"""Transform mypy expression ASTs to mypyc IR (Intermediate Representation). The top-level AST transformation logic is implemented in mypyc.irbuild.visitor and mypyc.irbuild.builder. """ from typing import List, Optional, Union, Callable, cast from mypy.nodes import ( Expression, NameExpr, MemberExpr, SuperExpr, CallExpr, UnaryExpr, OpExpr, IndexExpr, ConditionalExpr, ComparisonExpr, IntExpr, FloatExpr, ComplexExpr, StrExpr, BytesExpr, EllipsisExpr, ListExpr, TupleExpr, DictExpr, SetExpr, ListComprehension, SetComprehension, DictionaryComprehension, SliceExpr, GeneratorExpr, CastExpr, StarExpr, AssignmentExpr, AssertTypeExpr, Var, RefExpr, MypyFile, TypeInfo, TypeApplication, LDEF, ARG_POS ) from mypy.types import TupleType, Instance, TypeType, ProperType, get_proper_type from mypyc.common import MAX_SHORT_INT from mypyc.ir.ops import ( Value, Register, TupleGet, TupleSet, BasicBlock, Assign, LoadAddress, RaiseStandardError ) from mypyc.ir.rtypes import ( RTuple, object_rprimitive, is_none_rprimitive, int_rprimitive, is_int_rprimitive, is_list_rprimitive ) from mypyc.ir.func_ir import FUNC_CLASSMETHOD, FUNC_STATICMETHOD from mypyc.irbuild.format_str_tokenizer import ( tokenizer_printf_style, join_formatted_strings, convert_format_expr_to_str, convert_format_expr_to_bytes, join_formatted_bytes ) from mypyc.primitives.bytes_ops import bytes_slice_op from mypyc.primitives.registry import CFunctionDescription, builtin_names from mypyc.primitives.generic_ops import iter_op from mypyc.primitives.misc_ops import new_slice_op, ellipsis_op, type_op, get_module_dict_op from mypyc.primitives.list_ops import list_append_op, list_extend_op, list_slice_op from mypyc.primitives.tuple_ops import list_tuple_op, tuple_slice_op from mypyc.primitives.dict_ops import dict_new_op, dict_set_item_op, dict_get_item_op from mypyc.primitives.set_ops import set_add_op, set_update_op from mypyc.primitives.str_ops import str_slice_op from mypyc.primitives.int_ops import int_comparison_op_mapping from mypyc.irbuild.specialize import apply_function_specialization, apply_method_specialization from mypyc.irbuild.builder import IRBuilder, int_borrow_friendly_op from mypyc.irbuild.for_helpers import ( translate_list_comprehension, translate_set_comprehension, comprehension_helper ) from mypyc.irbuild.constant_fold import constant_fold_expr from mypyc.irbuild.ast_helpers import is_borrow_friendly_expr, process_conditional # Name and attribute references def transform_name_expr(builder: IRBuilder, expr: NameExpr) -> Value: if expr.node is None: builder.add(RaiseStandardError(RaiseStandardError.RUNTIME_ERROR, "mypyc internal error: should be unreachable", expr.line)) return builder.none() fullname = expr.node.fullname if fullname in builtin_names: typ, src = builtin_names[fullname] return builder.add(LoadAddress(typ, src, expr.line)) # special cases if fullname == 'builtins.None': return builder.none() if fullname == 'builtins.True': return builder.true() if fullname == 'builtins.False': return builder.false() if isinstance(expr.node, Var) and expr.node.is_final: value = builder.emit_load_final( expr.node, fullname, expr.name, builder.is_native_ref_expr(expr), builder.types[expr], expr.line, ) if value is not None: return value if isinstance(expr.node, MypyFile) and expr.node.fullname in builder.imports: return builder.load_module(expr.node.fullname) # If the expression is locally defined, then read the result from the corresponding # assignment target and return it. Otherwise if the expression is a global, load it from # the globals dictionary. # Except for imports, that currently always happens in the global namespace. if expr.kind == LDEF and not (isinstance(expr.node, Var) and expr.node.is_suppressed_import): # Try to detect and error when we hit the irritating mypy bug # where a local variable is cast to None. (#5423) if (isinstance(expr.node, Var) and is_none_rprimitive(builder.node_type(expr)) and expr.node.is_inferred): builder.error( 'Local variable "{}" has inferred type None; add an annotation'.format( expr.node.name), expr.node.line) # TODO: Behavior currently only defined for Var, FuncDef and MypyFile node types. if isinstance(expr.node, MypyFile): # Load reference to a module imported inside function from # the modules dictionary. It would be closer to Python # semantics to access modules imported inside functions # via local variables, but this is tricky since the mypy # AST doesn't include a Var node for the module. We # instead load the module separately on each access. mod_dict = builder.call_c(get_module_dict_op, [], expr.line) obj = builder.call_c(dict_get_item_op, [mod_dict, builder.load_str(expr.node.fullname)], expr.line) return obj else: return builder.read(builder.get_assignment_target(expr), expr.line) return builder.load_global(expr) def transform_member_expr(builder: IRBuilder, expr: MemberExpr) -> Value: # First check if this is maybe a final attribute. final = builder.get_final_ref(expr) if final is not None: fullname, final_var, native = final value = builder.emit_load_final(final_var, fullname, final_var.name, native, builder.types[expr], expr.line) if value is not None: return value if isinstance(expr.node, MypyFile) and expr.node.fullname in builder.imports: return builder.load_module(expr.node.fullname) can_borrow = builder.is_native_attr_ref(expr) obj = builder.accept(expr.expr, can_borrow=can_borrow) rtype = builder.node_type(expr) # Special case: for named tuples transform attribute access to faster index access. typ = get_proper_type(builder.types.get(expr.expr)) if isinstance(typ, TupleType) and typ.partial_fallback.type.is_named_tuple: fields = typ.partial_fallback.type.metadata['namedtuple']['fields'] if expr.name in fields: index = builder.builder.load_int(fields.index(expr.name)) return builder.gen_method_call(obj, '__getitem__', [index], rtype, expr.line) check_instance_attribute_access_through_class(builder, expr, typ) borrow = can_borrow and builder.can_borrow return builder.builder.get_attr(obj, expr.name, rtype, expr.line, borrow=borrow) def check_instance_attribute_access_through_class(builder: IRBuilder, expr: MemberExpr, typ: Optional[ProperType]) -> None: """Report error if accessing an instance attribute through class object.""" if isinstance(expr.expr, RefExpr): node = expr.expr.node if isinstance(typ, TypeType) and isinstance(typ.item, Instance): # TODO: Handle other item types node = typ.item.type if isinstance(node, TypeInfo): class_ir = builder.mapper.type_to_ir.get(node) if class_ir is not None and class_ir.is_ext_class: sym = node.get(expr.name) if (sym is not None and isinstance(sym.node, Var) and not sym.node.is_classvar and not sym.node.is_final): builder.error( 'Cannot access instance attribute "{}" through class object'.format( expr.name), expr.line ) builder.note( '(Hint: Use "x: Final = ..." or "x: ClassVar = ..." to define ' 'a class attribute)', expr.line ) def transform_super_expr(builder: IRBuilder, o: SuperExpr) -> Value: # warning(builder, 'can not optimize super() expression', o.line) sup_val = builder.load_module_attr_by_fullname('builtins.super', o.line) if o.call.args: args = [builder.accept(arg) for arg in o.call.args] else: assert o.info is not None typ = builder.load_native_type_object(o.info.fullname) ir = builder.mapper.type_to_ir[o.info] iter_env = iter(builder.builder.args) # Grab first argument vself: Value = next(iter_env) if builder.fn_info.is_generator: # grab sixth argument (see comment in translate_super_method_call) self_targ = list(builder.symtables[-1].values())[6] vself = builder.read(self_targ, builder.fn_info.fitem.line) elif not ir.is_ext_class: vself = next(iter_env) # second argument is self if non_extension class args = [typ, vself] res = builder.py_call(sup_val, args, o.line) return builder.py_get_attr(res, o.name, o.line) # Calls def transform_call_expr(builder: IRBuilder, expr: CallExpr) -> Value: if isinstance(expr.analyzed, CastExpr): return translate_cast_expr(builder, expr.analyzed) elif isinstance(expr.analyzed, AssertTypeExpr): # Compile to a no-op. return builder.accept(expr.analyzed.expr) callee = expr.callee if isinstance(callee, IndexExpr) and isinstance(callee.analyzed, TypeApplication): callee = callee.analyzed.expr # Unwrap type application if isinstance(callee, MemberExpr): return apply_method_specialization(builder, expr, callee) or \ translate_method_call(builder, expr, callee) elif isinstance(callee, SuperExpr): return translate_super_method_call(builder, expr, callee) else: return translate_call(builder, expr, callee) def translate_call(builder: IRBuilder, expr: CallExpr, callee: Expression) -> Value: # The common case of calls is refexprs if isinstance(callee, RefExpr): return apply_function_specialization(builder, expr, callee) or \ translate_refexpr_call(builder, expr, callee) function = builder.accept(callee) args = [builder.accept(arg) for arg in expr.args] return builder.py_call(function, args, expr.line, arg_kinds=expr.arg_kinds, arg_names=expr.arg_names) def translate_refexpr_call(builder: IRBuilder, expr: CallExpr, callee: RefExpr) -> Value: """Translate a non-method call.""" # Gen the argument values arg_values = [builder.accept(arg) for arg in expr.args] return builder.call_refexpr_with_args(expr, callee, arg_values) def translate_method_call(builder: IRBuilder, expr: CallExpr, callee: MemberExpr) -> Value: """Generate IR for an arbitrary call of form e.m(...). This can also deal with calls to module-level functions. """ if builder.is_native_ref_expr(callee): # Call to module-level native function or such return translate_call(builder, expr, callee) elif ( isinstance(callee.expr, RefExpr) and isinstance(callee.expr.node, TypeInfo) and callee.expr.node in builder.mapper.type_to_ir and builder.mapper.type_to_ir[callee.expr.node].has_method(callee.name) ): # Call a method via the *class* assert isinstance(callee.expr.node, TypeInfo) ir = builder.mapper.type_to_ir[callee.expr.node] decl = ir.method_decl(callee.name) args = [] arg_kinds, arg_names = expr.arg_kinds[:], expr.arg_names[:] # Add the class argument for class methods in extension classes if decl.kind == FUNC_CLASSMETHOD and ir.is_ext_class: args.append(builder.load_native_type_object(callee.expr.node.fullname)) arg_kinds.insert(0, ARG_POS) arg_names.insert(0, None) args += [builder.accept(arg) for arg in expr.args] if ir.is_ext_class: return builder.builder.call(decl, args, arg_kinds, arg_names, expr.line) else: obj = builder.accept(callee.expr) return builder.gen_method_call(obj, callee.name, args, builder.node_type(expr), expr.line, expr.arg_kinds, expr.arg_names) elif builder.is_module_member_expr(callee): # Fall back to a PyCall for non-native module calls function = builder.accept(callee) args = [builder.accept(arg) for arg in expr.args] return builder.py_call(function, args, expr.line, arg_kinds=expr.arg_kinds, arg_names=expr.arg_names) else: receiver_typ = builder.node_type(callee.expr) # If there is a specializer for this method name/type, try calling it. # We would return the first successful one. val = apply_method_specialization(builder, expr, callee, receiver_typ) if val is not None: return val obj = builder.accept(callee.expr) args = [builder.accept(arg) for arg in expr.args] return builder.gen_method_call(obj, callee.name, args, builder.node_type(expr), expr.line, expr.arg_kinds, expr.arg_names) def translate_super_method_call(builder: IRBuilder, expr: CallExpr, callee: SuperExpr) -> Value: if callee.info is None or (len(callee.call.args) != 0 and len(callee.call.args) != 2): return translate_call(builder, expr, callee) # We support two-argument super but only when it is super(CurrentClass, self) # TODO: We could support it when it is a parent class in many cases? if len(callee.call.args) == 2: self_arg = callee.call.args[1] if ( not isinstance(self_arg, NameExpr) or not isinstance(self_arg.node, Var) or not self_arg.node.is_self ): return translate_call(builder, expr, callee) typ_arg = callee.call.args[0] if ( not isinstance(typ_arg, NameExpr) or not isinstance(typ_arg.node, TypeInfo) or callee.info is not typ_arg.node ): return translate_call(builder, expr, callee) ir = builder.mapper.type_to_ir[callee.info] # Search for the method in the mro, skipping ourselves. We # determine targets of super calls to native methods statically. for base in ir.mro[1:]: if callee.name in base.method_decls: break else: if (ir.is_ext_class and ir.builtin_base is None and not ir.inherits_python and callee.name == '__init__' and len(expr.args) == 0): # Call translates to object.__init__(self), which is a # no-op, so omit the call. return builder.none() return translate_call(builder, expr, callee) decl = base.method_decl(callee.name) arg_values = [builder.accept(arg) for arg in expr.args] arg_kinds, arg_names = expr.arg_kinds[:], expr.arg_names[:] if decl.kind != FUNC_STATICMETHOD: # Grab first argument vself: Value = builder.self() if decl.kind == FUNC_CLASSMETHOD: vself = builder.call_c(type_op, [vself], expr.line) elif builder.fn_info.is_generator: # For generator classes, the self target is the 6th value # in the symbol table (which is an ordered dict). This is sort # of ugly, but we can't search by name since the 'self' parameter # could be named anything, and it doesn't get added to the # environment indexes. self_targ = list(builder.symtables[-1].values())[6] vself = builder.read(self_targ, builder.fn_info.fitem.line) arg_values.insert(0, vself) arg_kinds.insert(0, ARG_POS) arg_names.insert(0, None) return builder.builder.call(decl, arg_values, arg_kinds, arg_names, expr.line) def translate_cast_expr(builder: IRBuilder, expr: CastExpr) -> Value: src = builder.accept(expr.expr) target_type = builder.type_to_rtype(expr.type) return builder.coerce(src, target_type, expr.line) # Operators def transform_unary_expr(builder: IRBuilder, expr: UnaryExpr) -> Value: folded = try_constant_fold(builder, expr) if folded: return folded return builder.unary_op(builder.accept(expr.expr), expr.op, expr.line) def transform_op_expr(builder: IRBuilder, expr: OpExpr) -> Value: if expr.op in ('and', 'or'): return builder.shortcircuit_expr(expr) # Special case for string formatting if expr.op == '%' and (isinstance(expr.left, StrExpr) or isinstance(expr.left, BytesExpr)): ret = translate_printf_style_formatting(builder, expr.left, expr.right) if ret is not None: return ret folded = try_constant_fold(builder, expr) if folded: return folded # Special case some int ops to allow borrowing operands. if (is_int_rprimitive(builder.node_type(expr.left)) and is_int_rprimitive(builder.node_type(expr.right))): if expr.op == '//': expr = try_optimize_int_floor_divide(expr) if expr.op in int_borrow_friendly_op: borrow_left = is_borrow_friendly_expr(builder, expr.right) left = builder.accept(expr.left, can_borrow=borrow_left) right = builder.accept(expr.right, can_borrow=True) return builder.binary_op(left, right, expr.op, expr.line) return builder.binary_op( builder.accept(expr.left), builder.accept(expr.right), expr.op, expr.line ) def try_optimize_int_floor_divide(expr: OpExpr) -> OpExpr: """Replace // with a power of two with a right shift, if possible.""" if not isinstance(expr.right, IntExpr): return expr divisor = expr.right.value shift = divisor.bit_length() - 1 if 0 < shift < 28 and divisor == (1 << shift): return OpExpr('>>', expr.left, IntExpr(shift)) return expr def transform_index_expr(builder: IRBuilder, expr: IndexExpr) -> Value: index = expr.index base_type = builder.node_type(expr.base) is_list = is_list_rprimitive(base_type) can_borrow_base = is_list and is_borrow_friendly_expr(builder, index) base = builder.accept(expr.base, can_borrow=can_borrow_base) if isinstance(base.type, RTuple) and isinstance(index, IntExpr): return builder.add(TupleGet(base, index.value, expr.line)) if isinstance(index, SliceExpr): value = try_gen_slice_op(builder, base, index) if value: return value index_reg = builder.accept(expr.index, can_borrow=is_list) return builder.gen_method_call( base, '__getitem__', [index_reg], builder.node_type(expr), expr.line) def try_constant_fold(builder: IRBuilder, expr: Expression) -> Optional[Value]: """Return the constant value of an expression if possible. Return None otherwise. """ value = constant_fold_expr(builder, expr) if isinstance(value, int): return builder.load_int(value) elif isinstance(value, str): return builder.load_str(value) return None def try_gen_slice_op(builder: IRBuilder, base: Value, index: SliceExpr) -> Optional[Value]: """Generate specialized slice op for some index expressions. Return None if a specialized op isn't available. This supports obj[x:y], obj[:x], and obj[x:] for a few types. """ if index.stride: # We can only handle the default stride of 1. return None if index.begin_index: begin_type = builder.node_type(index.begin_index) else: begin_type = int_rprimitive if index.end_index: end_type = builder.node_type(index.end_index) else: end_type = int_rprimitive # Both begin and end index must be int (or missing). if is_int_rprimitive(begin_type) and is_int_rprimitive(end_type): if index.begin_index: begin = builder.accept(index.begin_index) else: begin = builder.load_int(0) if index.end_index: end = builder.accept(index.end_index) else: # Replace missing end index with the largest short integer # (a sequence can't be longer). end = builder.load_int(MAX_SHORT_INT) candidates = [list_slice_op, tuple_slice_op, str_slice_op, bytes_slice_op] return builder.builder.matching_call_c(candidates, [base, begin, end], index.line) return None def transform_conditional_expr(builder: IRBuilder, expr: ConditionalExpr) -> Value: if_body, else_body, next_block = BasicBlock(), BasicBlock(), BasicBlock() process_conditional(builder, expr.cond, if_body, else_body) expr_type = builder.node_type(expr) # Having actual Phi nodes would be really nice here! target = Register(expr_type) builder.activate_block(if_body) true_value = builder.accept(expr.if_expr) true_value = builder.coerce(true_value, expr_type, expr.line) builder.add(Assign(target, true_value)) builder.goto(next_block) builder.activate_block(else_body) false_value = builder.accept(expr.else_expr) false_value = builder.coerce(false_value, expr_type, expr.line) builder.add(Assign(target, false_value)) builder.goto(next_block) builder.activate_block(next_block) return target def transform_comparison_expr(builder: IRBuilder, e: ComparisonExpr) -> Value: # x in (...)/[...] # x not in (...)/[...] first_op = e.operators[0] if (first_op in ['in', 'not in'] and len(e.operators) == 1 and isinstance(e.operands[1], (TupleExpr, ListExpr))): items = e.operands[1].items n_items = len(items) # x in y -> x == y[0] or ... or x == y[n] # x not in y -> x != y[0] and ... and x != y[n] # 16 is arbitrarily chosen to limit code size if 1 < n_items < 16: if e.operators[0] == 'in': bin_op = 'or' cmp_op = '==' else: bin_op = 'and' cmp_op = '!=' lhs = e.operands[0] mypy_file = builder.graph['builtins'].tree assert mypy_file is not None bool_type = Instance(cast(TypeInfo, mypy_file.names['bool'].node), []) exprs = [] for item in items: expr = ComparisonExpr([cmp_op], [lhs, item]) builder.types[expr] = bool_type exprs.append(expr) or_expr: Expression = exprs.pop(0) for expr in exprs: or_expr = OpExpr(bin_op, or_expr, expr) builder.types[or_expr] = bool_type return builder.accept(or_expr) # x in [y]/(y) -> x == y # x not in [y]/(y) -> x != y elif n_items == 1: if e.operators[0] == 'in': cmp_op = '==' else: cmp_op = '!=' e.operators = [cmp_op] e.operands[1] = items[0] # x in []/() -> False # x not in []/() -> True elif n_items == 0: if e.operators[0] == 'in': return builder.false() else: return builder.true() if len(e.operators) == 1: # Special some common simple cases if first_op in ('is', 'is not'): right_expr = e.operands[1] if isinstance(right_expr, NameExpr) and right_expr.fullname == 'builtins.None': # Special case 'is None' / 'is not None'. return translate_is_none(builder, e.operands[0], negated=first_op != 'is') left_expr = e.operands[0] if is_int_rprimitive(builder.node_type(left_expr)): right_expr = e.operands[1] if is_int_rprimitive(builder.node_type(right_expr)): if first_op in int_borrow_friendly_op: borrow_left = is_borrow_friendly_expr(builder, right_expr) left = builder.accept(left_expr, can_borrow=borrow_left) right = builder.accept(right_expr, can_borrow=True) return builder.compare_tagged(left, right, first_op, e.line) # TODO: Don't produce an expression when used in conditional context # All of the trickiness here is due to support for chained conditionals # (`e1 < e2 > e3`, etc). `e1 < e2 > e3` is approximately equivalent to # `e1 < e2 and e2 > e3` except that `e2` is only evaluated once. expr_type = builder.node_type(e) # go(i, prev) generates code for `ei opi e{i+1} op{i+1} ... en`, # assuming that prev contains the value of `ei`. def go(i: int, prev: Value) -> Value: if i == len(e.operators) - 1: return transform_basic_comparison( builder, e.operators[i], prev, builder.accept(e.operands[i + 1]), e.line) next = builder.accept(e.operands[i + 1]) return builder.builder.shortcircuit_helper( 'and', expr_type, lambda: transform_basic_comparison( builder, e.operators[i], prev, next, e.line), lambda: go(i + 1, next), e.line) return go(0, builder.accept(e.operands[0])) def translate_is_none(builder: IRBuilder, expr: Expression, negated: bool) -> Value: v = builder.accept(expr, can_borrow=True) return builder.binary_op(v, builder.none_object(), 'is not' if negated else 'is', expr.line) def transform_basic_comparison(builder: IRBuilder, op: str, left: Value, right: Value, line: int) -> Value: if (is_int_rprimitive(left.type) and is_int_rprimitive(right.type) and op in int_comparison_op_mapping.keys()): return builder.compare_tagged(left, right, op, line) negate = False if op == 'is not': op, negate = 'is', True elif op == 'not in': op, negate = 'in', True target = builder.binary_op(left, right, op, line) if negate: target = builder.unary_op(target, 'not', line) return target def translate_printf_style_formatting(builder: IRBuilder, format_expr: Union[StrExpr, BytesExpr], rhs: Expression) -> Optional[Value]: tokens = tokenizer_printf_style(format_expr.value) if tokens is not None: literals, format_ops = tokens exprs = [] if isinstance(rhs, TupleExpr): exprs = rhs.items elif isinstance(rhs, Expression): exprs.append(rhs) if isinstance(format_expr, BytesExpr): substitutions = convert_format_expr_to_bytes(builder, format_ops, exprs, format_expr.line) if substitutions is not None: return join_formatted_bytes(builder, literals, substitutions, format_expr.line) else: substitutions = convert_format_expr_to_str(builder, format_ops, exprs, format_expr.line) if substitutions is not None: return join_formatted_strings(builder, literals, substitutions, format_expr.line) return None # Literals def transform_int_expr(builder: IRBuilder, expr: IntExpr) -> Value: return builder.builder.load_int(expr.value) def transform_float_expr(builder: IRBuilder, expr: FloatExpr) -> Value: return builder.builder.load_float(expr.value) def transform_complex_expr(builder: IRBuilder, expr: ComplexExpr) -> Value: return builder.builder.load_complex(expr.value) def transform_str_expr(builder: IRBuilder, expr: StrExpr) -> Value: return builder.load_str(expr.value) def transform_bytes_expr(builder: IRBuilder, expr: BytesExpr) -> Value: return builder.load_bytes_from_str_literal(expr.value) def transform_ellipsis(builder: IRBuilder, o: EllipsisExpr) -> Value: return builder.add(LoadAddress(ellipsis_op.type, ellipsis_op.src, o.line)) # Display expressions def transform_list_expr(builder: IRBuilder, expr: ListExpr) -> Value: return _visit_list_display(builder, expr.items, expr.line) def _visit_list_display(builder: IRBuilder, items: List[Expression], line: int) -> Value: return _visit_display( builder, items, builder.new_list_op, list_append_op, list_extend_op, line, True ) def transform_tuple_expr(builder: IRBuilder, expr: TupleExpr) -> Value: if any(isinstance(item, StarExpr) for item in expr.items): # create a tuple of unknown length return _visit_tuple_display(builder, expr) # create a tuple of fixed length (RTuple) tuple_type = builder.node_type(expr) # When handling NamedTuple et. al we might not have proper type info, # so make some up if we need it. types = (tuple_type.types if isinstance(tuple_type, RTuple) else [object_rprimitive] * len(expr.items)) items = [] for item_expr, item_type in zip(expr.items, types): reg = builder.accept(item_expr) items.append(builder.coerce(reg, item_type, item_expr.line)) return builder.add(TupleSet(items, expr.line)) def _visit_tuple_display(builder: IRBuilder, expr: TupleExpr) -> Value: """Create a list, then turn it into a tuple.""" val_as_list = _visit_list_display(builder, expr.items, expr.line) return builder.call_c(list_tuple_op, [val_as_list], expr.line) def transform_dict_expr(builder: IRBuilder, expr: DictExpr) -> Value: """First accepts all keys and values, then makes a dict out of them.""" key_value_pairs = [] for key_expr, value_expr in expr.items: key = builder.accept(key_expr) if key_expr is not None else None value = builder.accept(value_expr) key_value_pairs.append((key, value)) return builder.builder.make_dict(key_value_pairs, expr.line) def transform_set_expr(builder: IRBuilder, expr: SetExpr) -> Value: return _visit_display( builder, expr.items, builder.new_set_op, set_add_op, set_update_op, expr.line, False ) def _visit_display(builder: IRBuilder, items: List[Expression], constructor_op: Callable[[List[Value], int], Value], append_op: CFunctionDescription, extend_op: CFunctionDescription, line: int, is_list: bool ) -> Value: accepted_items = [] for item in items: if isinstance(item, StarExpr): accepted_items.append((True, builder.accept(item.expr))) else: accepted_items.append((False, builder.accept(item))) result: Union[Value, None] = None initial_items = [] for starred, value in accepted_items: if result is None and not starred and is_list: initial_items.append(value) continue if result is None: result = constructor_op(initial_items, line) builder.call_c(extend_op if starred else append_op, [result, value], line) if result is None: result = constructor_op(initial_items, line) return result # Comprehensions def transform_list_comprehension(builder: IRBuilder, o: ListComprehension) -> Value: if any(o.generator.is_async): builder.error('async comprehensions are unimplemented', o.line) return translate_list_comprehension(builder, o.generator) def transform_set_comprehension(builder: IRBuilder, o: SetComprehension) -> Value: if any(o.generator.is_async): builder.error('async comprehensions are unimplemented', o.line) return translate_set_comprehension(builder, o.generator) def transform_dictionary_comprehension(builder: IRBuilder, o: DictionaryComprehension) -> Value: if any(o.is_async): builder.error('async comprehensions are unimplemented', o.line) d = builder.call_c(dict_new_op, [], o.line) loop_params = list(zip(o.indices, o.sequences, o.condlists)) def gen_inner_stmts() -> None: k = builder.accept(o.key) v = builder.accept(o.value) builder.call_c(dict_set_item_op, [d, k, v], o.line) comprehension_helper(builder, loop_params, gen_inner_stmts, o.line) return d # Misc def transform_slice_expr(builder: IRBuilder, expr: SliceExpr) -> Value: def get_arg(arg: Optional[Expression]) -> Value: if arg is None: return builder.none_object() else: return builder.accept(arg) args = [get_arg(expr.begin_index), get_arg(expr.end_index), get_arg(expr.stride)] return builder.call_c(new_slice_op, args, expr.line) def transform_generator_expr(builder: IRBuilder, o: GeneratorExpr) -> Value: if any(o.is_async): builder.error('async comprehensions are unimplemented', o.line) builder.warning('Treating generator comprehension as list', o.line) return builder.call_c( iter_op, [translate_list_comprehension(builder, o)], o.line ) def transform_assignment_expr(builder: IRBuilder, o: AssignmentExpr) -> Value: value = builder.accept(o.value) target = builder.get_assignment_target(o.target) builder.assign(target, value, o.line) return value