def emit_union(m: Module, item: Item, *, resolver: Resolver) -> Definition:
typename = goname(item.type_.__name__)
kind_typename = typename + "Kind"
# type <typename> {
# Kind string `json:"$kind"`
# ...
# }
m.stmt(f"type {typename} struct {{")
with m.scope():
m.stmt(f'Kind {kind_typename} `json:"$kind"` // discriminator')
for subtype in item.args:
gotype: str = resolver.resolve_gotype(subtype)
m.append(f"{gotype} *{gotype}")
m.stmt(
f' `json:"{untitleize(str(gotype)).rstrip("_")},omitempty"`')
m.stmt("}")
m.sep()
# UnmarshalJSON
discriminator_field = ("$kind", typeinfo.typeinfo(str), metadata())
discriminator_field[-1]["_override_type"] = kind_typename
pseudo_fields = [(sub_type.__name__, typeinfo.typeinfo(sub_type),
metadata(required=False)) for sub_type in item.args]
pseudo_item = Item(
type_=item.type_,
fields=[discriminator_field] + pseudo_fields,
args=[],
)
unmarshalJSON_definition = emit_unmarshalJSON(m,
pseudo_item,
resolver=resolver)
m.sep()
# one-of validation
assert unmarshalJSON_definition.code_module is not None
this = m.symbol(f"{item.type_.__name__[0].lower()}")
maperr_pkg = m.import_("github.com/podhmo/maperr")
sm = unmarshalJSON_definition.code_module
sm.stmt("// one-of?")
sm.stmt("{")
with sm.scope():
for go_name, info, _ in pseudo_item.fields[1:]:
with sm.if_(
f'{this}.Kind == "{go_name}" && {this}.{go_name} == nil'):
sm.stmt(
f'err = err.Add("{go_name}", {maperr_pkg}.Message{{Text: "treated as {go_name}, but no data"}})'
)
sm.stmt("}")
# enums
emit_enums(m, item.type_, resolver=resolver, name=kind_typename)
definition = Definition(name=typename, code_module=None)
return definition
def emit(g: Graph) -> Module:
i = 0
m = Module()
variables: t.Dict[int, Symbol] = {}
# TODO: with type
# TODO: name
original_args = [
f"{node.name} string" for node in g.nodes if node.is_primitive
]
with m.func("run", *original_args, return_="error"):
for node in topological_sorted(g):
if node.is_primitive:
variables[node.uid] = m.symbol(node.name)
continue
args = []
for dep in node.depends:
args.append(variables[dep.uid])
m.letN
return_type = node.metadata.get("return_type", "")
if return_type == "":
[variables[node.uid]] = m.letN([f"v{i}"],
m.symbol(node.name)(*args))
elif return_type == "with-err":
variables[node.uid], err = m.letN((f"v{i}", "err"),
m.symbol(node.name)(*args))
with m.if_("err != nil"):
m.return_("err")
elif return_type == "with-cleanup":
variables[node.uid], cleanup = m.letN(
(f"v{i}", "cleanup"),
m.symbol(node.name)(*args))
m.stmt("defer cleanup()")
elif return_type == "with-cleanup-err":
variables[node.uid], cleanup, err = m.letN(
(f"v{i}", "cleanup", "err"),
m.symbol(node.name)(*args))
with m.if_("err != nil"):
m.return_("err")
m.stmt("defer cleanup()")
else:
raise ValueError(f"unexpected return_type {return_type}")
i += 1
m.return_("nil")
return m
def emit(m: Module, g: Graph) -> Symbol:
# TODO: name
# TODO: import_
i = 0
variables: t.Dict[int, Symbol] = {}
for node in topological_sorted(g):
if node.is_primitive:
variables[node.uid] = m.symbol(node.name)
continue
metadata = t.cast(Metadata, node.metadata)
return_type = metadata.get("return_type", "")
return_types = list(t.get_args(return_type) or [return_type])
var_names = [
f"v{i}",
*[getattr(typ, "name", typ.__name__) for typ in return_types[1:]],
]
spec: Fnspec = metadata.get("fnspec")
provider_callable: t.Optional[Symbol] = None
if spec is not None:
pkg_prefix = m.import_(metadata["component_type"].gopackage)
provider_callable = m.symbol(f"{pkg_prefix}.{spec.name}")
if provider_callable is None:
provider_callable = m.symbol(spec.name if spec else node.name)
args = [variables[dep.uid] for dep in node.depends]
variables[node.uid], *extra_vars = m.letN(var_names,
provider_callable(*args))
if extra_vars:
for sym, typ in sorted(
zip(extra_vars, return_types[1:]),
key=lambda pair: getattr(pair[1], "priority", 5),
reverse=True,
):
if hasattr(typ, "emit"):
typ.emit(m, sym)
i += 1
return variables[node.uid]
def emit(g: Graph) -> Module:
# TODO: name
# TODO: import_
i = 0
m = Module()
variables: t.Dict[int, Symbol] = {}
with m.func("run", *_get_args(g), return_="error"):
for node in topological_sorted(g):
if node.is_primitive:
variables[node.uid] = m.symbol(node.name)
continue
metadata = t.cast(Metadata, node.metadata)
return_type = metadata.get("return_type", "")
return_types = list(t.get_args(return_type) or [return_type])
var_names = [
f"v{i}",
*[
getattr(typ, "name", typ.__name__)
for typ in return_types[1:]
],
]
provider_callable = m.symbol(metadata.get("provider") or node.name)
args = [variables[dep.uid] for dep in node.depends]
variables[node.uid], *extra_vars = m.letN(var_names,
provider_callable(*args))
if extra_vars:
for sym, typ in sorted(
zip(extra_vars, return_types[1:]),
key=lambda pair: getattr(pair[1], "priority", 5),
reverse=True,
):
if hasattr(typ, "emit"):
typ.emit(m, sym)
i += 1
m.return_("nil")
return m
def emit(g: Graph) -> Module:
i = 0
m = Module()
variables: t.Dict[int, Symbol] = {}
# TODO: with type
# TODO: name
root_args = [
f"{node.name} string" for node in g.nodes if node.is_primitive
]
with m.func("run", *root_args, return_="error"):
for node in topological_sorted(g):
if node.is_primitive:
variables[node.uid] = m.symbol(node.name)
continue
metadata = t.cast(Metadata, node.metadata)
return_type = metadata.get("return_type", "")
return_types = list(t.get_args(return_type) or [return_type])
var_names = [
f"v{i}",
*[
getattr(typ, "name", typ.__name__)
for typ in return_types[1:]
],
]
provider_callable = m.symbol(metadata.get("provider") or node.name)
args = [variables[dep.uid] for dep in node.depends]
variables[node.uid], *extra_vars = m.letN(var_names,
provider_callable(*args))
if extra_vars:
for sym, typ in zip(extra_vars, return_types[1:]):
if hasattr(typ, "emit"):
typ.emit(m, sym)
i += 1
m.return_("nil")
return m
def inject(
m: Module,
g: Graph,
*,
variables: t.Dict[int, Symbol],
levels: t.Optional[t.Dict[int, int]] = None,
nodes: t.Optional[t.List[Node]] = None,
seen: t.Optional[t.Set[int]] = None,
strict: bool = True,
) -> Symbol:
# TODO: name
i = len(variables)
if levels is None:
levels = defaultdict(int)
if nodes:
node = nodes[0]
nodes = topological_sorted(g, seen=seen, nodes=nodes)
for node in nodes:
if node.is_primitive:
if strict:
assert node.uid in variables
else:
variables[node.uid] = m.symbol(node.name)
continue
metadata = t.cast(Metadata, node.metadata)
return_type = metadata.get("return_type", "")
# handling provider callable
return_types = list(typing_get_args(return_type) or [return_type])
var_names = [
f"v{i}",
*[getattr(typ, "name", typ.__name__) for typ in return_types[1:]],
]
spec: t.Optional[Fnspec] = metadata.get("fnspec")
provider_callable: t.Optional[Symbol] = None
if spec is not None:
provider = spec.name
pkg = get_gopackage(metadata["fnspec"].body)
if pkg is not None:
pkg_prefix = m.import_(pkg)
provider = f"{pkg_prefix}.{provider}"
provider_callable = m.symbol(provider)
if provider_callable is None:
provider_callable = m.symbol(spec.name if spec else node.name)
# handling arguments (pointer)
if spec is None:
args = [variables[dep.uid] for dep in node.depends] # todo: remove
else:
args = []
assert len(node.depends) == len(spec.arguments), (
len(node.depends),
len(spec.arguments),
)
for dep, (name, typ, _) in zip(node.depends,
spec.arguments): # parameters?
sym = variables[dep.uid]
current_level = levels[dep.uid]
need_level = metadata["levels"].get(name, 0) # more strict?
level_diff = need_level - current_level
if level_diff == 0:
pass
elif level_diff > 0:
sym = Symbol("&" * level_diff + str(sym))
else:
sym = Symbol("*" * -level_diff + str(sym))
args.append(sym)
levels[node.uid] = metadata["levels"]["return"]
variables[node.uid], *extra_vars = m.letN(var_names,
provider_callable(*args))
# handling error and cleanup:
if extra_vars:
for sym, typ in sorted(
zip(extra_vars, return_types[1:]),
key=lambda pair: getattr( # type:ignore
pair[1], "priority", priority.NORMAL),
reverse=True,
):
if hasattr(typ, "emit"):
typ.emit(m, sym)
i += 1
return variables[node.uid]
def emit_unmarshalJSON(m: Module, item: Item, *,
resolver: Resolver) -> Definition:
this = m.symbol(f"{item.type_.__name__[0].lower()}")
this_type = f"{resolver.resolve_gotype(item.type_)}"
this_type_pointer = f"*{this_type}"
# func (ob *Ob) UnmarshalJSON(b []byte) error {
b = m.symbol("b")
m.stmt(
f"func ({this} {this_type_pointer}) UnmarshalJSON({b} []byte) error {{"
)
with m.scope():
# var err *maperr.Error
err = m.symbol("err")
maperr_pkg = m.import_("github.com/podhmo/maperr")
m.stmt(f"var {err} *{maperr_pkg}.Error")
m.sep()
# var inner struct {
# ...
# }
m.stmt("// loading internal data")
inner = m.symbol("inner")
m.stmt(f"var {inner} struct {{")
with m.scope():
for name, info, metadata in item.fields:
if name.startswith("_"):
continue # xxx:
if "_override_type" in metadata:
gotype: str = metadata["_override_type"]
elif has_class_object(info):
json_pkg = m.import_("encoding/json")
gotype: str = str(json_pkg.RawMessage)
else:
gotype: str = resolver.resolve_gotype(info.raw)
m.append(f'{goname(name)} *{gotype} `json:"{name}"`')
m.stmt("// required" if metadata["required"] else "")
m.stmt("}")
# if rawErr := json.Unmarshal(b, &inner); rawErr != nil {
# ...
# }
json_pkg = m.import_("encoding/json")
raw_err = m.symbol("rawErr")
with m.if_(
f"{raw_err} := {json_pkg}.Unmarshal(b, &{inner}); {raw_err} != nil"
):
m.return_(err.AddSummary(raw_err.Error()))
m.sep()
# if <field> != nil {
# ob.<field> = *<field>
# } else {
# m.add(<field>, "required")
# }
rawerr = m.symbol("rawerr")
m.stmt("// binding field value and required check")
with m.block():
for name, info, metadata in item.fields:
field = m.symbol(goname(name))
with m.if_(f"{inner}.{field} != nil"):
if has_class_object(info):
# pointer
if info.is_optional:
gotype: str = resolver.resolve_gotype(
info.normalized)
m.stmt(f"{this}.{goname(name)} = &{gotype}{{}}")
ref = f"{this}.{field}"
elif hasattr(info, "args"): # xxx
gotype: str = resolver.resolve_gotype(
info.normalized)
m.stmt(f"{this}.{goname(name)} = {gotype}{{}}")
ref = f"&{this}.{field}"
else:
ref = f"&{this}.{field}"
with m.if_(
f"{rawerr} := json.Unmarshal(*{inner}.{field}, {ref}); {rawerr} != nil"
):
m.stmt(
f'{err} = {err}.Add("{name}", {maperr_pkg}.Message{{Error: {rawerr}}})'
)
else:
m.stmt(f"{this}.{field} = *{inner}.{field}")
if metadata["required"]:
with m.else_():
m.stmt(
f'{err} = err.Add("{name}", {maperr_pkg}.Message{{Text: "required"}})'
)
m.sep()
# NOTE: for injecting code from extrnal area
code_module = m.submodule("", newline=False)
# return err.Untyped()
m.return_(err.Untyped())
m.stmt("}")
return Definition(name="UnmarshalJSON", code_module=code_module)
def emit_enums(
m: Module,
literal_type: t.Type[t.Any],
*,
resolver: Resolver,
name: t.Optional[str] = None,
) -> str:
# literal_type or union_type
go_type = name or f"{resolver.resolve_gotype(literal_type)}"
first_of_args = t.get_args(literal_type)[0]
base_go_type = resolver.resolve_gotype(
type(getattr(first_of_args, "__name__", first_of_args)))
const_names = [getattr(x, "__name__", x) for x in t.get_args(literal_type)]
const_members = {name: f"{go_type}{goname(name)}" for name in const_names}
this = m.symbol("v")
as_literal = resolver.resolve_default
# type <enum> string
m.stmt(f"type {go_type} {base_go_type}")
m.sep()
# const (
# <enum>xxx <enum> = "xxx"
# ...
# )
with m.const_group() as cg:
for name in const_names:
cg(f"{const_members[name]} {go_type} = {as_literal(type(name), name)}"
)
m.sep()
# func (v <enum>) Valid() error {
# ...
# }
with m.method(f"{this} {go_type}", "Valid", returns="error"):
with m.switch(this) as sm:
with sm.case(", ".join(const_members.values())):
sm.return_("nil")
with sm.default() as sm:
fmt_pkg = m.import_("fmt")
candidates = ", ".join([str(x) for x in const_names])
sm.return_(
fmt_pkg.Errorf(
as_literal(
str,
f"%q is invalid enum value of ({candidates})"),
this,
))
sm.unnewline()
# func (v <enum>) UnmarshalJSON(b []byte) error {
# ...
# }
with m.method(f"{this} *{go_type}",
"UnmarshalJSON",
f"b []byte",
returns="error"):
strings_pkg = m.import_("strings")
m.stmt(f'*{this} = {go_type}({strings_pkg}.Trim(string(b), `"`))')
m.return_(this.Valid())
definition = Definition(name=go_type, code_module=None)
return definition