esphome/esphome/cpp_generator.py
2020-05-23 20:33:58 -03:00

724 lines
21 KiB
Python

import abc
import inspect
import math
# pylint: disable=unused-import, wrong-import-order
from typing import Any, Generator, List, Optional, Tuple, Type, Union, Sequence
from esphome.core import ( # noqa
CORE, HexInt, ID, Lambda, TimePeriod, TimePeriodMicroseconds,
TimePeriodMilliseconds, TimePeriodMinutes, TimePeriodSeconds, coroutine, Library, Define,
EnumValue)
from esphome.helpers import cpp_string_escape, indent_all_but_first_and_last
from esphome.util import OrderedDict
class Expression(abc.ABC):
__slots__ = ()
@abc.abstractmethod
def __str__(self):
"""
Convert expression into C++ code
"""
SafeExpType = Union[Expression, bool, str, str, int, float, TimePeriod,
Type[bool], Type[int], Type[float], Sequence[Any]]
class RawExpression(Expression):
__slots__ = ("text", )
def __init__(self, text: str):
self.text = text
def __str__(self):
return self.text
class AssignmentExpression(Expression):
__slots__ = ("type", "modifier", "name", "rhs", "obj")
def __init__(self, type_, modifier, name, rhs, obj):
self.type = type_
self.modifier = modifier
self.name = name
self.rhs = safe_exp(rhs)
self.obj = obj
def __str__(self):
if self.type is None:
return f"{self.name} = {self.rhs}"
return f"{self.type} {self.modifier}{self.name} = {self.rhs}"
class VariableDeclarationExpression(Expression):
__slots__ = ("type", "modifier", "name")
def __init__(self, type_, modifier, name):
self.type = type_
self.modifier = modifier
self.name = name
def __str__(self):
return f"{self.type} {self.modifier}{self.name}"
class ExpressionList(Expression):
__slots__ = ("args", )
def __init__(self, *args: Optional[SafeExpType]):
# Remove every None on end
args = list(args)
while args and args[-1] is None:
args.pop()
self.args = [safe_exp(arg) for arg in args]
def __str__(self):
text = ", ".join(str(x) for x in self.args)
return indent_all_but_first_and_last(text)
def __iter__(self):
return iter(self.args)
class TemplateArguments(Expression):
__slots__ = ("args", )
def __init__(self, *args: SafeExpType):
self.args = ExpressionList(*args)
def __str__(self):
return f'<{self.args}>'
def __iter__(self):
return iter(self.args)
class CallExpression(Expression):
__slots__ = ("base", "template_args", "args")
def __init__(self, base: Expression, *args: SafeExpType):
self.base = base
if args and isinstance(args[0], TemplateArguments):
self.template_args = args[0]
args = args[1:]
else:
self.template_args = None
self.args = ExpressionList(*args)
def __str__(self):
if self.template_args is not None:
return f'{self.base}{self.template_args}({self.args})'
return f'{self.base}({self.args})'
class StructInitializer(Expression):
__slots__ = ("base", "args")
def __init__(self, base: Expression, *args: Tuple[str, Optional[SafeExpType]]):
self.base = base
# TODO: args is always a Tuple, is this check required?
if not isinstance(args, OrderedDict):
args = OrderedDict(args)
self.args = OrderedDict()
for key, value in args.items():
if value is None:
continue
exp = safe_exp(value)
self.args[key] = exp
def __str__(self):
cpp = f'{self.base}{{\n'
for key, value in self.args.items():
cpp += f' .{key} = {value},\n'
cpp += '}'
return cpp
class ArrayInitializer(Expression):
__slots__ = ("multiline", "args")
def __init__(self, *args: Any, multiline: bool = False):
self.multiline = multiline
self.args = []
for arg in args:
if arg is None:
continue
exp = safe_exp(arg)
self.args.append(exp)
def __str__(self):
if not self.args:
return '{}'
if self.multiline:
cpp = '{\n'
for arg in self.args:
cpp += f' {arg},\n'
cpp += '}'
else:
cpp = '{' + ', '.join(str(arg) for arg in self.args) + '}'
return cpp
class ParameterExpression(Expression):
__slots__ = ("type", "id")
def __init__(self, type_, id_):
self.type = safe_exp(type_)
self.id = id_
def __str__(self):
return f"{self.type} {self.id}"
class ParameterListExpression(Expression):
__slots__ = ("parameters", )
def __init__(self, *parameters: Union[ParameterExpression, Tuple[SafeExpType, str]]):
self.parameters = []
for parameter in parameters:
if not isinstance(parameter, ParameterExpression):
parameter = ParameterExpression(*parameter)
self.parameters.append(parameter)
def __str__(self):
return ", ".join(str(x) for x in self.parameters)
class LambdaExpression(Expression):
__slots__ = ("parts", "parameters", "capture", "return_type")
def __init__(self, parts, parameters, capture: str = '=', return_type=None):
self.parts = parts
if not isinstance(parameters, ParameterListExpression):
parameters = ParameterListExpression(*parameters)
self.parameters = parameters
self.capture = capture
self.return_type = safe_exp(return_type) if return_type is not None else None
def __str__(self):
cpp = f'[{self.capture}]({self.parameters})'
if self.return_type is not None:
cpp += f' -> {self.return_type}'
cpp += f' {{\n{self.content}\n}}'
return indent_all_but_first_and_last(cpp)
@property
def content(self):
return ''.join(str(part) for part in self.parts)
# pylint: disable=abstract-method
class Literal(Expression, metaclass=abc.ABCMeta):
__slots__ = ()
class StringLiteral(Literal):
__slots__ = ("string", )
def __init__(self, string: str):
super().__init__()
self.string = string
def __str__(self):
return cpp_string_escape(self.string)
class IntLiteral(Literal):
__slots__ = ("i", )
def __init__(self, i: int):
super().__init__()
self.i = i
def __str__(self):
if self.i > 4294967295:
return f'{self.i}ULL'
if self.i > 2147483647:
return f'{self.i}UL'
if self.i < -2147483648:
return f'{self.i}LL'
return str(self.i)
class BoolLiteral(Literal):
__slots__ = ("binary", )
def __init__(self, binary: bool):
super().__init__()
self.binary = binary
def __str__(self):
return "true" if self.binary else "false"
class HexIntLiteral(Literal):
__slots__ = ("i", )
def __init__(self, i: int):
super().__init__()
self.i = HexInt(i)
def __str__(self):
return str(self.i)
class FloatLiteral(Literal):
__slots__ = ("f", )
def __init__(self, value: float):
super().__init__()
self.f = value
def __str__(self):
if math.isnan(self.f):
return "NAN"
return f"{self.f}f"
def safe_exp(obj: SafeExpType) -> Expression:
"""Try to convert obj to an expression by automatically converting native python types to
expressions/literals.
"""
from esphome.cpp_types import bool_, float_, int32
if isinstance(obj, Expression):
return obj
if isinstance(obj, EnumValue):
return safe_exp(obj.enum_value)
if isinstance(obj, bool):
return BoolLiteral(obj)
if isinstance(obj, str):
return StringLiteral(obj)
if isinstance(obj, HexInt):
return HexIntLiteral(obj)
if isinstance(obj, int):
return IntLiteral(obj)
if isinstance(obj, float):
return FloatLiteral(obj)
if isinstance(obj, TimePeriodMicroseconds):
return IntLiteral(int(obj.total_microseconds))
if isinstance(obj, TimePeriodMilliseconds):
return IntLiteral(int(obj.total_milliseconds))
if isinstance(obj, TimePeriodSeconds):
return IntLiteral(int(obj.total_seconds))
if isinstance(obj, TimePeriodMinutes):
return IntLiteral(int(obj.total_minutes))
if isinstance(obj, (tuple, list)):
return ArrayInitializer(*[safe_exp(o) for o in obj])
if obj is bool:
return bool_
if obj is int:
return int32
if obj is float:
return float_
if isinstance(obj, ID):
raise ValueError("Object {} is an ID. Did you forget to register the variable?"
"".format(obj))
if inspect.isgenerator(obj):
raise ValueError("Object {} is a coroutine. Did you forget to await the expression with "
"'yield'?".format(obj))
raise ValueError("Object is not an expression", obj)
class Statement(abc.ABC):
__slots__ = ()
@abc.abstractmethod
def __str__(self):
"""
Convert statement into C++ code
"""
class RawStatement(Statement):
__slots__ = ("text", )
def __init__(self, text: str):
self.text = text
def __str__(self):
return self.text
class ExpressionStatement(Statement):
__slots__ = ("expression", )
def __init__(self, expression):
self.expression = safe_exp(expression)
def __str__(self):
return f"{self.expression};"
class LineComment(Statement):
__slots__ = ("value", )
def __init__(self, value: str):
self.value = value
def __str__(self):
parts = self.value.split('\n')
parts = [f'// {x}' for x in parts]
return '\n'.join(parts)
class ProgmemAssignmentExpression(AssignmentExpression):
__slots__ = ()
def __init__(self, type_, name, rhs, obj):
super().__init__(type_, '', name, rhs, obj)
def __str__(self):
return f"static const {self.type} {self.name}[] PROGMEM = {self.rhs}"
def progmem_array(id_, rhs) -> "MockObj":
rhs = safe_exp(rhs)
obj = MockObj(id_, '.')
assignment = ProgmemAssignmentExpression(id_.type, id_, rhs, obj)
CORE.add(assignment)
CORE.register_variable(id_, obj)
return obj
def statement(expression: Union[Expression, Statement]) -> Statement:
"""Convert expression into a statement unless is already a statement.
"""
if isinstance(expression, Statement):
return expression
return ExpressionStatement(expression)
def variable(id_: ID, rhs: SafeExpType, type_: "MockObj" = None) -> "MockObj":
"""Declare a new variable (not pointer type) in the code generation.
:param id_: The ID used to declare the variable.
:param rhs: The expression to place on the right hand side of the assignment.
:param type_: Manually define a type for the variable, only use this when it's not possible
to do so during config validation phase (for example because of template arguments).
:returns The new variable as a MockObj.
"""
assert isinstance(id_, ID)
rhs = safe_exp(rhs)
obj = MockObj(id_, '.')
if type_ is not None:
id_.type = type_
assignment = AssignmentExpression(id_.type, '', id_, rhs, obj)
CORE.add(assignment)
CORE.register_variable(id_, obj)
return obj
def Pvariable(id_: ID, rhs: SafeExpType, type_: "MockObj" = None) -> "MockObj":
"""Declare a new pointer variable in the code generation.
:param id_: The ID used to declare the variable.
:param rhs: The expression to place on the right hand side of the assignment.
:param type_: Manually define a type for the variable, only use this when it's not possible
to do so during config validation phase (for example because of template arguments).
:returns The new variable as a MockObj.
"""
rhs = safe_exp(rhs)
obj = MockObj(id_, '->')
if type_ is not None:
id_.type = type_
decl = VariableDeclarationExpression(id_.type, '*', id_)
CORE.add_global(decl)
assignment = AssignmentExpression(None, None, id_, rhs, obj)
CORE.add(assignment)
CORE.register_variable(id_, obj)
return obj
def new_Pvariable(id_: ID, *args: SafeExpType) -> Pvariable:
"""Declare a new pointer variable in the code generation by calling it's constructor
with the given arguments.
:param id_: The ID used to declare the variable (also specifies the type).
:param args: The values to pass to the constructor.
:returns The new variable as a MockObj.
"""
if args and isinstance(args[0], TemplateArguments):
id_ = id_.copy()
id_.type = id_.type.template(args[0])
args = args[1:]
rhs = id_.type.new(*args)
return Pvariable(id_, rhs)
def add(expression: Union[Expression, Statement]):
"""Add an expression to the codegen section.
After this is called, the given given expression will
show up in the setup() function after this has been called.
"""
CORE.add(expression)
def add_global(expression: Union[SafeExpType, Statement]):
"""Add an expression to the codegen global storage (above setup())."""
CORE.add_global(expression)
def add_library(name: str, version: Optional[str]):
"""Add a library to the codegen library storage.
:param name: The name of the library (for example 'AsyncTCP')
:param version: The version of the library, may be None.
"""
CORE.add_library(Library(name, version))
def add_build_flag(build_flag: str):
"""Add a global build flag to the compiler flags."""
CORE.add_build_flag(build_flag)
def add_define(name: str, value: SafeExpType = None):
"""Add a global define to the auto-generated defines.h file.
Optionally define a value to set this define to.
"""
if value is None:
CORE.add_define(Define(name))
else:
CORE.add_define(Define(name, safe_exp(value)))
@coroutine
def get_variable(id_: ID) -> Generator["MockObj", None, None]:
"""
Wait for the given ID to be defined in the code generation and
return it as a MockObj.
This is a coroutine, you need to await it with a 'yield' expression!
:param id_: The ID to retrieve
:return: The variable as a MockObj.
"""
var = yield CORE.get_variable(id_)
yield var
@coroutine
def get_variable_with_full_id(id_: ID) -> Generator[Tuple[ID, "MockObj"], None, None]:
"""
Wait for the given ID to be defined in the code generation and
return it as a MockObj.
This is a coroutine, you need to await it with a 'yield' expression!
:param id_: The ID to retrieve
:return: The variable as a MockObj.
"""
full_id, var = yield CORE.get_variable_with_full_id(id_)
yield full_id, var
@coroutine
def process_lambda(
value: Lambda, parameters: List[Tuple[SafeExpType, str]],
capture: str = '=', return_type: SafeExpType = None
) -> Generator[LambdaExpression, None, None]:
"""Process the given lambda value into a LambdaExpression.
This is a coroutine because lambdas can depend on other IDs,
you need to await it with 'yield'!
:param value: The lambda to process.
:param parameters: The parameters to pass to the Lambda, list of tuples
:param capture: The capture expression for the lambda, usually ''.
:param return_type: The return type of the lambda.
:return: The generated lambda expression.
"""
from esphome.components.globals import GlobalsComponent
if value is None:
yield
return
parts = value.parts[:]
for i, id in enumerate(value.requires_ids):
full_id, var = yield CORE.get_variable_with_full_id(id)
if full_id is not None and isinstance(full_id.type, MockObjClass) and \
full_id.type.inherits_from(GlobalsComponent):
parts[i * 3 + 1] = var.value()
continue
if parts[i * 3 + 2] == '.':
parts[i * 3 + 1] = var._
else:
parts[i * 3 + 1] = var
parts[i * 3 + 2] = ''
yield LambdaExpression(parts, parameters, capture, return_type)
def is_template(value):
"""Return if value is a lambda expression."""
return isinstance(value, Lambda)
@coroutine
def templatable(value: Any,
args: List[Tuple[SafeExpType, str]],
output_type: Optional[SafeExpType],
to_exp: Any = None):
"""Generate code for a templatable config option.
If `value` is a templated value, the lambda expression is returned.
Otherwise the value is returned as-is (optionally process with to_exp).
:param value: The value to process.
:param args: The arguments for the lambda expression.
:param output_type: The output type of the lambda expression.
:param to_exp: An optional callable to use for converting non-templated values.
:return: The potentially templated value.
"""
if is_template(value):
lambda_ = yield process_lambda(value, args, return_type=output_type)
yield lambda_
else:
if to_exp is None:
yield value
elif isinstance(to_exp, dict):
yield to_exp[value]
else:
yield to_exp(value)
class MockObj(Expression):
"""A general expression that can be used to represent any value.
Mostly consists of magic methods that allow ESPHome's codegen syntax.
"""
__slots__ = ("base", "op")
def __init__(self, base, op='.'):
self.base = base
self.op = op
def __getattr__(self, attr: str) -> "MockObj":
next_op = '.'
if attr.startswith('P') and self.op not in ['::', '']:
attr = attr[1:]
next_op = '->'
if attr.startswith('_'):
attr = attr[1:]
return MockObj(f'{self.base}{self.op}{attr}', next_op)
def __call__(self, *args): # type: (SafeExpType) -> MockObj
call = CallExpression(self.base, *args)
return MockObj(call, self.op)
def __str__(self):
return str(self.base)
def __repr__(self):
return 'MockObj<{}>'.format(str(self.base))
@property
def _(self) -> "MockObj":
return MockObj(f'{self.base}{self.op}')
@property
def new(self) -> "MockObj":
return MockObj(f'new {self.base}', '->')
def template(self, *args: SafeExpType) -> "MockObj":
if len(args) != 1 or not isinstance(args[0], TemplateArguments):
args = TemplateArguments(*args)
else:
args = args[0]
return MockObj(f'{self.base}{args}')
def namespace(self, name: str) -> "MockObj":
return MockObj(f'{self._}{name}', '::')
def class_(self, name: str, *parents: "MockObjClass") -> "MockObjClass":
op = '' if self.op == '' else '::'
return MockObjClass(f'{self.base}{op}{name}', '.', parents=parents)
def struct(self, name: str) -> "MockObjClass":
return self.class_(name)
def enum(self, name: str, is_class: bool = False) -> "MockObj":
return MockObjEnum(enum=name, is_class=is_class, base=self.base, op=self.op)
def operator(self, name: str) -> "MockObj":
if name == 'ref':
return MockObj(f'{self.base} &', '')
if name == 'ptr':
return MockObj(f'{self.base} *', '')
if name == "const":
return MockObj(f'const {self.base}', '')
raise ValueError("Expected one of ref, ptr, const.")
@property
def using(self) -> "MockObj":
assert self.op == '::'
return MockObj(f'using namespace {self.base}')
def __getitem__(self, item: Union[str, Expression]) -> "MockObj":
next_op = '.'
if isinstance(item, str) and item.startswith('P'):
item = item[1:]
next_op = '->'
return MockObj(f'{self.base}[{item}]', next_op)
class MockObjEnum(MockObj):
def __init__(self, *args, **kwargs):
self._enum = kwargs.pop('enum')
self._is_class = kwargs.pop('is_class')
base = kwargs.pop('base')
if self._is_class:
base = base + '::' + self._enum
kwargs['op'] = '::'
kwargs['base'] = base
MockObj.__init__(self, *args, **kwargs)
def __str__(self):
if self._is_class:
return super().__str__()
return f'{self.base}{self.op}{self._enum}'
def __repr__(self):
return f'MockObj<{str(self.base)}>'
class MockObjClass(MockObj):
def __init__(self, *args, **kwargs):
parens = kwargs.pop('parents')
MockObj.__init__(self, *args, **kwargs)
self._parents = []
for paren in parens:
if not isinstance(paren, MockObjClass):
raise ValueError
self._parents.append(paren)
# pylint: disable=protected-access
self._parents += paren._parents
def inherits_from(self, other: "MockObjClass") -> bool:
if self == other:
return True
for parent in self._parents:
if parent == other:
return True
return False
def template(self, *args: SafeExpType) -> "MockObjClass":
if len(args) != 1 or not isinstance(args[0], TemplateArguments):
args = TemplateArguments(*args)
else:
args = args[0]
new_parents = self._parents[:]
new_parents.append(self)
return MockObjClass(f'{self.base}{args}', parents=new_parents)
def __repr__(self):
return f'MockObjClass<{str(self.base)}, parents={self._parents}>'