# Copyright 2021 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. from .generatorbase import GeneratorBase import re import json from .model import ( ReferenceManual, Function, Method, Object, ObjectType, Type, DataTypeInfo, ArgBase, PosArg, VarArgs, Kwarg, ) from pathlib import Path from textwrap import dedent import typing as T from mesonbuild import mlog PlaceholderTypes = T.Union[None, str, bool] FunctionDictType = T.Dict[ str, T.Union[ PlaceholderTypes, T.Dict[str, PlaceholderTypes], T.Dict[str, T.Dict[str, PlaceholderTypes]], T.Dict[str, T.List[T.Dict[str, PlaceholderTypes]]], T.List[T.Dict[str, PlaceholderTypes]], T.List[str], ] ] _ROOT_BASENAME = 'Reference-manual' _OBJ_ID_MAP = { ObjectType.ELEMENTARY: 'elementary', ObjectType.BUILTIN: 'builtin', ObjectType.MODULE: 'module', ObjectType.RETURNED: 'returned', } # Indent all but the first line with 4*depth spaces. # This function is designed to be used with `dedent` # and fstrings where multiline strings are used during # the string interpolation. def smart_indent(raw: str, depth: int = 3) -> str: lines = raw.split('\n') first_line = lines[0] lines = [' ' * (4 * depth) + x for x in lines] lines[0] = first_line # Do not indent the first line return '\n'.join(lines) def code_block(code: str) -> str: code = dedent(code) return f'
{code}
' class GeneratorMD(GeneratorBase): def __init__(self, manual: ReferenceManual, sitemap_out: Path, sitemap_in: Path, link_def_out: Path, enable_modules: bool) -> None: super().__init__(manual) self.sitemap_out = sitemap_out.resolve() self.sitemap_in = sitemap_in.resolve() self.link_def_out = link_def_out.resolve() self.out_dir = self.sitemap_out.parent self.enable_modules = enable_modules self.generated_files: T.Dict[str, str] = {} # Utility functions def _gen_filename(self, file_id: str, *, extension: str = 'md') -> str: parts = file_id.split('.') assert parts[0] == 'root' assert all([x for x in parts]) parts[0] = _ROOT_BASENAME parts = [re.sub(r'[0-9]+_', '', x) for x in parts] return f'{"_".join(parts)}.{extension}' def _gen_object_file_id(self, obj: Object) -> str: ''' Deterministically generate a unique file ID for the Object. This ID determines where the object will be inserted in the sitemap. ''' if obj.obj_type == ObjectType.RETURNED and obj.defined_by_module is not None: base = self._gen_object_file_id(obj.defined_by_module) return f'{base}.{obj.name}' return f'root.{_OBJ_ID_MAP[obj.obj_type]}.{obj.name}' def _link_to_object(self, obj: T.Union[Function, Object], in_code_block: bool = False) -> str: ''' Generate a palaceholder tag for the function/method/object documentation. This tag is then replaced in the custom hotdoc plugin. ''' prefix = '#' if in_code_block else '' if isinstance(obj, Object): return f'[[{prefix}@{obj.name}]]' elif isinstance(obj, Method): return f'[[{prefix}{obj.obj.name}.{obj.name}]]' elif isinstance(obj, Function): return f'[[{prefix}{obj.name}]]' else: raise RuntimeError(f'Invalid argument {obj}') def _write_file(self, data: str, file_id: str) -> None:# ''' Write the data to disk and store the id for the generated data ''' self.generated_files[file_id] = self._gen_filename(file_id) out_file = self.out_dir / self.generated_files[file_id] out_file.write_text(data, encoding='ascii') mlog.log('Generated', mlog.bold(out_file.name)) def _write_template(self, data: T.Dict[str, T.Any], file_id: str, template_name: T.Optional[str] = None) -> None: ''' Render the template mustache files and write the result ''' template_dir = Path(__file__).resolve().parent / 'templates' template_name = template_name or file_id template_name = f'{template_name}.mustache' template_file = template_dir / template_name # Import here, so that other generators don't also depend on it import chevron result = chevron.render( template=template_file.read_text(encoding='utf-8'), data=data, partials_path=template_dir.as_posix(), warn=True, ) self._write_file(result, file_id) # Actual generator functions def _gen_func_or_method(self, func: Function) -> FunctionDictType: def render_type(typ: Type, in_code_block: bool = False) -> str: def data_type_to_str(dt: DataTypeInfo) -> str: base = self._link_to_object(dt.data_type, in_code_block) if dt.holds: return f'{base}[{render_type(dt.holds, in_code_block)}]' return base assert typ.resolved return ' | '.join([data_type_to_str(x) for x in typ.resolved]) def len_stripped(s: str) -> int: s = s.replace(']]', '') # I know, this regex is ugly but it works. return len(re.sub(r'\[\[(#|@)*([^\[])', r'\2', s)) def arg_anchor(arg: ArgBase) -> str: return f'{func.name}_{arg.name.replace("<", "_").replace(">", "_")}' def render_signature() -> str: # Skip a lot of computations if the function does not take any arguments if not any([func.posargs, func.optargs, func.kwargs, func.varargs]): return f'{render_type(func.returns, True)} {func.name}()' signature = dedent(f'''\ # {self.brief(func)} {render_type(func.returns, True)} {func.name}( ''') # Calculate maximum lengths of the type and name all_args: T.List[ArgBase] = [] all_args += func.posargs all_args += func.optargs all_args += [func.varargs] if func.varargs else [] max_type_len = 0 max_name_len = 0 if all_args: max_type_len = max([len_stripped(render_type(x.type)) for x in all_args]) max_name_len = max([len(x.name) for x in all_args]) # Generate some common strings def prepare(arg: ArgBase, link: bool = True) -> T.Tuple[str, str, str, str]: type_str = render_type(arg.type, True) type_len = len_stripped(type_str) type_space = ' ' * (max_type_len - type_len) name_space = ' ' * (max_name_len - len(arg.name)) name_str = f'{arg.name.replace("<", "<").replace(">", ">")}' if link: name_str = f'{name_str}' return type_str, type_space, name_str, name_space for i in func.posargs: type_str, type_space, name_str, name_space = prepare(i) signature += f' {type_str}{type_space} {name_str},{name_space} # {self.brief(i)}\n' for i in func.optargs: type_str, type_space, name_str, name_space = prepare(i) signature += f' {type_str}{type_space} [{name_str}],{name_space} # {self.brief(i)}\n' if func.varargs: type_str, type_space, name_str, name_space = prepare(func.varargs, link=False) signature += f' {type_str}{type_space} {name_str}...,{name_space} # {self.brief(func.varargs)}\n' # Abort if there are no kwargs if not func.kwargs: return signature + ')' # Only add this separator if there are any posargs if all_args: signature += '\n # Keyword arguments:\n' # Recalculate lengths for kwargs all_args = list(func.kwargs.values()) max_type_len = max([len_stripped(render_type(x.type)) for x in all_args]) max_name_len = max([len(x.name) for x in all_args]) for kwarg in self.sorted_and_filtered(list(func.kwargs.values())): type_str, type_space, name_str, name_space = prepare(kwarg) required = ' [required] ' if kwarg.required else ' ' required = required if any([x.required for x in func.kwargs.values()]) else '' signature += f' {name_str}{name_space} : {type_str}{type_space} {required} # {self.brief(kwarg)}\n' return signature + ')' def gen_arg_data(arg: T.Union[PosArg, Kwarg, VarArgs], *, optional: bool = False) -> T.Dict[str, PlaceholderTypes]: data: T.Dict[str, PlaceholderTypes] = { 'row-id': arg_anchor(arg), 'name': arg.name, 'type': render_type(arg.type), 'description': arg.description, 'since': arg.since or None, 'deprecated': arg.deprecated or None, 'optional': optional, 'default': None, } if isinstance(arg, VarArgs): data.update({ 'min': str(arg.min_varargs) if arg.min_varargs > 0 else '0', 'max': str(arg.max_varargs) if arg.max_varargs > 0 else 'infinity', }) if isinstance(arg, (Kwarg, PosArg)): data.update({'default': arg.default or None}) if isinstance(arg, Kwarg): data.update({'required': arg.required}) return data mname = f'\\{func.name}' if func.name == '[index]' else func.name data: FunctionDictType = { 'name': f'{func.obj.name}.{mname}' if isinstance(func, Method) else func.name, 'base_level': '##' if isinstance(func, Method) else '#', 'type_name_upper': 'Method' if isinstance(func, Method) else 'Function', 'type_name': 'method' if isinstance(func, Method) else 'function', 'description': func.description, 'notes': func.notes, 'warnings': func.warnings, 'example': func.example or None, 'signature_level': 'h4' if isinstance(func, Method) else 'h3', 'signature': render_signature(), 'has_args': bool(func.posargs or func.optargs or func.kwargs or func.varargs), # Merge posargs and optargs by generating the *[optional]* tag for optargs 'posargs': { 'args': [gen_arg_data(x) for x in func.posargs] + [gen_arg_data(x, optional=True) for x in func.optargs] } if func.posargs or func.optargs else None, 'kwargs': {'args': [gen_arg_data(x) for x in self.sorted_and_filtered(list(func.kwargs.values()))]} if func.kwargs else None, 'varargs': gen_arg_data(func.varargs) if func.varargs else None, 'arg_flattening': func.arg_flattening, # For the feature taggs template 'since': func.since or None, 'deprecated': func.deprecated or None, 'optional': False, 'default': None } return data def _write_object(self, obj: Object) -> None: data = { 'name': obj.name, 'title': obj.long_name if obj.obj_type == ObjectType.RETURNED else obj.name, 'description': obj.description, 'notes': obj.notes, 'warnings': obj.warnings, 'long_name': obj.long_name, 'obj_type_name': _OBJ_ID_MAP[obj.obj_type].capitalize(), 'example': obj.example or None, 'has_methods': bool(obj.methods), 'has_inherited_methods': bool(obj.inherited_methods), 'has_subclasses': bool(obj.extended_by), 'is_returned': bool(obj.returned_by), 'extends': obj.extends_obj.name if obj.extends_obj else None, 'returned_by': [self._link_to_object(x) for x in self.sorted_and_filtered(obj.returned_by)], 'extended_by': [self._link_to_object(x) for x in self.sorted_and_filtered(obj.extended_by)], 'methods': [self._gen_func_or_method(m) for m in self.sorted_and_filtered(obj.methods)], 'inherited_methods': [self._gen_func_or_method(m) for m in self.sorted_and_filtered(obj.inherited_methods)], } self._write_template(data, self._gen_object_file_id(obj), 'object') def _write_functions(self) -> None: data = {'functions': [self._gen_func_or_method(x) for x in self.functions]} self._write_template(data, 'root.functions') def _root_refman_docs(self) -> None: def gen_obj_links(objs: T.List[Object]) -> T.List[T.Dict[str, str]]: ret: T.List[T.Dict[str, str]] = [] for o in objs: ret += [{'indent': '', 'link': self._link_to_object(o), 'brief': self.brief(o)}] for m in self.sorted_and_filtered(o.methods): ret += [{'indent': ' ', 'link': self._link_to_object(m), 'brief': self.brief(m)}] if o.obj_type == ObjectType.MODULE and self.extract_returned_by_module(o): tmp = gen_obj_links(self.extract_returned_by_module(o)) tmp = [{**x, 'indent': ' ' + x['indent']} for x in tmp] ret += [{'indent': ' ', 'link': '**New objects:**', 'brief': ''}] ret += [*tmp] return ret data = { 'root': self._gen_filename('root'), 'elementary': gen_obj_links(self.elementary), 'returned': gen_obj_links(self.returned), 'builtins': gen_obj_links(self.builtins), 'modules': gen_obj_links(self.modules), 'functions': [{'indent': '', 'link': self._link_to_object(x), 'brief': self.brief(x)} for x in self.functions], 'enable_modules': self.enable_modules, } dummy = {'root': self._gen_filename('root')} self._write_template(data, 'root') self._write_template({**dummy, 'name': 'Elementary types'}, f'root.{_OBJ_ID_MAP[ObjectType.ELEMENTARY]}', 'dummy') self._write_template({**dummy, 'name': 'Builtin objects'}, f'root.{_OBJ_ID_MAP[ObjectType.BUILTIN]}', 'dummy') self._write_template({**dummy, 'name': 'Returned objects'}, f'root.{_OBJ_ID_MAP[ObjectType.RETURNED]}', 'dummy') if self.enable_modules: self._write_template({**dummy, 'name': 'Modules'}, f'root.{_OBJ_ID_MAP[ObjectType.MODULE]}', 'dummy') def generate(self) -> None: mlog.log('Generating markdown files...') with mlog.nested(): self._write_functions() for obj in self.objects: if not self.enable_modules and (obj.obj_type == ObjectType.MODULE or obj.defined_by_module is not None): continue self._write_object(obj) self._root_refman_docs() self._configure_sitemap() self._generate_link_def() def _configure_sitemap(self) -> None: ''' Replaces the `@REFMAN_PLACEHOLDER@` placeholder with the reference manual sitemap. The structure of the sitemap is derived from the file IDs. ''' raw = self.sitemap_in.read_text(encoding='utf-8') out = '' for l in raw.split('\n'): if '@REFMAN_PLACEHOLDER@' not in l: out += f'{l}\n' continue mlog.log('Generating', mlog.bold(self.sitemap_out.as_posix())) base_indent = l.replace('@REFMAN_PLACEHOLDER@', '') for k in sorted(self.generated_files.keys()): indent = base_indent + '\t' * k.count('.') out += f'{indent}{self.generated_files[k]}\n' self.sitemap_out.write_text(out, encoding='utf-8') def _generate_link_def(self) -> None: ''' Generate the link definition file for the refman_links hotdoc plugin. The plugin is then responsible for replacing the [[tag]] tags with custom HTML elements. ''' data: T.Dict[str, str] = {} # Objects and methods for obj in self.objects: obj_file = self._gen_filename(self._gen_object_file_id(obj), extension='html') data[f'@{obj.name}'] = obj_file for m in obj.methods: data[f'{obj.name}.{m.name}'] = f'{obj_file}#{obj.name}{m.name}' # Functions funcs_file = self._gen_filename('root.functions', extension='html') for fn in self.functions: data[fn.name] = f'{funcs_file}#{fn.name}' self.link_def_out.write_text(json.dumps(data, indent=2), encoding='utf-8')