# # Copyright (C) 2016-2018 Codethink Limited # # This program is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library. If not, see . # # Authors: # Tristan Van Berkom """ Element - Base element class ============================ .. _core_element_abstract_methods: Abstract Methods ---------------- For loading and configuration purposes, Elements must implement the :ref:`Plugin base class abstract methods `. .. _core_element_build_phase: Build Phase ~~~~~~~~~~~ The following methods are the foundation of the element's *build phase*, they must be implemented by all Element classes, unless explicitly stated otherwise. * :func:`Element.configure_sandbox() ` Configures the :class:`.Sandbox`. This is called before anything else * :func:`Element.stage() ` Stage dependencies and :class:`Sources ` into the sandbox. * :func:`Element.prepare() ` Call preparation methods that should only be performed once in the lifetime of a build directory (e.g. autotools' ./configure). **Optional**: If left unimplemented, this step will be skipped. * :func:`Element.assemble() ` Perform the actual assembly of the element Miscellaneous ~~~~~~~~~~~~~ Miscellaneous abstract methods also exist: * :func:`Element.generate_script() ` For the purpose of ``bst source checkout --include-build-scripts``, an Element may optionally implement this. Class Reference --------------- """ import os import re import stat import copy from collections import OrderedDict import contextlib from contextlib import contextmanager from functools import partial from itertools import chain import tempfile import string from pyroaring import BitMap # pylint: disable=no-name-in-module from . import _yaml from ._variables import Variables from ._versions import BST_CORE_ARTIFACT_VERSION from ._exceptions import BstError, LoadError, LoadErrorReason, ImplError, \ ErrorDomain, SourceCacheError from .utils import UtilError from . import utils from . import _cachekey from . import _signals from . import _site from ._platform import Platform from .plugin import Plugin from .sandbox import SandboxFlags, SandboxCommandError from .sandbox._config import SandboxConfig from .sandbox._sandboxremote import SandboxRemote from .types import Consistency, CoreWarnings, Scope, _KeyStrength, _UniquePriorityQueue from ._artifact import Artifact from .storage.directory import Directory from .storage._filebaseddirectory import FileBasedDirectory from .storage._casbaseddirectory import CasBasedDirectory from .storage.directory import VirtualDirectoryError class ElementError(BstError): """This exception should be raised by :class:`.Element` implementations to report errors to the user. Args: message (str): The error message to report to the user detail (str): A possibly multiline, more detailed error message reason (str): An optional machine readable reason string, used for test cases collect (str): An optional directory containing partial install contents temporary (bool): An indicator to whether the error may occur if the operation was run again. (*Since: 1.2*) """ def __init__(self, message, *, detail=None, reason=None, collect=None, temporary=False): super().__init__(message, detail=detail, domain=ErrorDomain.ELEMENT, reason=reason, temporary=temporary) self.collect = collect class Element(Plugin): """Element() Base Element class. All elements derive from this class, this interface defines how the core will be interacting with Elements. """ __defaults = None # The defaults from the yaml file and project __instantiated_elements = {} # A hash of Element by MetaElement __redundant_source_refs = [] # A list of (source, ref) tuples which were redundantly specified BST_ARTIFACT_VERSION = 0 """The element plugin's artifact version Elements must first set this to 1 if they change their unique key structure in a way that would produce a different key for the same input, or introduce a change in the build output for the same unique key. Further changes of this nature require bumping the artifact version. """ BST_STRICT_REBUILD = False """Whether to rebuild this element in non strict mode if any of the dependencies have changed. """ BST_FORBID_RDEPENDS = False """Whether to raise exceptions if an element has runtime dependencies. *Since: 1.2* """ BST_FORBID_BDEPENDS = False """Whether to raise exceptions if an element has build dependencies. *Since: 1.2* """ BST_FORBID_SOURCES = False """Whether to raise exceptions if an element has sources. *Since: 1.2* """ BST_VIRTUAL_DIRECTORY = False """Whether to raise exceptions if an element uses Sandbox.get_directory instead of Sandbox.get_virtual_directory. *Since: 1.4* """ BST_RUN_COMMANDS = True """Whether the element may run commands using Sandbox.run. *Since: 1.4* """ def __init__(self, context, project, meta, plugin_conf): self.__cache_key_dict = None # Dict for cache key calculation self.__cache_key = None # Our cached cache key super().__init__(meta.name, context, project, meta.provenance, "element") # Ensure the project is fully loaded here rather than later on if not meta.is_junction: project.ensure_fully_loaded() self.normal_name = _get_normal_name(self.name) """A normalized element name This is the original element without path separators or the extension, it's used mainly for composing log file names and creating directory names and such. """ self.__runtime_dependencies = [] # Direct runtime dependency Elements self.__build_dependencies = [] # Direct build dependency Elements self.__reverse_build_deps = set() # Direct reverse build dependency Elements self.__reverse_runtime_deps = set() # Direct reverse runtime dependency Elements self.__remaining_build_deps_uncached = None # Built dependencies which are not yet cached self.__remaining_runtime_deps_uncached = None # Runtime dependencies which are not yet cached self.__ready_for_runtime = False # Whether the element has all dependencies ready and has a cache key self.__ready_for_runtime_and_cached = False # Whether all runtime deps are cached, as well as the element self.__sources = [] # List of Sources self.__weak_cache_key = None # Our cached weak cache key self.__strict_cache_key = None # Our cached cache key for strict builds self.__artifacts = context.artifactcache # Artifact cache self.__sourcecache = context.sourcecache # Source cache self.__consistency = Consistency.INCONSISTENT # Cached overall consistency state self.__assemble_scheduled = False # Element is scheduled to be assembled self.__assemble_done = False # Element is assembled self.__tracking_scheduled = False # Sources are scheduled to be tracked self.__tracking_done = False # Sources have been tracked self.__pull_done = False # Whether pull was attempted self.__splits = None # Resolved regex objects for computing split domains self.__whitelist_regex = None # Resolved regex object to check if file is allowed to overlap self.__staged_sources_directory = None # Location where Element.stage_sources() was called self.__tainted = None # Whether the artifact is tainted and should not be shared self.__required = False # Whether the artifact is required in the current session self.__artifact_files_required = False # Whether artifact files are required in the local cache self.__build_result = None # The result of assembling this Element (success, description, detail) self._build_log_path = None # The path of the build log for this Element self.__artifact = None # Artifact class for direct artifact composite interaction self.__strict_artifact = None # Artifact for strict cache key # the index of the last source in this element that requires previous # sources for staging self.__last_source_requires_previous_ix = None self.__batch_prepare_assemble = False # Whether batching across prepare()/assemble() is configured self.__batch_prepare_assemble_flags = 0 # Sandbox flags for batching across prepare()/assemble() self.__batch_prepare_assemble_collect = None # Collect dir for batching across prepare()/assemble() # Callbacks self.__required_callback = None # Callback to Queues self.__can_query_cache_callback = None # Callback to PullQueue/FetchQueue self.__buildable_callback = None # Callback to BuildQueue self._depth = None # Depth of Element in its current dependency graph # Ensure we have loaded this class's defaults self.__init_defaults(project, plugin_conf, meta.kind, meta.is_junction) # Collect the composited variables and resolve them variables = self.__extract_variables(project, meta) variables['element-name'] = self.name self.__variables = Variables(variables) # Collect the composited environment now that we have variables unexpanded_env = self.__extract_environment(project, meta) self.__environment = self.__expand_environment(unexpanded_env) # Collect the environment nocache blacklist list nocache = self.__extract_env_nocache(project, meta) self.__env_nocache = nocache # Grab public domain data declared for this instance unexpanded_public = self.__extract_public(meta) self.__public = self.__expand_splits(unexpanded_public) self.__dynamic_public = None # Collect the composited element configuration and # ask the element to configure itself. self.__config = self.__extract_config(meta) self._configure(self.__config) # Extract remote execution URL if meta.is_junction: self.__remote_execution_specs = None else: self.__remote_execution_specs = project.remote_execution_specs # Extract Sandbox config self.__sandbox_config = self.__extract_sandbox_config(project, meta) self.__sandbox_config_supported = True if not self.__use_remote_execution(): platform = Platform.get_platform() if not platform.check_sandbox_config(self.__sandbox_config): # Local sandbox does not fully support specified sandbox config. # This will taint the artifact, disable pushing. self.__sandbox_config_supported = False def __lt__(self, other): return self.name < other.name ############################################################# # Abstract Methods # ############################################################# def configure_sandbox(self, sandbox): """Configures the the sandbox for execution Args: sandbox (:class:`.Sandbox`): The build sandbox Raises: (:class:`.ElementError`): When the element raises an error Elements must implement this method to configure the sandbox object for execution. """ raise ImplError("element plugin '{kind}' does not implement configure_sandbox()".format( kind=self.get_kind())) def stage(self, sandbox): """Stage inputs into the sandbox directories Args: sandbox (:class:`.Sandbox`): The build sandbox Raises: (:class:`.ElementError`): When the element raises an error Elements must implement this method to populate the sandbox directory with data. This is done either by staging :class:`.Source` objects, by staging the artifacts of the elements this element depends on, or both. """ raise ImplError("element plugin '{kind}' does not implement stage()".format( kind=self.get_kind())) def prepare(self, sandbox): """Run one-off preparation commands. This is run before assemble(), but is guaranteed to run only the first time if we build incrementally - this makes it possible to run configure-like commands without causing the entire element to rebuild. Args: sandbox (:class:`.Sandbox`): The build sandbox Raises: (:class:`.ElementError`): When the element raises an error By default, this method does nothing, but may be overriden to allow configure-like commands. *Since: 1.2* """ def assemble(self, sandbox): """Assemble the output artifact Args: sandbox (:class:`.Sandbox`): The build sandbox Returns: (str): An absolute path within the sandbox to collect the artifact from Raises: (:class:`.ElementError`): When the element raises an error Elements must implement this method to create an output artifact from its sources and dependencies. """ raise ImplError("element plugin '{kind}' does not implement assemble()".format( kind=self.get_kind())) def generate_script(self): """Generate a build (sh) script to build this element Returns: (str): A string containing the shell commands required to build the element BuildStream guarantees the following environment when the generated script is run: - All element variables have been exported. - The cwd is `self.get_variable('build-root')/self.normal_name`. - $PREFIX is set to `self.get_variable('install-root')`. - The directory indicated by $PREFIX is an empty directory. Files are expected to be installed to $PREFIX. If the script fails, it is expected to return with an exit code != 0. """ raise ImplError("element plugin '{kind}' does not implement write_script()".format( kind=self.get_kind())) ############################################################# # Public Methods # ############################################################# def sources(self): """A generator function to enumerate the element sources Yields: (:class:`.Source`): The sources of this element """ for source in self.__sources: yield source def dependencies(self, scope, *, recurse=True, visited=None): """dependencies(scope, *, recurse=True) A generator function which yields the dependencies of the given element. If `recurse` is specified (the default), the full dependencies will be listed in deterministic staging order, starting with the basemost elements in the given `scope`. Otherwise, if `recurse` is not specified then only the direct dependencies in the given `scope` will be traversed, and the element itself will be omitted. Args: scope (:class:`.Scope`): The scope to iterate in recurse (bool): Whether to recurse Yields: (:class:`.Element`): The dependencies in `scope`, in deterministic staging order """ # The format of visited is (BitMap(), BitMap()), with the first BitMap # containing element that have been visited for the `Scope.BUILD` case # and the second one relating to the `Scope.RUN` case. if not recurse: if scope in (Scope.BUILD, Scope.ALL): yield from self.__build_dependencies if scope in (Scope.RUN, Scope.ALL): yield from self.__runtime_dependencies else: def visit(element, scope, visited): if scope == Scope.ALL: visited[0].add(element._unique_id) visited[1].add(element._unique_id) for dep in chain(element.__build_dependencies, element.__runtime_dependencies): if dep._unique_id not in visited[0] and dep._unique_id not in visited[1]: yield from visit(dep, Scope.ALL, visited) yield element elif scope == Scope.BUILD: visited[0].add(element._unique_id) for dep in element.__build_dependencies: if dep._unique_id not in visited[1]: yield from visit(dep, Scope.RUN, visited) elif scope == Scope.RUN: visited[1].add(element._unique_id) for dep in element.__runtime_dependencies: if dep._unique_id not in visited[1]: yield from visit(dep, Scope.RUN, visited) yield element else: yield element if visited is None: # Visited is of the form (Visited for Scope.BUILD, Visited for Scope.RUN) visited = (BitMap(), BitMap()) else: # We have already a visited set passed. we might be able to short-circuit if scope in (Scope.BUILD, Scope.ALL) and self._unique_id in visited[0]: return if scope in (Scope.RUN, Scope.ALL) and self._unique_id in visited[1]: return yield from visit(self, scope, visited) def search(self, scope, name): """Search for a dependency by name Args: scope (:class:`.Scope`): The scope to search name (str): The dependency to search for Returns: (:class:`.Element`): The dependency element, or None if not found. """ for dep in self.dependencies(scope): if dep.name == name: return dep return None def substitute_variables(self, value): return self.__variables.subst(value) def node_subst_member(self, node, member_name, default=_yaml._sentinel): """Fetch the value of a string node member, substituting any variables in the loaded value with the element contextual variables. Args: node (dict): A dictionary loaded from YAML member_name (str): The name of the member to fetch default (str): A value to return when *member_name* is not specified in *node* Returns: The value of *member_name* in *node*, otherwise *default* Raises: :class:`.LoadError`: When *member_name* is not found and no *default* was provided **Example:** .. code:: python # Expect a string 'name' in 'node', substituting any # variables in the returned string name = self.node_subst_member(node, 'name') """ value = node.get_str(member_name, default) try: return self.__variables.subst(value) except LoadError as e: provenance = _yaml.node_get_provenance(node, key=member_name) raise LoadError(e.reason, '{}: {}'.format(provenance, e), detail=e.detail) from e def node_subst_list(self, node, member_name): """Fetch a list from a node member, substituting any variables in the list Args: node (dict): A dictionary loaded from YAML member_name (str): The name of the member to fetch (a list) Returns: The list in *member_name* Raises: :class:`.LoadError` """ ret = [] for value in node.get_sequence(member_name): try: ret.append(self.__variables.subst(value.as_str())) except LoadError as e: provenance = _yaml.node_get_provenance(value) raise LoadError(e.reason, '{}: {}'.format(provenance, e), detail=e.detail) from e return ret def compute_manifest(self, *, include=None, exclude=None, orphans=True): """Compute and return this element's selective manifest The manifest consists on the list of file paths in the artifact. The files in the manifest are selected according to `include`, `exclude` and `orphans` parameters. If `include` is not specified then all files spoken for by any domain are included unless explicitly excluded with an `exclude` domain. Args: include (list): An optional list of domains to include files from exclude (list): An optional list of domains to exclude files from orphans (bool): Whether to include files not spoken for by split domains Yields: (str): The paths of the files in manifest """ self.__assert_cached() return self.__compute_splits(include, exclude, orphans) def get_artifact_name(self, key=None): """Compute and return this element's full artifact name Generate a full name for an artifact, including the project namespace, element name and cache key. This can also be used as a relative path safely, and will normalize parts of the element name such that only digits, letters and some select characters are allowed. Args: key (str): The element's cache key. Defaults to None Returns: (str): The relative path for the artifact """ project = self._get_project() if key is None: key = self._get_cache_key() assert key is not None return _compose_artifact_name(project.name, self.normal_name, key) def stage_artifact(self, sandbox, *, path=None, include=None, exclude=None, orphans=True, update_mtimes=None): """Stage this element's output artifact in the sandbox This will stage the files from the artifact to the sandbox at specified location. The files are selected for staging according to the `include`, `exclude` and `orphans` parameters; if `include` is not specified then all files spoken for by any domain are included unless explicitly excluded with an `exclude` domain. Args: sandbox (:class:`.Sandbox`): The build sandbox path (str): An optional sandbox relative path include (list): An optional list of domains to include files from exclude (list): An optional list of domains to exclude files from orphans (bool): Whether to include files not spoken for by split domains update_mtimes (list): An optional list of files whose mtimes to set to the current time. Raises: (:class:`.ElementError`): If the element has not yet produced an artifact. Returns: (:class:`~.utils.FileListResult`): The result describing what happened while staging .. note:: Directories in `dest` are replaced with files from `src`, unless the existing directory in `dest` is not empty in which case the path will be reported in the return value. **Example:** .. code:: python # Stage the dependencies for a build of 'self' for dep in self.dependencies(Scope.BUILD): dep.stage_artifact(sandbox) """ if not self._cached(): detail = "No artifacts have been cached yet for that element\n" + \ "Try building the element first with `bst build`\n" raise ElementError("No artifacts to stage", detail=detail, reason="uncached-checkout-attempt") if update_mtimes is None: update_mtimes = [] # Time to use the artifact, check once more that it's there self.__assert_cached() with self.timed_activity("Staging {}/{}".format(self.name, self._get_brief_display_key())): files_vdir = self.__artifact.get_files() # Hard link it into the staging area # vbasedir = sandbox.get_virtual_directory() vstagedir = vbasedir \ if path is None \ else vbasedir.descend(*path.lstrip(os.sep).split(os.sep)) split_filter = self.__split_filter_func(include, exclude, orphans) # We must not hardlink files whose mtimes we want to update if update_mtimes: def link_filter(path): return ((split_filter is None or split_filter(path)) and path not in update_mtimes) def copy_filter(path): return ((split_filter is None or split_filter(path)) and path in update_mtimes) else: link_filter = split_filter result = vstagedir.import_files(files_vdir, filter_callback=link_filter, report_written=True, can_link=True) if update_mtimes: copy_result = vstagedir.import_files(files_vdir, filter_callback=copy_filter, report_written=True, update_mtime=True) result = result.combine(copy_result) return result def stage_dependency_artifacts(self, sandbox, scope, *, path=None, include=None, exclude=None, orphans=True): """Stage element dependencies in scope This is primarily a convenience wrapper around :func:`Element.stage_artifact() ` which takes care of staging all the dependencies in `scope` and issueing the appropriate warnings. Args: sandbox (:class:`.Sandbox`): The build sandbox scope (:class:`.Scope`): The scope to stage dependencies in path (str): An optional sandbox relative path include (list): An optional list of domains to include files from exclude (list): An optional list of domains to exclude files from orphans (bool): Whether to include files not spoken for by split domains Raises: (:class:`.ElementError`): If any of the dependencies in `scope` have not yet produced artifacts, or if forbidden overlaps occur. """ ignored = {} overlaps = OrderedDict() files_written = {} old_dep_keys = None workspace = self._get_workspace() context = self._get_context() if self.__can_build_incrementally() and workspace.last_successful: # Try to perform an incremental build if the last successful # build is still in the artifact cache # if self.__artifacts.contains(self, workspace.last_successful): last_successful = Artifact(self, context, strong_key=workspace.last_successful) # Get a dict of dependency strong keys old_dep_keys = last_successful.get_metadata_dependencies() else: # Last successful build is no longer in the artifact cache, # so let's reset it and perform a full build now. workspace.prepared = False workspace.last_successful = None self.info("Resetting workspace state, last successful build is no longer in the cache") # In case we are staging in the main process if utils._is_main_process(): context.get_workspaces().save_config() for dep in self.dependencies(scope): # If we are workspaced, and we therefore perform an # incremental build, we must ensure that we update the mtimes # of any files created by our dependencies since the last # successful build. to_update = None if workspace and old_dep_keys: dep.__assert_cached() if dep.name in old_dep_keys: key_new = dep._get_cache_key() key_old = old_dep_keys[dep.name] # We only need to worry about modified and added # files, since removed files will be picked up by # build systems anyway. to_update, _, added = self.__artifacts.diff(dep, key_old, key_new) workspace.add_running_files(dep.name, to_update + added) to_update.extend(workspace.running_files[dep.name]) # In case we are running `bst shell`, this happens in the # main process and we need to update the workspace config if utils._is_main_process(): context.get_workspaces().save_config() result = dep.stage_artifact(sandbox, path=path, include=include, exclude=exclude, orphans=orphans, update_mtimes=to_update) if result.overwritten: for overwrite in result.overwritten: # Completely new overwrite if overwrite not in overlaps: # Find the overwritten element by checking where we've # written the element before for elm, contents in files_written.items(): if overwrite in contents: overlaps[overwrite] = [elm, dep.name] else: overlaps[overwrite].append(dep.name) files_written[dep.name] = result.files_written if result.ignored: ignored[dep.name] = result.ignored if overlaps: overlap_warning = False warning_detail = "Staged files overwrite existing files in staging area:\n" for f, elements in overlaps.items(): overlap_warning_elements = [] # The bottom item overlaps nothing overlapping_elements = elements[1:] for elm in overlapping_elements: element = self.search(scope, elm) if not element.__file_is_whitelisted(f): overlap_warning_elements.append(elm) overlap_warning = True warning_detail += _overlap_error_detail(f, overlap_warning_elements, elements) if overlap_warning: self.warn("Non-whitelisted overlaps detected", detail=warning_detail, warning_token=CoreWarnings.OVERLAPS) if ignored: detail = "Not staging files which would replace non-empty directories:\n" for key, value in ignored.items(): detail += "\nFrom {}:\n".format(key) detail += " " + " ".join(["/" + f + "\n" for f in value]) self.warn("Ignored files", detail=detail) def integrate(self, sandbox): """Integrate currently staged filesystem against this artifact. Args: sandbox (:class:`.Sandbox`): The build sandbox This modifies the sysroot staged inside the sandbox so that the sysroot is *integrated*. Only an *integrated* sandbox may be trusted for running the software therein, as the integration commands will create and update important system cache files required for running the installed software (such as the ld.so.cache). """ bstdata = self.get_public_data('bst') environment = self.get_environment() if bstdata is not None: with sandbox.batch(SandboxFlags.NONE): commands = bstdata.get_sequence('integration-commands', []).as_str_list() for command in commands: cmd = self.substitute_variables(command) sandbox.run(['sh', '-e', '-c', cmd], 0, env=environment, cwd='/', label=cmd) def stage_sources(self, sandbox, directory): """Stage this element's sources to a directory in the sandbox Args: sandbox (:class:`.Sandbox`): The build sandbox directory (str): An absolute path within the sandbox to stage the sources at """ # Hold on to the location where a plugin decided to stage sources, # this will be used to reconstruct the failed sysroot properly # after a failed build. # assert self.__staged_sources_directory is None self.__staged_sources_directory = directory self._stage_sources_in_sandbox(sandbox, directory) def get_public_data(self, domain): """Fetch public data on this element Args: domain (str): A public domain name to fetch data for Returns: (dict): The public data dictionary for the given domain .. note:: This can only be called the abstract methods which are called as a part of the :ref:`build phase ` and never before. """ if self.__dynamic_public is None: self.__load_public_data() data = self.__dynamic_public.get_mapping(domain, default=None) if data is not None: data = data.copy() return data def set_public_data(self, domain, data): """Set public data on this element Args: domain (str): A public domain name to fetch data for data (dict): The public data dictionary for the given domain This allows an element to dynamically mutate public data of elements or add new domains as the result of success completion of the :func:`Element.assemble() ` method. """ if self.__dynamic_public is None: self.__load_public_data() if data is not None: data = data.copy() self.__dynamic_public[domain] = data def get_environment(self): """Fetch the environment suitable for running in the sandbox Returns: (dict): A dictionary of string key/values suitable for passing to :func:`Sandbox.run() ` """ return self.__environment def get_variable(self, varname): """Fetch the value of a variable resolved for this element. Args: varname (str): The name of the variable to fetch Returns: (str): The resolved value for *varname*, or None if no variable was declared with the given name. """ # Flat is not recognized correctly by Pylint as being a dictionary return self.__variables.flat.get(varname) # pylint: disable=no-member def batch_prepare_assemble(self, flags, *, collect=None): """ Configure command batching across prepare() and assemble() Args: flags (:class:`.SandboxFlags`): The sandbox flags for the command batch collect (str): An optional directory containing partial install contents on command failure. This may be called in :func:`Element.configure_sandbox() ` to enable batching of all sandbox commands issued in prepare() and assemble(). """ if self.__batch_prepare_assemble: raise ElementError("{}: Command batching for prepare/assemble is already configured".format(self)) self.__batch_prepare_assemble = True self.__batch_prepare_assemble_flags = flags self.__batch_prepare_assemble_collect = collect ############################################################# # Private Methods used in BuildStream # ############################################################# # _new_from_meta(): # # Recursively instantiate a new Element instance, its sources # and its dependencies from a meta element. # # Args: # meta (MetaElement): The meta element # # Returns: # (Element): A newly created Element instance # @classmethod def _new_from_meta(cls, meta): if not meta.first_pass: meta.project.ensure_fully_loaded() if meta in cls.__instantiated_elements: return cls.__instantiated_elements[meta] element = meta.project.create_element(meta, first_pass=meta.first_pass) cls.__instantiated_elements[meta] = element # Instantiate sources and generate their keys for meta_source in meta.sources: meta_source.first_pass = meta.is_junction source = meta.project.create_source(meta_source, first_pass=meta.first_pass) redundant_ref = source._load_ref() element.__sources.append(source) # Collect redundant refs which occurred at load time if redundant_ref is not None: cls.__redundant_source_refs.append((source, redundant_ref)) # Instantiate dependencies for meta_dep in meta.dependencies: dependency = Element._new_from_meta(meta_dep) element.__runtime_dependencies.append(dependency) dependency.__reverse_runtime_deps.add(element) element.__remaining_runtime_deps_uncached = len(element.__runtime_dependencies) for meta_dep in meta.build_dependencies: dependency = Element._new_from_meta(meta_dep) element.__build_dependencies.append(dependency) dependency.__reverse_build_deps.add(element) element.__remaining_build_deps_uncached = len(element.__build_dependencies) return element # _clear_meta_elements_cache() # # Clear the internal meta elements cache. # # When loading elements from meta, we cache already instantiated elements # in order to not have to load the same elements twice. # This clears the cache. # # It should be called whenever we are done loading all elements in order # to save memory. # @classmethod def _clear_meta_elements_cache(cls): cls.__instantiated_elements = {} # _get_redundant_source_refs() # # Fetches a list of (Source, ref) tuples of all the Sources # which were loaded with a ref specified in the element declaration # for projects which use project.refs ref-storage. # # This is used to produce a warning @classmethod def _get_redundant_source_refs(cls): return cls.__redundant_source_refs # _reset_load_state() # # This is called by Pipeline.cleanup() and is used to # reset the loader state between multiple sessions. # @classmethod def _reset_load_state(cls): cls.__instantiated_elements = {} cls.__redundant_source_refs = [] # _get_consistency() # # Returns cached consistency state # def _get_consistency(self): return self.__consistency # _cached(): # # Returns: # (bool): Whether this element is already present in # the artifact cache # def _cached(self): if not self.__artifact: return False return self.__artifact.cached() # _get_build_result(): # # Returns: # (bool): Whether the artifact of this element present in the artifact cache is of a success # (str): Short description of the result # (str): Detailed description of the result # def _get_build_result(self): if self.__build_result is None: self.__load_build_result() return self.__build_result # __set_build_result(): # # Sets the assembly result # # Args: # success (bool): Whether the result is a success # description (str): Short description of the result # detail (str): Detailed description of the result # def __set_build_result(self, success, description, detail=None): self.__build_result = (success, description, detail) # _cached_success(): # # Returns: # (bool): Whether this element is already present in # the artifact cache and the element assembled successfully # def _cached_success(self): if not self._cached(): return False success, _, _ = self._get_build_result() return success # _cached_failure(): # # Returns: # (bool): Whether this element is already present in # the artifact cache and the element did not assemble successfully # def _cached_failure(self): if not self._cached(): return False success, _, _ = self._get_build_result() return not success # _buildable(): # # Returns: # (bool): Whether this element can currently be built # def _buildable(self): if self._get_consistency() < Consistency.CACHED and \ not self._source_cached(): return False if not self.__assemble_scheduled: return False return self.__remaining_build_deps_uncached == 0 # _get_cache_key(): # # Returns the cache key # # Args: # strength (_KeyStrength): Either STRONG or WEAK key strength # # Returns: # (str): A hex digest cache key for this Element, or None # # None is returned if information for the cache key is missing. # def _get_cache_key(self, strength=_KeyStrength.STRONG): if strength == _KeyStrength.STRONG: return self.__cache_key else: return self.__weak_cache_key # _can_query_cache(): # # Returns whether the cache key required for cache queries is available. # # Returns: # (bool): True if cache can be queried # def _can_query_cache(self): # If build has already been scheduled, we know that the element is # not cached and thus can allow cache query even if the strict cache key # is not available yet. # This special case is required for workspaced elements to prevent # them from getting blocked in the pull queue. if self.__assemble_scheduled: return True # cache cannot be queried until strict cache key is available return self.__strict_cache_key is not None # _update_state() # # Keep track of element state. Calculate cache keys if possible and # check whether artifacts are cached. # # This must be called whenever the state of an element may have changed. # def _update_state(self): context = self._get_context() # Compute and determine consistency of sources self.__update_source_state() if self._get_consistency() == Consistency.INCONSISTENT: # Tracking may still be pending return if self._get_workspace() and self.__assemble_scheduled: # If we have an active workspace and are going to build, then # discard current cache key values and invoke the buildable callback. # The correct keys can only be calculated once the build is complete self.__reset_cache_data() return self.__update_cache_keys() self.__update_artifact_state() # Workspaced sources are considered unstable if a build is pending # as the build will modify the contents of the workspace. # Determine as early as possible if a build is pending to discard # unstable cache keys. # Also, uncached workspaced elements must be assembled so we can know # the cache key. if (not self.__assemble_scheduled and not self.__assemble_done and self.__artifact and (self._is_required() or self._get_workspace()) and not self._cached_success() and not self._pull_pending()): self._schedule_assemble() # If a build has been scheduled, we know that the element # is not cached and can allow cache query even if the strict cache # key is not available yet. if self.__can_query_cache_callback is not None: self.__can_query_cache_callback(self) self.__can_query_cache_callback = None return if not context.get_strict(): self.__update_cache_key_non_strict() if not self.__ready_for_runtime and self.__cache_key is not None: self.__ready_for_runtime = all( dep.__ready_for_runtime for dep in self.__runtime_dependencies) # _get_display_key(): # # Returns cache keys for display purposes # # Returns: # (str): A full hex digest cache key for this Element # (str): An abbreviated hex digest cache key for this Element # (bool): True if key should be shown as dim, False otherwise # # Question marks are returned if information for the cache key is missing. # def _get_display_key(self): context = self._get_context() dim_key = True cache_key = self._get_cache_key() if not cache_key: cache_key = "{:?<64}".format('') elif self._get_cache_key() == self.__strict_cache_key: # Strong cache key used in this session matches cache key # that would be used in strict build mode dim_key = False length = min(len(cache_key), context.log_key_length) return (cache_key, cache_key[0:length], dim_key) # _get_brief_display_key() # # Returns an abbreviated cache key for display purposes # # Returns: # (str): An abbreviated hex digest cache key for this Element # # Question marks are returned if information for the cache key is missing. # def _get_brief_display_key(self): _, display_key, _ = self._get_display_key() return display_key # _preflight(): # # A wrapper for calling the abstract preflight() method on # the element and its sources. # def _preflight(self): if self.BST_FORBID_RDEPENDS and self.BST_FORBID_BDEPENDS: if any(self.dependencies(Scope.RUN, recurse=False)) or any(self.dependencies(Scope.BUILD, recurse=False)): raise ElementError("{}: Dependencies are forbidden for '{}' elements" .format(self, self.get_kind()), reason="element-forbidden-depends") if self.BST_FORBID_RDEPENDS: if any(self.dependencies(Scope.RUN, recurse=False)): raise ElementError("{}: Runtime dependencies are forbidden for '{}' elements" .format(self, self.get_kind()), reason="element-forbidden-rdepends") if self.BST_FORBID_BDEPENDS: if any(self.dependencies(Scope.BUILD, recurse=False)): raise ElementError("{}: Build dependencies are forbidden for '{}' elements" .format(self, self.get_kind()), reason="element-forbidden-bdepends") if self.BST_FORBID_SOURCES: if any(self.sources()): raise ElementError("{}: Sources are forbidden for '{}' elements" .format(self, self.get_kind()), reason="element-forbidden-sources") try: self.preflight() except BstError as e: # Prepend provenance to the error raise ElementError("{}: {}".format(self, e), reason=e.reason, detail=e.detail) from e # Ensure that the first source does not need access to previous soruces if self.__sources and self.__sources[0]._requires_previous_sources(): raise ElementError("{}: {} cannot be the first source of an element " "as it requires access to previous sources" .format(self, self.__sources[0])) # Preflight the sources for source in self.sources(): source._preflight() # _schedule_tracking(): # # Force an element state to be inconsistent. Any sources appear to be # inconsistent. # # This is used across the pipeline in sessions where the # elements in question are going to be tracked, causing the # pipeline to rebuild safely by ensuring cache key recalculation # and reinterrogation of element state after tracking of elements # succeeds. # def _schedule_tracking(self): self.__tracking_scheduled = True # _tracking_done(): # # This is called in the main process after the element has been tracked # def _tracking_done(self): assert self.__tracking_scheduled self.__tracking_scheduled = False self.__tracking_done = True self.__update_state_recursively() # _track(): # # Calls track() on the Element sources # # Raises: # SourceError: If one of the element sources has an error # # Returns: # (list): A list of Source object ids and their new references # def _track(self): refs = [] for index, source in enumerate(self.__sources): old_ref = source.get_ref() new_ref = source._track(self.__sources[0:index]) refs.append((source._unique_id, new_ref)) # Complimentary warning that the new ref will be unused. if old_ref != new_ref and self._get_workspace(): detail = "This source has an open workspace.\n" \ + "To start using the new reference, please close the existing workspace." source.warn("Updated reference will be ignored as source has open workspace", detail=detail) return refs # _prepare_sandbox(): # # This stages things for either _shell() (below) or also # is used to stage things by the `bst artifact checkout` codepath # @contextmanager def _prepare_sandbox(self, scope, directory, shell=False, integrate=True, usebuildtree=False): # bst shell and bst artifact checkout require a local sandbox. bare_directory = bool(directory) with self.__sandbox(directory, config=self.__sandbox_config, allow_remote=False, bare_directory=bare_directory) as sandbox: sandbox._usebuildtree = usebuildtree # Configure always comes first, and we need it. self.__configure_sandbox(sandbox) # Stage something if we need it if not directory: if shell and scope == Scope.BUILD: self.stage(sandbox) else: # Stage deps in the sandbox root with self.timed_activity("Staging dependencies", silent_nested=True): self.stage_dependency_artifacts(sandbox, scope) # Run any integration commands provided by the dependencies # once they are all staged and ready if integrate: with self.timed_activity("Integrating sandbox"): for dep in self.dependencies(scope): dep.integrate(sandbox) yield sandbox # _stage_sources_in_sandbox(): # # Stage this element's sources to a directory inside sandbox # # Args: # sandbox (:class:`.Sandbox`): The build sandbox # directory (str): An absolute path to stage the sources at # mount_workspaces (bool): mount workspaces if True, copy otherwise # def _stage_sources_in_sandbox(self, sandbox, directory, mount_workspaces=True): # Only artifact caches that implement diff() are allowed to # perform incremental builds. if mount_workspaces and self.__can_build_incrementally(): workspace = self._get_workspace() sandbox.mark_directory(directory) sandbox._set_mount_source(directory, workspace.get_absolute_path()) # Stage all sources that need to be copied sandbox_vroot = sandbox.get_virtual_directory() host_vdirectory = sandbox_vroot.descend(*directory.lstrip(os.sep).split(os.sep), create=True) self._stage_sources_at(host_vdirectory, mount_workspaces=mount_workspaces, usebuildtree=sandbox._usebuildtree) # _stage_sources_at(): # # Stage this element's sources to a directory # # Args: # vdirectory (:class:`.storage.Directory`): A virtual directory object to stage sources into. # mount_workspaces (bool): mount workspaces if True, copy otherwise # usebuildtree (bool): use a the elements build tree as its source. # def _stage_sources_at(self, vdirectory, mount_workspaces=True, usebuildtree=False): context = self._get_context() # It's advantageous to have this temporary directory on # the same file system as the rest of our cache. with self.timed_activity("Staging sources", silent_nested=True), \ utils._tempdir(dir=context.tmpdir, prefix='staging-temp') as temp_staging_directory: import_dir = temp_staging_directory if not isinstance(vdirectory, Directory): vdirectory = FileBasedDirectory(vdirectory) if not vdirectory.is_empty(): raise ElementError("Staging directory '{}' is not empty".format(vdirectory)) workspace = self._get_workspace() if workspace: # If mount_workspaces is set and we're doing incremental builds, # the workspace is already mounted into the sandbox. if not (mount_workspaces and self.__can_build_incrementally()): with self.timed_activity("Staging local files at {}" .format(workspace.get_absolute_path())): workspace.stage(import_dir) # Check if we have a cached buildtree to use elif usebuildtree: import_dir = self.__artifact.get_buildtree() if import_dir.is_empty(): detail = "Element type either does not expect a buildtree or it was explictily cached without one." self.warn("WARNING: {} Artifact contains an empty buildtree".format(self.name), detail=detail) # No workspace or cached buildtree, stage source from source cache else: # Ensure sources are cached self.__cache_sources() if self.__sources: sourcecache = context.sourcecache # find last required source last_required_previous_ix = self.__last_source_requires_previous() import_dir = CasBasedDirectory(context.get_cascache()) try: for source in self.__sources[last_required_previous_ix:]: source_dir = sourcecache.export(source) import_dir.import_files(source_dir) except SourceCacheError as e: raise ElementError("Error trying to export source for {}: {}" .format(self.name, e)) except VirtualDirectoryError as e: raise ElementError("Error trying to import sources together for {}: {}" .format(self.name, e), reason="import-source-files-fail") with utils._deterministic_umask(): vdirectory.import_files(import_dir) # Ensure deterministic mtime of sources at build time vdirectory.set_deterministic_mtime() # Ensure deterministic owners of sources at build time vdirectory.set_deterministic_user() # _set_required(): # # Mark this element and its runtime dependencies as required. # This unblocks pull/fetch/build. # def _set_required(self): if self.__required: # Already done return self.__required = True # Request artifacts of runtime dependencies for dep in self.dependencies(Scope.RUN, recurse=False): dep._set_required() self._update_state() # Callback to the Queue if self.__required_callback is not None: self.__required_callback(self) self.__required_callback = None # _is_required(): # # Returns whether this element has been marked as required. # def _is_required(self): return self.__required # _set_artifact_files_required(): # # Mark artifact files for this element and its runtime dependencies as # required in the local cache. # def _set_artifact_files_required(self): if self.__artifact_files_required: # Already done return self.__artifact_files_required = True # Request artifact files of runtime dependencies for dep in self.dependencies(Scope.RUN, recurse=False): dep._set_artifact_files_required() # _artifact_files_required(): # # Returns whether artifact files for this element have been marked as required. # def _artifact_files_required(self): return self.__artifact_files_required # _schedule_assemble(): # # This is called in the main process before the element is assembled # in a subprocess. # def _schedule_assemble(self): assert not self.__assemble_scheduled self.__assemble_scheduled = True # Requests artifacts of build dependencies for dep in self.dependencies(Scope.BUILD, recurse=False): dep._set_required() self._set_required() # Invalidate workspace key as the build modifies the workspace directory workspace = self._get_workspace() if workspace: workspace.invalidate_key() self._update_state() # _assemble_done(): # # This is called in the main process after the element has been assembled # and in the a subprocess after assembly completes. # # This will result in updating the element state. # def _assemble_done(self): assert self.__assemble_scheduled self.__assemble_scheduled = False self.__assemble_done = True # Artifact may have a cached success now. if self.__strict_artifact: self.__strict_artifact.reset_cached() if self.__artifact: self.__artifact.reset_cached() self.__update_state_recursively() self._update_ready_for_runtime_and_cached() if self._get_workspace() and self._cached_success(): assert utils._is_main_process(), \ "Attempted to save workspace configuration from child process" # # Note that this block can only happen in the # main process, since `self._cached_success()` cannot # be true when assembly is successful in the task. # # For this reason, it is safe to update and # save the workspaces configuration # key = self._get_cache_key() workspace = self._get_workspace() workspace.last_successful = key workspace.clear_running_files() self._get_context().get_workspaces().save_config() # This element will have already been marked as # required, but we bump the atime again, in case # we did not know the cache key until now. # # FIXME: This is not exactly correct, we should be # doing this at the time which we have discovered # a new cache key, this just happens to be the # last place where that can happen. # # Ultimately, we should be refactoring # Element._update_state() such that we know # when a cache key is actually discovered. # self.__artifacts.mark_required_elements([self]) # _assemble(): # # Internal method for running the entire build phase. # # This will: # - Prepare a sandbox for the build # - Call the public abstract methods for the build phase # - Cache the resulting artifact # # Returns: # (int): The size of the newly cached artifact # def _assemble(self): # Assert call ordering assert not self._cached_success() context = self._get_context() with self._output_file() as output_file: if not self.__sandbox_config_supported: self.warn("Sandbox configuration is not supported by the platform.", detail="Falling back to UID {} GID {}. Artifact will not be pushed." .format(self.__sandbox_config.build_uid, self.__sandbox_config.build_gid)) # Explicitly clean it up, keep the build dir around if exceptions are raised os.makedirs(context.builddir, exist_ok=True) rootdir = tempfile.mkdtemp(prefix="{}-".format(self.normal_name), dir=context.builddir) # Cleanup the build directory on explicit SIGTERM def cleanup_rootdir(): utils._force_rmtree(rootdir) with _signals.terminator(cleanup_rootdir), \ self.__sandbox(rootdir, output_file, output_file, self.__sandbox_config) as sandbox: # noqa # Let the sandbox know whether the buildtree will be required. # This allows the remote execution sandbox to skip buildtree # download when it's not needed. buildroot = self.get_variable('build-root') cache_buildtrees = context.cache_buildtrees if cache_buildtrees != 'never': always_cache_buildtrees = cache_buildtrees == 'always' sandbox._set_build_directory(buildroot, always=always_cache_buildtrees) if not self.BST_RUN_COMMANDS: # Element doesn't need to run any commands in the sandbox. # # Disable Sandbox.run() to allow CasBasedDirectory for all # sandboxes. sandbox._disable_run() # By default, the dynamic public data is the same as the static public data. # The plugin's assemble() method may modify this, though. self.__dynamic_public = self.__public.copy() # Call the abstract plugin methods # Step 1 - Configure self.__configure_sandbox(sandbox) # Step 2 - Stage self.stage(sandbox) try: if self.__batch_prepare_assemble: cm = sandbox.batch(self.__batch_prepare_assemble_flags, collect=self.__batch_prepare_assemble_collect) else: cm = contextlib.suppress() with cm: # Step 3 - Prepare self.__prepare(sandbox) # Step 4 - Assemble collect = self.assemble(sandbox) # pylint: disable=assignment-from-no-return self.__set_build_result(success=True, description="succeeded") except (ElementError, SandboxCommandError) as e: # Shelling into a sandbox is useful to debug this error e.sandbox = True # If there is a workspace open on this element, it will have # been mounted for sandbox invocations instead of being staged. # # In order to preserve the correct failure state, we need to # copy over the workspace files into the appropriate directory # in the sandbox. # workspace = self._get_workspace() if workspace and self.__staged_sources_directory: sandbox_vroot = sandbox.get_virtual_directory() path_components = self.__staged_sources_directory.lstrip(os.sep).split(os.sep) sandbox_vpath = sandbox_vroot.descend(*path_components) try: sandbox_vpath.import_files(workspace.get_absolute_path()) except UtilError as e2: self.warn("Failed to preserve workspace state for failed build sysroot: {}" .format(e2)) self.__set_build_result(success=False, description=str(e), detail=e.detail) self._cache_artifact(rootdir, sandbox, e.collect) raise else: return self._cache_artifact(rootdir, sandbox, collect) finally: cleanup_rootdir() def _cache_artifact(self, rootdir, sandbox, collect): context = self._get_context() buildresult = self.__build_result publicdata = self.__dynamic_public sandbox_vroot = sandbox.get_virtual_directory() collectvdir = None sandbox_build_dir = None cache_buildtrees = context.cache_buildtrees build_success = buildresult[0] # cache_buildtrees defaults to 'auto', only caching buildtrees # when necessary, which includes failed builds. # If only caching failed artifact buildtrees, then query the build # result. Element types without a build-root dir will be cached # with an empty buildtreedir regardless of this configuration. if cache_buildtrees == 'always' or (cache_buildtrees == 'auto' and not build_success): try: sandbox_build_dir = sandbox_vroot.descend( *self.get_variable('build-root').lstrip(os.sep).split(os.sep)) except VirtualDirectoryError: # Directory could not be found. Pre-virtual # directory behaviour was to continue silently # if the directory could not be found. pass if collect is not None: try: collectvdir = sandbox_vroot.descend(*collect.lstrip(os.sep).split(os.sep)) except VirtualDirectoryError: pass # ensure we have cache keys self._assemble_done() with self.timed_activity("Caching artifact"): artifact_size = self.__artifact.cache(rootdir, sandbox_build_dir, collectvdir, buildresult, publicdata) if collect is not None and collectvdir is None: raise ElementError( "Directory '{}' was not found inside the sandbox, " "unable to collect artifact contents" .format(collect)) return artifact_size def _get_build_log(self): return self._build_log_path # _fetch_done() # # Indicates that fetching the sources for this element has been done. # def _fetch_done(self): # We are not updating the state recursively here since fetching can # never end up in updating them. # Fetching changes the source state from RESOLVED to CACHED # Fetching cannot change the source state from INCONSISTENT to CACHED because # we prevent fetching when it's INCONSISTENT. # Therefore, only the source state will change. self.__update_source_state() # _pull_pending() # # Check whether the artifact will be pulled. If the pull operation is to # include a specific subdir of the element artifact (from cli or user conf) # then the local cache is queried for the subdirs existence. # # Returns: # (bool): Whether a pull operation is pending # def _pull_pending(self): if self._get_workspace(): # Workspace builds are never pushed to artifact servers return False # Check whether the pull has been invoked with a specific subdir requested # in user context, as to complete a partial artifact pull_buildtrees = self._get_context().pull_buildtrees if self.__strict_artifact: if self.__strict_artifact.cached() and pull_buildtrees: # If we've specified a subdir, check if the subdir is cached locally # or if it's possible to get if self._cached_buildtree() or not self._buildtree_exists(): return False elif self.__strict_artifact.cached(): return False # Pull is pending if artifact remote server available # and pull has not been attempted yet return self.__artifacts.has_fetch_remotes(plugin=self) and not self.__pull_done # _pull_done() # # Indicate that pull was attempted. # # This needs to be called in the main process after a pull # succeeds or fails so that we properly update the main # process data model # # This will result in updating the element state. # def _pull_done(self): self.__pull_done = True # Artifact may become cached after pulling, so let it query the # filesystem again to check self.__strict_artifact.reset_cached() self.__artifact.reset_cached() self.__update_state_recursively() self._update_ready_for_runtime_and_cached() # _pull(): # # Pull artifact from remote artifact repository into local artifact cache. # # Returns: True if the artifact has been downloaded, False otherwise # def _pull(self): context = self._get_context() # Get optional specific subdir to pull and optional list to not pull # based off of user context pull_buildtrees = context.pull_buildtrees # Attempt to pull artifact without knowing whether it's available pulled = self.__pull_strong(pull_buildtrees=pull_buildtrees) if not pulled and not self._cached() and not context.get_strict(): pulled = self.__pull_weak(pull_buildtrees=pull_buildtrees) if not pulled: return False # Notify successfull download return True def _skip_source_push(self): if not self.__sources or self._get_workspace(): return True return not (self.__sourcecache.has_push_remotes(plugin=self) and self._source_cached()) def _source_push(self): # try and push sources if we've got them if self.__sourcecache.has_push_remotes(plugin=self) and self._source_cached(): for source in self.sources(): if not self.__sourcecache.push(source): return False # Notify successful upload return True # _skip_push(): # # Determine whether we should create a push job for this element. # # Returns: # (bool): True if this element does not need a push job to be created # def _skip_push(self): if not self.__artifacts.has_push_remotes(plugin=self): # No push remotes for this element's project return True # Do not push elements that aren't cached, or that are cached with a dangling buildtree # ref unless element type is expected to have an an empty buildtree directory if not self._cached_buildtree() and self._buildtree_exists(): return True # Do not push tainted artifact if self.__get_tainted(): return True return False # _push(): # # Push locally cached artifact to remote artifact repository. # # Returns: # (bool): True if the remote was updated, False if it already existed # and no updated was required # def _push(self): self.__assert_cached() if self.__get_tainted(): self.warn("Not pushing tainted artifact.") return False # Push all keys used for local commit via the Artifact member pushed = self.__artifacts.push(self, self.__artifact) if not pushed: return False # Notify successful upload return True # _shell(): # # Connects the terminal with a shell running in a staged # environment # # Args: # scope (Scope): Either BUILD or RUN scopes are valid, or None # directory (str): A directory to an existing sandbox, or None # mounts (list): A list of (str, str) tuples, representing host/target paths to mount # isolate (bool): Whether to isolate the environment like we do in builds # prompt (str): A suitable prompt string for PS1 # command (list): An argv to launch in the sandbox # usebuildtree (bool): Use the buildtree as its source # # Returns: Exit code # # If directory is not specified, one will be staged using scope def _shell(self, scope=None, directory=None, *, mounts=None, isolate=False, prompt=None, command=None, usebuildtree=False): with self._prepare_sandbox(scope, directory, shell=True, usebuildtree=usebuildtree) as sandbox: environment = self.get_environment() environment = copy.copy(environment) flags = SandboxFlags.INTERACTIVE | SandboxFlags.ROOT_READ_ONLY # Fetch the main toplevel project, in case this is a junctioned # subproject, we want to use the rules defined by the main one. context = self._get_context() project = context.get_toplevel_project() shell_command, shell_environment, shell_host_files = project.get_shell_config() if prompt is not None: environment['PS1'] = prompt # Special configurations for non-isolated sandboxes if not isolate: # Open the network, and reuse calling uid/gid # flags |= SandboxFlags.NETWORK_ENABLED | SandboxFlags.INHERIT_UID # Apply project defined environment vars to set for a shell for key, value in shell_environment.items(): environment[key] = value # Setup any requested bind mounts if mounts is None: mounts = [] for mount in shell_host_files + mounts: if not os.path.exists(mount.host_path): if not mount.optional: self.warn("Not mounting non-existing host file: {}".format(mount.host_path)) else: sandbox.mark_directory(mount.path) sandbox._set_mount_source(mount.path, mount.host_path) if command: argv = [arg for arg in command] else: argv = shell_command self.status("Running command", detail=" ".join(argv)) # Run shells with network enabled and readonly root. return sandbox.run(argv, flags, env=environment) # _open_workspace(): # # "Open" a workspace for this element # # This requires that a workspace already be created in # the workspaces metadata first. # def _open_workspace(self): context = self._get_context() workspace = self._get_workspace() assert workspace is not None # First lets get a temp dir in our build directory # and stage there, then link the files over to the desired # path. # # We do this so that force opening workspaces which overwrites # files in the target directory actually works without any # additional support from Source implementations. # os.makedirs(context.builddir, exist_ok=True) with utils._tempdir(dir=context.builddir, prefix='workspace-{}' .format(self.normal_name)) as temp: for source in self.sources(): source._init_workspace(temp) # Now hardlink the files into the workspace target. utils.link_files(temp, workspace.get_absolute_path()) # _get_workspace(): # # Returns: # (Workspace|None): A workspace associated with this element # def _get_workspace(self): workspaces = self._get_context().get_workspaces() return workspaces.get_workspace(self._get_full_name()) # _write_script(): # # Writes a script to the given directory. def _write_script(self, directory): with open(_site.build_module_template, "r") as f: script_template = f.read() variable_string = "" for var, val in self.get_environment().items(): variable_string += "{0}={1} ".format(var, val) script = script_template.format( name=self.normal_name, build_root=self.get_variable('build-root'), install_root=self.get_variable('install-root'), variables=variable_string, commands=self.generate_script() ) os.makedirs(directory, exist_ok=True) script_path = os.path.join(directory, "build-" + self.normal_name) with self.timed_activity("Writing build script", silent_nested=True): with utils.save_file_atomic(script_path, "w") as script_file: script_file.write(script) os.chmod(script_path, stat.S_IEXEC | stat.S_IREAD) # _subst_string() # # Substitue a string, this is an internal function related # to how junctions are loaded and needs to be more generic # than the public node_subst_member() # # Args: # value (str): A string value # # Returns: # (str): The string after substitutions have occurred # def _subst_string(self, value): return self.__variables.subst(value) # Returns the element whose sources this element is ultimately derived from. # # This is intended for being used to redirect commands that operate on an # element to the element whose sources it is ultimately derived from. # # For example, element A is a build element depending on source foo, # element B is a filter element that depends on element A. The source # element of B is A, since B depends on A, and A has sources. # def _get_source_element(self): return self # _cached_buildtree() # # Check if element artifact contains expected buildtree. An # element's buildtree artifact will not be present if the rest # of the partial artifact is not cached. # # Returns: # (bool): True if artifact cached with buildtree, False if # element not cached or missing expected buildtree. # Note this only confirms if a buildtree is present, # not its contents. # def _cached_buildtree(self): if not self._cached(): return False return self.__artifact.cached_buildtree() # _buildtree_exists() # # Check if artifact was created with a buildtree. This does not check # whether the buildtree is present in the local cache. # # Returns: # (bool): True if artifact was created with buildtree, False if # element not cached or not created with a buildtree. # def _buildtree_exists(self): if not self._cached(): return False return self.__artifact.buildtree_exists() # _cached_logs() # # Check if the artifact is cached with log files. # # Returns: # (bool): True if artifact is cached with logs, False if # element not cached or missing logs. # def _cached_logs(self): return self.__artifact.cached_logs() # _fetch() # # Fetch the element's sources. # # Raises: # SourceError: If one of the element sources has an error # def _fetch(self, fetch_original=False): previous_sources = [] sources = self.__sources fetch_needed = False if sources and not fetch_original: for source in self.__sources: if self.__sourcecache.contains(source): continue # try and fetch from source cache if source._get_consistency() < Consistency.CACHED and \ self.__sourcecache.has_fetch_remotes(): if self.__sourcecache.pull(source): continue fetch_needed = True # We need to fetch original sources if fetch_needed or fetch_original: for source in self.sources(): source_consistency = source._get_consistency() if source_consistency != Consistency.CACHED: source._fetch(previous_sources) previous_sources.append(source) self.__cache_sources() # _calculate_cache_key(): # # Calculates the cache key # # Returns: # (str): A hex digest cache key for this Element, or None # # None is returned if information for the cache key is missing. # def _calculate_cache_key(self, dependencies): # No cache keys for dependencies which have no cache keys if None in dependencies: return None # Generate dict that is used as base for all cache keys if self.__cache_key_dict is None: # Filter out nocache variables from the element's environment cache_env = { key: value for key, value in self.__environment.items() if key not in self.__env_nocache } context = self._get_context() project = self._get_project() workspace = self._get_workspace() self.__cache_key_dict = { 'artifact-version': "{}.{}".format(BST_CORE_ARTIFACT_VERSION, self.BST_ARTIFACT_VERSION), 'context': context.get_cache_key(), 'project': project.get_cache_key(), 'element': self.get_unique_key(), 'execution-environment': self.__sandbox_config.get_unique_key(), 'environment': cache_env, 'sources': [s._get_unique_key(workspace is None) for s in self.__sources], 'workspace': '' if workspace is None else workspace.get_key(self._get_project()), 'public': self.__public.strip_node_info(), 'cache': 'CASCache' } self.__cache_key_dict['fatal-warnings'] = sorted(project._fatal_warnings) cache_key_dict = self.__cache_key_dict.copy() cache_key_dict['dependencies'] = dependencies return _cachekey.generate_key(cache_key_dict) # Check if sources are cached, generating the source key if it hasn't been def _source_cached(self): if self.__sources: sourcecache = self._get_context().sourcecache # Go through sources we'll cache generating keys for ix, source in enumerate(self.__sources): if not source._key: if source.BST_REQUIRES_PREVIOUS_SOURCES_STAGE: source._generate_key(self.__sources[:ix]) else: source._generate_key([]) # Check all sources are in source cache for source in self.__sources: if not sourcecache.contains(source): return False return True def _should_fetch(self, fetch_original=False): """ return bool of if we need to run the fetch stage for this element Args: fetch_original (bool): whether we need to original unstaged source """ if (self._get_consistency() == Consistency.CACHED and fetch_original) or \ (self._source_cached() and not fetch_original): return False else: return True # _set_required_callback() # # # Notify the pull/fetch/build queue that the element is potentially # ready to be processed. # # _Set the _required_callback - the _required_callback is invoked when an # element is marked as required. This informs us that the element needs to # either be pulled or fetched + built. # # Args: # callback (callable) - The callback function # def _set_required_callback(self, callback): self.__required_callback = callback # _set_can_query_cache_callback() # # Notify the pull/fetch queue that the element is potentially # ready to be processed. # # Set the _can_query_cache_callback - the _can_query_cache_callback is # invoked when an element becomes able to query the cache. That is, # the (non-workspaced) element's strict cache key has been calculated. # However, if the element is workspaced, we also invoke this callback # once its build has been scheduled - this ensures that the workspaced # element does not get blocked in the pull queue. # # Args: # callback (callable) - The callback function # def _set_can_query_cache_callback(self, callback): self.__can_query_cache_callback = callback # _set_buildable_callback() # # Notifiy the build queue that the element is potentially ready # to be processed # # Set the _buildable_callback - the _buildable_callback is invoked when # an element is marked as "buildable". That is, its sources are consistent, # its been scheduled to be built and all of its build dependencies have # had their cache key's calculated and are cached. # # Args: # callback (callable) - The callback function # def _set_buildable_callback(self, callback): self.__buildable_callback = callback # _set_depth() # # Set the depth of the Element. # # The depth represents the position of the Element within the current # session's dependency graph. A depth of zero represents the bottommost element. # def _set_depth(self, depth): self._depth = depth # _update_ready_for_runtime_and_cached() # # An Element becomes ready for runtime and cached once the following three criteria # are met: # 1. The Element has a strong cache key # 2. The Element is cached (locally) # 3. The runtime dependencies of the Element are ready for runtime and cached. # # These three criteria serve as potential trigger points as to when an Element may have # become ready for runtime and cached. # # Once an Element becomes ready for runtime and cached, we notify the reverse # runtime dependencies and the reverse build dependencies of the element, decrementing # the appropriate counters. # def _update_ready_for_runtime_and_cached(self): if not self.__ready_for_runtime_and_cached: if self.__remaining_runtime_deps_uncached == 0 and self.__cache_key and self._cached_success(): self.__ready_for_runtime_and_cached = True # Notify reverse dependencies for rdep in self.__reverse_runtime_deps: rdep.__on_runtime_dependency_ready_for_runtime_and_cached() for rdep in self.__reverse_build_deps: rdep.__on_build_dependency_ready_for_runtime_and_cached() ############################################################# # Private Local Methods # ############################################################# # __update_source_state() # # Updates source consistency state # # An element's source state must be resolved before it may compute # cache keys, because the source's ref, whether defined in yaml or # from the workspace, is a component of the element's cache keys. # def __update_source_state(self): # Cannot resolve source state until tracked if self.__tracking_scheduled: return self.__consistency = Consistency.CACHED workspace = self._get_workspace() # Special case for workspaces if workspace: # A workspace is considered inconsistent in the case # that its directory went missing # fullpath = workspace.get_absolute_path() if not os.path.exists(fullpath): self.__consistency = Consistency.INCONSISTENT else: # Determine overall consistency of the element for source in self.__sources: source._update_state() self.__consistency = min(self.__consistency, source._get_consistency()) # __can_build_incrementally() # # Check if the element can be built incrementally, this # is used to decide how to stage things # # Returns: # (bool): Whether this element can be built incrementally # def __can_build_incrementally(self): return bool(self._get_workspace()) # __configure_sandbox(): # # Internal method for calling public abstract configure_sandbox() method. # def __configure_sandbox(self, sandbox): self.__batch_prepare_assemble = False self.configure_sandbox(sandbox) # __prepare(): # # Internal method for calling public abstract prepare() method. # def __prepare(self, sandbox): workspace = self._get_workspace() # We need to ensure that the prepare() method is only called # once in workspaces, because the changes will persist across # incremental builds - not desirable, for example, in the case # of autotools' `./configure`. if not (workspace and workspace.prepared): self.prepare(sandbox) if workspace: def mark_workspace_prepared(): workspace.prepared = True # Defer workspace.prepared setting until pending batch commands # have been executed. sandbox._callback(mark_workspace_prepared) # __assert_cached() # # Raises an error if the artifact is not cached. # def __assert_cached(self): assert self._cached(), "{}: Missing artifact {}".format( self, self._get_brief_display_key()) # __get_tainted(): # # Checkes whether this artifact should be pushed to an artifact cache. # # Args: # recalculate (bool) - Whether to force recalculation # # Returns: # (bool) False if this artifact should be excluded from pushing. # # Note: # This method should only be called after the element's # artifact is present in the local artifact cache. # def __get_tainted(self, recalculate=False): if recalculate or self.__tainted is None: # Whether this artifact has a workspace workspaced = self.__artifact.get_metadata_workspaced() # Whether this artifact's dependencies have workspaces workspaced_dependencies = self.__artifact.get_metadata_workspaced_dependencies() # Other conditions should be or-ed self.__tainted = (workspaced or workspaced_dependencies or not self.__sandbox_config_supported) return self.__tainted # __use_remote_execution(): # # Returns True if remote execution is configured and the element plugin # supports it. # def __use_remote_execution(self): return bool(self.__remote_execution_specs) # __sandbox(): # # A context manager to prepare a Sandbox object at the specified directory, # if the directory is None, then a directory will be chosen automatically # in the configured build directory. # # Args: # directory (str): The local directory where the sandbox will live, or None # stdout (fileobject): The stream for stdout for the sandbox # stderr (fileobject): The stream for stderr for the sandbox # config (SandboxConfig): The SandboxConfig object # allow_remote (bool): Whether the sandbox is allowed to be remote # bare_directory (bool): Whether the directory is bare i.e. doesn't have # a separate 'root' subdir # # Yields: # (Sandbox): A usable sandbox # @contextmanager def __sandbox(self, directory, stdout=None, stderr=None, config=None, allow_remote=True, bare_directory=False): context = self._get_context() project = self._get_project() platform = Platform.get_platform() if directory is not None and allow_remote and self.__use_remote_execution(): if not self.BST_VIRTUAL_DIRECTORY: raise ElementError("Element {} is configured to use remote execution but plugin does not support it." .format(self.name), detail="Plugin '{kind}' does not support virtual directories." .format(kind=self.get_kind())) self.info("Using a remote sandbox for artifact {} with directory '{}'".format(self.name, directory)) output_files_required = context.require_artifact_files or self._artifact_files_required() sandbox = SandboxRemote(context, project, directory, plugin=self, stdout=stdout, stderr=stderr, config=config, specs=self.__remote_execution_specs, bare_directory=bare_directory, allow_real_directory=False, output_files_required=output_files_required) yield sandbox elif directory is not None and os.path.exists(directory): sandbox = platform.create_sandbox(context, project, directory, plugin=self, stdout=stdout, stderr=stderr, config=config, bare_directory=bare_directory, allow_real_directory=not self.BST_VIRTUAL_DIRECTORY) yield sandbox else: os.makedirs(context.builddir, exist_ok=True) rootdir = tempfile.mkdtemp(prefix="{}-".format(self.normal_name), dir=context.builddir) # Recursive contextmanager... with self.__sandbox(rootdir, stdout=stdout, stderr=stderr, config=config, allow_remote=allow_remote, bare_directory=False) as sandbox: yield sandbox # Cleanup the build dir utils._force_rmtree(rootdir) @classmethod def __compose_default_splits(cls, project, defaults, is_junction): element_public = defaults.get_mapping("public", default={}) element_bst = element_public.get_mapping("bst", default={}) element_splits = element_bst.get_mapping("split-rules", default={}) if is_junction: splits = element_splits.copy() else: assert project._splits is not None splits = project._splits.copy() # Extend project wide split rules with any split rules defined by the element element_splits.composite(splits) element_bst['split-rules'] = splits element_public['bst'] = element_bst defaults['public'] = element_public @classmethod def __init_defaults(cls, project, plugin_conf, kind, is_junction): # Defaults are loaded once per class and then reused # if cls.__defaults is None: defaults = _yaml.Node.from_dict({}) if plugin_conf is not None: # Load the plugin's accompanying .yaml file if one was provided try: defaults = _yaml.load(plugin_conf, os.path.basename(plugin_conf)) except LoadError as e: if e.reason != LoadErrorReason.MISSING_FILE: raise e # Special case; compose any element-wide split-rules declarations cls.__compose_default_splits(project, defaults, is_junction) # Override the element's defaults with element specific # overrides from the project.conf if is_junction: elements = project.first_pass_config.element_overrides else: elements = project.element_overrides overrides = elements.get_mapping(kind, default=None) if overrides: overrides.composite(defaults) # Set the data class wide cls.__defaults = defaults # This will acquire the environment to be used when # creating sandboxes for this element # @classmethod def __extract_environment(cls, project, meta): default_env = cls.__defaults.get_mapping("environment", default={}) if meta.is_junction: environment = _yaml.Node.from_dict({}) else: environment = project.base_environment.copy() default_env.composite(environment) meta.environment.composite(environment) environment._assert_fully_composited() return environment # This will resolve the final environment to be used when # creating sandboxes for this element # def __expand_environment(self, environment): # Resolve variables in environment value strings final_env = {} for key in environment.keys(): final_env[key] = self.node_subst_member(environment, key) return final_env @classmethod def __extract_env_nocache(cls, project, meta): if meta.is_junction: project_nocache = [] else: project_nocache = project.base_env_nocache default_nocache = cls.__defaults.get_sequence('environment-nocache', default=[]).as_str_list() element_nocache = meta.env_nocache # Accumulate values from the element default, the project and the element # itself to form a complete list of nocache env vars. env_nocache = set(project_nocache + default_nocache + element_nocache) # Convert back to list now we know they're unique return list(env_nocache) # This will resolve the final variables to be used when # substituting command strings to be run in the sandbox # @classmethod def __extract_variables(cls, project, meta): default_vars = cls.__defaults.get_mapping('variables', default={}) if meta.is_junction: variables = project.first_pass_config.base_variables.copy() else: variables = project.base_variables.copy() default_vars.composite(variables) meta.variables.composite(variables) variables._assert_fully_composited() for var in ('project-name', 'element-name', 'max-jobs'): provenance = _yaml.node_get_provenance(variables, var) if provenance and not provenance.is_synthetic: raise LoadError(LoadErrorReason.PROTECTED_VARIABLE_REDEFINED, "{}: invalid redefinition of protected variable '{}'" .format(provenance, var)) return variables # This will resolve the final configuration to be handed # off to element.configure() # @classmethod def __extract_config(cls, meta): # The default config is already composited with the project overrides config = cls.__defaults.get_mapping('config', default={}) config = config.copy() meta.config.composite(config) config._assert_fully_composited() return config # Sandbox-specific configuration data, to be passed to the sandbox's constructor. # @classmethod def __extract_sandbox_config(cls, project, meta): if meta.is_junction: sandbox_config = _yaml.Node.from_dict({ 'build-uid': 0, 'build-gid': 0 }) else: sandbox_config = project._sandbox.copy() # Get the platform to ask for host architecture platform = Platform.get_platform() host_arch = platform.get_host_arch() host_os = platform.get_host_os() # The default config is already composited with the project overrides sandbox_defaults = cls.__defaults.get_mapping('sandbox', default={}) sandbox_defaults = sandbox_defaults.copy() sandbox_defaults.composite(sandbox_config) meta.sandbox.composite(sandbox_config) sandbox_config._assert_fully_composited() # Sandbox config, unlike others, has fixed members so we should validate them _yaml.node_validate(sandbox_config, ['build-uid', 'build-gid', 'build-os', 'build-arch']) build_arch = sandbox_config.get_str('build-arch', default=None) if build_arch: build_arch = Platform.canonicalize_arch(build_arch) else: build_arch = host_arch return SandboxConfig( sandbox_config.get_int('build-uid'), sandbox_config.get_int('build-gid'), sandbox_config.get_str('build-os', default=host_os), build_arch) # This makes a special exception for the split rules, which # elements may extend but whos defaults are defined in the project. # @classmethod def __extract_public(cls, meta): base_public = cls.__defaults.get_mapping('public', default={}) base_public = base_public.copy() base_bst = base_public.get_mapping('bst', default={}) base_splits = base_bst.get_mapping('split-rules', default={}) element_public = meta.public.copy() element_bst = element_public.get_mapping('bst', default={}) element_splits = element_bst.get_mapping('split-rules', default={}) # Allow elements to extend the default splits defined in their project or # element specific defaults element_splits.composite(base_splits) element_bst['split-rules'] = base_splits element_public['bst'] = element_bst element_public._assert_fully_composited() return element_public # Expand the splits in the public data using the Variables in the element def __expand_splits(self, element_public): element_bst = element_public.get_mapping('bst', default={}) element_splits = element_bst.get_mapping('split-rules', default={}) # Resolve any variables in the public split rules directly for domain, splits in element_splits.items(): splits = [ self.__variables.subst(split.strip()) for split in splits.as_str_list() ] element_splits[domain] = splits return element_public def __init_splits(self): bstdata = self.get_public_data('bst') splits = bstdata.get_mapping('split-rules') self.__splits = { domain: re.compile('^(?:' + '|'.join([utils._glob2re(r) for r in rules.as_str_list()]) + ')$') for domain, rules in splits.items() } # __split_filter(): # # Returns True if the file with the specified `path` is included in the # specified split domains. This is used by `__split_filter_func()` to create # a filter callback. # # Args: # element_domains (list): All domains for this element # include (list): A list of domains to include files from # exclude (list): A list of domains to exclude files from # orphans (bool): Whether to include files not spoken for by split domains # path (str): The relative path of the file # # Returns: # (bool): Whether to include the specified file # def __split_filter(self, element_domains, include, exclude, orphans, path): # Absolute path is required for matching filename = os.path.join(os.sep, path) include_file = False exclude_file = False claimed_file = False for domain in element_domains: if self.__splits[domain].match(filename): claimed_file = True if domain in include: include_file = True if domain in exclude: exclude_file = True if orphans and not claimed_file: include_file = True return include_file and not exclude_file # __split_filter_func(): # # Returns callable split filter function for use with `copy_files()`, # `link_files()` or `Directory.import_files()`. # # Args: # include (list): An optional list of domains to include files from # exclude (list): An optional list of domains to exclude files from # orphans (bool): Whether to include files not spoken for by split domains # # Returns: # (callable): Filter callback that returns True if the file is included # in the specified split domains. # def __split_filter_func(self, include=None, exclude=None, orphans=True): # No splitting requested, no filter needed if orphans and not (include or exclude): return None if not self.__splits: self.__init_splits() element_domains = list(self.__splits.keys()) if not include: include = element_domains if not exclude: exclude = [] # Ignore domains that dont apply to this element # include = [domain for domain in include if domain in element_domains] exclude = [domain for domain in exclude if domain in element_domains] # The arguments element_domains, include, exclude, and orphans are # the same for all files. Use `partial` to create a function with # the required callback signature: a single `path` parameter. return partial(self.__split_filter, element_domains, include, exclude, orphans) def __compute_splits(self, include=None, exclude=None, orphans=True): filter_func = self.__split_filter_func(include=include, exclude=exclude, orphans=orphans) files_vdir = self.__artifact.get_files() element_files = files_vdir.list_relative_paths() if not filter_func: # No splitting requested, just report complete artifact yield from element_files else: for filename in element_files: if filter_func(filename): yield filename def __file_is_whitelisted(self, path): # Considered storing the whitelist regex for re-use, but public data # can be altered mid-build. # Public data is not guaranteed to stay the same for the duration of # the build, but I can think of no reason to change it mid-build. # If this ever changes, things will go wrong unexpectedly. if not self.__whitelist_regex: bstdata = self.get_public_data('bst') whitelist = bstdata.get_sequence('overlap-whitelist', default=[]).as_str_list() whitelist_expressions = [utils._glob2re(self.__variables.subst(exp.strip())) for exp in whitelist] expression = ('^(?:' + '|'.join(whitelist_expressions) + ')$') self.__whitelist_regex = re.compile(expression) return self.__whitelist_regex.match(os.path.join(os.sep, path)) # __load_public_data(): # # Loads the public data from the cached artifact # def __load_public_data(self): self.__assert_cached() assert self.__dynamic_public is None self.__dynamic_public = self.__artifact.load_public_data() def __load_build_result(self): self.__assert_cached() assert self.__build_result is None self.__build_result = self.__artifact.load_build_result() # __pull_strong(): # # Attempt pulling given element from configured artifact caches with # the strict cache key # # Args: # progress (callable): The progress callback, if any # subdir (str): The optional specific subdir to pull # excluded_subdirs (list): The optional list of subdirs to not pull # # Returns: # (bool): Whether or not the pull was successful # def __pull_strong(self, *, pull_buildtrees): weak_key = self._get_cache_key(strength=_KeyStrength.WEAK) key = self.__strict_cache_key if not self.__artifacts.pull(self, key, pull_buildtrees=pull_buildtrees): return False # update weak ref by pointing it to this newly fetched artifact self.__artifacts.link_key(self, key, weak_key) return True # __pull_weak(): # # Attempt pulling given element from configured artifact caches with # the weak cache key # # Args: # subdir (str): The optional specific subdir to pull # excluded_subdirs (list): The optional list of subdirs to not pull # # Returns: # (bool): Whether or not the pull was successful # def __pull_weak(self, *, pull_buildtrees): weak_key = self._get_cache_key(strength=_KeyStrength.WEAK) if not self.__artifacts.pull(self, weak_key, pull_buildtrees=pull_buildtrees): return False # extract strong cache key from this newly fetched artifact self._pull_done() # create tag for strong cache key key = self._get_cache_key(strength=_KeyStrength.STRONG) self.__artifacts.link_key(self, weak_key, key) return True # __cache_sources(): # # Caches the sources into the local CAS # def __cache_sources(self): if self.__sources and not self._source_cached(): last_requires_previous = 0 # commit all other sources by themselves for ix, source in enumerate(self.__sources): if source.BST_REQUIRES_PREVIOUS_SOURCES_STAGE: self.__sourcecache.commit(source, self.__sources[last_requires_previous:ix]) last_requires_previous = ix else: self.__sourcecache.commit(source, []) # __last_source_requires_previous # # This is the last source that requires previous sources to be cached. # Sources listed after this will be cached separately. # # Returns: # (int): index of last source that requires previous sources # def __last_source_requires_previous(self): if self.__last_source_requires_previous_ix is None: last_requires_previous = 0 for ix, source in enumerate(self.__sources): if source.BST_REQUIRES_PREVIOUS_SOURCES_STAGE: last_requires_previous = ix self.__last_source_requires_previous_ix = last_requires_previous return self.__last_source_requires_previous_ix # __update_state_recursively() # # Update the state of all reverse dependencies, recursively. # def __update_state_recursively(self): queue = _UniquePriorityQueue() queue.push(self._unique_id, self) while queue: element = queue.pop() old_ready_for_runtime = element.__ready_for_runtime old_strict_cache_key = element.__strict_cache_key element._update_state() if element.__ready_for_runtime != old_ready_for_runtime or \ element.__strict_cache_key != old_strict_cache_key: for rdep in element.__reverse_build_deps | element.__reverse_runtime_deps: queue.push(rdep._unique_id, rdep) # __on_runtime_dependency_ready_for_runtime_and_cached() # # This function is called once one of the Element's runtime dependencies has # become ready for runtime and cached. # # On calling this function, we decrement the Element's remaining runtime deps counter. # If this is zero, we attempt to notify all reverse dependencies of the Element. # def __on_runtime_dependency_ready_for_runtime_and_cached(self): self.__remaining_runtime_deps_uncached -= 1 assert not self.__remaining_runtime_deps_uncached < 0 # Try to notify reverse dependencies if all runtime deps are ready if self.__remaining_runtime_deps_uncached == 0: self._update_ready_for_runtime_and_cached() # __on_build_dependency_ready_for_runtime_and_cached() # # This function is called once one of the Element's build dependencies has become # ready for runtime and cached. # # On calling this function, we decrement the Element's remaining build deps counter. # If this is zero, we invoke the buildable callback. # def __on_build_dependency_ready_for_runtime_and_cached(self): self.__remaining_build_deps_uncached -= 1 assert not self.__remaining_build_deps_uncached < 0 if self.__buildable_callback is not None and self._buildable(): self.__buildable_callback(self) self.__buildable_callback = None # __reset_cache_data() # # Resets all data related to cache key calculation and whether an artifact # is cached. # # This is useful because we need to know whether a workspace is cached # before we know whether to assemble it, and doing that would generate a # different cache key to the initial one. # def __reset_cache_data(self): self.__build_result = None self.__cache_key_dict = None self.__cache_key = None self.__weak_cache_key = None self.__strict_cache_key = None self.__artifact = None self.__strict_artifact = None # __update_cache_keys() # # Updates weak and strict cache keys # # Note that it does not update *all* cache keys - In non-strict mode, the # strong cache key is updated in __update_cache_key_non_strict() # # If the cache keys are not stable (i.e. workspace that isn't cached), # then cache keys are erased. # Otherwise, the weak and strict cache keys will be calculated if not # already set. # The weak cache key is a cache key that doesn't necessarily change when # its dependencies change, useful for avoiding full rebuilds when one's # dependencies guarantee stability across versions. # The strict cache key is a cache key that changes if any build-dependency # has changed. # def __update_cache_keys(self): context = self._get_context() if self.__weak_cache_key is None: # Calculate weak cache key # Weak cache key includes names of direct build dependencies # but does not include keys of dependencies. if self.BST_STRICT_REBUILD: dependencies = [ e._get_cache_key(strength=_KeyStrength.WEAK) for e in self.dependencies(Scope.BUILD) ] else: dependencies = [ e.name for e in self.dependencies(Scope.BUILD, recurse=False) ] self.__weak_cache_key = self._calculate_cache_key(dependencies) if self.__weak_cache_key is None: # Weak cache key could not be calculated yet, therefore # the Strict cache key also can't be calculated yet. return if self.__strict_cache_key is None: dependencies = [ e.__strict_cache_key for e in self.dependencies(Scope.BUILD) ] self.__strict_cache_key = self._calculate_cache_key(dependencies) # In strict mode, the strong cache key always matches the strict cache key if context.get_strict(): self.__cache_key = self.__strict_cache_key # If the element is cached, and has all of its runtime dependencies cached, # now that we have the cache key, we are able to notify reverse dependencies # that the element it ready. This is a likely trigger for workspaced elements. self._update_ready_for_runtime_and_cached() if self.__strict_cache_key is not None and self.__can_query_cache_callback is not None: self.__can_query_cache_callback(self) self.__can_query_cache_callback = None # __update_artifact_state() # # Updates the data involved in knowing about the artifact corresponding # to this element. # # This involves erasing all data pertaining to artifacts if the cache # key is unstable. # # Element.__update_cache_keys() must be called before this to have # meaningful results, because the element must know its cache key before # it can check whether an artifact exists for that cache key. # def __update_artifact_state(self): context = self._get_context() if not self.__weak_cache_key: return if not context.get_strict() and not self.__artifact: # We've calculated the weak_key, so instantiate artifact instance member self.__artifact = Artifact(self, context, weak_key=self.__weak_cache_key) if not self.__strict_cache_key: return if not self.__strict_artifact: self.__strict_artifact = Artifact(self, context, strong_key=self.__strict_cache_key, weak_key=self.__weak_cache_key) # In strict mode, the strong cache key always matches the strict cache key if context.get_strict(): self.__artifact = self.__strict_artifact # __update_cache_key_non_strict() # # Calculates the strong cache key if it hasn't already been set. # # When buildstream runs in strict mode, this is identical to the # strict cache key, so no work needs to be done. # # When buildstream is not run in strict mode, this requires the artifact # state (as set in Element.__update_artifact_state()) to be set accordingly, # as the cache key can be loaded from the cache (possibly pulling from # a remote cache). # def __update_cache_key_non_strict(self): if not self.__strict_artifact: return # The final cache key can be None here only in non-strict mode if self.__cache_key is None: if self._pull_pending(): # Effective strong cache key is unknown until after the pull pass elif self._cached(): # Load the strong cache key from the artifact strong_key, _ = self.__artifact.get_metadata_keys() self.__cache_key = strong_key elif self.__assemble_scheduled or self.__assemble_done: # Artifact will or has been built, not downloaded dependencies = [ e._get_cache_key() for e in self.dependencies(Scope.BUILD) ] self.__cache_key = self._calculate_cache_key(dependencies) if self.__cache_key is None: # Strong cache key could not be calculated yet return # If the element is cached, and has all of its runtime dependencies cached, # now that we have the strong cache key, we are able to notify reverse dependencies # that the element it ready. This is a likely trigger for workspaced elements. self._update_ready_for_runtime_and_cached() # Now we have the strong cache key, update the Artifact self.__artifact._cache_key = self.__cache_key def _overlap_error_detail(f, forbidden_overlap_elements, elements): if forbidden_overlap_elements: return ("/{}: {} {} not permitted to overlap other elements, order {} \n" .format(f, " and ".join(forbidden_overlap_elements), "is" if len(forbidden_overlap_elements) == 1 else "are", " above ".join(reversed(elements)))) else: return "" # _get_normal_name(): # # Get the element name without path separators or # the extension. # # Args: # element_name (str): The element's name # # Returns: # (str): The normalised element name # def _get_normal_name(element_name): return os.path.splitext(element_name.replace(os.sep, '-'))[0] # _compose_artifact_name(): # # Compose the completely resolved 'artifact_name' as a filepath # # Args: # project_name (str): The project's name # normal_name (str): The element's normalised name # cache_key (str): The relevant cache key # # Returns: # (str): The constructed artifact name path # def _compose_artifact_name(project_name, normal_name, cache_key): valid_chars = string.digits + string.ascii_letters + '-._' normal_name = ''.join([ x if x in valid_chars else '_' for x in normal_name ]) # Note that project names are not allowed to contain slashes. Element names containing # a '/' will have this replaced with a '-' upon Element object instantiation. return '{0}/{1}/{2}'.format(project_name, normal_name, cache_key)