# The MIT License(MIT) # # Copyright(c) 2018 Hyperion Gray # # Permission is hereby granted, free of charge, to any person obtaining a copy # of this software and associated documentation files(the "Software"), to deal # in the Software without restriction, including without limitation the rights # to use, copy, modify, merge, publish, distribute, sublicense, and / or sell # copies of the Software, and to permit persons to whom the Software is # furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included in # all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE # AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, # OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN # THE SOFTWARE. # This is a copy of https://github.com/HyperionGray/python-chrome-devtools-protocol/blob/master/generator/generate.py # The license above is theirs and MUST be preserved. # flake8: noqa import builtins from dataclasses import dataclass from enum import Enum import itertools import json import logging import operator import os from pathlib import Path import re from textwrap import dedent, indent as tw_indent import typing import inflection # type: ignore log_level = getattr(logging, os.environ.get('LOG_LEVEL', 'warning').upper()) logging.basicConfig(level=log_level) logger = logging.getLogger('generate') SHARED_HEADER = '''# DO NOT EDIT THIS FILE! # # This file is generated from the CDP specification. If you need to make # changes, edit the generator and regenerate all of the modules.''' INIT_HEADER = '''{} '''.format(SHARED_HEADER) MODULE_HEADER = '''{} # # CDP domain: {{}}{{}} from __future__ import annotations from .util import event_class, T_JSON_DICT from dataclasses import dataclass import enum import typing '''.format(SHARED_HEADER) current_version = '' UTIL_PY = """ import typing T_JSON_DICT = typing.Dict[str, typing.Any] _event_parsers = dict() def event_class(method): ''' A decorator that registers a class as an event class. ''' def decorate(cls): _event_parsers[method] = cls cls.event_class = method return cls return decorate def parse_json_event(json: T_JSON_DICT) -> typing.Any: ''' Parse a JSON dictionary into a CDP event. ''' return _event_parsers[json['method']].from_json(json['params']) """ def indent(s, n): ''' A shortcut for ``textwrap.indent`` that always uses spaces. ''' return tw_indent(s, n * ' ') BACKTICK_RE = re.compile(r'`([^`]+)`(\w+)?') def escape_backticks(docstr): ''' Escape backticks in a docstring by doubling them up. This is a little tricky because RST requires a non-letter character after the closing backticks, but some CDPs docs have things like "`AxNodeId`s". If we double the backticks in that string, then it won't be valid RST. The fix is to insert an apostrophe if an "s" trails the backticks. ''' def replace_one(match): if match.group(2) == 's': return f"``{match.group(1)}``'s" if match.group(2): # This case (some trailer other than "s") doesn't currently exist # in the CDP definitions, but it's here just to be safe. return f'``{match.group(1)}`` {match.group(2)}' return f'``{match.group(1)}``' # Sometimes pipes are used where backticks should have been used. docstr = docstr.replace('|', '`') return BACKTICK_RE.sub(replace_one, docstr) def inline_doc(description): ''' Generate an inline doc, e.g. ``#: This type is a ...`` ''' if not description: return '' description = escape_backticks(description) lines = [f'#: {l}' for l in description.split('\n')] return '\n'.join(lines) def docstring(description): ''' Generate a docstring from a description. ''' if not description: return '' description = escape_backticks(description) return dedent("'''\n{}\n'''").format(description) def is_builtin(name): ''' Return True if ``name`` would shadow a builtin. ''' try: getattr(builtins, name) return True except AttributeError: return False def snake_case(name): ''' Convert a camel case name to snake case. If the name would shadow a Python builtin, then append an underscore. ''' name = inflection.underscore(name) if is_builtin(name): name += '_' return name def ref_to_python(ref): ''' Convert a CDP ``$ref`` to the name of a Python type. For a dotted ref, the part before the dot is snake cased. ''' if '.' in ref: domain, subtype = ref.split('.') ref = f'{snake_case(domain)}.{subtype}' return f"{ref}" class CdpPrimitiveType(Enum): ''' All of the CDP types that map directly to a Python type. ''' boolean = 'bool' integer = 'int' number = 'float' object = 'dict' string = 'str' @classmethod def get_annotation(cls, cdp_type): ''' Return a type annotation for the CDP type. ''' if cdp_type == 'any': return 'typing.Any' return cls[cdp_type].value @classmethod def get_constructor(cls, cdp_type, val): ''' Return the code to construct a value for a given CDP type. ''' if cdp_type == 'any': return val cons = cls[cdp_type].value return f'{cons}({val})' @dataclass class CdpItems: ''' Represents the type of a repeated item. ''' type: str ref: str @classmethod def from_json(cls, type): ''' Generate code to instantiate an item from a JSON object. ''' return cls(type.get('type'), type.get('$ref')) @dataclass class CdpProperty: ''' A property belonging to a non-primitive CDP type. ''' name: str description: typing.Optional[str] type: typing.Optional[str] ref: typing.Optional[str] enum: typing.List[str] items: typing.Optional[CdpItems] optional: bool experimental: bool deprecated: bool @property def py_name(self): ''' Get this property's Python name. ''' return snake_case(self.name) @property def py_annotation(self): ''' This property's Python type annotation. ''' if self.items: if self.items.ref: py_ref = ref_to_python(self.items.ref) ann = f"typing.List[{py_ref}]" else: ann = 'typing.List[{}]'.format( CdpPrimitiveType.get_annotation(self.items.type)) else: if self.ref: py_ref = ref_to_python(self.ref) ann = py_ref else: ann = CdpPrimitiveType.get_annotation( typing.cast(str, self.type)) if self.optional: ann = f'typing.Optional[{ann}]' return ann @classmethod def from_json(cls, property): ''' Instantiate a CDP property from a JSON object. ''' return cls( property['name'], property.get('description'), property.get('type'), property.get('$ref'), property.get('enum'), CdpItems.from_json(property['items']) if 'items' in property else None, property.get('optional', False), property.get('experimental', False), property.get('deprecated', False), ) def generate_decl(self): ''' Generate the code that declares this property. ''' code = inline_doc(self.description) if code: code += '\n' code += f'{self.py_name}: {self.py_annotation}' if self.optional: code += ' = None' return code def generate_to_json(self, dict_, use_self=True): ''' Generate the code that exports this property to the specified JSON dict. ''' self_ref = 'self.' if use_self else '' assign = f"{dict_}['{self.name}'] = " if self.items: if self.items.ref: assign += f"[i.to_json() for i in {self_ref}{self.py_name}]" else: assign += f"[i for i in {self_ref}{self.py_name}]" else: if self.ref: assign += f"{self_ref}{self.py_name}.to_json()" else: assign += f"{self_ref}{self.py_name}" if self.optional: code = dedent(f'''\ if {self_ref}{self.py_name} is not None: {assign}''') else: code = assign return code def generate_from_json(self, dict_): ''' Generate the code that creates an instance from a JSON dict named ``dict_``. ''' if self.items: if self.items.ref: py_ref = ref_to_python(self.items.ref) expr = f"[{py_ref}.from_json(i) for i in {dict_}['{self.name}']]" expr else: cons = CdpPrimitiveType.get_constructor(self.items.type, 'i') expr = f"[{cons} for i in {dict_}['{self.name}']]" else: if self.ref: py_ref = ref_to_python(self.ref) expr = f"{py_ref}.from_json({dict_}['{self.name}'])" else: expr = CdpPrimitiveType.get_constructor(self.type, f"{dict_}['{self.name}']") if self.optional: expr = f"{expr} if '{self.name}' in {dict_} else None" return expr @dataclass class CdpType: ''' A top-level CDP type. ''' id: str description: typing.Optional[str] type: str items: typing.Optional[CdpItems] enum: typing.List[str] properties: typing.List[CdpProperty] @classmethod def from_json(cls, type_): ''' Instantiate a CDP type from a JSON object. ''' return cls( type_['id'], type_.get('description'), type_['type'], CdpItems.from_json(type_['items']) if 'items' in type_ else None, type_.get('enum'), [CdpProperty.from_json(p) for p in type_.get('properties', [])], ) def generate_code(self): ''' Generate Python code for this type. ''' logger.debug('Generating type %s: %s', self.id, self.type) if self.enum: return self.generate_enum_code() if self.properties: return self.generate_class_code() return self.generate_primitive_code() def generate_primitive_code(self): ''' Generate code for a primitive type. ''' if self.items: if self.items.ref: nested_type = ref_to_python(self.items.ref) else: nested_type = CdpPrimitiveType.get_annotation(self.items.type) py_type = f'typing.List[{nested_type}]' superclass = 'list' else: # A primitive type cannot have a ref, so there is no branch here. py_type = CdpPrimitiveType.get_annotation(self.type) superclass = py_type code = f'class {self.id}({superclass}):\n' doc = docstring(self.description) if doc: code += indent(doc, 4) + '\n' def_to_json = dedent(f'''\ def to_json(self) -> {py_type}: return self''') code += indent(def_to_json, 4) def_from_json = dedent(f'''\ @classmethod def from_json(cls, json: {py_type}) -> {self.id}: return cls(json)''') code += '\n\n' + indent(def_from_json, 4) def_repr = dedent(f'''\ def __repr__(self): return '{self.id}({{}})'.format(super().__repr__())''') code += '\n\n' + indent(def_repr, 4) return code def generate_enum_code(self): ''' Generate an "enum" type. Enums are handled by making a python class that contains only class members. Each class member is upper snaked case, e.g. ``MyTypeClass.MY_ENUM_VALUE`` and is assigned a string value from the CDP metadata. ''' def_to_json = dedent('''\ def to_json(self): return self.value''') def_from_json = dedent('''\ @classmethod def from_json(cls, json): return cls(json)''') code = f'class {self.id}(enum.Enum):\n' doc = docstring(self.description) if doc: code += indent(doc, 4) + '\n' for enum_member in self.enum: snake_name = snake_case(enum_member).upper() enum_code = f'{snake_name} = "{enum_member}"\n' code += indent(enum_code, 4) code += '\n' + indent(def_to_json, 4) code += '\n\n' + indent(def_from_json, 4) return code def generate_class_code(self): ''' Generate a class type. Top-level types that are defined as a CDP ``object`` are turned into Python dataclasses. ''' # children = set() code = dedent(f'''\ @dataclass class {self.id}:\n''') doc = docstring(self.description) if doc: code += indent(doc, 4) + '\n' # Emit property declarations. These are sorted so that optional # properties come after required properties, which is required to make # the dataclass constructor work. props = list(self.properties) props.sort(key=operator.attrgetter('optional')) code += '\n\n'.join(indent(p.generate_decl(), 4) for p in props) code += '\n\n' # Emit to_json() method. The properties are sorted in the same order as # above for readability. def_to_json = dedent('''\ def to_json(self): json = dict() ''') assigns = (p.generate_to_json(dict_='json') for p in props) def_to_json += indent('\n'.join(assigns), 4) def_to_json += '\n' def_to_json += indent('return json', 4) code += indent(def_to_json, 4) + '\n\n' # Emit from_json() method. The properties are sorted in the same order # as above for readability. def_from_json = dedent('''\ @classmethod def from_json(cls, json): return cls( ''') from_jsons = [] for p in props: from_json = p.generate_from_json(dict_='json') from_jsons.append(f'{p.py_name}={from_json},') def_from_json += indent('\n'.join(from_jsons), 8) def_from_json += '\n' def_from_json += indent(')', 4) code += indent(def_from_json, 4) return code def get_refs(self): ''' Return all refs for this type. ''' refs = set() if self.enum: # Enum types don't have refs. pass elif self.properties: # Enumerate refs for a class type. for prop in self.properties: if prop.items and prop.items.ref: refs.add(prop.items.ref) elif prop.ref: refs.add(prop.ref) else: # A primitive type can't have a direct ref, but it can have an items # which contains a ref. if self.items and self.items.ref: refs.add(self.items.ref) return refs class CdpParameter(CdpProperty): ''' A parameter to a CDP command. ''' def generate_code(self): ''' Generate the code for a parameter in a function call. ''' if self.items: if self.items.ref: nested_type = ref_to_python(self.items.ref) py_type = f"typing.List[{nested_type}]" else: nested_type = CdpPrimitiveType.get_annotation(self.items.type) py_type = f'typing.List[{nested_type}]' else: if self.ref: py_type = f"{ref_to_python(self.ref)}" else: py_type = CdpPrimitiveType.get_annotation( typing.cast(str, self.type)) if self.optional: py_type = f'typing.Optional[{py_type}]' code = f"{self.py_name}: {py_type}" if self.optional: code += ' = None' return code def generate_decl(self): ''' Generate the declaration for this parameter. ''' if self.description: code = inline_doc(self.description) code += '\n' else: code = '' code += f'{self.py_name}: {self.py_annotation}' return code def generate_doc(self): ''' Generate the docstring for this parameter. ''' doc = f':param {self.py_name}:' if self.experimental: doc += ' **(EXPERIMENTAL)**' if self.optional: doc += ' *(Optional)*' if self.description: desc = self.description.replace('`', '``').replace('\n', ' ') doc += f' {desc}' return doc def generate_from_json(self, dict_): ''' Generate the code to instantiate this parameter from a JSON dict. ''' code = super().generate_from_json(dict_) return f'{self.py_name}={code}' class CdpReturn(CdpProperty): ''' A return value from a CDP command. ''' @property def py_annotation(self): ''' Return the Python type annotation for this return. ''' if self.items: if self.items.ref: py_ref = ref_to_python(self.items.ref) ann = f"typing.List[{py_ref}]" else: py_type = CdpPrimitiveType.get_annotation(self.items.type) ann = f'typing.List[{py_type}]' else: if self.ref: py_ref = ref_to_python(self.ref) ann = f"{py_ref}" else: ann = CdpPrimitiveType.get_annotation(self.type) if self.optional: ann = f'typing.Optional[{ann}]' return ann def generate_doc(self): ''' Generate the docstring for this return. ''' if self.description: doc = self.description.replace('\n', ' ') if self.optional: doc = f'*(Optional)* {doc}' else: doc = '' return doc def generate_return(self, dict_): ''' Generate code for returning this value. ''' return super().generate_from_json(dict_) @dataclass class CdpCommand: ''' A CDP command. ''' name: str description: str experimental: bool deprecated: bool parameters: typing.List[CdpParameter] returns: typing.List[CdpReturn] domain: str @property def py_name(self): ''' Get a Python name for this command. ''' return snake_case(self.name) @classmethod def from_json(cls, command, domain) -> 'CdpCommand': ''' Instantiate a CDP command from a JSON object. ''' parameters = command.get('parameters', []) returns = command.get('returns', []) return cls( command['name'], command.get('description'), command.get('experimental', False), command.get('deprecated', False), [typing.cast(CdpParameter, CdpParameter.from_json(p)) for p in parameters], [typing.cast(CdpReturn, CdpReturn.from_json(r)) for r in returns], domain, ) def generate_code(self): ''' Generate code for a CDP command. ''' global current_version # Generate the function header if len(self.returns) == 0: ret_type = 'None' elif len(self.returns) == 1: ret_type = self.returns[0].py_annotation else: nested_types = ', '.join(r.py_annotation for r in self.returns) ret_type = f'typing.Tuple[{nested_types}]' ret_type = f"typing.Generator[T_JSON_DICT,T_JSON_DICT,{ret_type}]" code = '' code += f'def {self.py_name}(' ret = f') -> {ret_type}:\n' if self.parameters: params = [p.generate_code() for p in self.parameters] optional = False clean_params = [] for para in params: if "= None" in para: optional = True if optional and "= None" not in para: para += ' = None' clean_params.append(para) code += '\n' code += indent( ',\n'.join(clean_params), 8) code += '\n' code += indent(ret, 4) else: code += ret # Generate the docstring doc = '' if self.description: doc = self.description if self.experimental: doc += '\n\n**EXPERIMENTAL**' if self.parameters and doc: doc += '\n\n' elif not self.parameters and self.returns: doc += '\n' doc += '\n'.join(p.generate_doc() for p in self.parameters) if len(self.returns) == 1: doc += '\n' ret_doc = self.returns[0].generate_doc() doc += f':returns: {ret_doc}' elif len(self.returns) > 1: doc += '\n' doc += ':returns: A tuple with the following items:\n\n' ret_docs = '\n'.join(f'{i}. **{r.name}** - {r.generate_doc()}' for i, r in enumerate(self.returns)) doc += indent(ret_docs, 4) if doc: code += indent(docstring(doc), 4) # Generate the function body if self.parameters: code += '\n' code += indent('params: T_JSON_DICT = dict()', 4) code += '\n' assigns = (p.generate_to_json(dict_='params', use_self=False) for p in self.parameters) code += indent('\n'.join(assigns), 4) code += '\n' code += indent('cmd_dict: T_JSON_DICT = {\n', 4) code += indent(f"'method': '{self.domain}.{self.name}',\n", 8) if self.parameters: code += indent("'params': params,\n", 8) code += indent('}\n', 4) code += indent('json = yield cmd_dict', 4) if len(self.returns) == 0: pass elif len(self.returns) == 1: ret = self.returns[0].generate_return(dict_='json') code += indent(f'\nreturn {ret}', 4) else: ret = '\nreturn (\n' expr = ',\n'.join(r.generate_return(dict_='json') for r in self.returns) ret += indent(expr, 4) ret += '\n)' code += indent(ret, 4) return code def get_refs(self): ''' Get all refs for this command. ''' refs = set() for type_ in itertools.chain(self.parameters, self.returns): if type_.items and type_.items.ref: refs.add(type_.items.ref) elif type_.ref: refs.add(type_.ref) return refs @dataclass class CdpEvent: ''' A CDP event object. ''' name: str description: typing.Optional[str] deprecated: bool experimental: bool parameters: typing.List[CdpParameter] domain: str @property def py_name(self): ''' Return the Python class name for this event. ''' return inflection.camelize(self.name, uppercase_first_letter=True) @classmethod def from_json(cls, json: dict, domain: str): ''' Create a new CDP event instance from a JSON dict. ''' return cls( json['name'], json.get('description'), json.get('deprecated', False), json.get('experimental', False), [typing.cast(CdpParameter, CdpParameter.from_json(p)) for p in json.get('parameters', [])], domain ) def generate_code(self): ''' Generate code for a CDP event. ''' global current_version code = dedent(f'''\ @event_class('{self.domain}.{self.name}') @dataclass class {self.py_name}:''') code += '\n' desc = '' if self.description or self.experimental: if self.experimental: desc += '**EXPERIMENTAL**\n\n' if self.description: desc += self.description code += indent(docstring(desc), 4) code += '\n' code += indent( '\n'.join(p.generate_decl() for p in self.parameters), 4) code += '\n\n' def_from_json = dedent(f'''\ @classmethod def from_json(cls, json: T_JSON_DICT) -> {self.py_name}: return cls( ''') code += indent(def_from_json, 4) from_json = ',\n'.join(p.generate_from_json(dict_='json') for p in self.parameters) code += indent(from_json, 12) code += '\n' code += indent(')', 8) return code def get_refs(self): ''' Get all refs for this event. ''' refs = set() for param in self.parameters: if param.items and param.items.ref: refs.add(param.items.ref) elif param.ref: refs.add(param.ref) return refs @dataclass class CdpDomain: ''' A CDP domain contains metadata, types, commands, and events. ''' domain: str description: typing.Optional[str] experimental: bool dependencies: typing.List[str] types: typing.List[CdpType] commands: typing.List[CdpCommand] events: typing.List[CdpEvent] @property def module(self): ''' The name of the Python module for this CDP domain. ''' return snake_case(self.domain) @classmethod def from_json(cls, domain: dict): ''' Instantiate a CDP domain from a JSON object. ''' types = domain.get('types', []) commands = domain.get('commands', []) events = domain.get('events', []) domain_name = domain['domain'] return cls( domain_name, domain.get('description'), domain.get('experimental', False), domain.get('dependencies', []), [CdpType.from_json(type) for type in types], [CdpCommand.from_json(command, domain_name) for command in commands], [CdpEvent.from_json(event, domain_name) for event in events] ) def generate_code(self): ''' Generate the Python module code for a given CDP domain. ''' exp = ' (experimental)' if self.experimental else '' code = MODULE_HEADER.format(self.domain, exp) import_code = self.generate_imports() if import_code: code += import_code code += '\n\n' code += '\n' item_iter_t = typing.Union[CdpEvent, CdpCommand, CdpType] item_iter: typing.Iterator[item_iter_t] = itertools.chain( iter(self.types), iter(self.commands), iter(self.events), ) code += '\n\n\n'.join(item.generate_code() for item in item_iter) code += '\n' return code def generate_imports(self): ''' Determine which modules this module depends on and emit the code to import those modules. Notice that CDP defines a ``dependencies`` field for each domain, but these dependencies are a subset of the modules that we actually need to import to make our Python code work correctly and type safe. So we ignore the CDP's declared dependencies and compute them ourselves. ''' refs = set() for type_ in self.types: refs |= type_.get_refs() for command in self.commands: refs |= command.get_refs() for event in self.events: refs |= event.get_refs() dependencies = set() for ref in refs: try: domain, _ = ref.split('.') except ValueError: continue if domain != self.domain: dependencies.add(snake_case(domain)) code = '\n'.join(f'from . import {d}' for d in sorted(dependencies)) return code def generate_sphinx(self): ''' Generate a Sphinx document for this domain. ''' docs = self.domain + '\n' docs += '=' * len(self.domain) + '\n\n' if self.description: docs += f'{self.description}\n\n' if self.experimental: docs += '*This CDP domain is experimental.*\n\n' docs += f'.. module:: cdp.{self.module}\n\n' docs += '* Types_\n* Commands_\n* Events_\n\n' docs += 'Types\n-----\n\n' if self.types: docs += dedent('''\ Generally, you do not need to instantiate CDP types yourself. Instead, the API creates objects for you as return values from commands, and then you can use those objects as arguments to other commands. ''') else: docs += '*There are no types in this module.*\n' for type in self.types: docs += f'\n.. autoclass:: {type.id}\n' docs += ' :members:\n' docs += ' :undoc-members:\n' docs += ' :exclude-members: from_json, to_json\n' docs += '\nCommands\n--------\n\n' if self.commands: docs += dedent('''\ Each command is a generator function. The return type ``Generator[x, y, z]`` indicates that the generator *yields* arguments of type ``x``, it must be resumed with an argument of type ``y``, and it returns type ``z``. In this library, types ``x`` and ``y`` are the same for all commands, and ``z`` is the return type you should pay attention to. For more information, see :ref:`Getting Started: Commands `. ''') else: docs += '*There are no types in this module.*\n' for command in sorted(self.commands, key=operator.attrgetter('py_name')): docs += f'\n.. autofunction:: {command.py_name}\n' docs += '\nEvents\n------\n\n' if self.events: docs += dedent('''\ Generally, you do not need to instantiate CDP events yourself. Instead, the API creates events for you and then you use the event\'s attributes. ''') else: docs += '*There are no events in this module.*\n' for event in self.events: docs += f'\n.. autoclass:: {event.py_name}\n' docs += ' :members:\n' docs += ' :undoc-members:\n' docs += ' :exclude-members: from_json, to_json\n' return docs def parse(json_path, output_path): ''' Parse JSON protocol description and return domain objects. :param Path json_path: path to a JSON CDP schema :param Path output_path: a directory path to create the modules in :returns: a list of CDP domain objects ''' global current_version with open(json_path, encoding="utf-8") as json_file: schema = json.load(json_file) version = schema['version'] assert (version['major'], version['minor']) == ('1', '3') current_version = f'{version["major"]}.{version["minor"]}' domains = [] for domain in schema['domains']: domains.append(CdpDomain.from_json(domain)) return domains def generate_init(init_path, domains): ''' Generate an ``__init__.py`` that exports the specified modules. :param Path init_path: a file path to create the init file in :param list[tuple] modules: a list of modules each represented as tuples of (name, list_of_exported_symbols) ''' with open(init_path, "w", encoding="utf-8") as init_file: init_file.write(INIT_HEADER) for domain in domains: init_file.write(f'from . import {domain.module}\n') init_file.write('from . import util\n\n') def generate_docs(docs_path, domains): ''' Generate Sphinx documents for each domain. ''' logger.info('Generating Sphinx documents') # Remove generated documents for subpath in docs_path.iterdir(): subpath.unlink() # Generate document for each domain for domain in domains: doc = docs_path / f'{domain.module}.rst' with doc.open('w') as f: f.write(domain.generate_sphinx()) def main(browser_protocol_path, js_protocol_path, output_path): ''' Main entry point. ''' output_path = Path(output_path).resolve() json_paths = [ browser_protocol_path, js_protocol_path, ] # Generate util.py util_path = output_path / "util.py" with util_path.open('w') as util_file: util_file.write(UTIL_PY) # Remove generated code for subpath in output_path.iterdir(): if subpath.is_file() and subpath.name not in ('py.typed', 'util.py'): subpath.unlink() # Parse domains domains = [] for json_path in json_paths: logger.info('Parsing JSON file %s', json_path) domains.extend(parse(json_path, output_path)) domains.sort(key=operator.attrgetter('domain')) # Patch up CDP errors. It's easier to patch that here than it is to modify # the generator code. # 1. DOM includes an erroneous $ref that refers to itself. # 2. Page includes an event with an extraneous backtick in the description. for domain in domains: if domain.domain == 'DOM': for cmd in domain.commands: if cmd.name == 'resolveNode': # Patch 1 cmd.parameters[1].ref = 'BackendNodeId' elif domain.domain == 'Page': for event in domain.events: if event.name == 'screencastVisibilityChanged': # Patch 2 event.description = event.description.replace('`', '') for domain in domains: logger.info('Generating module: %s → %s.py', domain.domain, domain.module) module_path = output_path / f'{domain.module}.py' with module_path.open('w') as module_file: module_file.write(domain.generate_code()) init_path = output_path / '__init__.py' generate_init(init_path, domains) # Not generating the docs as we don't want people to directly # Use the CDP APIs # docs_path = here.parent / 'docs' / 'api' # generate_docs(docs_path, domains) py_typed_path = output_path / 'py.typed' py_typed_path.touch() if __name__ == '__main__': import sys assert sys.version_info >= (3, 7), "To generate the CDP code requires python 3.7 or later" args = sys.argv[1:] main(*args)