creole/asm/creole.py

222 lines
5.8 KiB
Python

#!/usr/bin/python3
from enum import Enum
class MalformedArgument(Exception):
pass
def word_2c(w):
""" Negate a non-negative integer using two's compliment. """
return (~w + 1) & 0xFFFFFFFF
def ti(w):
""" Explicitly transform integer into two's compliment representation. """
return w if w >= 0 else word_wc(-w)
class ArgType(Enum):
""" Class denoting the type of an argument to an instruction. """
IMM = 1
""" Immediate values are ones that must be numbers (positive or negative). """
REG = 2
""" Type of registers. """
VAL = 3
""" Type that denotes either immediate values or registers. """
LAB = 4
""" Type of labels. """
def gettype(s):
""" Parses the type of the argument represented as a string
and returns a tuple with the first the first element being
the type and the second element being the integer value of
the argument.
"""
if s.isnumeric():
return (ArgType.IMM, int(s))
elif s[0] == "-" and s[1:].isnumeric():
return (ArgType.IMM, word_2c(int(s[1:])))
elif s[0] == 'r' and s[1:].isnumeric():
return (ArgType.REG, int(s[1:]))
elif s[0] == 'l' and s[1:].isnumeric():
return (ArgType.LAB, int(s[1:]))
else:
raise MalformedArgument(s)
def typecheck(self, s):
""" Parses the type of the string and returns it if it fits
the type of the enum value. """
t = ArgType.gettype(s)
if self == ArgType.VAL:
if t[0] == ArgType.REG or t[0] == ArgType.IMM:
return t
else:
return None
elif t[0] == self:
return t
else:
return None
class OpcodeException(Exception):
pass
class TypecheckLenException(Exception):
def __init__(self, opcode, insargs, argtypelen):
self.opcode = opcode
self.insargs = insargs
self.argtypelen = argtypelen
def __str__(self):
return f'arguments {insargs} to opcode {self.opcode} not length {self.argtypelen}'
class TypecheckException(Exception):
def __init__(self, argtype, sarg, i, opcode):
self.argtype = argtype
self.sarg = sarg
self.i = i
self.opcode = opcode
def __str__(self):
return f'opcode {self.opcode} has invalid value {self.sarg} (expected {self.argtype} in position {self.i}'
class Instruction(Enum):
""" Class of microcode instructions. The first number is the opcode
and the suceeding values are the types of each of the
arguments. """
NOP = 0
PUSH = 1, ArgType.VAL
POP = 2, ArgType.REG
ADD = 3, ArgType.VAL, ArgType.VAL, ArgType.VAL
MUL = 4, ArgType.VAL, ArgType.VAL, ArgType.VAL
DIV = 5, ArgType.VAL, ArgType.VAL, ArgType.VAL
JL = 6, ArgType.LAB, ArgType.VAL, ArgType.VAL
CLB = 7, ArgType.LAB
SYS = 8, ArgType.VAL
def __init__(self, opcode, *args):
if opcode > 0x7F or opcode < 0:
raise OpcodeException(opcode)
self.opcode = opcode
self.argtypes = args
def typecheck(self, sargs):
""" Pass arguments to the instruction and check if the
arguments are correct. """
rargs = []
if len(sargs) != len(self.argtypes):
raise TypecheckLenException(self.opcode, sargs,
len(self.argtypes))
for i in range(0, len(sargs)):
t = self.argtypes[i].typecheck(sargs[i])
if t is None:
raise TypecheckException(self.argtypes[i],
sargs[i],
i, self.opcode)
rargs.append(t)
return rargs
encoding_types = {
# start mask A B
2: (0x7F, 0xC0, 7),
3: (0xFFF, 0xE0, 12),
4: (0x1FFFF, 0xF0, 16),
5: (0x3FFFFF, 0xF8, 21),
6: (0x7FFFFFF, 0xFC, 26),
7: (0xFFFFFFFF, 0xFE, 36),
# A : number of bits in start byte
# B : Total number of bits excluding high bits
}
class InvalidNumberException(Exception):
pass
class InvalidLengthException(Exception):
pass
def encode_pseudo_utf8(n, high_bits, to):
if n < 0:
raise InvalidNumberException(n)
if to is None or to < 0:
for k in sorted(encoding_types):
if n <= encoding_types[k][0]:
to = k
break
if to is None:
raise InvalidNumberException(n)
if to > 8 or to < 0:
raise InvalidLengthException(to)
elif to == 1:
if n < 0x80:
return bytes([n])
else:
raise InvalidNumberException(n,to)
(maxval, start_byte, n_tot) = encoding_types[to]
if n > maxval or high_bits > 15:
raise InvalidNumberException(n, high_bits)
n = n | (high_bits << n_tot)
all_bytes = []
for i in range(0, to - 1):
all_bytes.append(0x80 | (n & 0x3F))
n >>= 6
all_bytes.append(start_byte | n)
return bytes(reversed(all_bytes))
class RangeCheckException(Exception):
pass
class Line:
def __init__(self, opcode, args):
self.opcode = opcode
self.args = args
def check_line(self, labnum, regnum):
for a in self.args:
if a[0] == ArgType.REG:
if a[1] < 0 or a[1] >= regnum:
raise RangeCheckException(a[0],
a[1],
regnum)
elif a[0] == ArgType.LAB:
if a[1] < 0 or a[1] >= labnum:
raise RangeCheckException(a[0],
a[1],
regnum)
def __call__(self):
b = bytes([self.opcode])
for a in self.args:
l = 2 if a[1] < 0x80 else None
if a[0] == ArgType.REG:
b = b + encode_pseudo_utf8(a[1],1,l)
else:
b = b + encode_pseudo_utf8(a[1],0,l)
return b + bytes([0])
class InstructionNotFoundException(Exception):
pass
class Program:
def asm_push_line(self, ins, args):
l = Line(ins, args)
l.check_line(self.labnum, self.regnum)
self.asm.append(l)
def parse_asm_line(self, line):
line = line.split()
line[0] = line[0].casefold()
try:
# TODO: is there no better way to do this in Python?
ins = getattr(Instruction, line[0].upper())
except Exception as e:
raise InstructionNotFoundException(line[0])
args_w_type = ins.typecheck(line[1:])
self.asm_push_line(ins.opcode, args_w_type)
def __call__(self):
b = bytes()
for line in self.asm:
b = b + line()
return b
def __init__(self, labnum=16, regnum=16):
self.asm = []
self.labnum = labnum
self.regnum = regnum