def rename(self, n):
new_name = self.rename_types.get(n, None)
if new_name:
arg_type_order = self.wrapper_order.get(new_name, None)
class_order = self.wrapper_order.get(self.current_class_name, None)
# arg type is defined after current class
if arg_type_order and class_order and arg_type_order > class_order:
return T.Constant(new_name)
if new_name == self.current_class_name:
return T.Constant(new_name)
return T.Name(new_name)
return n
def parse_int(self, val):
if val.startswith('0x'):
return T.Constant(int(val, base=16))
try:
return T.Constant(int(val))
except ValueError:
pass
try:
return T.Constant(float(val))
except ValueError:
pass
return None
def generate_function(self, elem: Cursor, depth=0, **kwargs):
"""Generate a type alias
Examples
--------
>>> from tide.generators.clang_utils import parse_clang
>>> tu, index = parse_clang('float add(float a, float b);')
>>> module = BindingGenerator().generate(tu)
>>> print(compact(unparse(module)))
<BLANKLINE>
add = _bind('add', [c_float, c_float], c_float, arg_names=['a', 'b'])
<BLANKLINE>
"""
log.debug(f'{d(depth)}Generate function `{elem.spelling}`')
definition: Cursor = elem.get_definition()
if definition is None:
definition = elem
rtype = self.generate_type(definition.result_type, depth + 1)
args = definition.get_arguments()
docstring = get_comment(elem)
pyargs = []
arg_names = []
for a in args:
atype = self.generate_type(a.type, depth + 1)
pyargs.append(atype)
if a.spelling != '':
arg_names.append(T.Constant(a.spelling))
funnane = definition.spelling
if not pyargs:
pyargs = T.Name('None')
else:
pyargs = T.List(elts=pyargs)
kwargs = []
if len(docstring) > 0:
kwargs.append(
T.Keyword('docstring', T.Constant(docstring, docstring=True)))
if arg_names:
kwargs.append(T.Keyword('arg_names', T.List(arg_names)))
binding_call = T.Call(T.Name('_bind'),
[T.Constant(funnane), pyargs, rtype], kwargs)
return T.Assign([T.Name(funnane)], binding_call)
def class_definition(self, class_def: T.ClassDef, depth):
assert class_def.name in self.ctypes
# Opaque struct: move on
# if class_def.name[0] == '_':
# return class_def
self_wrap = self.wrappers.get(class_def.name)
if self_wrap is None:
if T.Name('enumeration') in class_def.decorator_list:
return self.clean_up_enumeration(class_def)
_, names = parse_sdl_name(class_def.name)
cl_name = class_name(*names)
self_wrap = T.ClassDef(cl_name)
self.new_code.append((class_def.name, self_wrap))
self.wrappers[class_def.name] = self_wrap
self.wrappers_2_ctypes[self_wrap.name] = class_def.name
self.wrapper_order[self_wrap.name] = len(self.wrappers)
self_type = T.Call(T.Name('POINTER'), [T.Name(class_def.name)])
self_wrap.body.append(
T.AnnAssign(T.Name('handle'), self_type, T.Name('None')))
# Factory to build the wrapper form the ctype
# create an uninitialized version of the object and set the handle
from_ctype = T.FunctionDef('from_handle',
decorator_list=[T.Name('staticmethod')])
from_ctype.args = T.Arguments(args=[T.Arg('a', self_type)])
from_ctype.returns = T.Constant(cl_name)
from_ctype.body = [
T.Assign([T.Name('b')],
T.Call(T.Attribute(T.Name('object'), '__new__'),
[T.Name(cl_name)])),
T.Assign([T.Attribute(T.Name('b'), 'handle')], T.Name('a')),
T.Return(T.Name('b'))
]
self_wrap.body.append(from_ctype)
if not self.is_opaque_container(class_def.name):
# default init allocate a dummy object for it
default_init = T.FunctionDef('__init__')
default_init.args = T.Arguments(args=[T.Arg('self')])
default_init.body = [
T.Assign([T.Attribute(T.Name('self'), '_value')],
T.Call(T.Name(class_def.name), [])),
T.Assign([T.Attribute(T.Name('self'), 'handle')],
T.Call(T.Name('byref'),
[T.Attribute(T.Name('self'), '_value')]))
]
self_wrap.body.append(default_init)
self.rename_types[T.Call(T.Name('POINTER'),
[T.Name(class_def.name)])] = cl_name
return class_def
def generate_integer(self, elem: Cursor, **kwargs):
try:
val = list(elem.get_tokens())[0].spelling
val = val.replace('u', '')
val = val.replace('ll', '')
val = val.replace('U', '')
val = val.replace('L', '')
base = 10
if '0x' in val:
base = 16
return T.Constant(int(val, base=base))
except IndexError:
# this integer comes from __LINE__ macro
# this is not correct at all, this should return the line on which it is called
# but we cannot really do that in python I think
return T.Constant(int(elem.location.line))
def parse_expression(self, depth=0):
tok = self.peek()
log.debug(f'{d(depth)} parse_expression {tok.kind} {tok.spelling}')
if tok.spelling == '\\\n{':
body = []
self.next()
while tok.spelling != '\\\n}':
p = T.Expr(self.parse_expression(depth + 1))
body.append(p)
tok = self.peek()
if tok.spelling == ';':
self.next()
tok = self.peek()
self.next()
return T.If(T.Constant(True), body)
if is_operator(tok.spelling) and is_unary_operator(tok.spelling):
p = self.parse_unary(depth + 1)
else:
p = self.parse_primary(depth + 1)
tok = self.peek()
if tok is None:
return p
# we are doing a cast or call (type(expr))
if tok.spelling == '(':
self.next()
expr = self.parse_call(p, depth + 1)
if self.peek().spelling == ')':
self.next()
return expr
# argument list do not try to parse operators
if tok.spelling == ',' and self.is_call[-1]:
return p
if tok.spelling == ')':
return p
# cast (expr) <expr>
if not is_operator(tok.spelling):
return self.parse_cast(p, depth + 1)
# if tok.spelling == ')':
# return p
return self.parse_expression_1(p, 0, depth + 1)
def process_builtin_macros(self, cursor: Cursor):
tokens = list(cursor.get_tokens())
name, tok_args, tok_body = parse_macro(tokens)
if len(tok_body) == 0:
self.definitions[name.spelling] = T.Constant(True)
return
try:
bods = {t.spelling for t in tok_body}
if not bods.isdisjoint(self.unsupported_macros):
raise UnsupportedExpression()
py_body = parse_macro2(name, tok_args, tok_body)
except UnsupportedExpression:
self.unsupported_macros.add(name.spelling)
self.definitions[name.spelling] = py_body
def parse_literal(self, tok: Token, depth):
log.debug(f'{d(depth)} parse_literal {tok.kind} {tok.spelling}')
val = None
# 3243212132u
# 0x13223u
l = self.is_int_annotated(tok.spelling)
if l > 0:
val = self.parse_int(tok.spelling[:-l])
# 1232133 | 123.123
if val is None:
val = self.parse_int(tok.spelling)
# the rest
if val is None:
val = T.Constant(str(tok.spelling))
return val
def generate_field(self, body, attrs, attr, anonymous_renamed, depth,
**kwargs):
if attr.kind == CursorKind.FIELD_DECL:
# Rename anonymous types
uid = self.get_underlying_type_uid(attr.type)
log.debug(
f'{d(depth)}uid: {uid} {attr.type.spelling} {anonymous_renamed}'
)
if uid in anonymous_renamed:
parent, name = anonymous_renamed[uid]
if parent:
typename = T.Attribute(T.Name(parent), name)
else:
typename = T.Name(name)
if attr.type.kind == TypeKind.POINTER:
typename = T.Call(T.Name('POINTER'), [typename])
else:
typename = self.generate_type(attr.type, depth + 1)
pair = T.Tuple()
pair.elts = [T.Constant(attr.spelling), typename]
attrs.elts.append(pair)
elif attr.kind in (CursorKind.UNION_DECL, CursorKind.STRUCT_DECL):
nested_struct = self.generate_struct_union(
attr, depth + 1, nested=True, rename=anonymous_renamed)
body.append(nested_struct)
elif attr.kind == CursorKind.PACKED_ATTR:
for attr2 in attr.get_children():
self.generate_field(body, attrs, attr2, anonymous_renamed,
depth + 1)
# attrs.append(field)
else:
show_elem(attr)
print('NESTED ', attr.kind)
raise RuntimeError('')
def generate_string(self, elem, **kwargs):
return T.Constant(elem.spelling)
def generate_enum(self, elem: Cursor, depth=0, **kwargs):
""" Generate a enum class
Notes
-----
we cannot use enum.Enum because we need the class to be a ctype/c_int when they are used
a arguments
Examples
--------
>>> from tide.generators.clang_utils import parse_clang
>>> tu, index = parse_clang('enum Colors { Red, Green, Blue;};')
>>> module = BindingGenerator().generate(tu)
>>> print(compact(unparse(module)))
<BLANKLINE>
@enumeration
class Colors(c_int):
Red = 0
Green = 1
Blue = 2
<BLANKLINE>
"""
log.debug(f'{d(depth)}Generate Enum')
name = self.get_name(elem)
enum = []
ctypes = self.type_registry.get('int')
common = self.find_duplicate_name(elem)
if name == '':
name = common
if name[-1] == '_':
name = name[:-1]
if self.global_enum:
enum.append(T.Assign([T.Name(name)],
self.type_registry.get('int')))
def shorten_name(n):
if len(n) == len(common):
return n
if self.short_enum_names:
new_name = n[len(common):]
if not new_name[0].isalpha():
return n
# rename SDL_PIXELTYPE_UNKNOWN to SDL_PIXELTYPE.UNKNOWN
# useful to get editor auto-completion to show relevant values
self.renaming[n] = T.Attribute(T.Name(name), new_name)
return new_name
return n
for value in elem.get_children():
if value.kind == CursorKind.ENUM_CONSTANT_DECL:
n = shorten_name(self.get_name(value))
enum.append(T.Assign([T.Name(n)],
T.Constant(value.enum_value)))
else:
log.error(f'Unexpected children {value.kind}')
raise RuntimeError()
if not self.global_enum:
# this require renaming the code where the enum were used
# not implemented yet
self.import_enum = True
enum_class = T.ClassDef(name, bases=[ctypes])
enum_class.body = enum
enum_class.decorator_list.append(T.Name('enumeration'))
return enum_class
return enum
def generate_struct_union(self,
elem: Cursor,
depth=1,
nested=False,
rename=None,
**kwargs):
"""Generate a struct or union alias
Examples
--------
>>> from tide.generators.clang_utils import parse_clang
>>> tu, index = parse_clang('struct Point { float x, y;};')
>>> module = BindingGenerator().generate(tu)
>>> print(compact(unparse(module)))
<BLANKLINE>
class Point(Structure):
pass
<BLANKLINE>
Point._fields_ = [('x', c_float), ('y', c_float)]
<BLANKLINE>
>>> from tide.generators.clang_utils import parse_clang
>>> tu, index = parse_clang('union Point { float x; int y;};')
>>> module = BindingGenerator().generate(tu)
>>> print(compact(unparse(module)))
<BLANKLINE>
class Point(Union):
pass
<BLANKLINE>
Point._fields_ = [('x', c_float), ('y', c_int)]
<BLANKLINE>
"""
log.debug(f'{d(depth)}Generate struct `{elem.spelling}`')
pyname = self.get_name(elem, rename=rename, depth=depth + 1)
base = 'Structure'
if elem.kind == CursorKind.UNION_DECL:
base = 'Union'
# For recursive data structure
# log.debug(pyname)
self.type_registry[f'struct {pyname}'] = T.Name(pyname)
self.type_registry[f'const struct {pyname}'] = T.Name(pyname)
parent = pyname
anonymous_renamed = self.find_anonymous_fields(elem,
parent,
depth=depth + 1)
# Docstring is the first element of the body
# T.Constant(get_comment(elem))
body = []
docstring = get_comment(elem)
if docstring:
body.append(T.Expr(T.Constant(docstring, docstring=True)))
attrs = T.List()
need_pass = len(body)
attr: Cursor
for attr in elem.get_children():
self.generate_field(body, attrs, attr, anonymous_renamed, depth)
# insert pass even if we have a docstring because
# we will remove the docstring later
if need_pass == len(body):
body.append(ast.Pass())
if not attrs.elts:
return T.ClassDef(name=pyname, bases=[T.Name(base)], body=body)
fields = T.Assign([T.Attribute(T.Name(pyname), '_fields_')], attrs)
return [
T.ClassDef(name=pyname, bases=[T.Name(base)], body=body), fields
]
def _generate_type(self, type: Type, depth=0):
# print(type.kind, type.spelling, self.type_registry.get(type.spelling, 'NOT FOUND'))
if type.kind == TypeKind.VOID:
return T.Name('None')
if type.kind == TypeKind.INT:
return T.Name('c_int')
if type.kind == TypeKind.POINTER and type.get_pointee(
).kind == TypeKind.VOID:
return T.Name('c_void_p')
if type.kind == TypeKind.POINTER and type.get_pointee(
).kind == TypeKind.CHAR_S:
return T.Name('c_char_p')
if type.kind == TypeKind.POINTER:
pointee: Type = type.get_pointee()
# Typedef use the name that it is aliased to
if pointee.kind is TypeKind.TYPEDEF:
pointee = get_typename(pointee)
elif pointee.kind != TypeKind.VOID:
pointee = self.generate_type(pointee, depth + 1)
else:
pointee = T.Name('c_void_p')
# Function pointer do not need to be decorated by POINTER call
if isinstance(pointee, T.Call) and isinstance(
pointee.func, T.Name) and pointee.func.id == 'CFUNCTYPE':
return pointee
# for native types we need to keep ref because python will copy them
return T.Call(T.Name('POINTER'), [pointee])
if type.kind == TypeKind.CHAR_S:
return T.Name('c_char_p')
# if type.is_const_qualified():
# return T.Name(get_typename(type))
if type.kind == TypeKind.TYPEDEF:
return get_typename(type)
if type.kind == TypeKind.FUNCTIONPROTO or (
type.kind == TypeKind.UNEXPOSED
and type.get_canonical().kind == TypeKind.FUNCTIONPROTO):
# SDL_HitTest = CFUNCTYPE(SDL_HitTestResult, POINTER(SDL_Window), POINTER(SDL_Point), c_void_p)
canon = type
if type.kind == TypeKind.UNEXPOSED:
canon = type.get_canonical()
rtype = canon.get_result()
args = []
for arg in canon.argument_types():
args.append(self.generate_type(arg, depth + 1))
returntype = self.generate_type(rtype, depth + 1)
cargs = [returntype]
cargs.extend(args)
return T.Call(T.Name('CFUNCTYPE'), args=cargs)
if type.kind == TypeKind.CONSTANTARRAY:
t = self.generate_type(type.element_type, depth + 1)
return T.BinOp(t, ast.Mult(), T.Constant(type.element_count))
# Represents a C array with an unspecified size.
if type.kind == TypeKind.INCOMPLETEARRAY:
element_type = self.generate_type(type.element_type, depth + 1)
# char *[] -> char **
return T.Call(T.Name('POINTER'), [element_type])
# struct <TYPENAME>
if type.kind == TypeKind.ELABORATED:
return T.Name(get_typename(type).id.replace('struct', '').strip())
if type.kind == TypeKind.ENUM:
return get_typename(type)
# print('gentype')
show_elem(type, print_fun=log.debug)
return get_typename(type)
def generate_float(self, elem, **kwargs):
toks = [t.spelling for t in elem.get_tokens()]
assert len(toks) == 1
return T.Constant(float(toks[0]))
def parse_expression_1(self, lhs, min_precedence, depth):
lookahead = self.peek()
precedence = fetch_precedence(lookahead.spelling)
log.debug(
f'{d(depth)} parse_expression_1 {lhs} {lookahead.kind} {lookahead.spelling}'
)
while lookahead and precedence is not None and precedence >= min_precedence:
op = lookahead
self.next()
rhs = self.parse_primary(depth + 1)
lookahead = self.peek()
if lookahead is None:
break
is_binary = is_binary_operator(lookahead.spelling)
lookahead_pred = fetch_precedence(lookahead.spelling)
is_right_asso = is_right_associative(lookahead.spelling)
while lookahead and (is_binary and lookahead_pred > precedence
) or (is_right_asso
and lookahead_pred == precedence):
rhs = self.parse_expression_1(rhs, lookahead_pred, depth + 1)
lookahead = self.peek()
is_binary = is_binary_operator(lookahead.spelling)
lookahead_pred = fetch_precedence(lookahead.spelling)
is_right_asso = is_right_associative(lookahead.spelling)
if lookahead.spelling == ')':
break
# the result of applying op with operands lhs and rhs
pyop = fetch_python_op(op.spelling)
if pyop is not None and not isinstance(pyop, str):
if is_comparison(op.spelling):
lhs = T.Compare(left=lhs, ops=[pyop()], comparators=[rhs])
elif is_bool(op.spelling):
lhs = T.BoolOp(op=pyop(), values=[lhs, rhs])
else:
lhs = T.BinOp(left=lhs, op=pyop(), right=rhs)
elif pyop == 'if':
raise UnsupportedExpression()
elif pyop == 'assign':
lhs = T.Assign(targets=[lhs], value=rhs)
elif op.spelling == '[':
lhs = T.Subscript(value=lhs,
slice=T.Index(value=rhs),
ctx=T.Load())
tok = self.peek()
assert tok.spelling == ']'
self.next()
elif op.spelling == '->':
if isinstance(rhs, T.Name):
rhs = rhs.id
lhs = T.Attribute(lhs, rhs, ctx=T.Load())
elif op.spelling == ',':
lhs = T.If(T.Constant(True), [T.Expr(lhs), T.Return(rhs)])
else:
show_elem(op)
assert False
precedence = fetch_precedence(lookahead.spelling)
return lhs
tu = index.parse(filename, options=0x01)
for diag in tu.diagnostics:
print(diag.format())
for elem in tu.cursor.get_children():
show_elem(elem)
if elem.spelling == '__GNUC__':
break
pass
if __name__ == '__main__':
# show_file('/usr/include/SDL2/SDL.h')
from tide.generators.unparser_patch import unparse
import tide.generators.nodes as T
import ast
from astunparse import dump
mod = ast.parse("""
\"\"\"test\"\"\"
""")
mod = T.Constant("abc", docstring=True)
# print(dump(mod))
print(unparse(mod))
class APIPass:
"""Generate a more friendly API for C bindings
Notes
-----
* removes the explicit library namespace from the name of functions and struct
* Rewrites functions as method if first argument is a pointer to struct
* Method use original c argument names
* Method has the origin c docstring
* Method has a short name removing the object name and the library namespace
* enum values are now scoped inside an enum class
* enum values have shorter names since name clashing cannot happen anymore
* rewrites function that takes pointer arguments to return multiple values
"""
def __init__(self):
self.dispatcher = {
'Expr': self.expression,
'Assign': self.assign,
'ClassDef': self.class_definition,
'FunctionDef': self.function_definition
}
self.pre_dispatcher = {
'Expr': self.pre_expression,
'Assign': self.pre_assign,
'ClassDef': self.pre_class_definition,
}
self.ctypes = dict()
self.wrappers = dict()
self.wrappers_2_ctypes = dict()
# keep the order to know if we can annotate with Name of with string
self.wrapper_order = dict()
# we will remove wrappers that do not have methods
# i.e they are data struct only
self.wrapper_method_count = defaultdict(int)
self.wrapper_ctor = defaultdict(list)
self.ctypes_fields = dict()
self.new_code = []
self.names = Trie()
self.rename_types = dict()
self.current_class_name = None
self.new_names = set()
def pre_expression(self, expr: T.Expr, depth):
values = self.preprocess(expr.value, depth)
if isinstance(values, (tuple, list)):
return [T.Expr(v) for v in values]
return T.Expr(values)
def pre_class_definition(self, class_def: T.ClassDef, depth=0):
self.ctypes[class_def.name] = class_def
def pre_assign(self, expr: T.Assign, depth):
# <c-type>._fields_ = []
if match(expr.targets[0], 'Attribute') and match(
expr.value, 'List') and expr.targets[0].attr == '_fields_':
ctype_name = expr.targets[0].value.id
data = []
self.ctypes_fields[ctype_name] = data
for elem in expr.value.elts:
name = elem.elts[0].value
ctype = elem.elts[1]
data.append((name, ctype))
def preprocess(self, expr, depth):
handler = self.pre_dispatcher.get(expr.__class__.__name__, None)
if handler is not None:
handler(expr, depth)
def preprocessor(self, module: T.Module, depth=0):
for expr in module.body:
self.preprocess(expr, depth)
def post_process_class_defintion(self, class_def: T.ClassDef):
"""Make a final pass over the generated class to improve function names"""
# move the documentation over to our new class
c_class_name = self.wrappers_2_ctypes[class_def.name]
c_class_def = self.ctypes[c_class_name]
docstring = fetch_docstring(c_class_def)
if docstring:
class_def.body.insert(0, docstring)
# --
class_name = class_def.name.lower()
names = defaultdict(int)
for expr in class_def.body:
if not isinstance(expr, T.FunctionDef):
continue
for n in expr.name.split('_'):
if len(n) > 0:
names[n] += 1
names = list(names.items())
# remove names that are not used that often
names = sorted(filter(lambda x: x[1] > 2, names), key=lambda x: x[1])
# this is the magic filter that makes thing work
# by forcing the name we are removing to be part of the type name
# we are almost sure to remove duplicated data that is not useful
# even when it appears multiple times it can make sense to have it duplicated
# Example:
# read_le16, read_le32, read_le64
# write_le16, write_le32, write_le64
names = list(
map(lambda x: x[0], filter(lambda x: x[0] in class_name, names)))
for expr in class_def.body:
if not isinstance(expr, T.FunctionDef):
continue
for useless_name in names:
expr.name = clean_name(expr.name, useless_name)
def group_constant_to_enums(self):
pass
def clean_up_enumeration(self, class_def: T.ClassDef):
"""Removes superfluous prefix"""
_, names = parse_sdl_name(class_def.name)
cl_name = class_name(*names)
# make a short alias of the enum (without the hardcoded c namespace)
if cl_name != class_def.name:
self.new_code.append(
(None, T.Assign([T.Name(cl_name)], T.Name(class_def.name))))
t = Trie()
counts = 0
for expr in class_def.body:
if match(expr, 'Assign') and match(expr.targets[0], 'Name'):
constant_name = expr.targets[0].id
t.insert(constant_name)
counts += 1
_ = list(t.redundant_prefix())
if len(_) > 1:
# select the shortest prefix that is common to all
most_likely = _[0]
for c, n in _:
if len(n) < len(most_likely[1]):
most_likely = (c, n)
# check that the prefix is common to all
good = True
for c, n in _:
if not most_likely[1] in n:
good = False
break
if good:
_ = [most_likely]
else:
_ = []
if len(_) == 1:
c, namespace = _[0]
# SDL insert a None/Max enum that does not follow the pattern
if counts != c + 1:
return class_def
for expr in class_def.body:
if match(expr, 'Assign') and match(expr.targets[0], 'Name'):
constant_name = expr.targets[0].id
expr.targets[0].id = clean_name(constant_name, namespace)
return class_def
def is_opaque_container(self, name):
# does this class define fields
return self.ctypes_fields.get(name, None) is None
def class_definition(self, class_def: T.ClassDef, depth):
assert class_def.name in self.ctypes
# Opaque struct: move on
# if class_def.name[0] == '_':
# return class_def
self_wrap = self.wrappers.get(class_def.name)
if self_wrap is None:
if T.Name('enumeration') in class_def.decorator_list:
return self.clean_up_enumeration(class_def)
_, names = parse_sdl_name(class_def.name)
cl_name = class_name(*names)
self_wrap = T.ClassDef(cl_name)
self.new_code.append((class_def.name, self_wrap))
self.wrappers[class_def.name] = self_wrap
self.wrappers_2_ctypes[self_wrap.name] = class_def.name
self.wrapper_order[self_wrap.name] = len(self.wrappers)
self_type = T.Call(T.Name('POINTER'), [T.Name(class_def.name)])
self_wrap.body.append(
T.AnnAssign(T.Name('handle'), self_type, T.Name('None')))
# Factory to build the wrapper form the ctype
# create an uninitialized version of the object and set the handle
from_ctype = T.FunctionDef('from_handle',
decorator_list=[T.Name('staticmethod')])
from_ctype.args = T.Arguments(args=[T.Arg('a', self_type)])
from_ctype.returns = T.Constant(cl_name)
from_ctype.body = [
T.Assign([T.Name('b')],
T.Call(T.Attribute(T.Name('object'), '__new__'),
[T.Name(cl_name)])),
T.Assign([T.Attribute(T.Name('b'), 'handle')], T.Name('a')),
T.Return(T.Name('b'))
]
self_wrap.body.append(from_ctype)
if not self.is_opaque_container(class_def.name):
# default init allocate a dummy object for it
default_init = T.FunctionDef('__init__')
default_init.args = T.Arguments(args=[T.Arg('self')])
default_init.body = [
T.Assign([T.Attribute(T.Name('self'), '_value')],
T.Call(T.Name(class_def.name), [])),
T.Assign([T.Attribute(T.Name('self'), 'handle')],
T.Call(T.Name('byref'),
[T.Attribute(T.Name('self'), '_value')]))
]
self_wrap.body.append(default_init)
self.rename_types[T.Call(T.Name('POINTER'),
[T.Name(class_def.name)])] = cl_name
return class_def
def function_definition(self, function_def: T.FunctionDef, depth):
return function_def
SELF_HANDLE = T.Attribute(T.Name('self'), 'handle')
def rename(self, n):
new_name = self.rename_types.get(n, None)
if new_name:
arg_type_order = self.wrapper_order.get(new_name, None)
class_order = self.wrapper_order.get(self.current_class_name, None)
# arg type is defined after current class
if arg_type_order and class_order and arg_type_order > class_order:
return T.Constant(new_name)
if new_name == self.current_class_name:
return T.Constant(new_name)
return T.Name(new_name)
return n
def make_wrapping_call(
self,
call: BindCall,
replace_arg_names: Optional[List] = None,
replace_args: Optional[List] = None) -> Tuple[T.Arguments, T.Call]:
if replace_arg_names is None:
replace_arg_names = []
if replace_args is None:
replace_args = []
assert len(replace_args) == len(replace_arg_names)
fun_name = call.function_name
offset = len(replace_args)
ctype_args = list(call.arguments[offset:])
arg_names = list(call.argument_names[offset:])
fun_args = T.Arguments(
args=replace_arg_names +
[T.Arg(n, self.rename(t)) for n, t in zip(arg_names, ctype_args)])
fun_call = T.Call(
T.Name(fun_name), replace_args +
[T.Name(arg_names[i]) for i in range(len(ctype_args))])
return fun_args, fun_call
def add_docstring(self, new_fun: T.FunctionDef, binding: BindCall,
indent_level: int):
docstring = binding.docstring
if docstring:
docstring.value = docstring.value.replace(
'\n ', '\n' + ' ' * indent_level)
new_fun.body.insert(0, T.Expr(docstring))
def generate_constructor(self, class_def: T.ClassDef, call: BindCall):
self.current_class_name = class_def.name
cl_name = class_def.name
# because we can have multiple constructors we have a to generate a constructor as a static method
fun_name = call.function_name
ctype_return = call.return_type
_, names = parse_sdl_name(fun_name)
args, c_call = self.make_wrapping_call(call)
new_fun = T.FunctionDef(function_name(*names),
decorator_list=[T.Name('staticmethod')])
new_fun.returns = self.rename(ctype_return)
new_fun.args = args
new_fun.body = [
T.Assign([T.Name('b')],
T.Call(T.Attribute(T.Name('object'), '__new__'),
[T.Name(cl_name)])),
T.Assign([T.Attribute(T.Name('b'), 'handle')], c_call),
T.Return(T.Name('b'))
]
self.add_docstring(new_fun, call, 2)
call.clear_kwargs()
class_def.body.append(new_fun)
self.current_class_name = None
def get_arg_names(self, call: T.Call):
arg_names = get_kwarg_arg('arg_names', call.keywords, None)
if arg_names is not None:
return [a.value.lower() for a in arg_names.elts]
else:
return self.ARGS
def generate_method(self, call: BindCall, self_wrap: T.ClassDef):
fun_name = call.function_name
_, names = parse_sdl_name(fun_name)
self.current_class_name = self_wrap.name
args, c_call = self.make_wrapping_call(
call,
replace_arg_names=[T.Arg('self')],
replace_args=[self.SELF_HANDLE])
new_fun = T.FunctionDef(function_name(*names))
new_fun.returns = self.rename(call.return_type)
new_fun.args = args
# does the return type need to be wrapped
if new_fun.returns != call.return_type:
cast_to = new_fun.returns
if isinstance(new_fun.returns, T.Constant):
cast_to = T.Name(new_fun.returns.value)
c_call = T.Call(T.Attribute(cast_to, 'from_handle'), [c_call])
new_fun.body = [T.Return(c_call)]
self.add_docstring(new_fun, call, 2)
call.clear_kwargs()
if self.is_multi_output(new_fun, offset=1):
new_fun = self.rewrite_multi_output_function(new_fun, offset=1)
self_wrap.body.append(new_fun)
# we cannot automatically add a destructor because we do not know
# which object is owning what
# # try to find destructor and constructor functions
# for i, n in enumerate(names):
# arg_n = len(new_fun.args.args)
#
# # check if the function is named destroy + class_name
# if arg_n == 1 and n == 'destroy' and i + 2 == len(names) and names[i + 1] == self_wrap.name.lower():
# destructor = copy.deepcopy(new_fun)
# destructor.name = '__del__'
# self_wrap.body.append(destructor)
# break
#
# # sdl is not consistent with that one
# if n == 'free':
# destructor = copy.deepcopy(new_fun)
# destructor.name = '__del__'
# self_wrap.body.append(destructor)
self.wrapper_method_count[self.current_class_name] += 1
self.current_class_name = None
def generate_function_wrapper(self, call: BindCall):
fun_name = call.function_name
_, names = parse_sdl_name(fun_name)
args, c_call = self.make_wrapping_call(call)
new_name = function_name(*names)
if new_name not in self.new_names:
self.new_names.add(new_name)
else:
log.warning(
f'{new_name} already exist in this scope cannot rename {fun_name}'
)
new_name = fun_name
new_fun = T.FunctionDef(new_name)
new_fun.returns = self.rename(call.return_type)
new_fun.args = args
new_fun.body = [T.Return(c_call)]
self.add_docstring(new_fun, call, 1)
call.clear_kwargs()
if self.is_multi_output(new_fun, offset=0):
new_fun = self.rewrite_multi_output_function(new_fun, offset=0)
self.new_code.append((None, new_fun))
return
def process_bind_call(self, call: BindCall, parent):
"""Try to find the class this function belongs to"""
fun_name = call.function_name
# constructor
self_name = call.is_constructor()
if self_name and call.is_method() is None:
class_def: T.ClassDef = self.wrappers.get(self_name)
if class_def:
return self.generate_constructor(class_def, call)
return self.generate_function_wrapper(call)
# ---
self_name = call.is_method()
# not a method
if self_name is None:
self.generate_function_wrapper(call)
return parent
self_def = self.ctypes.get(self_name)
if not self_def:
log.debug(f'Method `{fun_name}` does not have c-class')
self.generate_function_wrapper(call)
return parent
# not a known class
if not match(self_def, 'ClassDef'):
self.generate_function_wrapper(call)
return parent
# Generate our new python class that will wrap the ctypes
self_wrap: T.ClassDef = self.wrappers.get(self_name)
if self_wrap is None and match(self_def, 'ClassDef'):
log.debug(
f'Method `{fun_name}` does not have wrapped class `{self_name}`'
)
return parent
self.generate_method(call, self_wrap)
return parent
handle_is_not_none = T.Assert(test=T.Compare(
left=T.Attribute(value=T.Name(id='self', ctx=T.Load()),
attr='handle',
ctx=T.Load()),
ops=[T.IsNot()],
comparators=[T.Constant(value=None, kind=None)]),
msg=None)
def is_multi_output(self, func: T.FunctionDef, offset):
expr = func.body[0]
if not match(expr, 'Expr', ('value', 'Constant')):
return False
expr: T.Constant = func.body[0].value
if not expr.docstring:
return False
# if doc string specify it returns an error
# or if function is known to return nothing
if (':return 0 on success, or -1' not in expr.value) and (match(
func.returns, 'Name') and func.returns.id != 'None'):
return False
if len(func.args.args[offset:]) == 0:
return False
count = 0
# multi output should group all the output at the end of the function call
previous_was_ptr = False
for arg in func.args.args[offset:]:
if match(arg.annotation, 'Call',
('func', 'Name')) and arg.annotation.func.id == 'POINTER':
count += 1
previous_was_ptr = True
elif previous_was_ptr:
return False
if count > 0:
log.debug(f'{func.name} has multiple outputs')
return True
return False
def rewrite_multi_output_function(self, func: T.FunctionDef, offset):
"""
Notes
-----
Outputs should be grouped at the end of the function to differentiate between an output and an
array input
"""
new_func = T.FunctionDef(func.name)
new_func.body = [func.body[0]]
arg_len = len(func.args.args[offset:])
if arg_len == 0:
return func
output_args = []
remaining_args = []
arg_type = dict()
# Filter output arguments
for i, arg in enumerate(func.args.args[offset:]):
if match(arg.annotation, 'Call',
('func', 'Name')) and arg.annotation.func.id == 'POINTER':
# Generate the result argument
var_type = arg.annotation.args[0]
new_func.body.append(
T.Assign([T.Name(arg.arg)], T.Call(var_type)))
output_args.append(arg)
arg_type[i] = 'O'
else:
remaining_args.append(arg)
arg_type[i] = 'I'
original_call: T.Call = func.body[1].value
for i in range(len(original_call.args[offset:])):
if arg_type[i] == 'O':
original_call.args[i + offset] = T.Call(
T.Name('byref'), [T.Name(func.args.args[i + offset].arg)])
new_func.body.append(T.Assign([T.Name('error')], original_call))
returns = [T.Name(arg.arg) for arg in output_args]
returns_types = [arg.annotation.args[0] for arg in output_args]
if len(returns) == 1:
new_func.body.append(T.Return(returns[0]))
new_func.returns = returns_types[0]
else:
new_func.body.append(T.Return(T.Tuple(returns)))
# new_func.returns = T.Call(T.Name('Tuple'), returns_types)
new_func.returns = T.Subscript(T.Name('Tuple'),
T.ExtSlice(dims=returns_types),
T.Load())
if offset == 1:
remaining_args = [T.Arg('self')] + remaining_args
new_func.args = T.Arguments(args=remaining_args)
return new_func
def struct_fields(self, expr: T.Assign):
ctype_name = expr.targets[0].value.id
assert ctype_name in self.ctypes_fields
def assign(self, expr: T.Assign, depth):
# <function> = _bind('c-function', [cargs], rtype, docstring=, arg_names=)
if BindCall.is_binding_call(expr.value):
expr = self.process_bind_call(BindCall(expr.value), expr)
# <c-type>._fields_ = []
elif match(expr.targets[0], 'Attribute') and match(
expr.value, 'List') and expr.targets[0].attr == '_fields_':
self.struct_fields(expr)
# <Name> = <Name>
elif match(expr.value, 'Name') and match(expr.targets[0], 'Name'):
alias_name = expr.targets[0].id
aliased_name = expr.value.id
aliased_ctype = self.ctypes.get(aliased_name)
aliased_wrapped = self.wrappers.get(aliased_name)
self.rename_types[aliased_name] = alias_name
self.ctypes[alias_name] = aliased_ctype
self.wrappers[alias_name] = aliased_wrapped
return expr
def expression(self, expr: T.Expr, depth):
values = self.dispatch(expr.value, depth)
if isinstance(values, (tuple, list)):
return [T.Expr(v) for v in values]
return T.Expr(values)
def generate(self, module: T.Module, depth=0):
new_module: T.Module = ast.Module()
new_module.body = []
self.preprocessor(module)
for expr in module.body:
self.dispatch(expr, depth + 1)
# insert our new bindings at the end
for k, v in self.new_code:
if isinstance(v, T.ClassDef):
if self.wrapper_method_count.get(v.name, 0) > 0:
self.post_process_class_defintion(v)
module.body.append(v)
elif v.name in self.wrappers_2_ctypes:
c_struct = self.wrappers_2_ctypes.get(v.name)
# make it an alias for the ctype
module.body.append(
T.Expr(T.Assign([T.Name(v.name)], T.Name(c_struct))))
else:
module.body.append(T.Expr(v))
return module
def dispatch(self, expr, depth) -> T.Expr:
handler = self.dispatcher.get(expr.__class__.__name__, None)
if handler is None:
print(expr)
assert False
return handler(expr, depth)
