def create_new_event(self, create_call: ast.Call) -> Event:
event = Event('')
event_args = create_call.args
if len(event_args) < 0:
self._log_error(
CompilerError.UnfilledArgument(line=create_call.lineno,
col=create_call.col_offset,
param=list(
Builtin.NewEvent.args)[0]))
elif len(event_args) > 0:
args_type = self.get_type(event_args[0])
if not Type.list.is_type_of(args_type):
self._log_error(
CompilerError.MismatchedTypes(
line=event_args[0].lineno,
col=event_args[0].col_offset,
expected_type_id=Type.list.identifier,
actual_type_id=args_type.identifier))
else:
for value in event_args[0].elts:
if not isinstance(value, ast.Tuple):
CompilerError.MismatchedTypes(
line=value.lineno,
col=value.col_offset,
expected_type_id=Type.tuple.identifier,
actual_type_id=self.get_type(value).identifier)
elif len(value.elts) < 2:
self._log_error(
CompilerError.UnfilledArgument(
line=value.lineno,
col=value.col_offset,
param=list(Builtin.NewEvent.args)[0]))
elif not (isinstance(value.elts[0], ast.Str) and
(isinstance(value.elts[1], ast.Name)
and isinstance(
self.get_symbol(value.elts[1].id), IType))):
CompilerError.MismatchedTypes(
line=value.lineno,
col=value.col_offset,
expected_type_id=Type.tuple.identifier,
actual_type_id=self.get_type(value).identifier)
else:
arg_name = value.elts[0].s
arg_type = self.get_symbol(value.elts[1].id)
event.args[arg_name] = Variable(arg_type)
if len(event_args) > 1:
if not isinstance(event_args[1], ast.Str):
name_type = self.get_type(event_args[1])
CompilerError.MismatchedTypes(
line=event_args[1].lineno,
col=event_args[1].col_offset,
expected_type_id=Type.str.identifier,
actual_type_id=name_type.identifier)
else:
event.name = event_args[1].s
return event
def visit_Num(self, num: ast.Num) -> int:
"""
Verifies if the number is an integer
:param num: the python ast number node
:return: returns the value of the number
"""
if not isinstance(num.n, int):
# only integer numbers are allowed
self._log_error(
CompilerError.InvalidType(num.lineno, num.col_offset, symbol_id=type(num.n).__name__)
)
return num.n
def visit_arg(self, arg: ast.arg):
"""
Verifies if the argument of a function has a type annotation
:param arg: the python ast arg node
"""
if arg.annotation is None:
self._log_error(
CompilerError.TypeHintMissing(arg.lineno, arg.col_offset, symbol_id=arg.arg)
)
# continue to walk through the tree
self.generic_visit(arg)
def visit_Constant(self, constant: ast.Constant) -> Any:
"""
Visitor of constant values node
:param constant: the python ast constant value node
:return: the value of the constant
"""
if isinstance(constant, ast.Num) and not isinstance(constant.value, int):
# only integer numbers are allowed
self._log_error(
CompilerError.InvalidType(constant.lineno, constant.col_offset, symbol_id=type(constant.value).__name__)
)
return constant.value
def visit_Module(self, module: ast.Module):
"""
Visitor of the module node
Fills module symbol table
:param module:
"""
mod: Module = Module()
self._current_module = mod
self._scope_stack.append(SymbolScope())
global_stmts = []
function_stmts = []
for stmt in module.body:
if isinstance(stmt, (ast.FunctionDef, ast.AsyncFunctionDef)):
function_stmts.append(stmt)
elif not (isinstance(stmt, ast.Expr) and isinstance(stmt.value, ast.Constant)):
# don't evaluate constant expression - for example: string for documentation
if self.visit(stmt) is not Builtin.Event:
global_stmts.append(stmt)
module.body = global_stmts + function_stmts
for var_id, var in mod.variables.items():
# all static fields must be initialized
if not mod.is_variable_assigned(var_id):
self._log_error(
CompilerError.UnresolvedReference(
line=var.origin.lineno if var.origin is not None else 0,
col=var.origin.col_offset if var.origin is not None else 0,
symbol_id=var_id
)
)
for stmt in function_stmts:
result = self.visit(stmt)
# don't evaluate the metadata function in the following analysers
if result is Builtin.Metadata:
module.body.remove(stmt)
# TODO: include the body of the builtin methods to the ast
# TODO: get module name
self.modules['main'] = mod
module_scope = self._scope_stack.pop()
for symbol_id, symbol in module_scope.symbols.items():
if symbol_id in self._global_assigned_variables:
mod.include_symbol(symbol_id, symbol)
mod.assign_variable(symbol_id)
self._global_assigned_variables.clear()
self._current_module = None
def visit_UnaryOp(self, un_op: ast.UnaryOp) -> Optional[IType]:
"""
Verifies if the type of the operand is valid to the operation
If the operation is valid, changes de Python operator by the Boa operator in the syntax tree
:param un_op: the python ast unary operation node
:return: the type of the result of the operation if the operation is valid. Otherwise, returns None
:rtype: IType or None
"""
operator: Operator = self.get_operator(un_op.op)
operand = self.visit(un_op.operand)
if not isinstance(operator, Operator):
# the operator is invalid or it was not implemented yet
self._log_error(
CompilerError.UnresolvedReference(un_op.lineno, un_op.col_offset, type(un_op.op).__name__)
)
try:
operation: UnaryOperation = self.get_un_op(operator, operand)
if operation is None:
self._log_error(
CompilerError.NotSupportedOperation(un_op.lineno, un_op.col_offset, operator)
)
elif not operation.is_supported:
self._log_error(
CompilerError.NotSupportedOperation(un_op.lineno, un_op.col_offset, operator)
)
else:
un_op.op = operation
return operation.result
except CompilerError.MismatchedTypes as raised_error:
raised_error.line = un_op.lineno
raised_error.col = un_op.col_offset
# raises the exception with the line/col info
self._log_error(raised_error)
def visit_Return(self, ret: ast.Return):
"""
Verifies if the return of the function is the same type as the return type annotation
:param ret: the python ast return node
"""
ret_value: Any = self.visit(ret.value) if ret.value is not None else None
if ret.value is not None and self.get_type(ret.value) is not Type.none:
# multiple returns are not allowed
if isinstance(ret.value, ast.Tuple):
self._log_error(
CompilerError.TooManyReturns(ret.lineno, ret.col_offset)
)
return
# it is returning something, but there is no type hint for return
elif self._current_method.return_type is Type.none:
self._log_error(
CompilerError.TypeHintMissing(ret.lineno, ret.col_offset, symbol_id=self._current_method_id)
)
return
self.validate_type_variable_assign(ret, ret_value, self._current_method)
# continue to walk through the tree
self.generic_visit(ret)
def visit_Return(self, ret: ast.Return):
"""
Visitor of the function return node
If the return is a name, verifies if the symbol is defined
:param ret: the python ast return node
"""
if isinstance(ret.value, ast.Name):
symbol_id = self.visit(ret.value)
symbol = self.get_symbol(symbol_id)
if symbol is None:
# the symbol doesn't exists
self._log_error(
CompilerError.UnresolvedReference(ret.value.lineno, ret.value.col_offset, symbol_id)
)
def validate_if(self, if_node: ast.AST):
"""
Verifies if the type of if test is valid
:param if_node: the python ast if statement node
:type if_node: ast.If or ast.IfExp
"""
test = self.visit(if_node.test)
test_type: IType = self.get_type(test)
if test_type is not Type.bool:
self._log_error(
CompilerError.MismatchedTypes(
if_node.lineno, if_node.col_offset,
actual_type_id=test_type.identifier,
expected_type_id=Type.bool.identifier)
)
def visit_Assign(self, assign: ast.Assign):
"""
Verifies if it is a multiple assignments statement
:param assign: the python ast variable assignment node
"""
# multiple assignments
if isinstance(assign.targets[0], ast.Tuple):
self._log_error(
CompilerError.NotSupportedOperation(assign.lineno, assign.col_offset, 'Multiple variable assignments')
)
else:
for target in assign.targets:
self.validate_type_variable_assign(target, assign.value)
# continue to walk through the tree
self.generic_visit(assign)
def visit_Raise(self, raise_node: ast.Raise):
"""
Visitor of the raise node
Verifies if the raised object is a exception
:param raise_node: the python ast raise node
"""
raised = self.visit(raise_node.exc)
raised_type: IType = self.get_type(raised)
if raised_type is not Type.exception:
self._log_error(
CompilerError.MismatchedTypes(
raise_node.lineno, raise_node.col_offset,
actual_type_id=raised_type.identifier,
expected_type_id=Type.exception.identifier
))
def _validate_IsInstanceMethod(self, method: IsInstanceMethod,
args_types: List[IType]):
"""
Validates the arguments for `isinstance` method
:param method: instance of the builtin method
:param args_types: types of the arguments
"""
last_arg = self.call.args[-1]
if isinstance(last_arg, ast.Tuple) and all(
isinstance(tpe, (ast.Attribute, ast.Name))
for tpe in last_arg.elts):
if len(last_arg.elts) == 1:
# if the types tuple has only one type, remove it from inside the tuple
last_arg = self.call.args[-1] = last_arg.elts[-1]
args_types[-1] = args_types[-1].value_type
elif len(last_arg.elts) > 1:
# if there are more than one type, updates information in the instance of the method
types: List[IType] = [
self.get_symbol_from_node(name) for name in last_arg.elts
]
method.set_instance_type(types)
self.call.args[-1] = last_arg.elts[-1]
return
from boa3.model.type.annotation.metatype import MetaType
from boa3.model.type.type import Type
is_ast_valid = (isinstance(last_arg, ast.Name)
or (isinstance(last_arg, ast.NameConstant)
and args_types[-1] is Type.none))
is_id_valid = (hasattr(last_arg, 'id')
and last_arg.id != args_types[-1].identifier
and last_arg.id != args_types[-1].raw_identifier
and isinstance(
self.get_type(last_arg, use_metadata=True),
MetaType))
if not is_ast_valid or is_id_valid:
# if the value is not the identifier of a type
self._log_error(
CompilerError.MismatchedTypes(
last_arg.lineno,
last_arg.col_offset,
expected_type_id=type.__name__,
actual_type_id=args_types[-1].identifier))
def visit_Expr(self, expr: ast.Expr):
"""
Visitor of the atom expression node
:param expr:
"""
value = self.visit(expr.value)
if isinstance(expr.value, ast.Name):
if (
# it is not a symbol of the method scope
(self._current_method is not None and value not in self._current_method.symbols)
# nor it is a symbol of the module scope
or (self._current_module is not None and value not in self._current_module.symbols)
# nor it is a symbol of the global scope
or value not in self.symbols
):
self._log_error(
CompilerError.UnresolvedReference(expr.value.lineno, expr.value.col_offset, value)
)
def validate_passed_arguments(self, call: ast.Call, args_types: List[IType], callable_id: str, callable: Callable):
if isinstance(callable, IBuiltinMethod):
builtin_analyser = BuiltinFunctionCallAnalyser(self, call, callable_id, callable)
if builtin_analyser.validate():
self.errors.extend(builtin_analyser.errors)
self.warnings.extend(builtin_analyser.warnings)
return
for index, (arg_id, arg_value) in enumerate(callable.args.items()):
param = call.args[index]
param_type = self.get_type(param)
args_types.append(param_type)
if not arg_value.type.is_type_of(param_type):
self._log_error(
CompilerError.MismatchedTypes(
param.lineno, param.col_offset,
arg_value.type.identifier,
param_type.identifier
))
def get_un_op(self, operator: Operator, operand: Any) -> UnaryOperation:
"""
Returns the binary operation specified by the operator and the types of the operands
:param operator: the operator
:param operand: the operand
:return: Returns the corresponding :class:`UnaryOperation` if the types are valid.
:raise MismatchedTypes: raised if the types aren't valid for the operator
"""
op_type: IType = self.get_type(operand)
actual_type: str = op_type.identifier
operation: UnaryOperation = UnaryOp.validate_type(operator, op_type)
if operation is not None:
return operation
else:
expected_op: UnaryOperation = UnaryOp.get_operation_by_operator(operator)
expected_type: str = expected_op.operand_type.identifier
raise CompilerError.MismatchedTypes(0, 0, expected_type, actual_type)
def visit_Call(self, call: ast.Call) -> Optional[IType]:
"""
Visitor of a function call node
:param call: the python ast function call node
:return: the result type of the called function. None if the function is not found
"""
func_id = self.visit(call.func)
func_symbol = self.get_symbol(func_id)
# if func_symbol is None, the called function may be a function written after in the code
# that's why it shouldn't log a compiler error here
if func_symbol is None:
return None
if not isinstance(func_symbol, Callable):
# verifiy if it is a builtin method with its name shadowed
func = Builtin.get_symbol(func_id)
func_symbol = func if func is not None else func_symbol
if func_symbol is Type.exception:
func_symbol = Builtin.Exception
elif isinstance(func_symbol, ClassType):
func_symbol = func_symbol.constructor_method()
if not isinstance(func_symbol, Callable):
# the symbol doesn't exists
self._log_error(
CompilerError.UnresolvedReference(call.func.lineno,
call.func.col_offset,
func_id))
elif isinstance(func_symbol, IBuiltinMethod):
if func_symbol.body is not None:
self._builtin_functions_to_visit[func_id] = func_symbol
elif func_symbol is Builtin.NewEvent:
new_event = self.create_new_event(call)
self.__include_callable(new_event.identifier, new_event)
self._current_event = new_event
return self.get_type(call.func)
def visit_While(self, while_node: ast.While):
"""
Verifies if the type of while test is valid
:param while_node: the python ast while statement node
"""
test = self.visit(while_node.test)
test_type: IType = self.get_type(test)
if test_type is not Type.bool:
self._log_error(
CompilerError.MismatchedTypes(
while_node.lineno, while_node.col_offset,
actual_type_id=test_type.identifier,
expected_type_id=Type.bool.identifier)
)
# continue to walk through the tree
for stmt in while_node.body:
self.visit(stmt)
for stmt in while_node.orelse:
self.visit(stmt)
def update_callable_after_validation(self, call: ast.Call, callable_id: str, callable_target: Callable):
# if the arguments are not generic, include the specified method in the symbol table
if (isinstance(callable_target, IBuiltinMethod)
and callable_target.identifier != callable_id
and callable_target.raw_identifier == callable_id
and callable_target.identifier not in self.symbols):
self.symbols[callable_target.identifier] = callable_target
call.func = ast.Name(lineno=call.func.lineno, col_offset=call.func.col_offset,
ctx=ast.Load(), id=callable_target.identifier)
# validates if metadata matches callable's requirements
if hasattr(callable_target, 'requires_storage') and callable_target.requires_storage:
if not self._metadata.has_storage:
self._log_error(
CompilerError.MetadataInformationMissing(
line=call.func.lineno, col=call.func.col_offset,
symbol_id=callable_target.identifier,
metadata_attr_id='has_storage'
)
)
else:
self._current_method.set_storage()
def visit_FunctionDef(self, function: ast.FunctionDef):
"""
Visitor of the function node
Performs the type checking in the body of the function
:param function: the python ast function definition node
"""
self.visit(function.args)
method = self.symbols[function.name]
from boa3.model.event import Event
if isinstance(method, Method):
self._current_method = method
for stmt in function.body:
self.visit(stmt)
self._validate_return(function)
if (len(function.body) > 0
and not isinstance(function.body[-1], ast.Return)
and method.return_type is Type.none):
# include return None in void functions
default_value: str = str(method.return_type.default_value)
node: ast.AST = ast.parse(default_value).body[0].value
function.body.append(
ast.Return(lineno=function.lineno, col_offset=function.col_offset, value=node)
)
self._current_method = None
elif (isinstance(method, Event) # events don't have return
and function.returns is not None):
return_type = self.get_type(function.returns)
if return_type is not Type.none:
self._log_error(
CompilerError.MismatchedTypes(line=function.lineno, col=function.col_offset,
expected_type_id=Type.none.identifier,
actual_type_id=return_type.identifier)
)
def _read_metadata_object(self, function: ast.FunctionDef):
"""
Gets the metadata object defined in this function
:param function:
"""
if self._metadata is not None:
# metadata function has been defined already
self._log_warning(
CompilerWarning.RedeclaredSymbol(
line=function.lineno,
col=function.col_offset,
symbol_id=Builtin.Metadata.identifier))
# this function must have a return and no arguments
elif len(function.args.args) != 0:
self._log_error(
CompilerError.UnexpectedArgument(line=function.lineno,
col=function.col_offset))
elif not any(isinstance(stmt, ast.Return) for stmt in function.body):
self._log_error(
CompilerError.MissingReturnStatement(line=function.lineno,
col=function.col_offset,
symbol_id=function.name))
else:
function.returns = None
function.decorator_list = []
module: ast.Module = ast.parse('')
module.body = [
node for node in self._tree.body
if isinstance(node, (ast.ImportFrom, ast.Import))
]
module.body.append(function)
ast.copy_location(module, function)
# executes the function
code = compile(module, filename='<boa3>', mode='exec')
namespace = {}
exec(code, namespace)
obj: Any = namespace[function.name]()
node: ast.AST = function.body[-1] if len(
function.body) > 0 else function
# return must be a NeoMetadata object
if not isinstance(obj, NeoMetadata):
obj_type = self.get_type(obj).identifier if self.get_type(
obj) is not Type.any else type(obj).__name__
self._log_error(
CompilerError.MismatchedTypes(
line=node.lineno,
col=node.col_offset,
expected_type_id=NeoMetadata.__name__,
actual_type_id=obj_type))
return
# validates the metadata attributes types
attributes: Dict[str, Any] = {
attr: value
for attr, value in dict(obj.__dict__).items()
if attr in Builtin.metadata_fields
}
if any(not isinstance(value, Builtin.metadata_fields[attr])
for attr, value in attributes.items()):
for expected, actual in [
(Builtin.metadata_fields[attr], type(v_type))
for attr, v_type in attributes.items() if
not isinstance(v_type, Builtin.metadata_fields[attr])
]:
if isinstance(expected, Iterable):
expected_id = 'Union[{0}]'.format(', '.join(
[tpe.__name__ for tpe in expected]))
elif hasattr(expected, '__name__'):
expected_id = expected.__name__
else:
expected_id = str(expected)
self._log_error(
CompilerError.MismatchedTypes(
line=node.lineno,
col=node.col_offset,
expected_type_id=expected_id,
actual_type_id=actual.__name__))
else:
# if the function was defined correctly, sets the metadata object of the smart contract
self._metadata = obj
self._metadata_node = function # for error messages only
def _log_unresolved_import(self, origin_node: ast.AST, import_id: str):
if self._log:
self._log_error(
CompilerError.UnresolvedReference(line=origin_node.lineno,
col=origin_node.col_offset,
symbol_id=import_id))
def visit_ClassDef(self, node: ast.ClassDef):
# TODO: refactor when classes defined by the user are implemented
self._log_error(
CompilerError.NotSupportedOperation(node.lineno,
node.col_offset,
symbol_id='class'))
def _validate_standards(self):
for standard in self.standards:
if standard in supportedstandard.neo_standards:
current_standard = supportedstandard.neo_standards[standard]
# validate standard's methods
for standard_method in current_standard.methods:
method_id = standard_method.external_name
is_implemented = False
found_methods = self.get_methods_by_display_name(method_id)
for method in found_methods:
if isinstance(
method,
Method) and current_standard.match_definition(
standard_method, method):
is_implemented = True
break
if not is_implemented:
self._log_error(
CompilerError.MissingStandardDefinition(
standard, method_id, standard_method))
# validate standard's events
events = [
symbol for symbol in self.symbols.values()
if isinstance(symbol, Event)
]
# imported events should be included in the validation
for imported in self._get_all_imports():
events.extend([
event for event in imported.all_symbols.values()
if isinstance(event, Event)
])
for standard_event in current_standard.events:
is_implemented = False
for event in events:
if (event.name == standard_event.name
and current_standard.match_definition(
standard_event, event)):
is_implemented = True
break
if not is_implemented:
self._log_error(
CompilerError.MissingStandardDefinition(
standard, standard_event.name, standard_event))
# validate optional methods
for optional_method in current_standard.optionals:
method_id = optional_method.external_name
is_implemented = False
found_methods = self.get_methods_by_display_name(method_id)
for method in found_methods:
if isinstance(
method,
Method) and current_standard.match_definition(
optional_method, method):
is_implemented = True
break
if found_methods and not is_implemented:
self._log_error(
CompilerError.MissingStandardDefinition(
standard, method_id, optional_method))
def validate_values(self, *params: Any) -> List[Any]:
values = []
if len(params) != 2:
return values
origin, visitor = params
values.append(self.external_name)
from boa3.analyser.astanalyser import IAstAnalyser
if not isinstance(visitor, IAstAnalyser):
return values
from boa3.exception import CompilerError
if not isinstance(origin, ast.Call):
visitor._log_error(
CompilerError.UnfilledArgument(origin.lineno,
origin.col_offset,
list(self.args.keys())[0]))
return values
args_names = list(self.args.keys())
if len(origin.args) > len(args_names):
visitor._log_error(
CompilerError.UnexpectedArgument(origin.lineno,
origin.col_offset))
return values
# read the called arguments
args_len = min(len(origin.args), len(args_names))
values.clear()
for x in range(args_len):
values.append(visitor.visit(origin.args[x]))
if len(values) < 1:
values.append(self.external_name)
# read the called keyword arguments
for kwarg in origin.keywords:
if kwarg.arg in args_names:
x = args_names.index(kwarg.arg)
value = visitor.visit(kwarg.value)
values[x] = value
else:
visitor._log_error(
CompilerError.UnexpectedArgument(kwarg.lineno,
kwarg.col_offset))
if not isinstance(values[0], str):
visitor._log_error(
CompilerError.UnfilledArgument(origin.lineno,
origin.col_offset,
list(self.args.keys())[0]))
return values
if visitor.get_symbol(values[0]) is not None:
visitor._log_error(
CompilerError.InvalidUsage(
origin.lineno, origin.col_offset,
"Only literal values are accepted for 'name' argument"))
values[0] = self.external_name
return values
