Mercurial > lcfOS
view python/ppci/irutils.py @ 362:c05ab629976a
Added CPUID for arm
author | Windel Bouwman |
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date | Sat, 15 Mar 2014 10:56:34 +0100 |
parents | e84047f29c78 |
children | 988f3fb861e4 |
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""" Some utilities for ir-code. """ import re from . import ir def dumpgv(m, outf): print('digraph G ', file=outf) print('{', file=outf) for f in m.Functions: print('{} [label="{}" shape=box3d]'.format(id(f), f), file=outf) for bb in f.Blocks: contents = str(bb) + '\n' contents += '\n'.join([str(i) for i in bb.Instructions]) print('{0} [shape=note label="{1}"];' .format(id(bb), contents), file=outf) for successor in bb.Successors: print('"{}" -> "{}"'.format(id(bb), id(successor)), file=outf) print('"{}" -> "{}" [label="entry"]' .format(id(f), id(f.entry)), file=outf) print('}', file=outf) class Writer: def __init__(self, extra_indent=''): self.extra_indent = extra_indent def write(self, ir, f): """ Write ir-code to file f """ print('{}{}'.format(self.extra_indent, ir), file=f) for v in ir.Variables: print('{}{}'.format(self.extra_indent, v), file=f) for function in ir.Functions: self.write_function(function, f) def write_function(self, fn, f): args = ','.join('i32 ' + str(a) for a in fn.arguments) print('{}function i32 {}({})'.format(self.extra_indent, fn.name, args), file=f) for bb in fn.Blocks: print('{} {}'.format(self.extra_indent, bb), file=f) for ins in bb.Instructions: print('{} {}'.format(self.extra_indent, ins), file=f) class IrParseException(Exception): pass class Reader: def read(self, f): """ Read ir code from file f """ # Read lines from the file: lines = [line.rstrip() for line in f] # Create a regular expression for the lexing part: tok_spec = [ ('NUMBER', r'\d+'), ('ID', r'[A-Za-z][A-Za-z\d_]*'), ('SKIP2', r' '), ('SKIP1', r' '), ('OTHER', r'[\.,=:;\-+*\[\]/\(\)]|>|<|{|}|&|\^|\|') ] tok_re = '|'.join('(?P<%s>%s)' % pair for pair in tok_spec) gettok = re.compile(tok_re).match def tokenize(): for line in lines: if not line: continue # Skip empty lines mo = gettok(line) first = True while mo: typ = mo.lastgroup val = mo.group(typ) if typ == 'ID': if val in ['function', 'module']: typ = val yield (typ, val) elif typ == 'OTHER': typ = val yield (typ, val) elif typ in ['SKIP1', 'SKIP2']: if first: yield (typ, val) elif typ == 'NUMBER': yield (typ, int(val)) else: raise NotImplementedError(str(typ)) first = False pos = mo.end() mo = gettok(line, pos) if len(line) != pos: raise IrParseException('Lex fault') yield ('eol', 'eol') yield ('eof', 'eof') self.tokens = tokenize() self.token = self.tokens.__next__() try: module = self.parse_module() return module except IrParseException as e: print(e) def next_token(self): t = self.token if t[0] != 'eof': self.token = self.tokens.__next__() return t @property def Peak(self): return self.token[0] def Consume(self, typ): if self.Peak == typ: return self.next_token() else: raise IrParseException('Expected "{}" got "{}"'.format(typ, self.Peak)) def parse_module(self): """ Entry for recursive descent parser """ self.Consume('module') name = self.Consume('ID')[1] module = ir.Module(name) self.Consume('eol') while self.Peak != 'eof': if self.Peak == 'function': module.add_function(self.parse_function()) else: raise IrParseException('Expected function got {}'.format(self.Peak)) return module def parse_function(self): self.Consume('function') self.parse_type() name = self.Consume('ID')[1] function = ir.Function(name) self.Consume('(') while self.Peak != ')': self.parse_type() self.Consume('ID') if self.Peak != ',': break else: self.Consume(',') self.Consume(')') self.Consume('eol') while self.Peak == 'SKIP1': function.add_block(self.parse_block()) return function def parse_type(self): self.Consume('ID') def parse_block(self): self.Consume('SKIP1') name = self.Consume('ID')[1] block = ir.Block(name) self.Consume(':') self.Consume('eol') while self.Peak == 'SKIP2': self.parse_statement() return block def parse_statement(self): self.Consume('SKIP2') while self.Peak != 'eol': # raise NotImplementedError() self.next_token() self.Consume('eol') # Constructing IR: class NamedClassGenerator: def __init__(self, prefix, cls): self.prefix = prefix self.cls = cls def NumGen(): a = 0 while True: yield a a = a + 1 self.nums = NumGen() def gen(self, prefix=None): if not prefix: prefix = self.prefix return self.cls('{0}{1}'.format(prefix, self.nums.__next__())) class Builder: """ Base class for ir code generators """ def __init__(self): self.prepare() def prepare(self): self.newTemp = NamedClassGenerator('reg', ir.Temp).gen self.newBlock2 = NamedClassGenerator('block', ir.Block).gen self.bb = None self.m = None self.fn = None self.loc = None # Helpers: def setModule(self, m): self.m = m def newFunction(self, name): f = ir.Function(name) self.m.add_function(f) return f def newBlock(self): assert self.fn b = self.newBlock2() b.function = self.fn return b def setFunction(self, f): self.fn = f self.bb = f.entry if f else None def setBlock(self, b): self.bb = b def setLoc(self, l): self.loc = l def emit(self, i): assert isinstance(i, ir.Statement) i.debugLoc = self.loc if not self.bb: raise Exception('No basic block') self.bb.addInstruction(i) class Verifier: def verify(self, module): """ Verifies a module for some sanity """ assert isinstance(module, ir.Module) for f in module.Functions: self.verify_function(f) def verify_function(self, function): for b in function.Blocks: self.verify_block_termination(b) # Now we can build a dominator tree for b in function.Blocks: self.verify_block(b) def verify_block_termination(self, block): assert not block.Empty assert block.LastInstruction.IsTerminator for i in block.Instructions[:-1]: assert not isinstance(i, ir.LastStatement) def verify_block(self, block): for instruction in block.Instructions: self.verify_instruction(instruction) def verify_instruction(self, instruction): pass