#!/usr/bin/env python3 # Copyright 2016 The Meson development team # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # http://www.apache.org/licenses/LICENSE-2.0 # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # This class contains the basic functionality needed to run any interpreter # or an interpreter-based tool. # This tool is used to manipulate an existing Meson build definition. # # - add a file to a target # - remove files from a target # - move targets # - reindent? from .ast import IntrospectionInterpreter, build_target_functions, AstConditionLevel, AstIDGenerator, AstIndentationGenerator, AstPrinter from mesonbuild.mesonlib import MesonException from . import mlog, environment from functools import wraps from .mparser import Token, ArrayNode, ArgumentNode, AssignmentNode, BaseNode, BooleanNode, ElementaryNode, IdNode, FunctionNode, StringNode import json, os, re, sys import typing as T class RewriterException(MesonException): pass def add_arguments(parser, formatter=None): parser.add_argument('-s', '--sourcedir', type=str, default='.', metavar='SRCDIR', help='Path to source directory.') parser.add_argument('-V', '--verbose', action='store_true', default=False, help='Enable verbose output') parser.add_argument('-S', '--skip-errors', dest='skip', action='store_true', default=False, help='Skip errors instead of aborting') subparsers = parser.add_subparsers(dest='type', title='Rewriter commands', description='Rewrite command to execute') # Target tgt_parser = subparsers.add_parser('target', help='Modify a target', formatter_class=formatter) tgt_parser.add_argument('-s', '--subdir', default='', dest='subdir', help='Subdirectory of the new target (only for the "add_target" action)') tgt_parser.add_argument('--type', dest='tgt_type', choices=rewriter_keys['target']['target_type'][2], default='executable', help='Type of the target to add (only for the "add_target" action)') tgt_parser.add_argument('target', help='Name or ID of the target') tgt_parser.add_argument('operation', choices=['add', 'rm', 'add_target', 'rm_target', 'info'], help='Action to execute') tgt_parser.add_argument('sources', nargs='*', help='Sources to add/remove') # KWARGS kw_parser = subparsers.add_parser('kwargs', help='Modify keyword arguments', formatter_class=formatter) kw_parser.add_argument('operation', choices=rewriter_keys['kwargs']['operation'][2], help='Action to execute') kw_parser.add_argument('function', choices=list(rewriter_func_kwargs.keys()), help='Function type to modify') kw_parser.add_argument('id', help='ID of the function to modify (can be anything for "project")') kw_parser.add_argument('kwargs', nargs='*', help='Pairs of keyword and value') # Default options def_parser = subparsers.add_parser('default-options', help='Modify the project default options', formatter_class=formatter) def_parser.add_argument('operation', choices=rewriter_keys['default_options']['operation'][2], help='Action to execute') def_parser.add_argument('options', nargs='*', help='Key, value pairs of configuration option') # JSON file/command cmd_parser = subparsers.add_parser('command', help='Execute a JSON array of commands', formatter_class=formatter) cmd_parser.add_argument('json', help='JSON string or file to execute') class RequiredKeys: def __init__(self, keys): self.keys = keys def __call__(self, f): @wraps(f) def wrapped(*wrapped_args, **wrapped_kwargs): assert(len(wrapped_args) >= 2) cmd = wrapped_args[1] for key, val in self.keys.items(): typ = val[0] # The type of the value default = val[1] # The default value -- None is required choices = val[2] # Valid choices -- None is for everything if key not in cmd: if default is not None: cmd[key] = default else: raise RewriterException('Key "{}" is missing in object for {}' .format(key, f.__name__)) if not isinstance(cmd[key], typ): raise RewriterException('Invalid type of "{}". Required is {} but provided was {}' .format(key, typ.__name__, type(cmd[key]).__name__)) if choices is not None: assert(isinstance(choices, list)) if cmd[key] not in choices: raise RewriterException('Invalid value of "{}": Possible values are {} but provided was "{}"' .format(key, choices, cmd[key])) return f(*wrapped_args, **wrapped_kwargs) return wrapped class MTypeBase: def __init__(self, node: T.Optional[BaseNode] = None): if node is None: self.node = self._new_node() # lgtm [py/init-calls-subclass] (node creation does not depend on base class state) else: self.node = node self.node_type = None for i in self.supported_nodes(): # lgtm [py/init-calls-subclass] (listing nodes does not depend on base class state) if isinstance(self.node, i): self.node_type = i def _new_node(self): # Overwrite in derived class raise RewriterException('Internal error: _new_node of MTypeBase was called') def can_modify(self): return self.node_type is not None def get_node(self): return self.node def supported_nodes(self): # Overwrite in derived class return [] def set_value(self, value): # Overwrite in derived class mlog.warning('Cannot set the value of type', mlog.bold(type(self).__name__), '--> skipping') def add_value(self, value): # Overwrite in derived class mlog.warning('Cannot add a value of type', mlog.bold(type(self).__name__), '--> skipping') def remove_value(self, value): # Overwrite in derived class mlog.warning('Cannot remove a value of type', mlog.bold(type(self).__name__), '--> skipping') def remove_regex(self, value): # Overwrite in derived class mlog.warning('Cannot remove a regex in type', mlog.bold(type(self).__name__), '--> skipping') class MTypeStr(MTypeBase): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_node(self): return StringNode(Token('', '', 0, 0, 0, None, '')) def supported_nodes(self): return [StringNode] def set_value(self, value): self.node.value = str(value) class MTypeBool(MTypeBase): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_node(self): return BooleanNode(Token('', '', 0, 0, 0, None, False)) def supported_nodes(self): return [BooleanNode] def set_value(self, value): self.node.value = bool(value) class MTypeID(MTypeBase): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_node(self): return IdNode(Token('', '', 0, 0, 0, None, '')) def supported_nodes(self): return [IdNode] def set_value(self, value): self.node.value = str(value) class MTypeList(MTypeBase): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_node(self): return ArrayNode(ArgumentNode(Token('', '', 0, 0, 0, None, '')), 0, 0, 0, 0) def _new_element_node(self, value): # Overwrite in derived class raise RewriterException('Internal error: _new_element_node of MTypeList was called') def _ensure_array_node(self): if not isinstance(self.node, ArrayNode): tmp = self.node self.node = self._new_node() self.node.args.arguments += [tmp] def _check_is_equal(self, node, value) -> bool: # Overwrite in derived class return False def _check_regex_matches(self, node, regex: str) -> bool: # Overwrite in derived class return False def get_node(self): if isinstance(self.node, ArrayNode): if len(self.node.args.arguments) == 1: return self.node.args.arguments[0] return self.node def supported_element_nodes(self): # Overwrite in derived class return [] def supported_nodes(self): return [ArrayNode] + self.supported_element_nodes() def set_value(self, value): if not isinstance(value, list): value = [value] self._ensure_array_node() self.node.args.arguments = [] # Remove all current nodes for i in value: self.node.args.arguments += [self._new_element_node(i)] def add_value(self, value): if not isinstance(value, list): value = [value] self._ensure_array_node() for i in value: self.node.args.arguments += [self._new_element_node(i)] def _remove_helper(self, value, equal_func): def check_remove_node(node): for j in value: if equal_func(i, j): return True return False if not isinstance(value, list): value = [value] self._ensure_array_node() removed_list = [] for i in self.node.args.arguments: if not check_remove_node(i): removed_list += [i] self.node.args.arguments = removed_list def remove_value(self, value): self._remove_helper(value, self._check_is_equal) def remove_regex(self, regex: str): self._remove_helper(regex, self._check_regex_matches) class MTypeStrList(MTypeList): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_element_node(self, value): return StringNode(Token('', '', 0, 0, 0, None, str(value))) def _check_is_equal(self, node, value) -> bool: if isinstance(node, StringNode): return node.value == value return False def _check_regex_matches(self, node, regex: str) -> bool: if isinstance(node, StringNode): return re.match(regex, node.value) is not None return False def supported_element_nodes(self): return [StringNode] class MTypeIDList(MTypeList): def __init__(self, node: T.Optional[BaseNode] = None): super().__init__(node) def _new_element_node(self, value): return IdNode(Token('', '', 0, 0, 0, None, str(value))) def _check_is_equal(self, node, value) -> bool: if isinstance(node, IdNode): return node.value == value return False def _check_regex_matches(self, node, regex: str) -> bool: if isinstance(node, StringNode): return re.match(regex, node.value) is not None return False def supported_element_nodes(self): return [IdNode] rewriter_keys = { 'default_options': { 'operation': (str, None, ['set', 'delete']), 'options': (dict, {}, None) }, 'kwargs': { 'function': (str, None, None), 'id': (str, None, None), 'operation': (str, None, ['set', 'delete', 'add', 'remove', 'remove_regex', 'info']), 'kwargs': (dict, {}, None) }, 'target': { 'target': (str, None, None), 'operation': (str, None, ['src_add', 'src_rm', 'target_rm', 'target_add', 'info']), 'sources': (list, [], None), 'subdir': (str, '', None), 'target_type': (str, 'executable', ['both_libraries', 'executable', 'jar', 'library', 'shared_library', 'shared_module', 'static_library']), } } rewriter_func_kwargs = { 'dependency': { 'language': MTypeStr, 'method': MTypeStr, 'native': MTypeBool, 'not_found_message': MTypeStr, 'required': MTypeBool, 'static': MTypeBool, 'version': MTypeStrList, 'modules': MTypeStrList }, 'target': { 'build_by_default': MTypeBool, 'build_rpath': MTypeStr, 'dependencies': MTypeIDList, 'gui_app': MTypeBool, 'link_with': MTypeIDList, 'export_dynamic': MTypeBool, 'implib': MTypeBool, 'install': MTypeBool, 'install_dir': MTypeStr, 'install_rpath': MTypeStr, 'pie': MTypeBool }, 'project': { 'default_options': MTypeStrList, 'meson_version': MTypeStr, 'license': MTypeStrList, 'subproject_dir': MTypeStr, 'version': MTypeStr } } class Rewriter: def __init__(self, sourcedir: str, generator: str = 'ninja', skip_errors: bool = False): self.sourcedir = sourcedir self.interpreter = IntrospectionInterpreter(sourcedir, '', generator, visitors = [AstIDGenerator(), AstIndentationGenerator(), AstConditionLevel()]) self.skip_errors = skip_errors self.modefied_nodes = [] self.to_remove_nodes = [] self.to_add_nodes = [] self.functions = { 'default_options': self.process_default_options, 'kwargs': self.process_kwargs, 'target': self.process_target, } self.info_dump = None def analyze_meson(self): mlog.log('Analyzing meson file:', mlog.bold(os.path.join(self.sourcedir, environment.build_filename))) self.interpreter.analyze() mlog.log(' -- Project:', mlog.bold(self.interpreter.project_data['descriptive_name'])) mlog.log(' -- Version:', mlog.cyan(self.interpreter.project_data['version'])) def add_info(self, cmd_type: str, cmd_id: str, data: dict): if self.info_dump is None: self.info_dump = {} if cmd_type not in self.info_dump: self.info_dump[cmd_type] = {} self.info_dump[cmd_type][cmd_id] = data def print_info(self): if self.info_dump is None: return sys.stderr.write(json.dumps(self.info_dump, indent=2)) def on_error(self): if self.skip_errors: return mlog.cyan('-->'), mlog.yellow('skipping') return mlog.cyan('-->'), mlog.red('aborting') def handle_error(self): if self.skip_errors: return None raise MesonException('Rewriting the meson.build failed') def find_target(self, target: str): def check_list(name: str) -> T.List[BaseNode]: result = [] for i in self.interpreter.targets: if name == i['name'] or name == i['id']: result += [i] return result targets = check_list(target) if targets: if len(targets) == 1: return targets[0] else: mlog.error('There are multiple targets matching', mlog.bold(target)) for i in targets: mlog.error(' -- Target name', mlog.bold(i['name']), 'with ID', mlog.bold(i['id'])) mlog.error('Please try again with the unique ID of the target', *self.on_error()) self.handle_error() return None # Check the assignments tgt = None if target in self.interpreter.assignments: node = self.interpreter.assignments[target] if isinstance(node, FunctionNode): if node.func_name in ['executable', 'jar', 'library', 'shared_library', 'shared_module', 'static_library', 'both_libraries']: tgt = self.interpreter.assign_vals[target] return tgt def find_dependency(self, dependency: str): def check_list(name: str): for i in self.interpreter.dependencies: if name == i['name']: return i return None dep = check_list(dependency) if dep is not None: return dep # Check the assignments if dependency in self.interpreter.assignments: node = self.interpreter.assignments[dependency] if isinstance(node, FunctionNode): if node.func_name in ['dependency']: name = self.interpreter.flatten_args(node.args)[0] dep = check_list(name) return dep @RequiredKeys(rewriter_keys['default_options']) def process_default_options(self, cmd): # First, remove the old values kwargs_cmd = { 'function': 'project', 'id': "/", 'operation': 'remove_regex', 'kwargs': { 'default_options': ['{}=.*'.format(x) for x in cmd['options'].keys()] } } self.process_kwargs(kwargs_cmd) # Then add the new values if cmd['operation'] != 'set': return kwargs_cmd['operation'] = 'add' kwargs_cmd['kwargs']['default_options'] = [] cdata = self.interpreter.coredata options = { **cdata.builtins, **cdata.builtins_per_machine.host, **{'build.' + k: o for k, o in cdata.builtins_per_machine.build.items()}, **cdata.backend_options, **cdata.base_options, **cdata.compiler_options.host, **{'build.' + k: o for k, o in cdata.compiler_options.build.items()}, **cdata.user_options, } for key, val in sorted(cmd['options'].items()): if key not in options: mlog.error('Unknown options', mlog.bold(key), *self.on_error()) self.handle_error() continue try: val = options[key].validate_value(val) except MesonException as e: mlog.error('Unable to set', mlog.bold(key), mlog.red(str(e)), *self.on_error()) self.handle_error() continue kwargs_cmd['kwargs']['default_options'] += ['{}={}'.format(key, val)] self.process_kwargs(kwargs_cmd) @RequiredKeys(rewriter_keys['kwargs']) def process_kwargs(self, cmd): mlog.log('Processing function type', mlog.bold(cmd['function']), 'with id', mlog.cyan("'" + cmd['id'] + "'")) if cmd['function'] not in rewriter_func_kwargs: mlog.error('Unknown function type', cmd['function'], *self.on_error()) return self.handle_error() kwargs_def = rewriter_func_kwargs[cmd['function']] # Find the function node to modify node = None arg_node = None if cmd['function'] == 'project': if cmd['id'] != '/': mlog.error('The ID for the function type project must be "/"', *self.on_error()) return self.handle_error() node = self.interpreter.project_node arg_node = node.args elif cmd['function'] == 'target': tmp = self.find_target(cmd['id']) if tmp: node = tmp['node'] arg_node = node.args elif cmd['function'] == 'dependency': tmp = self.find_dependency(cmd['id']) if tmp: node = tmp['node'] arg_node = node.args if not node: mlog.error('Unable to find the function node') assert(isinstance(node, FunctionNode)) assert(isinstance(arg_node, ArgumentNode)) # Transform the key nodes to plain strings arg_node.kwargs = {k.value: v for k, v in arg_node.kwargs.items()} # Print kwargs info if cmd['operation'] == 'info': info_data = {} for key, val in sorted(arg_node.kwargs.items()): info_data[key] = None if isinstance(val, ElementaryNode): info_data[key] = val.value elif isinstance(val, ArrayNode): data_list = [] for i in val.args.arguments: element = None if isinstance(i, ElementaryNode): element = i.value data_list += [element] info_data[key] = data_list self.add_info('kwargs', '{}#{}'.format(cmd['function'], cmd['id']), info_data) return # Nothing else to do # Modify the kwargs num_changed = 0 for key, val in sorted(cmd['kwargs'].items()): if key not in kwargs_def: mlog.error('Cannot modify unknown kwarg', mlog.bold(key), *self.on_error()) self.handle_error() continue # Remove the key from the kwargs if cmd['operation'] == 'delete': if key in arg_node.kwargs: mlog.log(' -- Deleting', mlog.bold(key), 'from the kwargs') del arg_node.kwargs[key] num_changed += 1 else: mlog.log(' -- Key', mlog.bold(key), 'is already deleted') continue if key not in arg_node.kwargs: arg_node.kwargs[key] = None modifyer = kwargs_def[key](arg_node.kwargs[key]) if not modifyer.can_modify(): mlog.log(' -- Skipping', mlog.bold(key), 'because it is to complex to modify') # Apply the operation val_str = str(val) if cmd['operation'] == 'set': mlog.log(' -- Setting', mlog.bold(key), 'to', mlog.yellow(val_str)) modifyer.set_value(val) elif cmd['operation'] == 'add': mlog.log(' -- Adding', mlog.yellow(val_str), 'to', mlog.bold(key)) modifyer.add_value(val) elif cmd['operation'] == 'remove': mlog.log(' -- Removing', mlog.yellow(val_str), 'from', mlog.bold(key)) modifyer.remove_value(val) elif cmd['operation'] == 'remove_regex': mlog.log(' -- Removing all values matching', mlog.yellow(val_str), 'from', mlog.bold(key)) modifyer.remove_regex(val) # Write back the result arg_node.kwargs[key] = modifyer.get_node() num_changed += 1 # Convert the keys back to IdNode's arg_node.kwargs = {IdNode(Token('', '', 0, 0, 0, None, k)): v for k, v in arg_node.kwargs.items()} if num_changed > 0 and node not in self.modefied_nodes: self.modefied_nodes += [node] def find_assignment_node(self, node: BaseNode) -> AssignmentNode: if node.ast_id and node.ast_id in self.interpreter.reverse_assignment: return self.interpreter.reverse_assignment[node.ast_id] return None @RequiredKeys(rewriter_keys['target']) def process_target(self, cmd): mlog.log('Processing target', mlog.bold(cmd['target']), 'operation', mlog.cyan(cmd['operation'])) target = self.find_target(cmd['target']) if target is None and cmd['operation'] != 'target_add': mlog.error('Unknown target', mlog.bold(cmd['target']), *self.on_error()) return self.handle_error() # Make source paths relative to the current subdir def rel_source(src: str) -> str: subdir = os.path.abspath(os.path.join(self.sourcedir, target['subdir'])) if os.path.isabs(src): return os.path.relpath(src, subdir) elif not os.path.exists(src): return src # Trust the user when the source doesn't exist # Make sure that the path is relative to the subdir return os.path.relpath(os.path.abspath(src), subdir) if target is not None: cmd['sources'] = [rel_source(x) for x in cmd['sources']] # Utility function to get a list of the sources from a node def arg_list_from_node(n): args = [] if isinstance(n, FunctionNode): args = list(n.args.arguments) if n.func_name in build_target_functions: args.pop(0) elif isinstance(n, ArrayNode): args = n.args.arguments elif isinstance(n, ArgumentNode): args = n.arguments return args to_sort_nodes = [] if cmd['operation'] == 'src_add': node = None if target['sources']: node = target['sources'][0] else: node = target['node'] assert(node is not None) # Generate the current source list src_list = [] for i in target['sources']: for j in arg_list_from_node(i): if isinstance(j, StringNode): src_list += [j.value] # Generate the new String nodes to_append = [] for i in sorted(set(cmd['sources'])): if i in src_list: mlog.log(' -- Source', mlog.green(i), 'is already defined for the target --> skipping') continue mlog.log(' -- Adding source', mlog.green(i), 'at', mlog.yellow('{}:{}'.format(node.filename, node.lineno))) token = Token('string', node.filename, 0, 0, 0, None, i) to_append += [StringNode(token)] # Append to the AST at the right place arg_node = None if isinstance(node, (FunctionNode, ArrayNode)): arg_node = node.args elif isinstance(node, ArgumentNode): arg_node = node assert(arg_node is not None) arg_node.arguments += to_append # Mark the node as modified if arg_node not in to_sort_nodes and not isinstance(node, FunctionNode): to_sort_nodes += [arg_node] if node not in self.modefied_nodes: self.modefied_nodes += [node] elif cmd['operation'] == 'src_rm': # Helper to find the exact string node and its parent def find_node(src): for i in target['sources']: for j in arg_list_from_node(i): if isinstance(j, StringNode): if j.value == src: return i, j return None, None for i in cmd['sources']: # Try to find the node with the source string root, string_node = find_node(i) if root is None: mlog.warning(' -- Unable to find source', mlog.green(i), 'in the target') continue # Remove the found string node from the argument list arg_node = None if isinstance(root, (FunctionNode, ArrayNode)): arg_node = root.args elif isinstance(root, ArgumentNode): arg_node = root assert(arg_node is not None) mlog.log(' -- Removing source', mlog.green(i), 'from', mlog.yellow('{}:{}'.format(string_node.filename, string_node.lineno))) arg_node.arguments.remove(string_node) # Mark the node as modified if arg_node not in to_sort_nodes and not isinstance(root, FunctionNode): to_sort_nodes += [arg_node] if root not in self.modefied_nodes: self.modefied_nodes += [root] elif cmd['operation'] == 'target_add': if target is not None: mlog.error('Can not add target', mlog.bold(cmd['target']), 'because it already exists', *self.on_error()) return self.handle_error() id_base = re.sub(r'[- ]', '_', cmd['target']) target_id = id_base + '_exe' if cmd['target_type'] == 'executable' else '_lib' source_id = id_base + '_sources' filename = os.path.join(cmd['subdir'], environment.build_filename) # Build src list src_arg_node = ArgumentNode(Token('string', filename, 0, 0, 0, None, '')) src_arr_node = ArrayNode(src_arg_node, 0, 0, 0, 0) src_far_node = ArgumentNode(Token('string', filename, 0, 0, 0, None, '')) src_fun_node = FunctionNode(filename, 0, 0, 0, 0, 'files', src_far_node) src_ass_node = AssignmentNode(filename, 0, 0, source_id, src_fun_node) src_arg_node.arguments = [StringNode(Token('string', filename, 0, 0, 0, None, x)) for x in cmd['sources']] src_far_node.arguments = [src_arr_node] # Build target tgt_arg_node = ArgumentNode(Token('string', filename, 0, 0, 0, None, '')) tgt_fun_node = FunctionNode(filename, 0, 0, 0, 0, cmd['target_type'], tgt_arg_node) tgt_ass_node = AssignmentNode(filename, 0, 0, target_id, tgt_fun_node) tgt_arg_node.arguments = [ StringNode(Token('string', filename, 0, 0, 0, None, cmd['target'])), IdNode(Token('string', filename, 0, 0, 0, None, source_id)) ] src_ass_node.accept(AstIndentationGenerator()) tgt_ass_node.accept(AstIndentationGenerator()) self.to_add_nodes += [src_ass_node, tgt_ass_node] elif cmd['operation'] == 'target_rm': to_remove = self.find_assignment_node(target['node']) if to_remove is None: to_remove = target['node'] self.to_remove_nodes += [to_remove] mlog.log(' -- Removing target', mlog.green(cmd['target']), 'at', mlog.yellow('{}:{}'.format(to_remove.filename, to_remove.lineno))) elif cmd['operation'] == 'info': # T.List all sources in the target src_list = [] for i in target['sources']: for j in arg_list_from_node(i): if isinstance(j, StringNode): src_list += [j.value] test_data = { 'name': target['name'], 'sources': src_list } self.add_info('target', target['id'], test_data) # Sort files for i in to_sort_nodes: convert = lambda text: int(text) if text.isdigit() else text.lower() alphanum_key = lambda key: [convert(c) for c in re.split('([0-9]+)', key)] path_sorter = lambda key: ([(key.count('/') <= idx, alphanum_key(x)) for idx, x in enumerate(key.split('/'))]) unknown = [x for x in i.arguments if not isinstance(x, StringNode)] sources = [x for x in i.arguments if isinstance(x, StringNode)] sources = sorted(sources, key=lambda x: path_sorter(x.value)) i.arguments = unknown + sources def process(self, cmd): if 'type' not in cmd: raise RewriterException('Command has no key "type"') if cmd['type'] not in self.functions: raise RewriterException('Unknown command "{}". Supported commands are: {}' .format(cmd['type'], list(self.functions.keys()))) self.functions[cmd['type']](cmd) def apply_changes(self): assert(all(hasattr(x, 'lineno') and hasattr(x, 'colno') and hasattr(x, 'filename') for x in self.modefied_nodes)) assert(all(hasattr(x, 'lineno') and hasattr(x, 'colno') and hasattr(x, 'filename') for x in self.to_remove_nodes)) assert(all(isinstance(x, (ArrayNode, FunctionNode)) for x in self.modefied_nodes)) assert(all(isinstance(x, (ArrayNode, AssignmentNode, FunctionNode)) for x in self.to_remove_nodes)) # Sort based on line and column in reversed order work_nodes = [{'node': x, 'action': 'modify'} for x in self.modefied_nodes] work_nodes += [{'node': x, 'action': 'rm'} for x in self.to_remove_nodes] work_nodes = list(sorted(work_nodes, key=lambda x: (x['node'].lineno, x['node'].colno), reverse=True)) work_nodes += [{'node': x, 'action': 'add'} for x in self.to_add_nodes] # Generating the new replacement string str_list = [] for i in work_nodes: new_data = '' if i['action'] == 'modify' or i['action'] == 'add': printer = AstPrinter() i['node'].accept(printer) printer.post_process() new_data = printer.result.strip() data = { 'file': i['node'].filename, 'str': new_data, 'node': i['node'], 'action': i['action'] } str_list += [data] # Load build files files = {} for i in str_list: if i['file'] in files: continue fpath = os.path.realpath(os.path.join(self.sourcedir, i['file'])) fdata = '' # Create an empty file if it does not exist if not os.path.exists(fpath): with open(fpath, 'w'): pass with open(fpath, 'r') as fp: fdata = fp.read() # Generate line offsets numbers m_lines = fdata.splitlines(True) offset = 0 line_offsets = [] for j in m_lines: line_offsets += [offset] offset += len(j) files[i['file']] = { 'path': fpath, 'raw': fdata, 'offsets': line_offsets } # Replace in source code def remove_node(i): offsets = files[i['file']]['offsets'] raw = files[i['file']]['raw'] node = i['node'] line = node.lineno - 1 col = node.colno start = offsets[line] + col end = start if isinstance(node, (ArrayNode, FunctionNode)): end = offsets[node.end_lineno - 1] + node.end_colno # Only removal is supported for assignments elif isinstance(node, AssignmentNode) and i['action'] == 'rm': if isinstance(node.value, (ArrayNode, FunctionNode)): remove_node({'file': i['file'], 'str': '', 'node': node.value, 'action': 'rm'}) raw = files[i['file']]['raw'] while raw[end] != '=': end += 1 end += 1 # Handle the '=' while raw[end] in [' ', '\n', '\t']: end += 1 files[i['file']]['raw'] = raw[:start] + i['str'] + raw[end:] for i in str_list: if i['action'] in ['modify', 'rm']: remove_node(i) elif i['action'] in ['add']: files[i['file']]['raw'] += i['str'] + '\n' # Write the files back for key, val in files.items(): mlog.log('Rewriting', mlog.yellow(key)) with open(val['path'], 'w') as fp: fp.write(val['raw']) target_operation_map = { 'add': 'src_add', 'rm': 'src_rm', 'add_target': 'target_add', 'rm_target': 'target_rm', 'info': 'info', } def list_to_dict(in_list: T.List[str]) -> T.Dict[str, str]: result = {} it = iter(in_list) try: for i in it: # calling next(it) is not a mistake, we're taking the next element from # the iterator, avoiding the need to preprocess it into a sequence of # key value pairs. result[i] = next(it) except StopIteration: raise TypeError('in_list parameter of list_to_dict must have an even length.') return result def generate_target(options) -> T.List[dict]: return [{ 'type': 'target', 'target': options.target, 'operation': target_operation_map[options.operation], 'sources': options.sources, 'subdir': options.subdir, 'target_type': options.tgt_type, }] def generate_kwargs(options) -> T.List[dict]: return [{ 'type': 'kwargs', 'function': options.function, 'id': options.id, 'operation': options.operation, 'kwargs': list_to_dict(options.kwargs), }] def generate_def_opts(options) -> T.List[dict]: return [{ 'type': 'default_options', 'operation': options.operation, 'options': list_to_dict(options.options), }] def genreate_cmd(options) -> T.List[dict]: if os.path.exists(options.json): with open(options.json, 'r') as fp: return json.load(fp) else: return json.loads(options.json) # Map options.type to the actual type name cli_type_map = { 'target': generate_target, 'tgt': generate_target, 'kwargs': generate_kwargs, 'default-options': generate_def_opts, 'def': generate_def_opts, 'command': genreate_cmd, 'cmd': genreate_cmd, } def run(options): if not options.verbose: mlog.set_quiet() try: rewriter = Rewriter(options.sourcedir, skip_errors=options.skip) rewriter.analyze_meson() if options.type is None: mlog.error('No command specified') return 1 commands = cli_type_map[options.type](options) if not isinstance(commands, list): raise TypeError('Command is not a list') for i in commands: if not isinstance(i, object): raise TypeError('Command is not an object') rewriter.process(i) rewriter.apply_changes() rewriter.print_info() return 0 except Exception as e: raise e finally: mlog.set_verbose()