def test_from_sequence(self): self.assert_length_value( 8, b'\x01', BitString.from_sequence([1], BitString.from_byte)) self.assert_error( lambda: BitString.from_sequence([256], BitString.from_byte)) self.assert_length_value( 16, b'\x01\x02', BitString.from_sequence([1, 2], BitString.from_byte))
def test_from_sequence(self): self.assert_length_value(8, b'\x01', BitString.from_sequence([1], BitString.from_byte)) self.assert_error(lambda: BitString.from_sequence([256], BitString.from_byte)) self.assert_length_value(16, b'\x01\x02', BitString.from_sequence([1,2], BitString.from_byte))
def make_binary_parser(): ''' Create a parser for binary data. ''' # avoid import loops from lepl import Word, Letter, Digit, UnsignedInteger, \ Regexp, DfaRegexp, Drop, Separator, Delayed, Optional, Any, First, \ args, Trace, TraceVariables from lepl.bin.bits import BitString from lepl.support.node import Node classes = {} def named_class(name, *args): ''' Given a name and some args, create a sub-class of Binary and create an instance with the given content. ''' if name not in classes: classes[name] = type(name, (Node,), {}) return classes[name](*args) with TraceVariables(False): mult = lambda l, n: BitString.from_sequence([l] * int(n, 0)) # an attribute or class name name = Word(Letter(), Letter() | Digit() | '_') # lengths can be integers (bits) or floats (bytes.bits) # but if we have a float, we do not want to parse as an int # (or we will get a conversion error due to too small length) length = First(UnsignedInteger() + '.' + Optional(UnsignedInteger()), UnsignedInteger()) # a literal decimal decimal = UnsignedInteger() # a binary number (without pre/postfix) binary = Any('01')[1:] # an octal number (without pre/postfix) octal = Any('01234567')[1:] # a hex number (without pre/postfix) hex_ = Regexp('[a-fA-F0-9]')[1:] # the letters used for binary, octal and hex values #(eg the 'x' in 0xffee) # pylint: disable-msg=C0103 b, o, x, d = Any('bB'), Any('oO'), Any('xX'), Any('dD') # a decimal with optional pre/postfix dec = '0' + d + decimal | decimal + d + '0' | decimal # little-endian literals have normal prefix syntax (eg 0xffee) little = decimal | '0' + (b + binary | o + octal | x + hex_) # big-endian literals have postfix (eg ffeex0) big = (binary + b | octal + o | hex_ + x) + '0' # optional spaces - will be ignored # (use DFA here because it's multi-line, so \n will match ok) spaces = Drop(DfaRegexp('[ \t\n\r]*')) with Separator(spaces): # the grammar is recursive - expressions can contain expressions - # so we use a delayed matcher here as a placeholder, so that we can # use them before they are defined. expr = Delayed() # an implicit length value can be big or little-endian ivalue = big | little > args(BitString.from_int) # a value with a length can also be decimal lvalue = (big | little | dec) & Drop('/') & length \ > args(BitString.from_int) value = lvalue | ivalue repeat = value & Drop('*') & little > args(mult) # a named value is also a tuple named = name & Drop('=') & (expr | value | repeat) > tuple # an entry in the expression could be any of these entry = named | value | repeat | expr # and an expression itself consists of a comma-separated list of # one or more entries, surrounded by paremtheses entries = Drop('(') & entry[1:, Drop(',')] & Drop(')') # the Binary node may be explicit or implicit and takes the list of # entries as an argument list node = Optional(Drop('Node')) & entries > Node # alternatively, we can give a name and create a named sub-class other = name & entries > args(named_class) # and finally, we "tie the knot" by giving a definition for the # delayed matcher we introduced earlier, which is either a binary # node or a subclass expr += spaces & (node | other) & spaces #expr = Trace(expr) # this changes order, making 0800x0 parse as binary expr.config.no_compile_to_regexp() # use sequence to force regexp over multiple lines return expr.get_parse_sequence()
def make_binary_parser(): ''' Create a parser for binary data. ''' # avoid import loops from lepl import Word, Letter, Digit, UnsignedInteger, \ Regexp, DfaRegexp, Drop, Separator, Delayed, Optional, Any, First, \ args, Trace, TraceVariables from lepl.bin.bits import BitString from lepl.support.node import Node classes = {} def named_class(name, *args): ''' Given a name and some args, create a sub-class of Binary and create an instance with the given content. ''' if name not in classes: classes[name] = type(name, (Node, ), {}) return classes[name](*args) with TraceVariables(False): mult = lambda l, n: BitString.from_sequence([l] * int(n, 0)) # an attribute or class name name = Word(Letter(), Letter() | Digit() | '_') # lengths can be integers (bits) or floats (bytes.bits) # but if we have a float, we do not want to parse as an int # (or we will get a conversion error due to too small length) length = First( UnsignedInteger() + '.' + Optional(UnsignedInteger()), UnsignedInteger()) # a literal decimal decimal = UnsignedInteger() # a binary number (without pre/postfix) binary = Any('01')[1:] # an octal number (without pre/postfix) octal = Any('01234567')[1:] # a hex number (without pre/postfix) hex_ = Regexp('[a-fA-F0-9]')[1:] # the letters used for binary, octal and hex values #(eg the 'x' in 0xffee) # pylint: disable-msg=C0103 b, o, x, d = Any('bB'), Any('oO'), Any('xX'), Any('dD') # a decimal with optional pre/postfix dec = '0' + d + decimal | decimal + d + '0' | decimal # little-endian literals have normal prefix syntax (eg 0xffee) little = decimal | '0' + (b + binary | o + octal | x + hex_) # big-endian literals have postfix (eg ffeex0) big = (binary + b | octal + o | hex_ + x) + '0' # optional spaces - will be ignored # (use DFA here because it's multi-line, so \n will match ok) spaces = Drop(DfaRegexp('[ \t\n\r]*')) with Separator(spaces): # the grammar is recursive - expressions can contain expressions - # so we use a delayed matcher here as a placeholder, so that we can # use them before they are defined. expr = Delayed() # an implicit length value can be big or little-endian ivalue = big | little > args(BitString.from_int) # a value with a length can also be decimal lvalue = (big | little | dec) & Drop('/') & length \ > args(BitString.from_int) value = lvalue | ivalue repeat = value & Drop('*') & little > args(mult) # a named value is also a tuple named = name & Drop('=') & (expr | value | repeat) > tuple # an entry in the expression could be any of these entry = named | value | repeat | expr # and an expression itself consists of a comma-separated list of # one or more entries, surrounded by paremtheses entries = Drop('(') & entry[1:, Drop(',')] & Drop(')') # the Binary node may be explicit or implicit and takes the list of # entries as an argument list node = Optional(Drop('Node')) & entries > Node # alternatively, we can give a name and create a named sub-class other = name & entries > args(named_class) # and finally, we "tie the knot" by giving a definition for the # delayed matcher we introduced earlier, which is either a binary # node or a subclass expr += spaces & (node | other) & spaces #expr = Trace(expr) # this changes order, making 0800x0 parse as binary expr.config.no_compile_to_regexp() # use sequence to force regexp over multiple lines return expr.get_parse_sequence()