def init_translated_method(orig_method, context):
assert 'translation' not in orig_method.__dict__
logging.debug('entered [init_translated_method] with method:' + repr(orig_method))
method = cpp.cpp_method('lua_munch_' + orig_method.name,
static=True, returns= cpp.cpp_type('int'),
params=[cpp.cpp_variable('L', cpp.cpp_type('lua_State', pointer=True))])
if orig_method.parent:
method.parent = orig_method.parent.translation
method.orig_name = orig_method.name
method.public = True
#now we embed the default object with a very specific format that will be useful later
method.initialization = [] # will contain initialization steps
method.validation = [] # will contain validation steps
method.recover = [] # will contain the steps to translate the lua arg to a C++ arg
method.execution = [] # will contain execution steps, i.e, calling the native method
method.lua_return = [] # will contain the steps to push a value back to lua
if not 'is_overload' in method.__dict__:
method.is_overload = False
if orig_method.parent and orig_method.is_virtual:
method.parameters.append(cpp.cpp_variable('lua_self', cpp.cpp_type(orig_method.parent.qualname, pointer=True)))
method.return_value = cpp.cpp_return(0)
#we 'tie' the translated method on the original method
#so it's easier to work with them without needing to search for them on every callback
orig_method.translation = method
def make_binder(orig_class, lua_cls):
cls_type = cpp.cpp_type('void')
binder = cpp.cpp_method('bind',
static=True,
returns=cls_type,
params=[cpp.cpp_variable('L', cpp.cpp_type('lua_State', pointer=True))])
binder.exprs.append('lua_newtable(L)')
binder.exprs.append('luaL_setfuncs (L, lua_reg_{},0)'.format(orig_class.identifier_name))
binder.exprs.append('lua_setfield(L, -2, "{}")'.format(orig_class.name))
return binder
def init_translated_class(orig_class, context):
assert 'translation' not in orig_class.__dict__
lua_cls = cpp.cpp_class('lua_munch_' + orig_class.identifier_name)
orig_class.translation = lua_cls
luaReg = cpp.cpp_variable_array('lua_reg_' + orig_class.identifier_name,
cpp.cpp_type('constexpr luaL_Reg', static=True))
logging.debug('baking methods for class: %s : %s' % (orig_class.name ,orig_class.public))
#lua_cls.public.append(make_getter(orig_class))
#we now bake all methods and subclasses from this class, but not preprocess them
class_ctx = lua_context_builder.bake(orig_class.public, preprocess=False)
for item in class_ctx.translated:
if item.public:
lua_cls.public.append(item)
else:
lua_cls.protected.append(item)
if type(item) == cpp.cpp_method and item.public:
luaReg.expr.append('{ "%s" , lua_munch_%s::%s }' % (item.orig_name, orig_class.identifier_name, item.name))
lua_cls.public.append(make_binder(orig_class, lua_cls))
#the base methods are shims that only retrieve it's self and pass it down to the
#base class
for base in orig_class.bases:
for item in base.public:
if type(item) != cpp.cpp_method:
continue
method = cpp.cpp_method('lua_munch_' + item.name,
static=True, returns=cpp.cpp_type('int'),
params=[cpp.cpp_variable('L', cpp.cpp_type('lua_State', pointer=True))])
if item.parent:
item.parameters.append(cpp.cpp_variable('lua_self', cpp.cpp_type(item.parent.name, pointer=True)))
method.exprs.append('%s* lua_self = lua_munch_%s::get(L, %d)' % (orig_class.qualname, orig_class.identifier_name, 1))
method.exprs.append(cpp.cpp_return(cpp.cpp_method_call('lua_munch_%s::lua_munch_%s' % (item.parent.name, item.name), params=['L', 'lua_self'])))
lua_cls.public.append(method)
if not item.is_constructor:
luaReg.expr.append('{ "%s" , lua_munch_%s::lua_munch_%s }' % (item.name, orig_class.name, item.name))
luaReg.expr.append('{ 0, 0 }')
lua_cls.public.append(luaReg)
context.binder_method.exprs.append('{}::bind(L)'.format(lua_cls.name))
luaReg.parent = lua_cls
vardecl = luaReg.define()
vardecl = vardecl.replace('static', '')
context.luareg_declarations.append(vardecl)
orig_class.translation = lua_cls
def lua_preprocess(data, context):
classes = filter(lambda item: type(item) == cpp.cpp_class, data)
functions = filter(lambda item: type(item) == cpp.cpp_method and item.parent == None, data)
other = filter(lambda item: type(item) != cpp.cpp_method and type(item) != cpp.cpp_class, data)
del data[:]
#resolving overloads
for item in classes:
item.identifier_name = item.qualname\
.replace('::', '_')\
.replace(' ', '')\
.replace('<','_')\
.replace('>', '_')\
.replace(',', '_')
process_functions(item)
#resolving dependencies
sorted_classes = []
class_set = set([])
previous_count = len(classes)
iteration = 0
while classes:
current = classes.pop(0)
processed = True
#print 'testing', current.name, current.dependencies
for dependency in current.dependencies:
if 'std' in dependency or dependency == current.qualname:
continue
#remove this once the generator knows how to get template items
if '<' in dependency:
templates = dependency[dependency.find('<') + 1:dependency.find('>')].split(',')
current.dependencies += templates
if not dependency in class_set and not iteration == 10:
#print 'I dont have dependency: ', dependency
classes.append(current)
processed = False
break
if processed:
#print '### added', current.name
sorted_classes.append(current)
class_set.add(current.qualname)
iteration = 0
if previous_count == len(classes):
if iteration == 10:
raise Exception("Couldn't resolve dependencies for the classes:" + str(classes))
iteration += 1
previous_count = len(classes)
fake_cls = cpp.cpp_class('Fake')
fake_cls.public = functions
process_functions(fake_cls)
data += sorted_classes + fake_cls.public + other
context.binder_method = cpp.cpp_method('luaopen_gdx',
returns=cpp.cpp_type('int'),
attributes=['extern', '"C"'],
params=[cpp.cpp_variable('L', cpp.cpp_type('lua_State', pointer=True))])
context.luareg_declarations = []
context.binder_method.exprs.append('lua_newtable(L)')
context.binder_method.return_value = cpp.cpp_return(1)
def process_functions(cls):
overloads = {}
for item in cls.public:
if type(item) == cpp.cpp_method:
if item.name in overloads:
overloads[item.name].append(item)
else:
overloads[item.name] = [item]
final_functions = []
overload_count = 0
for func in overloads:
#if there is only one function with this name, it's not an overload it safely
if len(overloads[func]) == 1:
overloads[func][0].is_overload = False
overloads[func][0].has_overload = False
final_functions.append(overloads[func][0])
else:
newfun = cpp.cpp_method(func)
newfun.has_overload = True
newfun.is_overload = False
newfun.overloads = {
'by_arg_count' : [],
'by_lua_type' : [],
'by_cpp_type' : []
}
newfun.is_constructor = overloads[func][0].is_constructor
newfun.parent = cls
for i, function in enumerate(overloads[func]):
function.name = '%s_overload_%d' % (function.name, overload_count)
function.is_overload = True
function.has_overload = False
function.orig_name = newfun.name
overload_count += 1
if function.is_virtual:
newfun.is_virtual = True
#resolving functions that can be deduced by the count of it's arguments
same_qnt = False
for other_f in overloads[func]:
if other_f == function: continue
if len(function.parameters) == len(other_f.parameters):
same_qnt = True
break
if not same_qnt:
newfun.overloads['by_arg_count'].append(function)
continue
#resolving functions that can be deduced by the type of it's lua arguments
for other_f in overloads[func]:
if other_f == function: continue
same_basic_types = False
for a,b in zip(function.parameters, other_f.parameters):
if a.ctype == b.ctype and not is_basic(a):
same_basic_types = True
break
if same_basic_types:
break
if not same_basic_types:
newfun.overloads['by_lua_type'].append(function)
continue
newfun.overloads['by_cpp_type'].append(function)
final_functions.append(newfun)
#filter every
final_public = filter(lambda item: type(item) != cpp.cpp_method, cls.public)
cls.public = final_public + final_functions
