# SPDX-License-Identifier: Apache-2.0 # Copyright 2013-2024 The Meson development team # Copyright © 2023-2024 Intel Corporation from __future__ import annotations import copy from . import mlog, options import pickle, os, uuid import sys from itertools import chain from pathlib import PurePath from collections import OrderedDict, abc from dataclasses import dataclass from .mesonlib import ( MesonBugException, MesonException, MachineChoice, PerMachine, PerMachineDefaultable, OptionKey, OptionType, stringlistify, pickle_load ) from .machinefile import CmdLineFileParser import ast import argparse import enum import shlex import typing as T if T.TYPE_CHECKING: from typing_extensions import Protocol from . import dependencies from .compilers.compilers import Compiler, CompileResult, RunResult, CompileCheckMode from .dependencies.detect import TV_DepID from .environment import Environment from .mesonlib import FileOrString from .cmake.traceparser import CMakeCacheEntry from .interpreterbase import SubProject class SharedCMDOptions(Protocol): """Representation of command line options from Meson setup, configure, and dist. :param projectoptions: The raw list of command line options given :param cmd_line_options: command line options parsed into an OptionKey: str mapping """ cmd_line_options: T.Dict[OptionKey, str] projectoptions: T.List[str] cross_file: T.List[str] native_file: T.List[str] OptionDictType = T.Union[T.Dict[str, 'options.UserOption[T.Any]'], 'OptionsView'] MutableKeyedOptionDictType = T.Dict['OptionKey', 'options.UserOption[T.Any]'] KeyedOptionDictType = T.Union[MutableKeyedOptionDictType, 'OptionsView'] CompilerCheckCacheKey = T.Tuple[T.Tuple[str, ...], str, FileOrString, T.Tuple[str, ...], CompileCheckMode] # code, args RunCheckCacheKey = T.Tuple[str, T.Tuple[str, ...]] # typeshed StrOrBytesPath = T.Union[str, bytes, os.PathLike[str], os.PathLike[bytes]] # Check major_versions_differ() if changing versioning scheme. # # Pip requires that RCs are named like this: '0.1.0.rc1' # But the corresponding Git tag needs to be '0.1.0rc1' version = '1.4.99' # The next stable version when we are in dev. This is used to allow projects to # require meson version >=1.2.0 when using 1.1.99. FeatureNew won't warn when # using a feature introduced in 1.2.0 when using Meson 1.1.99. stable_version = version if stable_version.endswith('.99'): stable_version_array = stable_version.split('.') stable_version_array[-1] = '0' stable_version_array[-2] = str(int(stable_version_array[-2]) + 1) stable_version = '.'.join(stable_version_array) def get_genvs_default_buildtype_list() -> list[str]: # just debug, debugoptimized, and release for now # but this should probably be configurable through some extra option, alongside --genvslite. return options.buildtypelist[1:-2] class MesonVersionMismatchException(MesonException): '''Build directory generated with Meson version is incompatible with current version''' def __init__(self, old_version: str, current_version: str, extra_msg: str = '') -> None: super().__init__(f'Build directory has been generated with Meson version {old_version}, ' f'which is incompatible with the current version {current_version}.' + extra_msg) self.old_version = old_version self.current_version = current_version class DependencyCacheType(enum.Enum): OTHER = 0 PKG_CONFIG = 1 CMAKE = 2 @classmethod def from_type(cls, dep: 'dependencies.Dependency') -> 'DependencyCacheType': # As more types gain search overrides they'll need to be added here if dep.type_name == 'pkgconfig': return cls.PKG_CONFIG if dep.type_name == 'cmake': return cls.CMAKE return cls.OTHER class DependencySubCache: def __init__(self, type_: DependencyCacheType): self.types = [type_] self.__cache: T.Dict[T.Tuple[str, ...], 'dependencies.Dependency'] = {} def __getitem__(self, key: T.Tuple[str, ...]) -> 'dependencies.Dependency': return self.__cache[key] def __setitem__(self, key: T.Tuple[str, ...], value: 'dependencies.Dependency') -> None: self.__cache[key] = value def __contains__(self, key: T.Tuple[str, ...]) -> bool: return key in self.__cache def values(self) -> T.Iterable['dependencies.Dependency']: return self.__cache.values() class DependencyCache: """Class that stores a cache of dependencies. This class is meant to encapsulate the fact that we need multiple keys to successfully lookup by providing a simple get/put interface. """ def __init__(self, builtins: 'KeyedOptionDictType', for_machine: MachineChoice): self.__cache: T.MutableMapping[TV_DepID, DependencySubCache] = OrderedDict() self.__builtins = builtins self.__pkg_conf_key = OptionKey('pkg_config_path', machine=for_machine) self.__cmake_key = OptionKey('cmake_prefix_path', machine=for_machine) def __calculate_subkey(self, type_: DependencyCacheType) -> T.Tuple[str, ...]: data: T.Dict[DependencyCacheType, T.List[str]] = { DependencyCacheType.PKG_CONFIG: stringlistify(self.__builtins[self.__pkg_conf_key].value), DependencyCacheType.CMAKE: stringlistify(self.__builtins[self.__cmake_key].value), DependencyCacheType.OTHER: [], } assert type_ in data, 'Someone forgot to update subkey calculations for a new type' return tuple(data[type_]) def __iter__(self) -> T.Iterator['TV_DepID']: return self.keys() def put(self, key: 'TV_DepID', dep: 'dependencies.Dependency') -> None: t = DependencyCacheType.from_type(dep) if key not in self.__cache: self.__cache[key] = DependencySubCache(t) subkey = self.__calculate_subkey(t) self.__cache[key][subkey] = dep def get(self, key: 'TV_DepID') -> T.Optional['dependencies.Dependency']: """Get a value from the cache. If there is no cache entry then None will be returned. """ try: val = self.__cache[key] except KeyError: return None for t in val.types: subkey = self.__calculate_subkey(t) try: return val[subkey] except KeyError: pass return None def values(self) -> T.Iterator['dependencies.Dependency']: for c in self.__cache.values(): yield from c.values() def keys(self) -> T.Iterator['TV_DepID']: return iter(self.__cache.keys()) def items(self) -> T.Iterator[T.Tuple['TV_DepID', T.List['dependencies.Dependency']]]: for k, v in self.__cache.items(): vs: T.List[dependencies.Dependency] = [] for t in v.types: subkey = self.__calculate_subkey(t) if subkey in v: vs.append(v[subkey]) yield k, vs def clear(self) -> None: self.__cache.clear() class CMakeStateCache: """Class that stores internal CMake compiler states. This cache is used to reduce the startup overhead of CMake by caching all internal CMake compiler variables. """ def __init__(self) -> None: self.__cache: T.Dict[str, T.Dict[str, T.List[str]]] = {} self.cmake_cache: T.Dict[str, 'CMakeCacheEntry'] = {} def __iter__(self) -> T.Iterator[T.Tuple[str, T.Dict[str, T.List[str]]]]: return iter(self.__cache.items()) def items(self) -> T.Iterator[T.Tuple[str, T.Dict[str, T.List[str]]]]: return iter(self.__cache.items()) def update(self, language: str, variables: T.Dict[str, T.List[str]]): if language not in self.__cache: self.__cache[language] = {} self.__cache[language].update(variables) @property def languages(self) -> T.Set[str]: return set(self.__cache.keys()) # Can't bind this near the class method it seems, sadly. _V = T.TypeVar('_V') # This class contains all data that must persist over multiple # invocations of Meson. It is roughly the same thing as # cmakecache. class CoreData: def __init__(self, options: SharedCMDOptions, scratch_dir: str, meson_command: T.List[str]): self.lang_guids = { 'default': '8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942', 'c': '8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942', 'cpp': '8BC9CEB8-8B4A-11D0-8D11-00A0C91BC942', 'test': '3AC096D0-A1C2-E12C-1390-A8335801FDAB', 'directory': '2150E333-8FDC-42A3-9474-1A3956D46DE8', } self.test_guid = str(uuid.uuid4()).upper() self.regen_guid = str(uuid.uuid4()).upper() self.install_guid = str(uuid.uuid4()).upper() self.meson_command = meson_command self.target_guids = {} self.version = version self.options: 'MutableKeyedOptionDictType' = {} self.cross_files = self.__load_config_files(options, scratch_dir, 'cross') self.compilers: PerMachine[T.Dict[str, Compiler]] = PerMachine(OrderedDict(), OrderedDict()) # Stores the (name, hash) of the options file, The name will be either # "meson_options.txt" or "meson.options". # This is used by mconf to reload the option file if it's changed. self.options_files: T.Dict[SubProject, T.Optional[T.Tuple[str, str]]] = {} # Set of subprojects that have already been initialized once, this is # required to be stored and reloaded with the coredata, as we don't # want to overwrite options for such subprojects. self.initialized_subprojects: T.Set[str] = set() # For host == build configurations these caches should be the same. self.deps: PerMachine[DependencyCache] = PerMachineDefaultable.default( self.is_cross_build(), DependencyCache(self.options, MachineChoice.BUILD), DependencyCache(self.options, MachineChoice.HOST)) self.compiler_check_cache: T.Dict['CompilerCheckCacheKey', 'CompileResult'] = OrderedDict() self.run_check_cache: T.Dict['RunCheckCacheKey', 'RunResult'] = OrderedDict() # CMake cache self.cmake_cache: PerMachine[CMakeStateCache] = PerMachine(CMakeStateCache(), CMakeStateCache()) # Only to print a warning if it changes between Meson invocations. self.config_files = self.__load_config_files(options, scratch_dir, 'native') self.builtin_options_libdir_cross_fixup() self.init_builtins('') @staticmethod def __load_config_files(options: SharedCMDOptions, scratch_dir: str, ftype: str) -> T.List[str]: # Need to try and make the passed filenames absolute because when the # files are parsed later we'll have chdir()d. if ftype == 'cross': filenames = options.cross_file else: filenames = options.native_file if not filenames: return [] found_invalid: T.List[str] = [] missing: T.List[str] = [] real: T.List[str] = [] for i, f in enumerate(filenames): f = os.path.expanduser(os.path.expandvars(f)) if os.path.exists(f): if os.path.isfile(f): real.append(os.path.abspath(f)) continue elif os.path.isdir(f): found_invalid.append(os.path.abspath(f)) else: # in this case we've been passed some kind of pipe, copy # the contents of that file into the meson private (scratch) # directory so that it can be re-read when wiping/reconfiguring copy = os.path.join(scratch_dir, f'{uuid.uuid4()}.{ftype}.ini') with open(f, encoding='utf-8') as rf: with open(copy, 'w', encoding='utf-8') as wf: wf.write(rf.read()) real.append(copy) # Also replace the command line argument, as the pipe # probably won't exist on reconfigure filenames[i] = copy continue if sys.platform != 'win32': paths = [ os.environ.get('XDG_DATA_HOME', os.path.expanduser('~/.local/share')), ] + os.environ.get('XDG_DATA_DIRS', '/usr/local/share:/usr/share').split(':') for path in paths: path_to_try = os.path.join(path, 'meson', ftype, f) if os.path.isfile(path_to_try): real.append(path_to_try) break else: missing.append(f) else: missing.append(f) if missing: if found_invalid: mlog.log('Found invalid candidates for', ftype, 'file:', *found_invalid) mlog.log('Could not find any valid candidate for', ftype, 'files:', *missing) raise MesonException(f'Cannot find specified {ftype} file: {f}') return real def builtin_options_libdir_cross_fixup(self) -> None: # By default set libdir to "lib" when cross compiling since # getting the "system default" is always wrong on multiarch # platforms as it gets a value like lib/x86_64-linux-gnu. if self.cross_files: options.BUILTIN_OPTIONS[OptionKey('libdir')].default = 'lib' def sanitize_prefix(self, prefix: str) -> str: prefix = os.path.expanduser(prefix) if not os.path.isabs(prefix): raise MesonException(f'prefix value {prefix!r} must be an absolute path') if prefix.endswith('/') or prefix.endswith('\\'): # On Windows we need to preserve the trailing slash if the # string is of type 'C:\' because 'C:' is not an absolute path. if len(prefix) == 3 and prefix[1] == ':': pass # If prefix is a single character, preserve it since it is # the root directory. elif len(prefix) == 1: pass else: prefix = prefix[:-1] return prefix def sanitize_dir_option_value(self, prefix: str, option: OptionKey, value: T.Any) -> T.Any: ''' If the option is an installation directory option, the value is an absolute path and resides within prefix, return the value as a path relative to the prefix. Otherwise, return it as is. This way everyone can do f.ex, get_option('libdir') and usually get the library directory relative to prefix, even though it really should not be relied upon. ''' try: value = PurePath(value) except TypeError: return value if option.name.endswith('dir') and value.is_absolute() and \ option not in options.BUILTIN_DIR_NOPREFIX_OPTIONS: try: # Try to relativize the path. value = value.relative_to(prefix) except ValueError: # Path is not relative, let’s keep it as is. pass if '..' in value.parts: raise MesonException( f'The value of the \'{option}\' option is \'{value}\' but ' 'directory options are not allowed to contain \'..\'.\n' f'If you need a path outside of the {prefix!r} prefix, ' 'please use an absolute path.' ) # .as_posix() keeps the posix-like file separators Meson uses. return value.as_posix() def init_builtins(self, subproject: str) -> None: # Create builtin options with default values for key, opt in options.BUILTIN_OPTIONS.items(): self.add_builtin_option(self.options, key.evolve(subproject=subproject), opt) for for_machine in iter(MachineChoice): for key, opt in options.BUILTIN_OPTIONS_PER_MACHINE.items(): self.add_builtin_option(self.options, key.evolve(subproject=subproject, machine=for_machine), opt) @staticmethod def add_builtin_option(opts_map: 'MutableKeyedOptionDictType', key: OptionKey, opt: 'options.BuiltinOption') -> None: if key.subproject: if opt.yielding: # This option is global and not per-subproject return value = opts_map[key.as_root()].value else: value = None opts_map[key] = opt.init_option(key, value, options.default_prefix()) def init_backend_options(self, backend_name: str) -> None: if backend_name == 'ninja': self.options[OptionKey('backend_max_links')] = options.UserIntegerOption( 'backend_max_links', 'Maximum number of linker processes to run or 0 for no ' 'limit', (0, None, 0)) elif backend_name.startswith('vs'): self.options[OptionKey('backend_startup_project')] = options.UserStringOption( 'backend_startup_project', 'Default project to execute in Visual Studio', '') def get_option(self, key: OptionKey) -> T.Union[T.List[str], str, int, bool]: try: v = self.options[key].value return v except KeyError: pass try: v = self.options[key.as_root()] if v.yielding: return v.value except KeyError: pass raise MesonException(f'Tried to get unknown builtin option {str(key)}') def set_option(self, key: OptionKey, value, first_invocation: bool = False) -> bool: dirty = False if key.is_builtin(): if key.name == 'prefix': value = self.sanitize_prefix(value) else: prefix = self.options[OptionKey('prefix')].value value = self.sanitize_dir_option_value(prefix, key, value) try: opt = self.options[key] except KeyError: raise MesonException(f'Tried to set unknown builtin option {str(key)}') if opt.deprecated is True: mlog.deprecation(f'Option {key.name!r} is deprecated') elif isinstance(opt.deprecated, list): for v in opt.listify(value): if v in opt.deprecated: mlog.deprecation(f'Option {key.name!r} value {v!r} is deprecated') elif isinstance(opt.deprecated, dict): def replace(v): newvalue = opt.deprecated.get(v) if newvalue is not None: mlog.deprecation(f'Option {key.name!r} value {v!r} is replaced by {newvalue!r}') return newvalue return v newvalue = [replace(v) for v in opt.listify(value)] value = ','.join(newvalue) elif isinstance(opt.deprecated, str): # Option is deprecated and replaced by another. Note that a project # option could be replaced by a built-in or module option, which is # why we use OptionKey.from_string(newname) instead of # key.evolve(newname). We set the value on both the old and new names, # assuming they accept the same value. That could for example be # achieved by adding the values from old option as deprecated on the # new option, for example in the case of boolean option is replaced # by a feature option with a different name. newname = opt.deprecated newkey = OptionKey.from_string(newname).evolve(subproject=key.subproject) mlog.deprecation(f'Option {key.name!r} is replaced by {newname!r}') dirty |= self.set_option(newkey, value, first_invocation) changed = opt.set_value(value) if changed and opt.readonly and not first_invocation: raise MesonException(f'Tried modify read only option {str(key)!r}') dirty |= changed if key.name == 'buildtype': dirty |= self._set_others_from_buildtype(value) return dirty def clear_cache(self) -> None: self.deps.host.clear() self.deps.build.clear() self.compiler_check_cache.clear() self.run_check_cache.clear() def get_nondefault_buildtype_args(self) -> T.List[T.Union[T.Tuple[str, str, str], T.Tuple[str, bool, bool]]]: result: T.List[T.Union[T.Tuple[str, str, str], T.Tuple[str, bool, bool]]] = [] value = self.options[OptionKey('buildtype')].value if value == 'plain': opt = 'plain' debug = False elif value == 'debug': opt = '0' debug = True elif value == 'debugoptimized': opt = '2' debug = True elif value == 'release': opt = '3' debug = False elif value == 'minsize': opt = 's' debug = True else: assert value == 'custom' return [] actual_opt = self.options[OptionKey('optimization')].value actual_debug = self.options[OptionKey('debug')].value if actual_opt != opt: result.append(('optimization', actual_opt, opt)) if actual_debug != debug: result.append(('debug', actual_debug, debug)) return result def _set_others_from_buildtype(self, value: str) -> bool: dirty = False if value == 'plain': opt = 'plain' debug = False elif value == 'debug': opt = '0' debug = True elif value == 'debugoptimized': opt = '2' debug = True elif value == 'release': opt = '3' debug = False elif value == 'minsize': opt = 's' debug = True else: assert value == 'custom' return False dirty |= self.options[OptionKey('optimization')].set_value(opt) dirty |= self.options[OptionKey('debug')].set_value(debug) return dirty @staticmethod def is_per_machine_option(optname: OptionKey) -> bool: if optname.as_host() in options.BUILTIN_OPTIONS_PER_MACHINE: return True return optname.lang is not None def get_external_args(self, for_machine: MachineChoice, lang: str) -> T.List[str]: # mypy cannot analyze type of OptionKey return T.cast('T.List[str]', self.options[OptionKey('args', machine=for_machine, lang=lang)].value) def get_external_link_args(self, for_machine: MachineChoice, lang: str) -> T.List[str]: # mypy cannot analyze type of OptionKey return T.cast('T.List[str]', self.options[OptionKey('link_args', machine=for_machine, lang=lang)].value) def update_project_options(self, options: 'MutableKeyedOptionDictType', subproject: SubProject) -> None: for key, value in options.items(): if not key.is_project(): continue if key not in self.options: self.options[key] = value continue if key.subproject != subproject: raise MesonBugException(f'Tried to set an option for subproject {key.subproject} from {subproject}!') oldval = self.options[key] if type(oldval) is not type(value): self.options[key] = value elif oldval.choices != value.choices: # If the choices have changed, use the new value, but attempt # to keep the old options. If they are not valid keep the new # defaults but warn. self.options[key] = value try: value.set_value(oldval.value) except MesonException: mlog.warning(f'Old value(s) of {key} are no longer valid, resetting to default ({value.value}).', fatal=False) # Find any extranious keys for this project and remove them for key in self.options.keys() - options.keys(): if key.is_project() and key.subproject == subproject: del self.options[key] def is_cross_build(self, when_building_for: MachineChoice = MachineChoice.HOST) -> bool: if when_building_for == MachineChoice.BUILD: return False return len(self.cross_files) > 0 def copy_build_options_from_regular_ones(self) -> bool: dirty = False assert not self.is_cross_build() for k in options.BUILTIN_OPTIONS_PER_MACHINE: o = self.options[k] dirty |= self.options[k.as_build()].set_value(o.value) for bk, bv in self.options.items(): if bk.machine is MachineChoice.BUILD: hk = bk.as_host() try: hv = self.options[hk] dirty |= bv.set_value(hv.value) except KeyError: continue return dirty def set_options(self, opts_to_set: T.Dict[OptionKey, T.Any], subproject: str = '', first_invocation: bool = False) -> bool: dirty = False if not self.is_cross_build(): opts_to_set = {k: v for k, v in opts_to_set.items() if k.machine is not MachineChoice.BUILD} # Set prefix first because it's needed to sanitize other options pfk = OptionKey('prefix') if pfk in opts_to_set: prefix = self.sanitize_prefix(opts_to_set[pfk]) dirty |= self.options[OptionKey('prefix')].set_value(prefix) for key in options.BUILTIN_DIR_NOPREFIX_OPTIONS: if key not in opts_to_set: dirty |= self.options[key].set_value(options.BUILTIN_OPTIONS[key].prefixed_default(key, prefix)) unknown_options: T.List[OptionKey] = [] for k, v in opts_to_set.items(): if k == pfk: continue elif k in self.options: dirty |= self.set_option(k, v, first_invocation) elif k.machine != MachineChoice.BUILD and k.type != OptionType.COMPILER: unknown_options.append(k) if unknown_options: unknown_options_str = ', '.join(sorted(str(s) for s in unknown_options)) sub = f'In subproject {subproject}: ' if subproject else '' raise MesonException(f'{sub}Unknown options: "{unknown_options_str}"') if not self.is_cross_build(): dirty |= self.copy_build_options_from_regular_ones() return dirty def set_default_options(self, default_options: T.MutableMapping[OptionKey, str], subproject: str, env: 'Environment') -> None: from .compilers import base_options # Main project can set default options on subprojects, but subprojects # can only set default options on themselves. # Preserve order: if env.options has 'buildtype' it must come after # 'optimization' if it is in default_options. options: T.MutableMapping[OptionKey, T.Any] = OrderedDict() for k, v in default_options.items(): if not subproject or k.subproject == subproject: options[k] = v options.update(env.options) env.options = options # Create a subset of options, keeping only project and builtin # options for this subproject. # Language and backend specific options will be set later when adding # languages and setting the backend (builtin options must be set first # to know which backend we'll use). options = OrderedDict() for k, v in env.options.items(): # If this is a subproject, don't use other subproject options if k.subproject and k.subproject != subproject: continue # If the option is a builtin and is yielding then it's not allowed per subproject. # # Always test this using the HOST machine, as many builtin options # are not valid for the BUILD machine, but the yielding value does # not differ between them even when they are valid for both. if subproject and k.is_builtin() and self.options[k.evolve(subproject='', machine=MachineChoice.HOST)].yielding: continue # Skip base, compiler, and backend options, they are handled when # adding languages and setting backend. if k.type in {OptionType.COMPILER, OptionType.BACKEND}: continue if k.type == OptionType.BASE and k.as_root() in base_options: # set_options will report unknown base options continue options[k] = v self.set_options(options, subproject=subproject, first_invocation=env.first_invocation) def add_compiler_options(self, options: MutableKeyedOptionDictType, lang: str, for_machine: MachineChoice, env: Environment, subproject: str) -> None: for k, o in options.items(): value = env.options.get(k) if value is not None: o.set_value(value) if not subproject: self.options[k] = o # override compiler option on reconfigure self.options.setdefault(k, o) if subproject: sk = k.evolve(subproject=subproject) value = env.options.get(sk) or value if value is not None: o.set_value(value) self.options[sk] = o # override compiler option on reconfigure self.options.setdefault(sk, o) def add_lang_args(self, lang: str, comp: T.Type['Compiler'], for_machine: MachineChoice, env: 'Environment') -> None: """Add global language arguments that are needed before compiler/linker detection.""" from .compilers import compilers # These options are all new at this point, because the compiler is # responsible for adding its own options, thus calling # `self.options.update()`` is perfectly safe. self.options.update(compilers.get_global_options(lang, comp, for_machine, env)) def process_compiler_options(self, lang: str, comp: Compiler, env: Environment, subproject: str) -> None: from . import compilers self.add_compiler_options(comp.get_options(), lang, comp.for_machine, env, subproject) enabled_opts: T.List[OptionKey] = [] for key in comp.base_options: if subproject: skey = key.evolve(subproject=subproject) else: skey = key if skey not in self.options: self.options[skey] = copy.deepcopy(compilers.base_options[key]) if skey in env.options: self.options[skey].set_value(env.options[skey]) enabled_opts.append(skey) elif subproject and key in env.options: self.options[skey].set_value(env.options[key]) enabled_opts.append(skey) if subproject and key not in self.options: self.options[key] = copy.deepcopy(self.options[skey]) elif skey in env.options: self.options[skey].set_value(env.options[skey]) elif subproject and key in env.options: self.options[skey].set_value(env.options[key]) self.emit_base_options_warnings(enabled_opts) def emit_base_options_warnings(self, enabled_opts: T.List[OptionKey]) -> None: if OptionKey('b_bitcode') in enabled_opts: mlog.warning('Base option \'b_bitcode\' is enabled, which is incompatible with many linker options. Incompatible options such as \'b_asneeded\' have been disabled.', fatal=False) mlog.warning('Please see https://mesonbuild.com/Builtin-options.html#Notes_about_Apple_Bitcode_support for more details.', fatal=False) def get_cmd_line_file(build_dir: str) -> str: return os.path.join(build_dir, 'meson-private', 'cmd_line.txt') def read_cmd_line_file(build_dir: str, options: SharedCMDOptions) -> None: filename = get_cmd_line_file(build_dir) if not os.path.isfile(filename): return config = CmdLineFileParser() config.read(filename) # Do a copy because config is not really a dict. options.cmd_line_options # overrides values from the file. d = {OptionKey.from_string(k): v for k, v in config['options'].items()} d.update(options.cmd_line_options) options.cmd_line_options = d properties = config['properties'] if not options.cross_file: options.cross_file = ast.literal_eval(properties.get('cross_file', '[]')) if not options.native_file: # This will be a string in the form: "['first', 'second', ...]", use # literal_eval to get it into the list of strings. options.native_file = ast.literal_eval(properties.get('native_file', '[]')) def write_cmd_line_file(build_dir: str, options: SharedCMDOptions) -> None: filename = get_cmd_line_file(build_dir) config = CmdLineFileParser() properties: OrderedDict[str, str] = OrderedDict() if options.cross_file: properties['cross_file'] = options.cross_file if options.native_file: properties['native_file'] = options.native_file config['options'] = {str(k): str(v) for k, v in options.cmd_line_options.items()} config['properties'] = properties with open(filename, 'w', encoding='utf-8') as f: config.write(f) def update_cmd_line_file(build_dir: str, options: SharedCMDOptions) -> None: filename = get_cmd_line_file(build_dir) config = CmdLineFileParser() config.read(filename) config['options'].update({str(k): str(v) for k, v in options.cmd_line_options.items()}) with open(filename, 'w', encoding='utf-8') as f: config.write(f) def format_cmd_line_options(options: SharedCMDOptions) -> str: cmdline = ['-D{}={}'.format(str(k), v) for k, v in options.cmd_line_options.items()] if options.cross_file: cmdline += [f'--cross-file={f}' for f in options.cross_file] if options.native_file: cmdline += [f'--native-file={f}' for f in options.native_file] return ' '.join([shlex.quote(x) for x in cmdline]) def major_versions_differ(v1: str, v2: str) -> bool: v1_major, v1_minor = v1.rsplit('.', 1) v2_major, v2_minor = v2.rsplit('.', 1) # Major version differ, or one is development version but not the other. return v1_major != v2_major or ('99' in {v1_minor, v2_minor} and v1_minor != v2_minor) def load(build_dir: str, suggest_reconfigure: bool = True) -> CoreData: filename = os.path.join(build_dir, 'meson-private', 'coredata.dat') return pickle_load(filename, 'Coredata', CoreData, suggest_reconfigure) def save(obj: CoreData, build_dir: str) -> str: filename = os.path.join(build_dir, 'meson-private', 'coredata.dat') prev_filename = filename + '.prev' tempfilename = filename + '~' if major_versions_differ(obj.version, version): raise MesonException('Fatal version mismatch corruption.') if os.path.exists(filename): import shutil shutil.copyfile(filename, prev_filename) with open(tempfilename, 'wb') as f: pickle.dump(obj, f) f.flush() os.fsync(f.fileno()) os.replace(tempfilename, filename) return filename def register_builtin_arguments(parser: argparse.ArgumentParser) -> None: for n, b in options.BUILTIN_OPTIONS.items(): b.add_to_argparse(str(n), parser, '') for n, b in options.BUILTIN_OPTIONS_PER_MACHINE.items(): b.add_to_argparse(str(n), parser, ' (just for host machine)') b.add_to_argparse(str(n.as_build()), parser, ' (just for build machine)') parser.add_argument('-D', action='append', dest='projectoptions', default=[], metavar="option", help='Set the value of an option, can be used several times to set multiple options.') def create_options_dict(options: T.List[str], subproject: str = '') -> T.Dict[OptionKey, str]: result: T.OrderedDict[OptionKey, str] = OrderedDict() for o in options: try: (key, value) = o.split('=', 1) except ValueError: raise MesonException(f'Option {o!r} must have a value separated by equals sign.') k = OptionKey.from_string(key) if subproject: k = k.evolve(subproject=subproject) result[k] = value return result def parse_cmd_line_options(args: SharedCMDOptions) -> None: args.cmd_line_options = create_options_dict(args.projectoptions) # Merge builtin options set with --option into the dict. for key in chain( options.BUILTIN_OPTIONS.keys(), (k.as_build() for k in options.BUILTIN_OPTIONS_PER_MACHINE.keys()), options.BUILTIN_OPTIONS_PER_MACHINE.keys(), ): name = str(key) value = getattr(args, name, None) if value is not None: if key in args.cmd_line_options: cmdline_name = options.BuiltinOption.argparse_name_to_arg(name) raise MesonException( f'Got argument {name} as both -D{name} and {cmdline_name}. Pick one.') args.cmd_line_options[key] = value delattr(args, name) @dataclass class OptionsView(abc.Mapping): '''A view on an options dictionary for a given subproject and with overrides. ''' # TODO: the typing here could be made more explicit using a TypeDict from # python 3.8 or typing_extensions original_options: KeyedOptionDictType subproject: T.Optional[str] = None overrides: T.Optional[T.Mapping[OptionKey, T.Union[str, int, bool, T.List[str]]]] = None def __getitem__(self, key: OptionKey) -> options.UserOption: # FIXME: This is fundamentally the same algorithm than interpreter.get_option_internal(). # We should try to share the code somehow. key = key.evolve(subproject=self.subproject) if not key.is_project(): opt = self.original_options.get(key) if opt is None or opt.yielding: opt = self.original_options[key.as_root()] else: opt = self.original_options[key] if opt.yielding: opt = self.original_options.get(key.as_root(), opt) if self.overrides: override_value = self.overrides.get(key.as_root()) if override_value is not None: opt = copy.copy(opt) opt.set_value(override_value) return opt def __iter__(self) -> T.Iterator[OptionKey]: return iter(self.original_options) def __len__(self) -> int: return len(self.original_options) FORBIDDEN_TARGET_NAMES = frozenset({ 'clean', 'clean-ctlist', 'clean-gcno', 'clean-gcda', 'coverage', 'coverage-text', 'coverage-xml', 'coverage-html', 'phony', 'PHONY', 'all', 'test', 'benchmark', 'install', 'uninstall', 'build.ninja', 'scan-build', 'reconfigure', 'dist', 'distcheck', })