construct a list of things which uniquely depend on each provider # since this may help the user figure out which dependency is triggering this warning # msg += "\nA list of tasks depending on these providers is shown and may help explain where the dependency comes from." deplist = {} commondeps = None for provfn in prov_list[prov]: deps = set() for tid in self.runtaskentries: fn = fn_from_tid(tid) if fn != provfn: continue for dep in self.runtaskentries[tid].revdeps: fn = fn_from_tid(dep) if fn == provfn: continue deps.add(dep) if not commondeps: commondeps = set(deps) else: commondeps &= deps deplist[provfn] = deps for provfn in deplist: msg += "\n%s has unique dependees:\n %s" % (provfn, "\n ".join(deplist[provfn] - commondeps)) # # Construct a list of provides and runtime providers for each recipe # (rprovides has to cover RPROVIDES, PACKAGES, PACKAGES_DYNAMIC) # msg += "\nIt could be that one recipe provides something the other doesn't and should. The following provider and runtime provider differences may be helpful." provide_results = {} rprovide_results = {} commonprovs = None commonrprovs = None for provfn in prov_list[prov]: provides = set(self.dataCaches[mc].fn_provides[provfn]) rprovides = set() for rprovide in self.dataCaches[mc].rproviders: if provfn in self.dataCaches[mc].rproviders[rprovide]: rprovides.add(rprovide) for package in self.dataCaches[mc].packages: if provfn in self.dataCaches[mc].packages[package]: rprovides.add(package) for package in self.dataCaches[mc].packages_dynamic: if provfn in self.dataCaches[mc].packages_dynamic[package]: rprovides.add(package) if not commonprovs: commonprovs = set(provides) else: commonprovs &= provides provide_results[provfn] = provides if not commonrprovs: commonrprovs = set(rprovides) else: commonrprovs &= rprovides rprovide_results[provfn] = rprovides #msg += "\nCommon provides:\n %s" % ("\n ".join(commonprovs)) #msg += "\nCommon rprovides:\n %s" % ("\n ".join(commonrprovs)) for provfn in prov_list[prov]: msg += "\n%s has unique provides:\n %s" % (provfn, "\n ".join(provide_results[provfn] - commonprovs)) msg += "\n%s has unique rprovides:\n %s" % (provfn, "\n ".join(rprovide_results[provfn] - commonrprovs)) if self.warn_multi_bb: logger.verbnote(msg) else: logger.error(msg) self.init_progress_reporter.next_stage() # Create a whitelist usable by the stamp checks self.stampfnwhitelist = {} for mc in self.taskData: self.stampfnwhitelist[mc] = [] for entry in self.stampwhitelist.split(): if entry not in self.taskData[mc].build_targets: continue fn = self.taskData.build_targets[entry][0] self.stampfnwhitelist[mc].append(fn) self.init_progress_reporter.next_stage() # Iterate over the task list looking for tasks with a 'setscene' function self.runq_setscene_tids = [] if not self.cooker.configuration.nosetscene: for tid in self.runtaskentries: (mc, fn, taskname, _) = split_tid_mcfn(tid) setscenetid = tid + "_setscene" if setscenetid not in taskData[mc].taskentries: continue self.runq_setscene_tids.append(tid) def invalidate_task(tid, error_nostamp): (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) taskdep = self.dataCaches[mc].task_deps[taskfn] if fn + ":" + taskname not in taskData[mc].taskentries: logger.warning("Task %s does not exist, invalidating this task will have no effect" % taskname) if 'nostamp' in taskdep and taskname in taskdep['nostamp']: if error_nostamp: bb.fatal("Task %s is marked nostamp, cannot invalidate this task" % taskname) else: bb.debug(1, "Task %s is marked nostamp, cannot invalidate this task" % taskname) else: logger.verbose("Invalidate task %s, %s", taskname, fn) bb.parse.siggen.invalidate_task(taskname, self.dataCaches[mc], taskfn) self.init_progress_reporter.next_stage() # Invalidate task if force mode active if self.cooker.configuration.force: for tid in self.target_tids: invalidate_task(tid, False) # Invalidate task if invalidate mode active if self.cooker.configuration.invalidate_stamp: for tid in self.target_tids: fn = fn_from_tid(tid) for st in self.cooker.configuration.invalidate_stamp.split(','): if not st.startswith("do_"): st = "do_%s" % st invalidate_task(fn + ":" + st, True) self.init_progress_reporter.next_stage() # Create and print to the logs a virtual/xxxx -> PN (fn) table for mc in taskData: virtmap = taskData[mc].get_providermap(prefix="virtual/") virtpnmap = {} for v in virtmap: virtpnmap[v] = self.dataCaches[mc].pkg_fn[virtmap[v]] bb.debug(2, "%s resolved to: %s (%s)" % (v, virtpnmap[v], virtmap[v])) if hasattr(bb.parse.siggen, "tasks_resolved"): bb.parse.siggen.tasks_resolved(virtmap, virtpnmap, self.dataCaches[mc]) self.init_progress_reporter.next_stage() # Iterate over the task list and call into the siggen code dealtwith = set() todeal = set(self.runtaskentries) while len(todeal) > 0: for tid in todeal.copy(): if len(self.runtaskentries[tid].depends - dealtwith) == 0: dealtwith.add(tid) todeal.remove(tid) self.prepare_task_hash(tid) bb.parse.siggen.writeout_file_checksum_cache() #self.dump_data() return len(self.runtaskentries) def prepare_task_hash(self, tid): procdep = [] for dep in self.runtaskentries[tid].depends: procdep.append(fn_from_tid(dep) + "." + taskname_from_tid(dep)) (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) self.runtaskentries[tid].hash = bb.parse.siggen.get_taskhash(taskfn, taskname, procdep, self.dataCaches[mc]) self.runtaskentries[tid].unihash = bb.parse.siggen.get_unihash(taskfn + "." + taskname) def dump_data(self): """ Dump some debug information on the internal data structures """ logger.debug(3, "run_tasks:") for tid in self.runtaskentries: logger.debug(3, " %s: %s Deps %s RevDeps %s", tid, self.runtaskentries[tid].weight, self.runtaskentries[tid].depends, self.runtaskentries[tid].revdeps) class RunQueueWorker(): def __init__(self, process, pipe): self.process = process self.pipe = pipe class RunQueue: def __init__(self, cooker, cfgData, dataCaches, taskData, targets): self.cooker = cooker self.cfgData = cfgData self.rqdata = RunQueueData(self, cooker, cfgData, dataCaches, taskData, targets) self.stamppolicy = cfgData.getVar("BB_STAMP_POLICY") or "perfile" self.hashvalidate = cfgData.getVar("BB_HASHCHECK_FUNCTION") or None self.depvalidate = cfgData.getVar("BB_SETSCENE_DEPVALID") or None self.state = runQueuePrepare # For disk space monitor # Invoked at regular time intervals via the bitbake heartbeat event # while the build is running. We generate a unique name for the handler # here, just in case that there ever is more than one RunQueue instance, # start the handler when reaching runQueueSceneRun, and stop it when # done with the build. self.dm = monitordisk.diskMonitor(cfgData) self.dm_event_handler_name = '_bb_diskmonitor_' + str(id(self)) self.dm_event_handler_registered = False self.rqexe = None self.worker = {} self.fakeworker = {} def _start_worker(self, mc, fakeroot = False, rqexec = None): logger.debug(1, "Starting bitbake-worker") magic = "decafbad" if self.cooker.configuration.profile: magic = "decafbadbad" if fakeroot: magic = magic + "beef" mcdata = self.cooker.databuilder.mcdata[mc] fakerootcmd = shlex.split(mcdata.getVar("FAKEROOTCMD")) fakerootenv = (mcdata.getVar("FAKEROOTBASEENV") or "").split() env = os.environ.copy() for key, value in (var.split('=') for var in fakerootenv): env[key] = value worker = subprocess.Popen(fakerootcmd + ["bitbake-worker", magic], stdout=subprocess.PIPE, stdin=subprocess.PIPE, env=env) else: worker = subprocess.Popen(["bitbake-worker", magic], stdout=subprocess.PIPE, stdin=subprocess.PIPE) bb.utils.nonblockingfd(worker.stdout) workerpipe = runQueuePipe(worker.stdout, None, self.cfgData, self, rqexec) workerdata = { "taskdeps" : self.rqdata.dataCaches[mc].task_deps, "fakerootenv" : self.rqdata.dataCaches[mc].fakerootenv, "fakerootdirs" : self.rqdata.dataCaches[mc].fakerootdirs, "fakerootnoenv" : self.rqdata.dataCaches[mc].fakerootnoenv, "sigdata" : bb.parse.siggen.get_taskdata(), "logdefaultdebug" : bb.msg.loggerDefaultDebugLevel, "logdefaultverbose" : bb.msg.loggerDefaultVerbose, "logdefaultverboselogs" : bb.msg.loggerVerboseLogs, "logdefaultdomain" : bb.msg.loggerDefaultDomains, "prhost" : self.cooker.prhost, "buildname" : self.cfgData.getVar("BUILDNAME"), "date" : self.cfgData.getVar("DATE"), "time" : self.cfgData.getVar("TIME"), } worker.stdin.write(b"" + pickle.dumps(self.cooker.configuration) + b"") worker.stdin.write(b"" + pickle.dumps(self.cooker.extraconfigdata) + b"") worker.stdin.write(b"" + pickle.dumps(workerdata) + b"") worker.stdin.flush() return RunQueueWorker(worker, workerpipe) def _teardown_worker(self, worker): if not worker: return logger.debug(1, "Teardown for bitbake-worker") try: worker.process.stdin.write(b"") worker.process.stdin.flush() worker.process.stdin.close() except IOError: pass while worker.process.returncode is None: worker.pipe.read() worker.process.poll() while worker.pipe.read(): continue worker.pipe.close() def start_worker(self): if self.worker: self.teardown_workers() self.teardown = False for mc in self.rqdata.dataCaches: self.worker[mc] = self._start_worker(mc) def start_fakeworker(self, rqexec, mc): if not mc in self.fakeworker: self.fakeworker[mc] = self._start_worker(mc, True, rqexec) def teardown_workers(self): self.teardown = True for mc in self.worker: self._teardown_worker(self.worker[mc]) self.worker = {} for mc in self.fakeworker: self._teardown_worker(self.fakeworker[mc]) self.fakeworker = {} def read_workers(self): for mc in self.worker: self.worker[mc].pipe.read() for mc in self.fakeworker: self.fakeworker[mc].pipe.read() def active_fds(self): fds = [] for mc in self.worker: fds.append(self.worker[mc].pipe.input) for mc in self.fakeworker: fds.append(self.fakeworker[mc].pipe.input) return fds def check_stamp_task(self, tid, taskname = None, recurse = False, cache = None): def get_timestamp(f): try: if not os.access(f, os.F_OK): return None return os.stat(f)[stat.ST_MTIME] except: return None (mc, fn, tn, taskfn) = split_tid_mcfn(tid) if taskname is None: taskname = tn if self.stamppolicy == "perfile": fulldeptree = False else: fulldeptree = True stampwhitelist = [] if self.stamppolicy == "whitelist": stampwhitelist = self.rqdata.stampfnwhitelist[mc] stampfile = bb.build.stampfile(taskname, self.rqdata.dataCaches[mc], taskfn) # If the stamp is missing, it's not current if not os.access(stampfile, os.F_OK): logger.debug(2, "Stampfile %s not available", stampfile) return False # If it's a 'nostamp' task, it's not current taskdep = self.rqdata.dataCaches[mc].task_deps[taskfn] if 'nostamp' in taskdep and taskname in taskdep['nostamp']: logger.debug(2, "%s.%s is nostamp\n", fn, taskname) return False if taskname != "do_setscene" and taskname.endswith("_setscene"): return True if cache is None: cache = {} iscurrent = True t1 = get_timestamp(stampfile) for dep in self.rqdata.runtaskentries[tid].depends: if iscurrent: (mc2, fn2, taskname2, taskfn2) = split_tid_mcfn(dep) stampfile2 = bb.build.stampfile(taskname2, self.rqdata.dataCaches[mc2], taskfn2) stampfile3 = bb.build.stampfile(taskname2 + "_setscene", self.rqdata.dataCaches[mc2], taskfn2) t2 = get_timestamp(stampfile2) t3 = get_timestamp(stampfile3) if t3 and not t2: continue if t3 and t3 > t2: continue if fn == fn2 or (fulldeptree and fn2 not in stampwhitelist): if not t2: logger.debug(2, 'Stampfile %s does not exist', stampfile2) iscurrent = False break if t1 < t2: logger.debug(2, 'Stampfile %s < %s', stampfile, stampfile2) iscurrent = False break if recurse and iscurrent: if dep in cache: iscurrent = cache[dep] if not iscurrent: logger.debug(2, 'Stampfile for dependency %s:%s invalid (cached)' % (fn2, taskname2)) else: iscurrent = self.check_stamp_task(dep, recurse=True, cache=cache) cache[dep] = iscurrent if recurse: cache[tid] = iscurrent return iscurrent def validate_hash(self, *, sq_fn, sq_task, sq_hash, sq_hashfn, siginfo, sq_unihash, d): locs = {"sq_fn" : sq_fn, "sq_task" : sq_task, "sq_hash" : sq_hash, "sq_hashfn" : sq_hashfn, "sq_unihash" : sq_unihash, "siginfo" : siginfo, "d" : d} hashvalidate_args = ("(sq_fn, sq_task, sq_hash, sq_hashfn, d, siginfo=siginfo, sq_unihash=sq_unihash)", "(sq_fn, sq_task, sq_hash, sq_hashfn, d, siginfo=siginfo)", "(sq_fn, sq_task, sq_hash, sq_hashfn, d)") for args in hashvalidate_args[:-1]: try: call = self.hashvalidate + args return bb.utils.better_eval(call, locs) except TypeError: continue # Call the last entry without a try...catch to propagate any thrown # TypeError call = self.hashvalidate + hashvalidate_args[-1] return bb.utils.better_eval(call, locs) def _execute_runqueue(self): """ Run the tasks in a queue prepared by rqdata.prepare() Upon failure, optionally try to recover the build using any alternate providers (if the abort on failure configuration option isn't set) """ retval = True if self.state is runQueuePrepare: # NOTE: if you add, remove or significantly refactor the stages of this # process then you should recalculate the weightings here. This is quite # easy to do - just change the next line temporarily to pass debug=True as # the last parameter and you'll get a printout of the weightings as well # as a map to the lines where next_stage() was called. Of course this isn't # critical, but it helps to keep the progress reporting accurate. self.rqdata.init_progress_reporter = bb.progress.MultiStageProcessProgressReporter(self.cooker.data, "Initialising tasks", [43, 967, 4, 3, 1, 5, 3, 7, 13, 1, 2, 1, 1, 246, 35, 1, 38, 1, 35, 2, 338, 204, 142, 3, 3, 37, 244]) if self.rqdata.prepare() == 0: self.state = runQueueComplete else: self.state = runQueueSceneInit if self.state is runQueueSceneInit: self.rqdata.init_progress_reporter.next_stage() # we are ready to run, emit dependency info to any UI or class which # needs it depgraph = self.cooker.buildDependTree(self, self.rqdata.taskData) self.rqdata.init_progress_reporter.next_stage() bb.event.fire(bb.event.DepTreeGenerated(depgraph), self.cooker.data) if not self.dm_event_handler_registered: res = bb.event.register(self.dm_event_handler_name, lambda x: self.dm.check(self) if self.state in [runQueueSceneRun, runQueueRunning, runQueueCleanUp] else False, ('bb.event.HeartbeatEvent',)) self.dm_event_handler_registered = True dump = self.cooker.configuration.dump_signatures if dump: self.rqdata.init_progress_reporter.finish() if 'printdiff' in dump: invalidtasks = self.print_diffscenetasks() self.dump_signatures(dump) if 'printdiff' in dump: self.write_diffscenetasks(invalidtasks) self.state = runQueueComplete if self.state is runQueueSceneInit: self.rqdata.init_progress_reporter.next_stage() self.start_worker() self.rqdata.init_progress_reporter.next_stage() self.rqexe = RunQueueExecute(self) # If we don't have any setscene functions, skip execution if len(self.rqdata.runq_setscene_tids) == 0: self.rqdata.init_progress_reporter.finish() self.state = runQueueRunInit else: logger.info('Executing SetScene Tasks') self.state = runQueueSceneRun if self.state is runQueueSceneRun: retval = self.rqexe.sq_execute() if self.state is runQueueRunInit: if self.cooker.configuration.setsceneonly: self.state = runQueueComplete if self.state is runQueueRunInit: logger.info("Executing RunQueue Tasks") start_runqueue_tasks(self.rqexe) self.state = runQueueRunning if self.state is runQueueRunning: retval = self.rqexe.execute() if self.state is runQueueCleanUp: retval = self.rqexe.finish() build_done = self.state is runQueueComplete or self.state is runQueueFailed if build_done and self.dm_event_handler_registered: bb.event.remove(self.dm_event_handler_name, None) self.dm_event_handler_registered = False if build_done and self.rqexe: self.teardown_workers() if self.rqexe: if self.rqexe.stats.failed: logger.info("Tasks Summary: Attempted %d tasks of which %d didn't need to be rerun and %d failed.", self.rqexe.stats.completed + self.rqexe.stats.failed, self.rqexe.stats.skipped, self.rqexe.stats.failed) else: # Let's avoid the word "failed" if nothing actually did logger.info("Tasks Summary: Attempted %d tasks of which %d didn't need to be rerun and all succeeded.", self.rqexe.stats.completed, self.rqexe.stats.skipped) if self.state is runQueueFailed: raise bb.runqueue.TaskFailure(self.rqexe.failed_tids) if self.state is runQueueComplete: # All done return False # Loop return retval def execute_runqueue(self): # Catch unexpected exceptions and ensure we exit when an error occurs, not loop. try: return self._execute_runqueue() except bb.runqueue.TaskFailure: raise except SystemExit: raise except bb.BBHandledException: try: self.teardown_workers() except: pass self.state = runQueueComplete raise except Exception as err: logger.exception("An uncaught exception occurred in runqueue") try: self.teardown_workers() except: pass self.state = runQueueComplete raise def finish_runqueue(self, now = False): if not self.rqexe: self.state = runQueueComplete return if now: self.rqexe.finish_now() else: self.rqexe.finish() def rq_dump_sigfn(self, fn, options): bb_cache = bb.cache.NoCache(self.cooker.databuilder) the_data = bb_cache.loadDataFull(fn, self.cooker.collection.get_file_appends(fn)) siggen = bb.parse.siggen dataCaches = self.rqdata.dataCaches siggen.dump_sigfn(fn, dataCaches, options) def dump_signatures(self, options): fns = set() bb.note("Reparsing files to collect dependency data") for tid in self.rqdata.runtaskentries: fn = fn_from_tid(tid) fns.add(fn) max_process = int(self.cfgData.getVar("BB_NUMBER_PARSE_THREADS") or os.cpu_count() or 1) # We cannot use the real multiprocessing.Pool easily due to some local data # that can't be pickled. This is a cheap multi-process solution. launched = [] while fns: if len(launched) < max_process: p = Process(target=self.rq_dump_sigfn, args=(fns.pop(), options)) p.start() launched.append(p) for q in launched: # The finished processes are joined when calling is_alive() if not q.is_alive(): launched.remove(q) for p in launched: p.join() bb.parse.siggen.dump_sigs(self.rqdata.dataCaches, options) return def print_diffscenetasks(self): valid = [] sq_hash = [] sq_hashfn = [] sq_unihash = [] sq_fn = [] sq_taskname = [] sq_task = [] noexec = [] stamppresent = [] valid_new = set() for tid in self.rqdata.runtaskentries: (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) taskdep = self.rqdata.dataCaches[mc].task_deps[taskfn] if 'noexec' in taskdep and taskname in taskdep['noexec']: noexec.append(tid) continue sq_fn.append(fn) sq_hashfn.append(self.rqdata.dataCaches[mc].hashfn[taskfn]) sq_hash.append(self.rqdata.runtaskentries[tid].hash) sq_unihash.append(self.rqdata.runtaskentries[tid].unihash) sq_taskname.append(taskname) sq_task.append(tid) valid = self.validate_hash(sq_fn=sq_fn, sq_task=sq_taskname, sq_hash=sq_hash, sq_hashfn=sq_hashfn, siginfo=True, sq_unihash=sq_unihash, d=self.cooker.data) for v in valid: valid_new.add(sq_task[v]) # Tasks which are both setscene and noexec never care about dependencies # We therefore find tasks which are setscene and noexec and mark their # unique dependencies as valid. for tid in noexec: if tid not in self.rqdata.runq_setscene_tids: continue for dep in self.rqdata.runtaskentries[tid].depends: hasnoexecparents = True for dep2 in self.rqdata.runtaskentries[dep].revdeps: if dep2 in self.rqdata.runq_setscene_tids and dep2 in noexec: continue hasnoexecparents = False break if hasnoexecparents: valid_new.add(dep) invalidtasks = set() for tid in self.rqdata.runtaskentries: if tid not in valid_new and tid not in noexec: invalidtasks.add(tid) found = set() processed = set() for tid in invalidtasks: toprocess = set([tid]) while toprocess: next = set() for t in toprocess: for dep in self.rqdata.runtaskentries[t].depends: if dep in invalidtasks: found.add(tid) if dep not in processed: processed.add(dep) next.add(dep) toprocess = next if tid in found: toprocess = set() tasklist = [] for tid in invalidtasks.difference(found): tasklist.append(tid) if tasklist: bb.plain("The differences between the current build and any cached tasks start at the following tasks:\n" + "\n".join(tasklist)) return invalidtasks.difference(found) def write_diffscenetasks(self, invalidtasks): # Define recursion callback def recursecb(key, hash1, hash2): hashes = [hash1, hash2] hashfiles = bb.siggen.find_siginfo(key, None, hashes, self.cfgData) recout = [] if len(hashfiles) == 2: out2 = bb.siggen.compare_sigfiles(hashfiles[hash1], hashfiles[hash2], recursecb) recout.extend(list(' ' + l for l in out2)) else: recout.append("Unable to find matching sigdata for %s with hashes %s or %s" % (key, hash1, hash2)) return recout for tid in invalidtasks: (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) pn = self.rqdata.dataCaches[mc].pkg_fn[taskfn] h = self.rqdata.runtaskentries[tid].hash matches = bb.siggen.find_siginfo(pn, taskname, [], self.cfgData) match = None for m in matches: if h in m: match = m if match is None: bb.fatal("Can't find a task we're supposed to have written out? (hash: %s)?" % h) matches = {k : v for k, v in iter(matches.items()) if h not in k} if matches: latestmatch = sorted(matches.keys(), key=lambda f: matches[f])[-1] prevh = __find_sha256__.search(latestmatch).group(0) output = bb.siggen.compare_sigfiles(latestmatch, match, recursecb) bb.plain("\nTask %s:%s couldn't be used from the cache because:\n We need hash %s, closest matching task was %s\n " % (pn, taskname, h, prevh) + '\n '.join(output)) def process_setscene_whitelist(rq, rqdata, stampcache, sched, rqex): # Check tasks that are going to run against the whitelist def check_norun_task(tid, showerror=False): (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) # Ignore covered tasks if tid in rqex.tasks_covered: return False # Ignore stamped tasks if rq.check_stamp_task(tid, taskname, cache=stampcache): return False # Ignore noexec tasks taskdep = rqdata.dataCaches[mc].task_deps[taskfn] if 'noexec' in taskdep and taskname in taskdep['noexec']: return False pn = rqdata.dataCaches[mc].pkg_fn[taskfn] if not check_setscene_enforce_whitelist(pn, taskname, rqdata.setscenewhitelist): if showerror: if tid in rqdata.runq_setscene_tids: logger.error('Task %s.%s attempted to execute unexpectedly and should have been setscened' % (pn, taskname)) else: logger.error('Task %s.%s attempted to execute unexpectedly' % (pn, taskname)) return True return False # Look to see if any tasks that we think shouldn't run are going to unexpected = False for tid in rqdata.runtaskentries: if check_norun_task(tid): unexpected = True break if unexpected: # Run through the tasks in the rough order they'd have executed and print errors # (since the order can be useful - usually missing sstate for the last few tasks # is the cause of the problem) task = sched.next() while task is not None: check_norun_task(task, showerror=True) rqex.task_skip(task, 'Setscene enforcement check') task = sched.next() rq.state = runQueueCleanUp return True class RunQueueExecute: def __init__(self, rq): self.rq = rq self.cooker = rq.cooker self.cfgData = rq.cfgData self.rqdata = rq.rqdata self.number_tasks = int(self.cfgData.getVar("BB_NUMBER_THREADS") or 1) self.scheduler = self.cfgData.getVar("BB_SCHEDULER") or "speed" self.sq_buildable = set() self.sq_running = set() self.sq_live = set() self.runq_buildable = set() self.runq_running = set() self.runq_complete = set() self.build_stamps = {} self.build_stamps2 = [] self.failed_tids = [] self.stampcache = {} self.stats = RunQueueStats(len(self.rqdata.runtaskentries)) self.sq_stats = RunQueueStats(len(self.rqdata.runq_setscene_tids)) for mc in rq.worker: rq.worker[mc].pipe.setrunqueueexec(self) for mc in rq.fakeworker: rq.fakeworker[mc].pipe.setrunqueueexec(self) if self.number_tasks <= 0: bb.fatal("Invalid BB_NUMBER_THREADS %s" % self.number_tasks) # List of setscene tasks which we've covered self.scenequeue_covered = set() # List of tasks which are covered (including setscene ones) self.tasks_covered = set() self.scenequeue_notcovered = set() self.scenequeue_notneeded = set() if len(self.rqdata.runq_setscene_tids) > 0: self.sqdata = SQData() build_scenequeue_data(self.sqdata, self.rqdata, self.rq, self.cooker, self.stampcache, self) schedulers = self.get_schedulers() for scheduler in schedulers: if self.scheduler == scheduler.name: self.sched = scheduler(self, self.rqdata) logger.debug(1, "Using runqueue scheduler '%s'", scheduler.name) break else: bb.fatal("Invalid scheduler '%s'. Available schedulers: %s" % (self.scheduler, ", ".join(obj.name for obj in schedulers))) def runqueue_process_waitpid(self, task, status): # self.build_stamps[pid] may not exist when use shared work directory. if task in self.build_stamps: self.build_stamps2.remove(self.build_stamps[task]) del self.build_stamps[task] if task in self.sq_live: if status != 0: self.sq_task_fail(task, status) else: self.sq_task_complete(task) self.sq_live.remove(task) else: if status != 0: self.task_fail(task, status) else: self.task_complete(task) return True def finish_now(self): for mc in self.rq.worker: try: self.rq.worker[mc].process.stdin.write(b"") self.rq.worker[mc].process.stdin.flush() except IOError: # worker must have died? pass for mc in self.rq.fakeworker: try: self.rq.fakeworker[mc].process.stdin.write(b"") self.rq.fakeworker[mc].process.stdin.flush() except IOError: # worker must have died? pass if len(self.failed_tids) != 0: self.rq.state = runQueueFailed return self.rq.state = runQueueComplete return def finish(self): self.rq.state = runQueueCleanUp active = self.stats.active + self.sq_stats.active if active > 0: bb.event.fire(runQueueExitWait(active), self.cfgData) self.rq.read_workers() return self.rq.active_fds() if len(self.failed_tids) != 0: self.rq.state = runQueueFailed return True self.rq.state = runQueueComplete return True # Used by setscene only def check_dependencies(self, task, taskdeps): if not self.rq.depvalidate: return False taskdata = {} taskdeps.add(task) for dep in taskdeps: (mc, fn, taskname, taskfn) = split_tid_mcfn(dep) pn = self.rqdata.dataCaches[mc].pkg_fn[taskfn] taskdata[dep] = [pn, taskname, fn] call = self.rq.depvalidate + "(task, taskdata, notneeded, d)" locs = { "task" : task, "taskdata" : taskdata, "notneeded" : self.scenequeue_notneeded, "d" : self.cooker.data } valid = bb.utils.better_eval(call, locs) return valid def can_start_task(self): active = self.stats.active + self.sq_stats.active can_start = active < self.number_tasks return can_start def get_schedulers(self): schedulers = set(obj for obj in globals().values() if type(obj) is type and issubclass(obj, RunQueueScheduler)) user_schedulers = self.cfgData.getVar("BB_SCHEDULERS") if user_schedulers: for sched in user_schedulers.split(): if not "." in sched: bb.note("Ignoring scheduler '%s' from BB_SCHEDULERS: not an import" % sched) continue modname, name = sched.rsplit(".", 1) try: module = __import__(modname, fromlist=(name,)) except ImportError as exc: logger.critical("Unable to import scheduler '%s' from '%s': %s" % (name, modname, exc)) raise SystemExit(1) else: schedulers.add(getattr(module, name)) return schedulers def setbuildable(self, task): self.runq_buildable.add(task) self.sched.newbuildable(task) def task_completeoutright(self, task): """ Mark a task as completed Look at the reverse dependencies and mark any task with completed dependencies as buildable """ self.runq_complete.add(task) for revdep in self.rqdata.runtaskentries[task].revdeps: if revdep in self.runq_running: continue if revdep in self.runq_buildable: continue alldeps = True for dep in self.rqdata.runtaskentries[revdep].depends: if dep not in self.runq_complete: alldeps = False break if alldeps: self.setbuildable(revdep) logger.debug(1, "Marking task %s as buildable", revdep) def task_complete(self, task): self.stats.taskCompleted() bb.event.fire(runQueueTaskCompleted(task, self.stats, self.rq), self.cfgData) self.task_completeoutright(task) def task_fail(self, task, exitcode): """ Called when a task has failed Updates the state engine with the failure """ self.stats.taskFailed() self.failed_tids.append(task) bb.event.fire(runQueueTaskFailed(task, self.stats, exitcode, self.rq), self.cfgData) if self.rqdata.taskData[''].abort: self.rq.state = runQueueCleanUp def task_skip(self, task, reason): self.runq_running.add(task) self.setbuildable(task) bb.event.fire(runQueueTaskSkipped(task, self.stats, self.rq, reason), self.cfgData) self.task_completeoutright(task) self.stats.taskSkipped() self.stats.taskCompleted() def execute(self): """ Run the tasks in a queue prepared by rqdata.prepare() """ if self.rqdata.setscenewhitelist is not None and not self.rqdata.setscenewhitelist_checked: self.rqdata.setscenewhitelist_checked = True if process_setscenewhitelist(self.rq, self.rqdata, self.stampcache, self.sched, self): return True self.rq.read_workers() if self.stats.total == 0: # nothing to do self.rq.state = runQueueCleanUp task = self.sched.next() if task is not None: (mc, fn, taskname, taskfn) = split_tid_mcfn(task) if task in self.tasks_covered: logger.debug(2, "Setscene covered task %s", task) self.task_skip(task, "covered") return True if self.rq.check_stamp_task(task, taskname, cache=self.stampcache): logger.debug(2, "Stamp current task %s", task) self.task_skip(task, "existing") return True taskdep = self.rqdata.dataCaches[mc].task_deps[taskfn] if 'noexec' in taskdep and taskname in taskdep['noexec']: startevent = runQueueTaskStarted(task, self.stats, self.rq, noexec=True) bb.event.fire(startevent, self.cfgData) self.runq_running.add(task) self.stats.taskActive() if not (self.cooker.configuration.dry_run or self.rqdata.setscene_enforce): bb.build.make_stamp(taskname, self.rqdata.dataCaches[mc], taskfn) self.task_complete(task) return True else: startevent = runQueueTaskStarted(task, self.stats, self.rq) bb.event.fire(startevent, self.cfgData) taskdepdata = self.build_taskdepdata(task) taskdep = self.rqdata.dataCaches[mc].task_deps[taskfn] taskhash = self.rqdata.get_task_hash(task) unihash = self.rqdata.get_task_unihash(task) if 'fakeroot' in taskdep and taskname in taskdep['fakeroot'] and not (self.cooker.configuration.dry_run or self.rqdata.setscene_enforce): if not mc in self.rq.fakeworker: try: self.rq.start_fakeworker(self, mc) except OSError as exc: logger.critical("Failed to spawn fakeroot worker to run %s: %s" % (task, str(exc))) self.rq.state = runQueueFailed self.stats.taskFailed() return True self.rq.fakeworker[mc].process.stdin.write(b"" + pickle.dumps((taskfn, task, taskname, taskhash, unihash, False, self.cooker.collection.get_file_appends(taskfn), taskdepdata, self.rqdata.setscene_enforce)) + b"") self.rq.fakeworker[mc].process.stdin.flush() else: self.rq.worker[mc].process.stdin.write(b"" + pickle.dumps((taskfn, task, taskname, taskhash, unihash, False, self.cooker.collection.get_file_appends(taskfn), taskdepdata, self.rqdata.setscene_enforce)) + b"") self.rq.worker[mc].process.stdin.flush() self.build_stamps[task] = bb.build.stampfile(taskname, self.rqdata.dataCaches[mc], taskfn, noextra=True) self.build_stamps2.append(self.build_stamps[task]) self.runq_running.add(task) self.stats.taskActive() if self.can_start_task(): return True if self.stats.active > 0: self.rq.read_workers() return self.rq.active_fds() if len(self.failed_tids) != 0: self.rq.state = runQueueFailed return True # Sanity Checks for task in self.rqdata.runtaskentries: if task not in self.runq_buildable: logger.error("Task %s never buildable!", task) if task not in self.runq_running: logger.error("Task %s never ran!", task) if task not in self.runq_complete: logger.error("Task %s never completed!", task) self.rq.state = runQueueComplete return True def filtermcdeps(self, task, deps): ret = set() mainmc = mc_from_tid(task) for dep in deps: mc = mc_from_tid(dep) if mc != mainmc: continue ret.add(dep) return ret # We filter out multiconfig dependencies from taskdepdata we pass to the tasks # as most code can't handle them def build_taskdepdata(self, task): taskdepdata = {} next = self.rqdata.runtaskentries[task].depends next.add(task) next = self.filtermcdeps(task, next) while next: additional = [] for revdep in next: (mc, fn, taskname, taskfn) = split_tid_mcfn(revdep) pn = self.rqdata.dataCaches[mc].pkg_fn[taskfn] deps = self.rqdata.runtaskentries[revdep].depends provides = self.rqdata.dataCaches[mc].fn_provides[taskfn] taskhash = self.rqdata.runtaskentries[revdep].hash unihash = self.rqdata.runtaskentries[revdep].unihash deps = self.filtermcdeps(task, deps) taskdepdata[revdep] = [pn, taskname, fn, deps, provides, taskhash, unihash] for revdep2 in deps: if revdep2 not in taskdepdata: additional.append(revdep2) next = additional #bb.note("Task %s: " % task + str(taskdepdata).replace("], ", "],\n")) return taskdepdata def scenequeue_updatecounters(self, task, fail = False): for dep in self.sqdata.sq_deps[task]: if fail and task in self.sqdata.sq_harddeps and dep in self.sqdata.sq_harddeps[task]: logger.debug(2, "%s was unavailable and is a hard dependency of %s so skipping" % (task, dep)) self.sq_task_failoutright(dep) continue if task not in self.sqdata.sq_revdeps2[dep]: # May already have been removed by the fail case above continue self.sqdata.sq_revdeps2[dep].remove(task) if len(self.sqdata.sq_revdeps2[dep]) == 0: self.sq_buildable.add(dep) def sq_task_completeoutright(self, task): """ Mark a task as completed Look at the reverse dependencies and mark any task with completed dependencies as buildable """ logger.debug(1, 'Found task %s which could be accelerated', task) self.scenequeue_covered.add(task) self.tasks_covered.add(task) self.scenequeue_updatecounters(task) def sq_check_taskfail(self, task): if self.rqdata.setscenewhitelist is not None: realtask = task.split('_setscene')[0] (mc, fn, taskname, taskfn) = split_tid_mcfn(realtask) pn = self.rqdata.dataCaches[mc].pkg_fn[taskfn] if not check_setscene_enforce_whitelist(pn, taskname, self.rqdata.setscenewhitelist): logger.error('Task %s.%s failed' % (pn, taskname + "_setscene")) self.rq.state = runQueueCleanUp def sq_task_complete(self, task): self.sq_stats.taskCompleted() bb.event.fire(sceneQueueTaskCompleted(task, self.sq_stats, self.rq), self.cfgData) self.sq_task_completeoutright(task) def sq_task_fail(self, task, result): self.sq_stats.taskFailed() bb.event.fire(sceneQueueTaskFailed(task, self.sq_stats, result, self), self.cfgData) self.scenequeue_notcovered.add(task) self.scenequeue_updatecounters(task, True) self.sq_check_taskfail(task) def sq_task_failoutright(self, task): self.sq_running.add(task) self.sq_buildable.add(task) self.sq_stats.taskSkipped() self.sq_stats.taskCompleted() self.scenequeue_notcovered.add(task) self.scenequeue_updatecounters(task, True) def sq_task_skip(self, task): self.sq_running.add(task) self.sq_buildable.add(task) self.sq_task_completeoutright(task) self.sq_stats.taskSkipped() self.sq_stats.taskCompleted() def sq_execute(self): """ Run the tasks in a queue prepared by prepare_runqueue """ self.rq.read_workers() task = None if self.can_start_task(): # Find the next setscene to run for nexttask in self.rqdata.runq_setscene_tids: if nexttask in self.sq_buildable and nexttask not in self.sq_running and self.sqdata.stamps[nexttask] not in self.build_stamps.values(): if nexttask in self.sqdata.unskippable: logger.debug(2, "Setscene task %s is unskippable" % nexttask) if nexttask not in self.sqdata.unskippable and len(self.sqdata.sq_revdeps[nexttask]) > 0 and self.sqdata.sq_revdeps[nexttask].issubset(self.scenequeue_covered) and self.check_dependencies(nexttask, self.sqdata.sq_revdeps[nexttask]): fn = fn_from_tid(nexttask) foundtarget = False if nexttask in self.rqdata.target_tids: foundtarget = True if not foundtarget: logger.debug(2, "Skipping setscene for task %s" % nexttask) self.sq_task_skip(nexttask) self.scenequeue_notneeded.add(nexttask) return True if nexttask in self.sqdata.outrightfail: self.sq_task_failoutright(nexttask) return True task = nexttask break if task is not None: (mc, fn, taskname, taskfn) = split_tid_mcfn(task) taskname = taskname + "_setscene" if self.rq.check_stamp_task(task, taskname_from_tid(task), recurse = True, cache=self.stampcache): logger.debug(2, 'Stamp for underlying task %s is current, so skipping setscene variant', task) self.sq_task_failoutright(task) return True if self.cooker.configuration.force: if task in self.rqdata.target_tids: self.sq_task_failoutright(task) return True if self.rq.check_stamp_task(task, taskname, cache=self.stampcache): logger.debug(2, 'Setscene stamp current task %s, so skip it and its dependencies', task) self.sq_task_skip(task) return True if self.cooker.configuration.skipsetscene: logger.debug(2, 'No setscene tasks should be executed. Skipping %s', task) self.sq_task_failoutright(task) return True startevent = sceneQueueTaskStarted(task, self.sq_stats, self.rq) bb.event.fire(startevent, self.cfgData) taskdepdata = self.sq_build_taskdepdata(task) taskdep = self.rqdata.dataCaches[mc].task_deps[taskfn] taskhash = self.rqdata.get_task_hash(task) unihash = self.rqdata.get_task_unihash(task) if 'fakeroot' in taskdep and taskname in taskdep['fakeroot'] and not self.cooker.configuration.dry_run: if not mc in self.rq.fakeworker: self.rq.start_fakeworker(self, mc) self.rq.fakeworker[mc].process.stdin.write(b"" + pickle.dumps((taskfn, task, taskname, taskhash, unihash, True, self.cooker.collection.get_file_appends(taskfn), taskdepdata, False)) + b"") self.rq.fakeworker[mc].process.stdin.flush() else: self.rq.worker[mc].process.stdin.write(b"" + pickle.dumps((taskfn, task, taskname, taskhash, unihash, True, self.cooker.collection.get_file_appends(taskfn), taskdepdata, False)) + b"") self.rq.worker[mc].process.stdin.flush() self.build_stamps[task] = bb.build.stampfile(taskname, self.rqdata.dataCaches[mc], taskfn, noextra=True) self.build_stamps2.append(self.build_stamps[task]) self.sq_running.add(task) self.sq_live.add(task) self.sq_stats.taskActive() if self.can_start_task(): return True if self.sq_stats.active > 0: self.rq.read_workers() return self.rq.active_fds() #for tid in self.sqdata.sq_revdeps: # if tid not in self.sq_running: # buildable = tid in self.sq_buildable # revdeps = self.sqdata.sq_revdeps[tid] # bb.warn("Found we didn't run %s %s %s" % (tid, buildable, str(revdeps))) logger.debug(1, 'We can skip tasks %s', "\n".join(sorted(self.scenequeue_covered))) self.rq.state = runQueueRunInit completeevent = sceneQueueComplete(self.sq_stats, self.rq) bb.event.fire(completeevent, self.cfgData) return True def sq_build_taskdepdata(self, task): def getsetscenedeps(tid): deps = set() (mc, fn, taskname, _) = split_tid_mcfn(tid) realtid = tid + "_setscene" idepends = self.rqdata.taskData[mc].taskentries[realtid].idepends for (depname, idependtask) in idepends: if depname not in self.rqdata.taskData[mc].build_targets: continue depfn = self.rqdata.taskData[mc].build_targets[depname][0] if depfn is None: continue deptid = depfn + ":" + idependtask.replace("_setscene", "") deps.add(deptid) return deps taskdepdata = {} next = getsetscenedeps(task) next.add(task) while next: additional = [] for revdep in next: (mc, fn, taskname, taskfn) = split_tid_mcfn(revdep) pn = self.rqdata.dataCaches[mc].pkg_fn[taskfn] deps = getsetscenedeps(revdep) provides = self.rqdata.dataCaches[mc].fn_provides[taskfn] taskhash = self.rqdata.runtaskentries[revdep].hash unihash = self.rqdata.runtaskentries[revdep].unihash taskdepdata[revdep] = [pn, taskname, fn, deps, provides, taskhash, unihash] for revdep2 in deps: if revdep2 not in taskdepdata: additional.append(revdep2) next = additional #bb.note("Task %s: " % task + str(taskdepdata).replace("], ", "],\n")) return taskdepdata class SQData(object): def __init__(self): # SceneQueue dependencies self.sq_deps = {} # SceneQueue reverse dependencies self.sq_revdeps = {} # Copy of reverse dependencies used by sq processing code self.sq_revdeps2 = {} # Injected inter-setscene task dependencies self.sq_harddeps = {} # Cache of stamp files so duplicates can't run in parallel self.stamps = {} # Setscene tasks directly depended upon by the build self.unskippable = set() # List of setscene tasks which aren't present self.outrightfail = [] # A list of normal tasks a setscene task covers self.sq_covered_tasks = {} def build_scenequeue_data(sqdata, rqdata, rq, cooker, stampcache, sqrq): sq_revdeps = {} sq_revdeps_squash = {} sq_collated_deps = {} # We need to construct a dependency graph for the setscene functions. Intermediate # dependencies between the setscene tasks only complicate the code. This code # therefore aims to collapse the huge runqueue dependency tree into a smaller one # only containing the setscene functions. rqdata.init_progress_reporter.next_stage() # First process the chains up to the first setscene task. endpoints = {} for tid in rqdata.runtaskentries: sq_revdeps[tid] = copy.copy(rqdata.runtaskentries[tid].revdeps) sq_revdeps_squash[tid] = set() if (len(sq_revdeps[tid]) == 0) and tid not in rqdata.runq_setscene_tids: #bb.warn("Added endpoint %s" % (tid)) endpoints[tid] = set() rqdata.init_progress_reporter.next_stage() # Secondly process the chains between setscene tasks. for tid in rqdata.runq_setscene_tids: sq_collated_deps[tid] = set() #bb.warn("Added endpoint 2 %s" % (tid)) for dep in rqdata.runtaskentries[tid].depends: if tid in sq_revdeps[dep]: sq_revdeps[dep].remove(tid) if dep not in endpoints: endpoints[dep] = set() #bb.warn(" Added endpoint 3 %s" % (dep)) endpoints[dep].add(tid) rqdata.init_progress_reporter.next_stage() def process_endpoints(endpoints): newendpoints = {} for point, task in endpoints.items(): tasks = set() if task: tasks |= task if sq_revdeps_squash[point]: tasks |= sq_revdeps_squash[point] if point not in rqdata.runq_setscene_tids: for t in tasks: sq_collated_deps[t].add(point) sq_revdeps_squash[point] = set() if point in rqdata.runq_setscene_tids: sq_revdeps_squash[point] = tasks tasks = set() continue for dep in rqdata.runtaskentries[point].depends: if point in sq_revdeps[dep]: sq_revdeps[dep].remove(point) if tasks: sq_revdeps_squash[dep] |= tasks if len(sq_revdeps[dep]) == 0 and dep not in rqdata.runq_setscene_tids: newendpoints[dep] = task if len(newendpoints) != 0: process_endpoints(newendpoints) process_endpoints(endpoints) rqdata.init_progress_reporter.next_stage() # Build a list of setscene tasks which are "unskippable" # These are direct endpoints referenced by the build # Take the build endpoints (no revdeps) and find the sstate tasks they depend upon new = True for tid in rqdata.runtaskentries: if len(rqdata.runtaskentries[tid].revdeps) == 0: sqdata.unskippable.add(tid) while new: new = False for tid in sqdata.unskippable.copy(): if tid in rqdata.runq_setscene_tids: continue sqdata.unskippable.remove(tid) sqdata.unskippable |= rqdata.runtaskentries[tid].depends new = True rqdata.init_progress_reporter.next_stage(len(rqdata.runtaskentries)) # Sanity check all dependencies could be changed to setscene task references for taskcounter, tid in enumerate(rqdata.runtaskentries): if tid in rqdata.runq_setscene_tids: pass elif len(sq_revdeps_squash[tid]) != 0: bb.msg.fatal("RunQueue", "Something went badly wrong during scenequeue generation, aborting. Please report this problem.") else: del sq_revdeps_squash[tid] rqdata.init_progress_reporter.update(taskcounter) rqdata.init_progress_reporter.next_stage() # Resolve setscene inter-task dependencies # e.g. do_sometask_setscene[depends] = "targetname:do_someothertask_setscene" # Note that anything explicitly depended upon will have its reverse dependencies removed to avoid circular dependencies for tid in rqdata.runq_setscene_tids: (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) realtid = tid + "_setscene" idepends = rqdata.taskData[mc].taskentries[realtid].idepends sqdata.stamps[tid] = bb.build.stampfile(taskname + "_setscene", rqdata.dataCaches[mc], taskfn, noextra=True) for (depname, idependtask) in idepends: if depname not in rqdata.taskData[mc].build_targets: continue depfn = rqdata.taskData[mc].build_targets[depname][0] if depfn is None: continue deptid = depfn + ":" + idependtask.replace("_setscene", "") if deptid not in rqdata.runtaskentries: bb.msg.fatal("RunQueue", "Task %s depends upon non-existent task %s:%s" % (realtid, depfn, idependtask)) if not deptid in sqdata.sq_harddeps: sqdata.sq_harddeps[deptid] = set() sqdata.sq_harddeps[deptid].add(tid) sq_revdeps_squash[tid].add(deptid) # Have to zero this to avoid circular dependencies sq_revdeps_squash[deptid] = set() rqdata.init_progress_reporter.next_stage() for task in sqdata.sq_harddeps: for dep in sqdata.sq_harddeps[task]: sq_revdeps_squash[dep].add(task) rqdata.init_progress_reporter.next_stage() #for tid in sq_revdeps_squash: # data = "" # for dep in sq_revdeps_squash[tid]: # data = data + "\n %s" % dep # bb.warn("Task %s_setscene: is %s " % (tid, data)) sqdata.sq_revdeps = sq_revdeps_squash sqdata.sq_revdeps2 = copy.deepcopy(sqdata.sq_revdeps) sqdata.sq_covered_tasks = sq_collated_deps # Build reverse version of revdeps to populate deps structure for tid in sqdata.sq_revdeps: sqdata.sq_deps[tid] = set() for tid in sqdata.sq_revdeps: for dep in sqdata.sq_revdeps[tid]: sqdata.sq_deps[dep].add(tid) rqdata.init_progress_reporter.next_stage() for tid in sqdata.sq_revdeps: if len(sqdata.sq_revdeps[tid]) == 0: sqrq.sq_buildable.add(tid) rqdata.init_progress_reporter.finish() if rq.hashvalidate: sq_hash = [] sq_hashfn = [] sq_unihash = [] sq_fn = [] sq_taskname = [] sq_task = [] noexec = [] stamppresent = [] for tid in sqdata.sq_revdeps: (mc, fn, taskname, taskfn) = split_tid_mcfn(tid) taskdep = rqdata.dataCaches[mc].task_deps[taskfn] if 'noexec' in taskdep and taskname in taskdep['noexec']: noexec.append(tid) sqrq.sq_task_skip(tid) bb.build.make_stamp(taskname + "_setscene", rqdata.dataCaches[mc], taskfn) continue if rq.check_stamp_task(tid, taskname + "_setscene", cache=stampcache): logger.debug(2, 'Setscene stamp current for task %s', tid) stamppresent.append(tid) sqrq.sq_task_skip(tid) continue if rq.check_stamp_task(tid, taskname, recurse = True, cache=stampcache): logger.debug(2, 'Normal stamp current for task %s', tid) stamppresent.append(tid) sqrq.sq_task_skip(tid) continue sq_fn.append(fn) sq_hashfn.append(rqdata.dataCaches[mc].hashfn[taskfn]) sq_hash.append(rqdata.runtaskentries[tid].hash) sq_unihash.append(rqdata.runtaskentries[tid].unihash) sq_taskname.append(taskname) sq_task.append(tid) cooker.data.setVar("BB_SETSCENE_STAMPCURRENT_COUNT", len(stamppresent)) valid = rq.validate_hash(sq_fn=sq_fn, sq_task=sq_taskname, sq_hash=sq_hash, sq_hashfn=sq_hashfn, siginfo=False, sq_unihash=sq_unihash, d=cooker.data) cooker.data.delVar("BB_SETSCENE_STAMPCURRENT_COUNT") valid_new = stamppresent for v in valid: valid_new.append(sq_task[v]) for tid in sqdata.sq_revdeps: if tid not in valid_new and tid not in noexec: logger.debug(2, 'No package found, so skipping setscene task %s', tid) sqdata.outrightfail.append(tid) def start_runqueue_tasks(rqexec): # Mark initial buildable tasks for tid in rqexec.rqdata.runtaskentries: if len(rqexec.rqdata.runtaskentries[tid].depends) == 0: rqexec.setbuildable(tid) if len(rqexec.rqdata.runtaskentries[tid].revdeps) > 0 and rqexec.rqdata.runtaskentries[tid].revdeps.issubset(rqexec.tasks_covered): rqexec.tasks_covered.add(tid) found = True while found: found = False for tid in rqexec.rqdata.runtaskentries: if tid in rqexec.tasks_covered: continue logger.debug(1, 'Considering %s: %s' % (tid, str(rqexec.rqdata.runtaskentries[tid].revdeps))) if len(rqexec.rqdata.runtaskentries[tid].revdeps) > 0 and rqexec.rqdata.runtaskentries[tid].revdeps.issubset(rqexec.tasks_covered): if tid in rqexec.scenequeue_notcovered: continue found = True rqexec.tasks_covered.add(tid) logger.debug(1, 'Skip list %s', sorted(rqexec.tasks_covered)) for task in self.rq.scenequeue_notcovered: logger.debug(1, 'Not skipping task %s', task) class TaskFailure(Exception): """ Exception raised when a task in a runqueue fails """ def __init__(self, x): self.args = x class runQueueExitWait(bb.event.Event): """ Event when waiting for task processes to exit """ def __init__(self, remain): self.remain = remain self.message = "Waiting for %s active tasks to finish" % remain bb.event.Event.__init__(self) class runQueueEvent(bb.event.Event): """ Base runQueue event class """ def __init__(self, task, stats, rq): self.taskid = task self.taskstring = task self.taskname = taskname_from_tid(task) self.taskfile = fn_from_tid(task) self.taskhash = rq.rqdata.get_task_hash(task) self.stats = stats.copy() bb.event.Event.__init__(self) class sceneQueueEvent(runQueueEvent): """ Base sceneQueue event class """ def __init__(self, task, stats, rq, noexec=False): runQueueEvent.__init__(self, task, stats, rq) self.taskstring = task + "_setscene" self.taskname = taskname_from_tid(task) + "_setscene" self.taskfile = fn_from_tid(task) self.taskhash = rq.rqdata.get_task_hash(task) class runQueueTaskStarted(runQueueEvent): """ Event notifying a task was started """ def __init__(self, task, stats, rq, noexec=False): runQueueEvent.__init__(self, task, stats, rq) self.noexec = noexec class sceneQueueTaskStarted(sceneQueueEvent): """ Event notifying a setscene task was started """ def __init__(self, task, stats, rq, noexec=False): sceneQueueEvent.__init__(self, task, stats, rq) self.noexec = noexec class runQueueTaskFailed(runQueueEvent): """ Event notifying a task failed """ def __init__(self, task, stats, exitcode, rq): runQueueEvent.__init__(self, task, stats, rq) self.exitcode = exitcode def __str__(self): return "Task (%s) failed with exit code '%s'" % (self.taskstring, self.exitcode) class sceneQueueTaskFailed(sceneQueueEvent): """ Event notifying a setscene task failed """ def __init__(self, task, stats, exitcode, rq): sceneQueueEvent.__init__(self, task, stats, rq) self.exitcode = exitcode def __str__(self): return "Setscene task (%s) failed with exit code '%s' - real task will be run instead" % (self.taskstring, self.exitcode) class sceneQueueComplete(sceneQueueEvent): """ Event when all the sceneQueue tasks are complete """ def __init__(self, stats, rq): self.stats = stats.copy() bb.event.Event.__init__(self) class runQueueTaskCompleted(runQueueEvent): """ Event notifying a task completed """ class sceneQueueTaskCompleted(sceneQueueEvent): """ Event notifying a setscene task completed """ class runQueueTaskSkipped(runQueueEvent): """ Event notifying a task was skipped """ def __init__(self, task, stats, rq, reason): runQueueEvent.__init__(self, task, stats, rq) self.reason = reason class runQueuePipe(): """ Abstraction for a pipe between a worker thread and the server """ def __init__(self, pipein, pipeout, d, rq, rqexec): self.input = pipein if pipeout: pipeout.close() bb.utils.nonblockingfd(self.input) self.queue = b"" self.d = d self.rq = rq self.rqexec = rqexec def setrunqueueexec(self, rqexec): self.rqexec = rqexec def read(self): for workers, name in [(self.rq.worker, "Worker"), (self.rq.fakeworker, "Fakeroot")]: for worker in workers.values(): worker.process.poll() if worker.process.returncode is not None and not self.rq.teardown: bb.error("%s process (%s) exited unexpectedly (%s), shutting down..." % (name, worker.process.pid, str(worker.process.returncode))) self.rq.finish_runqueue(True) start = len(self.queue) try: self.queue = self.queue + (self.input.read(102400) or b"") except (OSError, IOError) as e: if e.errno != errno.EAGAIN: raise end = len(self.queue) found = True while found and len(self.queue): found = False index = self.queue.find(b"") while index != -1 and self.queue.startswith(b""): try: event = pickle.loads(self.queue[7:index]) except ValueError as e: bb.msg.fatal("RunQueue", "failed load pickle '%s': '%s'" % (e, self.queue[7:index])) bb.event.fire_from_worker(event, self.d) found = True self.queue = self.queue[index+8:] index = self.queue.find(b"") index = self.queue.find(b"") while index != -1 and self.queue.startswith(b""): try: task, status = pickle.loads(self.queue[10:index]) except ValueError as e: bb.msg.fatal("RunQueue", "failed load pickle '%s': '%s'" % (e, self.queue[10:index])) self.rqexec.runqueue_process_waitpid(task, status) found = True self.queue = self.queue[index+11:] index = self.queue.find(b"") return (end > start) def close(self): while self.read(): continue if len(self.queue) > 0: print("Warning, worker left partial message: %s" % self.queue) self.input.close() def get_setscene_enforce_whitelist(d): if d.getVar('BB_SETSCENE_ENFORCE') != '1': return None whitelist = (d.getVar("BB_SETSCENE_ENFORCE_WHITELIST") or "").split() outlist = [] for item in whitelist[:]: if item.startswith('%:'): for target in sys.argv[1:]: if not target.startswith('-'): outlist.append(target.split(':')[0] + ':' + item.split(':')[1]) else: outlist.append(item) return outlist def check_setscene_enforce_whitelist(pn, taskname, whitelist): import fnmatch if whitelist is not None: item = '%s:%s' % (pn, taskname) for whitelist_item in whitelist: if fnmatch.fnmatch(item, whitelist_item): return True return False return True