def test_timestamps(self): ''' Ensure that modifying a timestamp on one of the inputs has no effect. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Bump the timestamps on the input. st = os.stat(input) os.utime(input, (st[stat.ST_ATIME] + 3600, st[stat.ST_MTIME] + 3600)) # Ensure we can find what we just saved. output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world') # And after a flush. c.flush() output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world')
def test_miss_on_disk2(self): ''' Same as the in-memory miss test except we flush the cache in-between, at a point at which the entry is already invalid. The invalidity is not actually detected then, but the later lookup should still miss. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Now cause the entry to be invalid by modifying inputs. with open(input, 'wt') as f: f.write('bar foo') # Flush the (now invalid) entry to disk. c.flush() # Ensure we miss when now performing a lookup. output = c.load(['arg1', 'arg2'], cwd) self.assertIsNone(output)
def test_no_inputs(self): ''' Ensure we can handle an entry with no inputs. ''' root = self.mkdtemp() c = Cache(root) inputs = prime_inputs([]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Ensure we can find what we just saved. output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world') # Ensure it is preserved after a flush. c.flush() output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world')
def test_no_args(self): root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save([], cwd, 'hello world', inputs) # Ensure we can find what we just saved. output = c.load([], cwd) self.assertEqual(output, 'hello world') # Ensure it is preserved after a flush. c.flush() output = c.load([], cwd) self.assertEqual(output, 'hello world')
def test_basic(self): ''' Test we can look up something we've just saved. Note that this test will not actually perform an on-disk lookup. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Ensure we can find what we just saved. output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world')
def test_basic_with_flush(self): ''' Same as the basic test, but we'll flush in-between to ensure we perform an on-disk lookup. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) c.flush() # Ensure we can find what we just saved. output = c.load(['arg1', 'arg2'], cwd) self.assertEqual(output, 'hello world')
def test_miss_from_missing_file1(self): ''' Ensure cache misses from missing files function correctly. ''' root = self.mkdtemp() c = Cache(root) _, input = tempfile.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Now cause the entry to be invalid by deleting its input. os.remove(input) # Ensure we miss when now performing a lookup. output = c.load(['arg1', 'arg2'], cwd) self.assertIsNone(output)
def test_miss_on_disk1(self): ''' Same as the in-memory miss test except we flush the cache in-between. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) c.flush() # Now cause the entry to be invalid by modifying inputs. with open(input, 'wt') as f: f.write('bar foo') # Ensure we miss when now performing a lookup. output = c.load(['arg1', 'arg2'], cwd) self.assertIsNone(output)
def test_miss_in_memory(self): ''' Test that an induced cache miss while the cache entry is still in memory works correctly. ''' root = self.mkdtemp() c = Cache(root) input = self.mkstemp() with open(input, 'wt') as f: f.write('foo bar') inputs = prime_inputs([input]) cwd = os.getcwd() c.save(['arg1', 'arg2'], cwd, 'hello world', inputs) # Now cause the entry to be invalid by modifying inputs. with open(input, 'wt') as f: f.write('bar foo') # Ensure we miss when now performing a lookup. output = c.load(['arg1', 'arg2'], cwd) self.assertIsNone(output)
def main(argv, out, err): # We need a UTF-8 locale, so bail out if we don't have one. More # specifically, things like the version() computation traverse the file # system and, if they hit a UTF-8 filename, they try to decode it into your # preferred encoding and trigger an exception. encoding = locale.getpreferredencoding().lower() if encoding not in ('utf-8', 'utf8'): err.write('CAmkES uses UTF-8 encoding, but your locale\'s preferred ' 'encoding is %s. You can override your locale with the LANG ' 'environment variable.\n' % encoding) return -1 options = parse_args(argv, out, err) # Ensure we were supplied equal items and outfiles if len(options.outfile) != len(options.item): err.write( 'Different number of items and outfiles. Required one outfile location ' 'per item requested.\n') return -1 # No duplicates in items or outfiles if len(set(options.item)) != len(options.item): err.write('Duplicate items requested through --item.\n') return -1 if len(set(options.outfile)) != len(options.outfile): err.write('Duplicate outfiles requrested through --outfile.\n') return -1 # Save us having to pass debugging everywhere. die = functools.partial(_die, options) log.set_verbosity(options.verbosity) cwd = os.getcwd() # Build a list of item/outfile pairs that we have yet to match and process all_items = set(zip(options.item, options.outfile)) done_items = set([]) # Construct the compilation caches if requested. cachea = None cacheb = None if options.cache: # Construct a modified version of the command line arguments that we'll # use in the keys to the caches. Essentially we elide --outfile and its # parameter under the assumption that this value is never used in code # generation. The purpose of this is to allow us to successfully cache # ancillary outputs that we generate along the way to the current # output. If we were to include --outfile in the key, future attempts # to generate these ancillary outputs would unnecessarily miss the # entries generated by this execution. args = [] skip = False for index, arg in enumerate(argv[1:]): if skip: skip = False continue if arg in ('--outfile', '-O'): skip = True continue args.append(arg) cachea = LevelACache( os.path.join(options.cache_dir, version(), 'cachea')) cacheb = LevelBCache( os.path.join(options.cache_dir, version(), 'cacheb')) def done(s, file, item): ret = 0 if s: file.write(s) file.close() if cachea is not None: try: cachea.flush() except sqlite3.OperationalError as e: # The following suppresses two spurious errors: # 1. The database is locked. In a large, parallel build, writes # to the level A cache are heavily contended and this error # can occur. # 2. The database structure is unexpected. If the CAmkES # sources have changed *while* the runner was executing, # the level A cache can be looking in a different place to # where the cache was created. # Both of these are non-critical (will just result in a # potential future cache miss) so there's no need to alarm the # user. if re.search(r'database is locked', str(e)) is not None or \ re.search(r'no such table', str(e)) is not None: log.debug('failed to flush level A cache: %s' % str(e)) else: raise if cacheb is not None: try: cacheb.flush() except sqlite3.OperationalError as e: # As above for the level B cache. if re.search(r'database is locked', str(e)): log.debug('failed to flush level B cache: %s' % str(e)) else: raise done_items.add((item, file)) if len(all_items - done_items) == 0: sys.exit(ret) # Try to find this output in the level A cache if possible. This check will # 'hit' if the source files representing the input spec are identical to # some previously observed execution. if cachea is not None: assert 'args' in locals() assert len(options.outfile) == 1, 'level A cache only supported when requestiong ' \ 'single items' output = cachea.load(args, cwd) if output is not None: log.debug('Retrieved %(platform)s/%(item)s from level A cache' % options.__dict__) done(output, options.outfile[0], options.item[0]) filename = os.path.abspath(options.file.name) try: # Build the parser options parse_options = ParserOptions(options.cpp, options.cpp_flag, options.import_path, options.verbosity, options.allow_forward_references) ast, read = parse_file_cached(filename, options.data_structure_cache_dir, parse_options) except (ASTError, ParseError) as e: die(e.args) # Locate the assembly. assembly = ast.assembly if assembly is None: die('No assembly found') # Do some extra checks if the user asked for verbose output. if options.verbosity >= 2: # Try to catch type mismatches in attribute settings. Note that it is # not possible to conclusively evaluate type correctness because the # attributes' type system is (deliberately) too loose. That is, the # type of an attribute can be an uninterpreted C type the user will # provide post hoc. for i in assembly.composition.instances: for a in i.type.attributes: value = assembly.configuration[i.name].get(a.name) if value is not None: if a.type == 'string' and not \ isinstance(value, six.string_types): log.warning('attribute %s.%s has type string but is ' 'set to a value that is not a string' % (i.name, a.name)) elif a.type == 'int' and not \ isinstance(value, numbers.Number): log.warning('attribute %s.%s has type int but is set ' 'to a value that is not an integer' % (i.name, a.name)) obj_space = ObjectAllocator() obj_space.spec.arch = options.architecture cspaces = {} pds = {} conf = assembly.configuration shmem = collections.defaultdict(ShmemFactory()) kept_symbols = {} fill_frames = {} templates = Templates(options.platform) [templates.add_root(t) for t in options.templates] try: r = Renderer(templates, options.cache, options.cache_dir) except jinja2.exceptions.TemplateSyntaxError as e: die('template syntax error: %s' % e) # The user may have provided their own connector definitions (with # associated) templates, in which case they won't be in the built-in lookup # dictionary. Let's add them now. Note, definitions here that conflict with # existing lookup entries will overwrite the existing entries. Note that # the extra check that the connector has some templates is just an # optimisation; the templates module handles connectors without templates # just fine. extra_templates = set() for c in (x for x in ast.items if isinstance(x, Connector) and ( x.from_template is not None or x.to_template is not None)): try: # Find a connection that uses this type. connection = next(x for x in ast if isinstance(x, Connection) and x.type == c) # Add the custom templates and update our collection of read # inputs. It is necessary to update the read set here to avoid # false compilation cache hits when the source of a custom template # has changed. extra_templates |= templates.add(c, connection) except TemplateError as e: die('while adding connector %s: %s' % (c.name, e)) except StopIteration: # No connections use this type. There's no point adding it to the # template lookup dictionary. pass # Check if our current target is in the level B cache. The level A cache # will 'miss' and this one will 'hit' when the input spec is identical to # some previously observed execution modulo a semantically irrelevant # element (e.g. an introduced comment). ast_hash = None if cacheb is not None: ast_hash = level_b_prime(ast) assert 'args' in locals() assert len(options.item) == 1, 'level B cache only supported when requesting ' \ 'single items' output = cacheb.load(ast_hash, args, set(options.elf) | extra_templates) if output is not None: log.debug('Retrieved %(platform)s/%(item)s from level B cache' % options.__dict__) done(output, options.outfile[0], options.item[0]) # Add custom templates. read |= extra_templates # Add the CAmkES sources themselves to the accumulated list of inputs. read |= set(path for path, _ in sources()) # Add any ELF files we were passed as inputs. read |= set(options.elf) # Write a Makefile dependency rule if requested. if options.makefile_dependencies is not None: options.makefile_dependencies.write( '%s: \\\n %s\n' % (filename, ' \\\n '.join(sorted(read)))) # If we have a cache, allow outputs to be saved to it. if options.cache: assert cachea is not None, 'level A cache not available, though the ' \ 'cache is enabled (bug in runner?)' # The logic of this cache currently only works when a single item is requested # on the command line assert len(options.item) == 1, 'level A cache only supported when requesting ' \ 'single items' # Calculate the input files to the level A cache. inputs = level_a_prime(read) # Work out the position of the --item argument in the command line # parameters. We will use this to cache not only outputs for this # execution, but also outputs for ones with a different target. item_index = None assert 'args' in locals() for index, arg in enumerate(args[:-1]): if arg in ('--item', '-T'): item_index = index + 1 break assert item_index is not None, 'failed to find required argument ' \ '--item (bug in runner?)' # We should already have the necessary inputs for the level B cache. assert cacheb is not None, 'level B cache not available, though the ' \ 'cache is enabled (bug in runner?)' assert ast_hash is not None, 'AST hash not pre-computed (bug in ' \ 'runner?)' def save(item, value): # Juggle the command line arguments to cache the predicted # arguments for a call that would generate this item. new_args = args[:item_index] + [item] + args[item_index + 1:] # Save entries in both caches. cachea.save(new_args, cwd, value, inputs) if item != 'Makefile' and item != 'camkes-gen.cmake': # We avoid caching the generated Makefile because it is not # safe. The inputs to generation of the Makefile are not only # the AST, but also the file names (`inputs`). If we cache it in # the level B cache we risk the following scenario: # # 1. Generate the Makefile, caching it in the level B cache; # 2. Modify the spec to import a file containing only white # space and/or comments; then # 3. Generate the Makefile, missing the level A cache, but # hitting the level B cache. # # At this point, the generated Makefile is incorrect because it # does not capture any dependencies on the imported file. We can # now introduce something semantically relevant into this file # (e.g. an Assembly block) and it will not be seen by the build # system. cacheb.save(ast_hash, new_args, set(options.elf) | extra_templates, value) else: def save(item, value): pass def apply_capdl_filters(): # Derive a set of usable ELF objects from the filenames we were passed. elfs = {} for e in options.elf: try: name = os.path.basename(e) if name in elfs: raise Exception( 'duplicate ELF files of name \'%s\' encountered' % name) elf = ELF(e, name, options.architecture) p = Perspective(phase=RUNNER, elf_name=name) group = p['group'] # Avoid inferring a TCB as we've already created our own. elf_spec = elf.get_spec(infer_tcb=False, infer_asid=False, pd=pds[group], use_large_frames=options.largeframe) obj_space.merge(elf_spec, label=group) elfs[name] = (e, elf) except Exception as inst: die('While opening \'%s\': %s' % (e, inst)) # It's only relevant to run these filters if the final target is CapDL. # Note, this will no longer be true if we add any other templates that # depend on a fully formed CapDL spec. Guarding this loop with an if # is just an optimisation and the conditional can be removed if # desired. filteroptions = FilterOptions( options.architecture, options.realtime, options.largeframe, options.largeframe_dma, options.default_priority, options.default_max_priority, options.default_criticality, options.default_max_criticality, options.default_affinity, options.default_period, options.default_budget, options.default_data, options.default_size_bits, options.debug_fault_handlers, options.fprovide_tcb_caps) for f in CAPDL_FILTERS: try: # Pass everything as named arguments to allow filters to # easily ignore what they don't want. f(ast=ast, obj_space=obj_space, cspaces=cspaces, elfs=elfs, options=filteroptions, shmem=shmem, fill_frames=fill_frames) except Exception as inst: die('While forming CapDL spec: %s' % inst) renderoptions = RenderOptions( options.file, options.verbosity, options.frpc_lock_elision, options.fspecialise_syscall_stubs, options.fprovide_tcb_caps, options.fsupport_init, options.largeframe, options.largeframe_dma, options.architecture, options.debug_fault_handlers, options.realtime) def instantiate_misc_template(): for (item, outfile) in (all_items - done_items): try: template = templates.lookup(item) if template: g = r.render(assembly, assembly, template, obj_space, None, shmem, kept_symbols, fill_frames, imported=read, options=renderoptions) save(item, g) done(g, outfile, item) except TemplateError as inst: die([ 'While rendering %s: %s' % (item, line) for line in inst.args ]) if options.item[0] in ('capdl', 'label-mapping') and options.data_structure_cache_dir is not None \ and len(options.outfile) == 1: # It's possible that data structures required to instantiate the capdl spec # were saved during a previous invocation of this script in the current build. cache_path = os.path.realpath(options.data_structure_cache_dir) pickle_path = os.path.join(cache_path, CAPDL_STATE_PICKLE) if os.path.isfile(pickle_path): with open(pickle_path, 'rb') as pickle_file: # Found a cached version of the necessary data structures obj_space, shmem, cspaces, pds, kept_symbols, fill_frames = pickle.load( pickle_file) apply_capdl_filters() instantiate_misc_template() # If a template wasn't instantiated, something went wrong, and we can't recover raise CAmkESError( "No template instantiated on capdl generation fastpath") # We're now ready to instantiate the template the user requested, but there # are a few wrinkles in the process. Namely, # 1. Template instantiation needs to be done in a deterministic order. The # runner is invoked multiple times and template code needs to be # allocated identical cap slots in each run. # 2. Components and connections need to be instantiated before any other # templates, regardless of whether they are the ones we are after. Some # other templates, such as the Makefile depend on the obj_space and # cspaces. # 3. All actual code templates, up to the template that was requested, # need to be instantiated. This is related to (1) in that the cap slots # allocated are dependent on what allocations have been done prior to a # given allocation call. # Instantiate the per-component source and header files. for i in assembly.composition.instances: # Don't generate any code for hardware components. if i.type.hardware: continue if i.address_space not in cspaces: p = Perspective(phase=RUNNER, instance=i.name, group=i.address_space) cnode = obj_space.alloc(seL4_CapTableObject, name=p['cnode'], label=i.address_space) cspaces[i.address_space] = CSpaceAllocator(cnode) pd = obj_space.alloc(lookup_architecture( options.architecture).vspace().object, name=p['pd'], label=i.address_space) pds[i.address_space] = pd for t in ('%s/source' % i.name, '%s/header' % i.name, '%s/linker' % i.name): try: template = templates.lookup(t, i) g = '' if template: g = r.render(i, assembly, template, obj_space, cspaces[i.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[i.address_space]) save(t, g) for (item, outfile) in (all_items - done_items): if item == t: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) break except TemplateError as inst: die([ 'While rendering %s: %s' % (i.name, line) for line in inst.args ]) # Instantiate the per-connection files. for c in assembly.composition.connections: for t in (('%s/from/source' % c.name, c.from_ends), ('%s/from/header' % c.name, c.from_ends), ('%s/to/source' % c.name, c.to_ends), ('%s/to/header' % c.name, c.to_ends)): template = templates.lookup(t[0], c) if template is not None: for id, e in enumerate(t[1]): item = '%s/%d' % (t[0], id) g = '' try: g = r.render(e, assembly, template, obj_space, cspaces[e.instance.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[e.instance.address_space]) except TemplateError as inst: die([ 'While rendering %s: %s' % (item, line) for line in inst.args ]) except jinja2.exceptions.TemplateNotFound: die('While rendering %s: missing template for %s' % (item, c.type.name)) save(item, g) for (target, outfile) in (all_items - done_items): if target == item: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) break # The following block handles instantiations of per-connection # templates that are neither a 'source' or a 'header', as handled # above. We assume that none of these need instantiation unless we are # actually currently looking for them (== options.item). That is, we # assume that following templates, like the CapDL spec, do not require # these templates to be rendered prior to themselves. # FIXME: This is a pretty ugly way of handling this. It would be nicer # for the runner to have a more general notion of per-'thing' templates # where the per-component templates, the per-connection template loop # above, and this loop could all be done in a single unified control # flow. for (item, outfile) in (all_items - done_items): for t in (('%s/from/' % c.name, c.from_ends), ('%s/to/' % c.name, c.to_ends)): if not item.startswith(t[0]): # This is not the item we're looking for. continue # If we've reached here then this is the exact item we're after. template = templates.lookup(item, c) if template is None: die('no registered template for %s' % item) for e in t[1]: try: g = r.render(e, assembly, template, obj_space, cspaces[e.instance.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[e.instance.address_space]) save(item, g) done(g, outfile, item) except TemplateError as inst: die([ 'While rendering %s: %s' % (item, line) for line in inst.args ]) # Perform any per component special generation. This needs to happen last # as these template needs to run after all other capabilities have been # allocated for i in assembly.composition.instances: # Don't generate any code for hardware components. if i.type.hardware: continue assert i.address_space in cspaces SPECIAL_TEMPLATES = [('debug', 'debug'), ('simple', 'simple'), ('rump_config', 'rumprun')] for special in [ bl for bl in SPECIAL_TEMPLATES if conf[i.name].get(bl[0]) ]: for t in ('%s/%s' % (i.name, special[1]), ): try: template = templates.lookup(t, i) g = '' if template: g = r.render(i, assembly, template, obj_space, cspaces[i.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[i.address_space]) save(t, g) for (item, outfile) in (all_items - done_items): if item == t: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) except TemplateError as inst: die([ 'While rendering %s: %s' % (i.name, line) for line in inst.args ]) if options.data_structure_cache_dir is not None: # At this point the capdl database is in the state required for applying capdl # filters and generating the capdl spec. In case the capdl spec isn't the current # target, we pickle the database here, so when the capdl spec is built, these # data structures don't need to be regenerated. cache_path = os.path.realpath(options.data_structure_cache_dir) pickle_path = os.path.join(cache_path, CAPDL_STATE_PICKLE) with open(pickle_path, 'wb') as pickle_file: pickle.dump( (obj_space, shmem, cspaces, pds, kept_symbols, fill_frames), pickle_file) for (item, outfile) in (all_items - done_items): if item in ('capdl', 'label-mapping'): apply_capdl_filters() # Instantiate any other, miscellaneous template. If we've reached this # point, we know the user did not request a code template. instantiate_misc_template() # Check if there are any remaining items not_done = all_items - done_items if len(not_done) > 0: for (item, outfile) in not_done: err.write('No valid element matching --item %s.\n' % item) return -1 return 0
def main(argv, out, err): # We need a UTF-8 locale, so bail out if we don't have one. More # specifically, things like the version() computation traverse the file # system and, if they hit a UTF-8 filename, they try to decode it into your # preferred encoding and trigger an exception. encoding = locale.getpreferredencoding().lower() if encoding not in ('utf-8', 'utf8'): err.write('CAmkES uses UTF-8 encoding, but your locale\'s preferred ' 'encoding is %s. You can override your locale with the LANG ' 'environment variable.\n' % encoding) return -1 options = parse_args(argv, out, err) # Ensure we were supplied equal items and outfiles if len(options.outfile) != len(options.item): err.write('Different number of items and outfiles. Required one outfile location ' 'per item requested.\n') return -1 # No duplicates in items or outfiles if len(set(options.item)) != len(options.item): err.write('Duplicate items requested through --item.\n') return -1 if len(set(options.outfile)) != len(options.outfile): err.write('Duplicate outfiles requrested through --outfile.\n') return -1 # Save us having to pass debugging everywhere. die = functools.partial(_die, options) log.set_verbosity(options.verbosity) cwd = os.getcwd() # Build a list of item/outfile pairs that we have yet to match and process all_items = set(zip(options.item, options.outfile)) done_items = set([]) # Construct the compilation caches if requested. cachea = None cacheb = None if options.cache: # Construct a modified version of the command line arguments that we'll # use in the keys to the caches. Essentially we elide --outfile and its # parameter under the assumption that this value is never used in code # generation. The purpose of this is to allow us to successfully cache # ancillary outputs that we generate along the way to the current # output. If we were to include --outfile in the key, future attempts # to generate these ancillary outputs would unnecessarily miss the # entries generated by this execution. args = [] skip = False for index, arg in enumerate(argv[1:]): if skip: skip = False continue if arg in ('--outfile', '-O'): skip = True continue args.append(arg) cachea = LevelACache(os.path.join(options.cache_dir, version(), 'cachea')) cacheb = LevelBCache(os.path.join(options.cache_dir, version(), 'cacheb')) def done(s, file, item): ret = 0 if s: file.write(s) file.close() if cachea is not None: try: cachea.flush() except sqlite3.OperationalError as e: # The following suppresses two spurious errors: # 1. The database is locked. In a large, parallel build, writes # to the level A cache are heavily contended and this error # can occur. # 2. The database structure is unexpected. If the CAmkES # sources have changed *while* the runner was executing, # the level A cache can be looking in a different place to # where the cache was created. # Both of these are non-critical (will just result in a # potential future cache miss) so there's no need to alarm the # user. if re.search(r'database is locked', str(e)) is not None or \ re.search(r'no such table', str(e)) is not None: log.debug('failed to flush level A cache: %s' % str(e)) else: raise if cacheb is not None: try: cacheb.flush() except sqlite3.OperationalError as e: # As above for the level B cache. if re.search(r'database is locked', str(e)): log.debug('failed to flush level B cache: %s' % str(e)) else: raise done_items.add((item, file)) if len(all_items - done_items) == 0: sys.exit(ret) # Try to find this output in the level A cache if possible. This check will # 'hit' if the source files representing the input spec are identical to # some previously observed execution. if cachea is not None: assert 'args' in locals() assert len(options.outfile) == 1, 'level A cache only supported when requestiong ' \ 'single items' output = cachea.load(args, cwd) if output is not None: log.debug('Retrieved %(platform)s/%(item)s from level A cache' % options.__dict__) done(output, options.outfile[0], options.item[0]) filename = os.path.abspath(options.file.name) try: # Build the parser options parse_options = ParserOptions(options.cpp, options.cpp_flag, options.import_path, options.verbosity, options.allow_forward_references) ast, read = parse_file_cached(filename, options.data_structure_cache_dir, parse_options) except (ASTError, ParseError) as e: die(e.args) # Locate the assembly. assembly = ast.assembly if assembly is None: die('No assembly found') # Do some extra checks if the user asked for verbose output. if options.verbosity >= 2: # Try to catch type mismatches in attribute settings. Note that it is # not possible to conclusively evaluate type correctness because the # attributes' type system is (deliberately) too loose. That is, the # type of an attribute can be an uninterpreted C type the user will # provide post hoc. for i in assembly.composition.instances: for a in i.type.attributes: value = assembly.configuration[i.name].get(a.name) if value is not None: if a.type == 'string' and not \ isinstance(value, six.string_types): log.warning('attribute %s.%s has type string but is ' 'set to a value that is not a string' % (i.name, a.name)) elif a.type == 'int' and not \ isinstance(value, numbers.Number): log.warning('attribute %s.%s has type int but is set ' 'to a value that is not an integer' % (i.name, a.name)) obj_space = ObjectAllocator() obj_space.spec.arch = options.architecture cspaces = {} pds = {} conf = assembly.configuration shmem = collections.defaultdict(ShmemFactory()) kept_symbols = {} fill_frames = {} templates = Templates(options.platform) [templates.add_root(t) for t in options.templates] try: r = Renderer(templates, options.cache, options.cache_dir) except jinja2.exceptions.TemplateSyntaxError as e: die('template syntax error: %s' % e) # The user may have provided their own connector definitions (with # associated) templates, in which case they won't be in the built-in lookup # dictionary. Let's add them now. Note, definitions here that conflict with # existing lookup entries will overwrite the existing entries. Note that # the extra check that the connector has some templates is just an # optimisation; the templates module handles connectors without templates # just fine. extra_templates = set() for c in (x for x in ast.items if isinstance(x, Connector) and (x.from_template is not None or x.to_template is not None)): try: # Find a connection that uses this type. connection = next(x for x in ast if isinstance(x, Connection) and x.type == c) # Add the custom templates and update our collection of read # inputs. It is necessary to update the read set here to avoid # false compilation cache hits when the source of a custom template # has changed. extra_templates |= templates.add(c, connection) except TemplateError as e: die('while adding connector %s: %s' % (c.name, e)) except StopIteration: # No connections use this type. There's no point adding it to the # template lookup dictionary. pass # Check if our current target is in the level B cache. The level A cache # will 'miss' and this one will 'hit' when the input spec is identical to # some previously observed execution modulo a semantically irrelevant # element (e.g. an introduced comment). ast_hash = None if cacheb is not None: ast_hash = level_b_prime(ast) assert 'args' in locals() assert len(options.item) == 1, 'level B cache only supported when requesting ' \ 'single items' output = cacheb.load(ast_hash, args, set(options.elf) | extra_templates) if output is not None: log.debug('Retrieved %(platform)s/%(item)s from level B cache' % options.__dict__) done(output, options.outfile[0], options.item[0]) # Add custom templates. read |= extra_templates # Add the CAmkES sources themselves to the accumulated list of inputs. read |= set(path for path, _ in sources()) # Add any ELF files we were passed as inputs. read |= set(options.elf) # Write a Makefile dependency rule if requested. if options.makefile_dependencies is not None: options.makefile_dependencies.write('%s: \\\n %s\n' % (filename, ' \\\n '.join(sorted(read)))) # If we have a cache, allow outputs to be saved to it. if options.cache: assert cachea is not None, 'level A cache not available, though the ' \ 'cache is enabled (bug in runner?)' # The logic of this cache currently only works when a single item is requested # on the command line assert len(options.item) == 1, 'level A cache only supported when requesting ' \ 'single items' # Calculate the input files to the level A cache. inputs = level_a_prime(read) # Work out the position of the --item argument in the command line # parameters. We will use this to cache not only outputs for this # execution, but also outputs for ones with a different target. item_index = None assert 'args' in locals() for index, arg in enumerate(args[:-1]): if arg in ('--item', '-T'): item_index = index + 1 break assert item_index is not None, 'failed to find required argument ' \ '--item (bug in runner?)' # We should already have the necessary inputs for the level B cache. assert cacheb is not None, 'level B cache not available, though the ' \ 'cache is enabled (bug in runner?)' assert ast_hash is not None, 'AST hash not pre-computed (bug in ' \ 'runner?)' def save(item, value): # Juggle the command line arguments to cache the predicted # arguments for a call that would generate this item. new_args = args[:item_index] + [item] + args[item_index + 1:] # Save entries in both caches. cachea.save(new_args, cwd, value, inputs) if item != 'Makefile' and item != 'camkes-gen.cmake': # We avoid caching the generated Makefile because it is not # safe. The inputs to generation of the Makefile are not only # the AST, but also the file names (`inputs`). If we cache it in # the level B cache we risk the following scenario: # # 1. Generate the Makefile, caching it in the level B cache; # 2. Modify the spec to import a file containing only white # space and/or comments; then # 3. Generate the Makefile, missing the level A cache, but # hitting the level B cache. # # At this point, the generated Makefile is incorrect because it # does not capture any dependencies on the imported file. We can # now introduce something semantically relevant into this file # (e.g. an Assembly block) and it will not be seen by the build # system. cacheb.save(ast_hash, new_args, set(options.elf) | extra_templates, value) else: def save(item, value): pass def apply_capdl_filters(): # Derive a set of usable ELF objects from the filenames we were passed. elfs = {} for e in options.elf: try: name = os.path.basename(e) if name in elfs: raise Exception('duplicate ELF files of name \'%s\' encountered' % name) elf = ELF(e, name, options.architecture) p = Perspective(phase=RUNNER, elf_name=name) group = p['group'] # Avoid inferring a TCB as we've already created our own. elf_spec = elf.get_spec(infer_tcb=False, infer_asid=False, pd=pds[group], use_large_frames=options.largeframe) obj_space.merge(elf_spec, label=group) elfs[name] = (e, elf) except Exception as inst: die('While opening \'%s\': %s' % (e, inst)) filteroptions = FilterOptions(options.architecture, options.realtime, options.largeframe, options.largeframe_dma, options.default_priority, options.default_max_priority, options.default_affinity, options.default_period, options.default_budget, options.default_data, options.default_size_bits, options.debug_fault_handlers, options.fprovide_tcb_caps) for f in CAPDL_FILTERS: try: # Pass everything as named arguments to allow filters to # easily ignore what they don't want. f(ast=ast, obj_space=obj_space, cspaces=cspaces, elfs=elfs, options=filteroptions, shmem=shmem, fill_frames=fill_frames) except Exception as inst: die('While forming CapDL spec: %s' % inst) renderoptions = RenderOptions(options.file, options.verbosity, options.frpc_lock_elision, options.fspecialise_syscall_stubs, options.fprovide_tcb_caps, options.fsupport_init, options.largeframe, options.largeframe_dma, options.architecture, options.debug_fault_handlers, options.realtime) def instantiate_misc_template(): for (item, outfile) in (all_items - done_items): try: template = templates.lookup(item) if template: g = r.render(assembly, assembly, template, obj_space, None, shmem, kept_symbols, fill_frames, imported=read, options=renderoptions) save(item, g) done(g, outfile, item) except TemplateError as inst: die(rendering_error(item, inst)) if options.item[0] in ('capdl', 'label-mapping') and options.data_structure_cache_dir is not None \ and len(options.outfile) == 1: # It's possible that data structures required to instantiate the capdl spec # were saved during a previous invocation of this script in the current build. cache_path = os.path.realpath(options.data_structure_cache_dir) pickle_path = os.path.join(cache_path, CAPDL_STATE_PICKLE) if os.path.isfile(pickle_path): with open(pickle_path, 'rb') as pickle_file: # Found a cached version of the necessary data structures obj_space, shmem, cspaces, pds, kept_symbols, fill_frames = pickle.load(pickle_file) apply_capdl_filters() instantiate_misc_template() # If a template wasn't instantiated, something went wrong, and we can't recover raise CAmkESError("No template instantiated on capdl generation fastpath") # We're now ready to instantiate the template the user requested, but there # are a few wrinkles in the process. Namely, # 1. Template instantiation needs to be done in a deterministic order. The # runner is invoked multiple times and template code needs to be # allocated identical cap slots in each run. # 2. Components and connections need to be instantiated before any other # templates, regardless of whether they are the ones we are after. Some # other templates, such as the Makefile depend on the obj_space and # cspaces. # 3. All actual code templates, up to the template that was requested, # need to be instantiated. This is related to (1) in that the cap slots # allocated are dependent on what allocations have been done prior to a # given allocation call. # Instantiate the per-component source and header files. for i in assembly.composition.instances: # Don't generate any code for hardware components. if i.type.hardware: continue if i.address_space not in cspaces: p = Perspective(phase=RUNNER, instance=i.name, group=i.address_space) cnode = obj_space.alloc(seL4_CapTableObject, name=p['cnode'], label=i.address_space) cspaces[i.address_space] = CSpaceAllocator(cnode) pd = obj_space.alloc(lookup_architecture(options.architecture).vspace().object, name=p['pd'], label=i.address_space) pds[i.address_space] = pd for t in ('%s/source' % i.name, '%s/header' % i.name, '%s/c_environment_source' % i.name, '%s/cakeml_start_source' % i.name, '%s/cakeml_end_source' % i.name, '%s/linker' % i.name): try: template = templates.lookup(t, i) g = '' if template: g = r.render(i, assembly, template, obj_space, cspaces[i.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[i.address_space]) save(t, g) for (item, outfile) in (all_items - done_items): if item == t: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) break except TemplateError as inst: die(rendering_error(i.name, inst)) # Instantiate the per-connection files. for c in assembly.composition.connections: for t in (('%s/from/source' % c.name, c.from_ends), ('%s/from/header' % c.name, c.from_ends), ('%s/to/source' % c.name, c.to_ends), ('%s/to/header' % c.name, c.to_ends)): template = templates.lookup(t[0], c) if template is not None: for id, e in enumerate(t[1]): item = '%s/%d' % (t[0], id) g = '' try: g = r.render(e, assembly, template, obj_space, cspaces[e.instance.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[e.instance.address_space]) except TemplateError as inst: die(rendering_error(item, inst)) except jinja2.exceptions.TemplateNotFound: die('While rendering %s: missing template for %s' % (item, c.type.name)) save(item, g) for (target, outfile) in (all_items - done_items): if target == item: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) break # The following block handles instantiations of per-connection # templates that are neither a 'source' or a 'header', as handled # above. We assume that none of these need instantiation unless we are # actually currently looking for them (== options.item). That is, we # assume that following templates, like the CapDL spec, do not require # these templates to be rendered prior to themselves. # FIXME: This is a pretty ugly way of handling this. It would be nicer # for the runner to have a more general notion of per-'thing' templates # where the per-component templates, the per-connection template loop # above, and this loop could all be done in a single unified control # flow. for (item, outfile) in (all_items - done_items): for t in (('%s/from/' % c.name, c.from_ends), ('%s/to/' % c.name, c.to_ends)): if not item.startswith(t[0]): # This is not the item we're looking for. continue # If we've reached here then this is the exact item we're after. template = templates.lookup(item, c) if template is None: die('no registered template for %s' % item) for e in t[1]: try: g = r.render(e, assembly, template, obj_space, cspaces[e.instance.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[e.instance.address_space]) save(item, g) done(g, outfile, item) except TemplateError as inst: die(rendering_error(item, inst)) # Perform any per component special generation. This needs to happen last # as these template needs to run after all other capabilities have been # allocated for i in assembly.composition.instances: # Don't generate any code for hardware components. if i.type.hardware: continue assert i.address_space in cspaces SPECIAL_TEMPLATES = [('debug', 'debug'), ('simple', 'simple'), ('rump_config', 'rumprun')] for special in [bl for bl in SPECIAL_TEMPLATES if conf[i.name].get(bl[0])]: for t in ('%s/%s' % (i.name, special[1]),): try: template = templates.lookup(t, i) g = '' if template: g = r.render(i, assembly, template, obj_space, cspaces[i.address_space], shmem, kept_symbols, fill_frames, options=renderoptions, my_pd=pds[i.address_space]) save(t, g) for (item, outfile) in (all_items - done_items): if item == t: if not template: log.warning('Warning: no template for %s' % item) done(g, outfile, item) except TemplateError as inst: die(rendering_error(i.name, inst)) if options.data_structure_cache_dir is not None: # At this point the capdl database is in the state required for applying capdl # filters and generating the capdl spec. In case the capdl spec isn't the current # target, we pickle the database here, so when the capdl spec is built, these # data structures don't need to be regenerated. cache_path = os.path.realpath(options.data_structure_cache_dir) pickle_path = os.path.join(cache_path, CAPDL_STATE_PICKLE) with open(pickle_path, 'wb') as pickle_file: pickle.dump((obj_space, shmem, cspaces, pds, kept_symbols, fill_frames), pickle_file) for (item, outfile) in (all_items - done_items): if item in ('capdl', 'label-mapping'): apply_capdl_filters() # Instantiate any other, miscellaneous template. If we've reached this # point, we know the user did not request a code template. instantiate_misc_template() # Check if there are any remaining items not_done = all_items - done_items if len(not_done) > 0: for (item, outfile) in not_done: err.write('No valid element matching --item %s.\n' % item) return -1 return 0