''' This module contains helper classes for structure fields and length expressions. ''' class Field(object): ''' Represents a field of a structure. type is the datatype object for the field. field_type is the name of the type (string tuple) field_name is the name of the structure field. visible is true iff the field should be in the request API. wire is true iff the field should be in the request structure. auto is true iff the field is on the wire but not in the request API (e.g. opcode) enum is the enum name this field refers to, if any. ''' def __init__(self, type, field_type, field_name, visible, wire, auto, enum=None, isfd=False): self.type = type self.field_type = field_type self.field_name = field_name self.enum = enum self.visible = visible self.wire = wire self.auto = auto self.isfd = isfd self.parent = None def __str__(self): field_string = "Field" if self.field_name is None: if self.field_type is not None: field_string += " with type " + str(self.type) else: field_string += " \"" + self.field_name + "\"" if self.parent is not None: field_string += " in " + str(self.parent) return field_string class Expression(object): ''' Represents a mathematical expression for a list length or exprfield. Public fields: op is the operation (text +,*,/,<<,~) or None. lhs and rhs are the sub-Expressions if op is set. lenfield_name is the name of the length field, or None for request lists. lenfield is the Field object for the length field, or None. bitfield is True if the length field is a bitmask instead of a number. nmemb is the fixed size (value)of the expression, or None ''' def __init__(self, elt, parent): self.parent = parent self.nmemb = None self.lenfield_name = None self.lenfield_type = None self.lenfield_parent = None self.lenfield = None self.lenwire = False self.bitfield = False self.op = None self.lhs = None self.rhs = None self.contains_listelement_ref = False if elt.tag == 'list': # List going into a request, which has no length field (inferred by server) self.lenfield_name = elt.get('name') + '_len' self.lenfield_type = 'CARD32' elif elt.tag == 'fieldref': # Standard list with a fieldref self.lenfield_name = elt.text elif elt.tag == 'paramref': self.lenfield_name = elt.text self.lenfield_type = elt.get('type') elif elt.tag == 'op': # Op field. Need to recurse. self.op = elt.get('op') self.lhs = Expression(list(elt)[0], parent) self.rhs = Expression(list(elt)[1], parent) # Hopefully we don't have two separate length fields... self.lenfield_name = self.lhs.lenfield_name if self.lenfield_name == None: self.lenfield_name = self.rhs.lenfield_name elif elt.tag == 'unop': # Op field. Need to recurse. self.op = elt.get('op') self.rhs = Expression(list(elt)[0], parent) self.lenfield_name = self.rhs.lenfield_name elif elt.tag == 'value': # Constant expression self.nmemb = int(elt.text, 0) elif elt.tag == 'popcount': self.op = 'popcount' self.rhs = Expression(list(elt)[0], parent) self.lenfield_name = self.rhs.lenfield_name # xcb_popcount returns 'int' - handle the type in the language-specific part elif elt.tag == 'enumref': self.op = 'enumref' self.lenfield_name = (elt.get('ref'), elt.text) elif elt.tag == 'sumof': self.op = 'sumof' self.lenfield_name = elt.get('ref') subexpressions = list(elt) if len(subexpressions) > 0: # sumof with a nested expression which is to be evaluated # for each list-element in the context of that list-element. # sumof then returns the sum of the results of these evaluations self.rhs = Expression(subexpressions[0], parent) elif elt.tag == 'listelement-ref': # current list element inside iterating expressions such as sumof self.op = 'listelement-ref' self.contains_listelement_ref = True else: # Notreached raise Exception("undefined tag '%s'" % elt.tag) def fixed_size(self): return self.nmemb != None def get_value(self): return self.nmemb # if the value of the expression is a guaranteed multiple of a number # return this number, else return 1 (which is trivially guaranteed for integers) def get_multiple(self): multiple = 1 if self.op == '*': if self.lhs.fixed_size(): multiple *= self.lhs.get_value() if self.rhs.fixed_size(): multiple *= self.rhs.get_value() return multiple def recursive_resolve_tasks(self, module, parents): for subexpr in (self.lhs, self.rhs): if subexpr != None: subexpr.recursive_resolve_tasks(module, parents) self.contains_listelement_ref |= subexpr.contains_listelement_ref def resolve(self, module, parents): if self.op == 'enumref': self.lenfield_type = module.get_type(self.lenfield_name[0]) self.lenfield_name = self.lenfield_name[1] elif self.op == 'sumof': # need to find the field with lenfield_name for p in reversed(parents): fields = dict([(f.field_name, f) for f in p.fields]) if self.lenfield_name in fields.keys(): if p.is_case_or_bitcase: # switch is the anchestor self.lenfield_parent = p.parents[-1] else: self.lenfield_parent = p self.lenfield_type = fields[self.lenfield_name].field_type self.lenfield = fields[self.lenfield_name] break self.recursive_resolve_tasks(module, parents)