Mercurial > lcfOS
view python/asm.py @ 314:38f5f298ce0e
Add log for interference graph
| author | Windel Bouwman |
|---|---|
| date | Wed, 18 Dec 2013 20:22:20 +0100 |
| parents | be7f60545368 |
| children | 084cccaa5deb |
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#!/usr/bin/env python3 import re, argparse import pyyacc from ppci import Token, CompilerError, SourceLocation from target import Target, Label from asmnodes import ALabel, AInstruction, ABinop, AUnop, ASymbol, ANumber def tokenize(s): """ Tokenizer, generates an iterator that returns tokens! This GREAT example was taken from python re doc page! """ tok_spec = [ ('REAL', r'\d+\.\d+'), ('HEXNUMBER', r'0x[\da-fA-F]+'), ('NUMBER', r'\d+'), ('ID', r'[A-Za-z][A-Za-z\d_]*'), ('SKIP', r'[ \t]'), ('LEESTEKEN', r':=|[\.,=:\-+*\[\]/\(\)]|>=|<=|<>|>|<|}|{'), ('STRING', r"'.*?'"), ('COMMENT', r";.*") ] tok_re = '|'.join('(?P<%s>%s)' % pair for pair in tok_spec) gettok = re.compile(tok_re).match line = 1 pos = line_start = 0 mo = gettok(s) while mo is not None: typ = mo.lastgroup val = mo.group(typ) if typ == 'NEWLINE': line_start = pos line += 1 elif typ != 'SKIP': if typ == 'LEESTEKEN': typ = val elif typ == 'NUMBER': val = int(val) elif typ == 'HEXNUMBER': val = int(val[2:], 16) typ = 'NUMBER' elif typ == 'REAL': val = float(val) elif typ == 'STRING': val = val[1:-1] col = mo.start() - line_start loc = SourceLocation('', line, col, 0) # TODO retrieve length? yield Token(typ, val, loc) pos = mo.end() mo = gettok(s, pos) if pos != len(s): col = pos - line_start loc = SourceLocation('', line, col, 0) raise CompilerError('Unexpected character {0}'.format(s[pos]), loc) class Lexer: def __init__(self, src): self.tokens = tokenize(src) self.curTok = self.tokens.__next__() def eat(self): t = self.curTok self.curTok = self.tokens.__next__() return t @property def Peak(self): return self.curTok class Parser: def __init__(self): # Construct a parser given a grammar: ident = lambda x: x # Identity helper function g = pyyacc.Grammar(['ID', 'NUMBER', ',', '[', ']', ':', '+', '-', '*', pyyacc.EPS, 'COMMENT', '{', '}']) g.add_production('asmline', ['asmline2']) g.add_production('asmline', ['asmline2', 'COMMENT']) g.add_production('asmline2', ['label', 'instruction']) g.add_production('asmline2', ['instruction']) g.add_production('asmline2', ['label']) g.add_production('asmline2', []) g.add_production('optcomment', []) g.add_production('optcomment', ['COMMENT']) g.add_production('label', ['ID', ':'], self.p_label) g.add_production('instruction', ['opcode', 'operands'], self.p_ins_1) g.add_production('instruction', ['opcode'], self.p_ins_2) g.add_production('opcode', ['ID'], ident) g.add_production('operands', ['operand'], self.p_operands_1) g.add_production('operands', ['operands', ',', 'operand'], self.p_operands_2) g.add_production('operand', ['expression'], ident) g.add_production('operand', ['[', 'expression', ']'], self.p_mem_op) g.add_production('operand', ['{', 'listitems', '}'], self.p_list_op) g.add_production('listitems', ['expression'], self.p_listitems_1) g.add_production('listitems', ['listitems', ',', 'expression'], self.p_listitems_2) g.add_production('expression', ['term'], ident) g.add_production('expression', ['expression', 'addop', 'term'], self.p_binop) g.add_production('addop', ['-'], ident) g.add_production('addop', ['+'], ident) g.add_production('mulop', ['*'], ident) g.add_production('term', ['factor'], ident) g.add_production('term', ['term', 'mulop', 'factor'], self.p_binop) g.add_production('factor', ['ID'], lambda name: ASymbol(name)) g.add_production('factor', ['NUMBER'], lambda num: ANumber(int(num))) g.start_symbol = 'asmline' self.p = g.genParser() # Parser handlers: def p_ins_1(self, opc, ops): ins = AInstruction(opc, ops) self.emit(ins) def p_ins_2(self, opc): self.p_ins_1(opc, []) def p_operands_1(self, op1): return [op1] def p_operands_2(self, ops, comma, op2): assert type(ops) is list ops.append(op2) return ops def p_listitems_1(self, li1): return [li1] def p_listitems_2(self, lis, comma, li2): assert type(lis) is list lis.append(li2) return lis def p_list_op(self, brace_open, lst, brace_close): return AUnop('{}', lst) def p_mem_op(self, brace_open, exp, brace_close): return AUnop('[]', exp) def p_label(self, lname, cn): lab = ALabel(lname) self.emit(lab) def p_binop(self, exp1, op, exp2): return ABinop(op, exp1, exp2) def parse(self, tokens, emitter): self.emit = emitter self.p.parse(tokens) # Pre construct parser to save time: asmParser = Parser() class Assembler: def __init__(self, target=None, stream=None): self.target = target self.stream = stream self.restart() self.p = asmParser # Top level interface: def restart(self): self.stack = [] def emit(self, a): """ Emit a parsed instruction """ self.stack.append(a) def parse_line(self, line): """ Parse line into asm AST """ tokens = tokenize(line) self.p.parse(tokens, self.emit) def assemble(self, asmsrc): """ Assemble this source snippet """ for line in asmsrc.split('\n'): self.assemble_line(line) def assemble_line(self, line): """ Assemble a single source line. Do not take newlines into account """ self.parse_line(line) self.assemble_aast() def assemble_aast(self): """ Assemble a parsed asm line """ # TODO if not self.target: raise CompilerError('Cannot assemble without target') while self.stack: vi = self.stack.pop(0) if type(vi) is AInstruction: mi = self.target.mapInstruction(vi) elif type(vi) is ALabel: mi = Label(vi.name) else: raise NotImplementedError('{}'.format(vi)) if self.stream: self.stream.emit(mi) if __name__ == '__main__': # When run as main file, try to grab command line arguments: parser = argparse.ArgumentParser(description="Assembler") parser.add_argument('sourcefile', type=argparse.FileType('r'), help='the source file to assemble') args = parser.parse_args() a = Assembler() obj = a.assemble(args.sourcefile.read())