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'''Generate header file for nanopb from a ProtoBuf FileDescriptorSet.'''
import google.protobuf.descriptor_pb2 as descriptor
import nanopb_pb2
import os.path
# Values are tuple (c type, pb ltype)
FieldD = descriptor.FieldDescriptorProto
datatypes = {
FieldD.TYPE_BOOL: ('bool', 'PB_LTYPE_VARINT'),
FieldD.TYPE_DOUBLE: ('double', 'PB_LTYPE_FIXED64'),
FieldD.TYPE_FIXED32: ('uint32_t', 'PB_LTYPE_FIXED32'),
FieldD.TYPE_FIXED64: ('uint64_t', 'PB_LTYPE_FIXED64'),
FieldD.TYPE_FLOAT: ('float', 'PB_LTYPE_FIXED32'),
FieldD.TYPE_INT32: ('int32_t', 'PB_LTYPE_VARINT'),
FieldD.TYPE_INT64: ('int64_t', 'PB_LTYPE_VARINT'),
FieldD.TYPE_SFIXED32: ('int32_t', 'PB_LTYPE_FIXED32'),
FieldD.TYPE_SFIXED64: ('int64_t', 'PB_LTYPE_FIXED64'),
FieldD.TYPE_SINT32: ('int32_t', 'PB_LTYPE_SVARINT'),
FieldD.TYPE_SINT64: ('int64_t', 'PB_LTYPE_SVARINT'),
FieldD.TYPE_UINT32: ('uint32_t', 'PB_LTYPE_VARINT'),
FieldD.TYPE_UINT64: ('uint64_t', 'PB_LTYPE_VARINT')
}
class Names:
'''Keeps a set of nested names and formats them to C identifier.
You can subclass this with your own implementation.
'''
def __init__(self, parts = ()):
if isinstance(parts, Names):
parts = parts.parts
self.parts = tuple(parts)
def __str__(self):
return '_'.join(self.parts)
def __add__(self, other):
if isinstance(other, (str, unicode)):
return Names(self.parts + (other,))
elif isinstance(other, tuple):
return Names(self.parts + other)
else:
raise ValueError("Name parts should be of type str")
def names_from_type_name(type_name):
'''Parse Names() from FieldDescriptorProto type_name'''
if type_name[0] != '.':
raise NotImplementedError("Lookup of non-absolute type names is not supported")
return Names(type_name[1:].split('.'))
class Enum:
def __init__(self, names, desc):
'''desc is EnumDescriptorProto'''
self.names = names + desc.name
self.values = [(self.names + x.name, x.number) for x in desc.value]
def __str__(self):
result = 'typedef enum {\n'
result += ',\n'.join([" %s = %d" % x for x in self.values])
result += '\n} %s;' % self.names
return result
class Field:
def __init__(self, struct_name, desc):
'''desc is FieldDescriptorProto'''
self.tag = desc.number
self.struct_name = struct_name
self.name = desc.name
self.default = None
self.max_size = None
self.max_count = None
self.array_decl = ""
# Parse nanopb-specific field options
if desc.options.HasExtension(nanopb_pb2.nanopb):
ext = desc.options.Extensions[nanopb_pb2.nanopb]
if ext.HasField("max_size"):
self.max_size = ext.max_size
if ext.HasField("max_count"):
self.max_count = ext.max_count
if desc.HasField('default_value'):
self.default = desc.default_value
# Decide HTYPE
# HTYPE is the high-order nibble of nanopb field description,
# defining whether value is required/optional/repeated.
is_callback = False
if desc.label == FieldD.LABEL_REQUIRED:
self.htype = 'PB_HTYPE_REQUIRED'
elif desc.label == FieldD.LABEL_OPTIONAL:
self.htype = 'PB_HTYPE_OPTIONAL'
elif desc.label == FieldD.LABEL_REPEATED:
if self.max_count is None:
is_callback = True
else:
self.htype = 'PB_HTYPE_ARRAY'
self.array_decl = '[%d]' % self.max_count
else:
raise NotImplementedError(desc.label)
# Decide LTYPE and CTYPE
# LTYPE is the low-order nibble of nanopb field description,
# defining how to decode an individual value.
# CTYPE is the name of the c type to use in the struct.
if datatypes.has_key(desc.type):
self.ctype, self.ltype = datatypes[desc.type]
elif desc.type == FieldD.TYPE_ENUM:
self.ltype = 'PB_LTYPE_VARINT'
self.ctype = names_from_type_name(desc.type_name)
if self.default is not None:
self.default = self.ctype + self.default
elif desc.type == FieldD.TYPE_STRING:
self.ltype = 'PB_LTYPE_STRING'
if self.max_size is None:
is_callback = True
else:
self.ctype = 'char'
self.array_decl += '[%d]' % self.max_size
elif desc.type == FieldD.TYPE_BYTES:
self.ltype = 'PB_LTYPE_BYTES'
if self.max_size is None:
is_callback = True
else:
self.ctype = self.struct_name + self.name + 't'
elif desc.type == FieldD.TYPE_MESSAGE:
self.ltype = 'PB_LTYPE_SUBMESSAGE'
self.ctype = self.submsgname = names_from_type_name(desc.type_name)
else:
raise NotImplementedError(desc.type)
if is_callback:
self.htype = 'PB_HTYPE_CALLBACK'
self.ctype = 'pb_callback_t'
self.array_decl = ''
def __cmp__(self, other):
return cmp(self.tag, other.tag)
def __str__(self):
if self.htype == 'PB_HTYPE_OPTIONAL':
result = ' bool has_' + self.name + ';\n'
elif self.htype == 'PB_HTYPE_ARRAY':
result = ' size_t ' + self.name + '_count;\n'
else:
result = ''
result += ' %s %s%s;' % (self.ctype, self.name, self.array_decl)
return result
def types(self):
'''Return definitions for any special types this field might need.'''
if self.ltype == 'PB_LTYPE_BYTES' and self.max_size is not None:
result = 'typedef struct {\n'
result += ' size_t size;\n'
result += ' uint8_t bytes[%d];\n' % self.max_size
result += '} %s;\n' % self.ctype
else:
result = None
return result
def default_decl(self, declaration_only = False):
'''Return definition for this field's default value.'''
if self.default is None:
return None
if self.ltype == 'PB_LTYPE_STRING':
ctype = 'char'
if self.max_size is None:
return None # Not implemented
else:
array_decl = '[%d]' % (self.max_size + 1)
default = str(self.default).encode('string_escape')
default = default.replace('"', '\\"')
default = '"' + default + '"'
elif self.ltype == 'PB_LTYPE_BYTES':
data = self.default.decode('string_escape')
data = ['0x%02x' % ord(c) for c in data]
if self.max_size is None:
return None # Not implemented
else:
ctype = self.ctype
default = '{%d, {%s}}' % (len(data), ','.join(data))
array_decl = ''
else:
ctype, default = self.ctype, self.default
array_decl = ''
if declaration_only:
return 'extern const %s %s_default%s;' % (ctype, self.struct_name + self.name, array_decl)
else:
return 'const %s %s_default%s = %s;' % (ctype, self.struct_name + self.name, array_decl, default)
def pb_field_t(self, prev_field_name):
'''Return the pb_field_t initializer to use in the constant array.
prev_field_name is the name of the previous field or None.
'''
result = ' {%d, ' % self.tag
result += self.htype
if self.ltype is not None:
result += ' | ' + self.ltype
result += ',\n'
if prev_field_name is None:
result += ' offsetof(%s, %s),' % (self.struct_name, self.name)
else:
result += ' pb_delta_end(%s, %s, %s),' % (self.struct_name, self.name, prev_field_name)
if self.htype == 'PB_HTYPE_OPTIONAL':
result += '\n pb_delta(%s, has_%s, %s),' % (self.struct_name, self.name, self.name)
elif self.htype == 'PB_HTYPE_ARRAY':
result += '\n pb_delta(%s, %s_count, %s),' % (self.struct_name, self.name, self.name)
else:
result += ' 0,'
if self.htype == 'PB_HTYPE_ARRAY':
result += '\n pb_membersize(%s, %s[0]),' % (self.struct_name, self.name)
result += ('\n pb_membersize(%s, %s) / pb_membersize(%s, %s[0]),'
% (self.struct_name, self.name, self.struct_name, self.name))
else:
result += '\n pb_membersize(%s, %s),' % (self.struct_name, self.name)
result += ' 0,'
if self.ltype == 'PB_LTYPE_SUBMESSAGE':
result += '\n &%s_fields}' % self.submsgname
elif self.default is None or self.htype == 'PB_HTYPE_CALLBACK':
result += ' 0}'
else:
result += '\n &%s_default}' % (self.struct_name + self.name)
return result
class Message:
def __init__(self, names, desc):
self.name = names
self.fields = [Field(self.name, f) for f in desc.field]
self.ordered_fields = self.fields[:]
self.ordered_fields.sort()
def get_dependencies(self):
'''Get list of type names that this structure refers to.'''
return [str(field.ctype) for field in self.fields]
def __str__(self):
result = 'typedef struct {\n'
result += '\n'.join([str(f) for f in self.ordered_fields])
result += '\n} %s;' % self.name
return result
def types(self):
result = ""
for field in self.fields:
types = field.types()
if types is not None:
result += types + '\n'
return result
def default_decl(self, declaration_only = False):
result = ""
for field in self.fields:
default = field.default_decl(declaration_only)
if default is not None:
result += default + '\n'
return result
def fields_declaration(self):
result = 'extern const pb_field_t %s_fields[%d];' % (self.name, len(self.fields) + 1)
return result
def fields_definition(self):
result = 'const pb_field_t %s_fields[%d] = {\n' % (self.name, len(self.fields) + 1)
prev = None
for field in self.ordered_fields:
result += field.pb_field_t(prev)
result += ',\n\n'
prev = field.name
result += ' PB_LAST_FIELD\n};'
return result
def iterate_messages(desc, names = Names()):
'''Recursively find all messages. For each, yield name, DescriptorProto.'''
if hasattr(desc, 'message_type'):
submsgs = desc.message_type
else:
submsgs = desc.nested_type
for submsg in submsgs:
sub_names = names + submsg.name
yield sub_names, submsg
for x in iterate_messages(submsg, sub_names):
yield x
def parse_file(fdesc):
'''Takes a FileDescriptorProto and returns tuple (enum, messages).'''
enums = []
messages = []
if fdesc.package:
base_name = Names(fdesc.package.split('.'))
else:
base_name = Names()
for enum in fdesc.enum_type:
enums.append(Enum(base_name, enum))
for names, message in iterate_messages(fdesc, base_name):
messages.append(Message(names, message))
for enum in message.enum_type:
enums.append(Enum(names, enum))
return enums, messages
def toposort2(data):
'''Topological sort.
From http://code.activestate.com/recipes/577413-topological-sort/
This function is under the MIT license.
'''
for k, v in data.items():
v.discard(k) # Ignore self dependencies
extra_items_in_deps = reduce(set.union, data.values()) - set(data.keys())
data.update(dict([(item, set()) for item in extra_items_in_deps]))
while True:
ordered = set(item for item,dep in data.items() if not dep)
if not ordered:
break
for item in sorted(ordered):
yield item
data = dict([(item, (dep - ordered)) for item,dep in data.items()
if item not in ordered])
assert not data, "A cyclic dependency exists amongst %r" % data
def sort_dependencies(messages):
'''Sort a list of Messages based on dependencies.'''
dependencies = {}
message_by_name = {}
for message in messages:
dependencies[str(message.name)] = set(message.get_dependencies())
message_by_name[str(message.name)] = message
for msgname in toposort2(dependencies):
if msgname in message_by_name:
yield message_by_name[msgname]
def generate_header(headername, enums, messages):
'''Generate content for a header file.
Generates strings, which should be concatenated and stored to file.
'''
yield '/* Automatically generated nanopb header */\n'
symbol = headername.replace('.', '_').upper()
yield '#ifndef _PB_%s_\n' % symbol
yield '#define _PB_%s_\n' % symbol
yield '#include <pb.h>\n\n'
yield '/* Enum definitions */\n'
for enum in enums:
yield str(enum) + '\n\n'
yield '/* Struct definitions */\n'
for msg in sort_dependencies(messages):
yield msg.types()
yield str(msg) + '\n\n'
yield '/* Default values for struct fields */\n'
for msg in messages:
yield msg.default_decl(True)
yield '\n'
yield '/* Struct field encoding specification for nanopb */\n'
for msg in messages:
yield msg.fields_declaration() + '\n'
yield '\n#endif\n'
def generate_source(headername, enums, messages):
'''Generate content for a source file.'''
yield '/* Automatically generated nanopb constant definitions */\n'
yield '#include "%s"\n\n' % headername
for msg in messages:
yield msg.default_decl(False)
yield '\n\n'
for msg in messages:
yield msg.fields_definition() + '\n\n'
if __name__ == '__main__':
import sys
import os.path
if len(sys.argv) != 2:
print "Usage: " + sys.argv[0] + " file.pb"
print "where file.pb has been compiled from .proto by:"
print "protoc -ofile.pb file.proto"
print "Output fill be written to file.pb.h and file.pb.c"
sys.exit(1)
data = open(sys.argv[1], 'rb').read()
fdesc = descriptor.FileDescriptorSet.FromString(data)
enums, messages = parse_file(fdesc.file[0])
noext = os.path.splitext(sys.argv[1])[0]
headername = noext + '.pb.h'
sourcename = noext + '.pb.c'
headerbasename = os.path.basename(headername)
print "Writing to " + headername + " and " + sourcename
header = open(headername, 'w')
for part in generate_header(headerbasename, enums, messages):
header.write(part)
source = open(sourcename, 'w')
for part in generate_source(headerbasename, enums, messages):
source.write(part)
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