Mercurial > lcfOS
view python/ppci/c3/codegenerator.py @ 333:dcae6574c974
Increment to qt5
author | Windel Bouwman |
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date | Sun, 09 Feb 2014 15:27:57 +0100 |
parents | 56e6ff84f646 |
children | 6f4753202b9a |
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import logging from .. import ir from .. import irutils from . import astnodes as ast class SemanticError(Exception): """ Error thrown when a semantic issue is observed """ def __init__(self, msg, loc): super().__init__() self.msg = msg self.loc = loc class CodeGenerator(irutils.Builder): """ Generates intermediate (IR) code from a package. The entry function is 'genModule'. The main task of this part is to rewrite complex control structures, such as while and for loops into simple conditional jump statements. Also complex conditional statements are simplified. Such as 'and' and 'or' statements are rewritten in conditional jumps. And structured datatypes are rewritten. Type checking is done in one run with code generation. """ def __init__(self, diag): self.logger = logging.getLogger('c3cgen') self.diag = diag def gencode(self, pkg): """ Generate code for a single module """ self.prepare() assert type(pkg) is ast.Package self.pkg = pkg self.intType = pkg.scope['int'] self.boolType = pkg.scope['bool'] self.logger.info('Generating ir-code for {}'.format(pkg.name), extra={'c3_ast':pkg}) self.varMap = {} # Maps variables to storage locations. self.funcMap = {} self.m = ir.Module(pkg.name) try: for s in pkg.innerScope.Functions: f = self.newFunction(s.name) self.funcMap[s] = f for v in pkg.innerScope.Variables: self.varMap[v] = self.newTemp() for s in pkg.innerScope.Functions: self.gen_function(s) except SemanticError as e: self.error(e.msg, e.loc) if self.pkg.ok: return self.m def error(self, msg, loc=None): self.pkg.ok = False self.diag.error(msg, loc) def gen_function(self, fn): # TODO: handle arguments f = self.funcMap[fn] f.return_value = self.newTemp() self.setFunction(f) l2 = self.newBlock() self.emit(ir.Jump(l2)) self.setBlock(l2) # generate room for locals: for sym in fn.innerScope: self.the_type(sym.typ) if sym.isParameter: p = ir.Parameter(sym.name) variable = ir.LocalVariable(sym.name + '_copy') f.addParameter(p) f.addLocal(variable) # Move parameter into local copy: self.emit(ir.Move(ir.Mem(variable), p)) elif sym.isLocal: variable = ir.LocalVariable(sym.name) f.addLocal(variable) elif isinstance(sym, ast.Variable): variable = ir.LocalVariable(sym.name) f.addLocal(variable) else: raise NotImplementedError('{}'.format(sym)) self.varMap[sym] = variable self.genCode(fn.body) self.emit(ir.Move(f.return_value, ir.Const(0))) self.emit(ir.Jump(f.epiloog)) self.setFunction(None) def genCode(self, code): """ Wrapper around gen_stmt to catch errors """ try: self.gen_stmt(code) except SemanticError as e: self.error(e.msg, e.loc) def gen_stmt(self, code): """ Generate code for a statement """ assert isinstance(code, ast.Statement) self.setLoc(code.loc) if type(code) is ast.Compound: for s in code.statements: self.genCode(s) elif type(code) is ast.Empty: pass elif type(code) is ast.Assignment: lval = self.genExprCode(code.lval) rval = self.genExprCode(code.rval) if not self.equalTypes(code.lval.typ, code.rval.typ): msg = 'Cannot assign {} to {}'.format(code.rval.typ, code.lval.typ) raise SemanticError(msg, code.loc) if not code.lval.lvalue: raise SemanticError('No valid lvalue {}'.format(code.lval), code.lval.loc) self.emit(ir.Move(lval, rval)) elif type(code) is ast.ExpressionStatement: self.emit(ir.Exp(self.genExprCode(code.ex))) elif type(code) is ast.If: bbtrue = self.newBlock() bbfalse = self.newBlock() te = self.newBlock() self.gen_cond_code(code.condition, bbtrue, bbfalse) self.setBlock(bbtrue) self.genCode(code.truestatement) self.emit(ir.Jump(te)) self.setBlock(bbfalse) self.genCode(code.falsestatement) self.emit(ir.Jump(te)) self.setBlock(te) elif type(code) is ast.Return: re = self.genExprCode(code.expr) self.emit(ir.Move(self.fn.return_value, re)) self.emit(ir.Jump(self.fn.epiloog)) b = self.newBlock() self.setBlock(b) elif type(code) is ast.While: bbdo = self.newBlock() bbtest = self.newBlock() te = self.newBlock() self.emit(ir.Jump(bbtest)) self.setBlock(bbtest) self.gen_cond_code(code.condition, bbdo, te) self.setBlock(bbdo) self.genCode(code.statement) self.emit(ir.Jump(bbtest)) self.setBlock(te) elif type(code) is ast.For: bbdo = self.newBlock() bbtest = self.newBlock() te = self.newBlock() self.genCode(code.init) self.emit(ir.Jump(bbtest)) self.setBlock(bbtest) self.gen_cond_code(code.condition, bbdo, te) self.setBlock(bbdo) self.genCode(code.statement) self.emit(ir.Jump(bbtest)) self.setBlock(te) else: raise NotImplementedError('Unknown stmt {}'.format(code)) def gen_cond_code(self, expr, bbtrue, bbfalse): """ Generate conditional logic. Implement sequential logical operators. """ if type(expr) is ast.Binop: if expr.op == 'or': l2 = self.newBlock() self.gen_cond_code(expr.a, bbtrue, l2) if not self.equalTypes(expr.a.typ, self.boolType): raise SemanticError('Must be boolean', expr.a.loc) self.setBlock(l2) self.gen_cond_code(expr.b, bbtrue, bbfalse) if not self.equalTypes(expr.b.typ, self.boolType): raise SemanticError('Must be boolean', expr.b.loc) elif expr.op == 'and': l2 = self.newBlock() self.gen_cond_code(expr.a, l2, bbfalse) if not self.equalTypes(expr.a.typ, self.boolType): self.error('Must be boolean', expr.a.loc) self.setBlock(l2) self.gen_cond_code(expr.b, bbtrue, bbfalse) if not self.equalTypes(expr.b.typ, self.boolType): raise SemanticError('Must be boolean', expr.b.loc) elif expr.op in ['==', '>', '<', '!=', '<=', '>=']: ta = self.genExprCode(expr.a) tb = self.genExprCode(expr.b) if not self.equalTypes(expr.a.typ, expr.b.typ): raise SemanticError('Types unequal {} != {}' .format(expr.a.typ, expr.b.typ), expr.loc) self.emit(ir.CJump(ta, expr.op, tb, bbtrue, bbfalse)) else: raise SemanticError('non-bool: {}'.format(expr.op), expr.loc) expr.typ = self.boolType elif type(expr) is ast.Literal: self.genExprCode(expr) if expr.val: self.emit(ir.Jump(bbtrue)) else: self.emit(ir.Jump(bbfalse)) else: raise NotImplementedError('Unknown cond {}'.format(expr)) if not self.equalTypes(expr.typ, self.boolType): self.error('Condition must be boolean', expr.loc) def genExprCode(self, expr): """ Generate code for an expression. Return the generated ir-value """ assert isinstance(expr, ast.Expression) if type(expr) is ast.Binop: expr.lvalue = False if expr.op in ['+', '-', '*', '/', '<<', '>>', '|', '&']: ra = self.genExprCode(expr.a) rb = self.genExprCode(expr.b) if self.equalTypes(expr.a.typ, self.intType) and \ self.equalTypes(expr.b.typ, self.intType): expr.typ = expr.a.typ else: raise SemanticError('Can only add integers', expr.loc) else: raise NotImplementedError("Cannot use equality as expressions") return ir.Binop(ra, expr.op, rb) elif type(expr) is ast.Unop: if expr.op == '&': ra = self.genExprCode(expr.a) expr.typ = ast.PointerType(expr.a.typ) if not expr.a.lvalue: raise SemanticError('No valid lvalue', expr.a.loc) expr.lvalue = False assert type(ra) is ir.Mem return ra.e else: raise NotImplementedError('Unknown unop {0}'.format(expr.op)) elif type(expr) is ast.Identifier: # Generate code for this identifier. tg = self.resolveSymbol(expr) expr.kind = type(tg) expr.typ = tg.typ # This returns the dereferenced variable. if isinstance(tg, ast.Variable): expr.lvalue = True return ir.Mem(self.varMap[tg]) elif isinstance(tg, ast.Constant): c_val = self.genExprCode(tg.value) return self.evalConst(c_val) else: raise NotImplementedError(str(tg)) elif type(expr) is ast.Deref: # dereference pointer type: addr = self.genExprCode(expr.ptr) ptr_typ = self.the_type(expr.ptr.typ) expr.lvalue = True if type(ptr_typ) is ast.PointerType: expr.typ = ptr_typ.ptype return ir.Mem(addr) else: raise SemanticError('Cannot deref non-pointer', expr.loc) elif type(expr) is ast.Member: base = self.genExprCode(expr.base) expr.lvalue = expr.base.lvalue basetype = self.the_type(expr.base.typ) if type(basetype) is ast.StructureType: if basetype.hasField(expr.field): expr.typ = basetype.fieldType(expr.field) else: raise SemanticError('{} does not contain field {}' .format(basetype, expr.field), expr.loc) else: raise SemanticError('Cannot select {} of non-structure type {}' .format(expr.field, basetype), expr.loc) assert type(base) is ir.Mem, type(base) bt = self.the_type(expr.base.typ) offset = ir.Const(bt.fieldOffset(expr.field)) return ir.Mem(ir.Add(base.e, offset)) elif type(expr) is ast.Literal: expr.lvalue = False typemap = {int: 'int', float: 'double', bool: 'bool', str:'string'} if type(expr.val) in typemap: expr.typ = self.pkg.scope[typemap[type(expr.val)]] else: raise SemanticError('Unknown literal type {}'.format(expr.val), expr.loc) return ir.Const(expr.val) elif type(expr) is ast.TypeCast: return self.gen_type_cast(expr) elif type(expr) is ast.FunctionCall: return self.gen_function_call(expr) else: raise NotImplementedError('Unknown expr {}'.format(expr)) def gen_type_cast(self, expr): """ Generate code for type casting """ ar = self.genExprCode(expr.a) from_type = self.the_type(expr.a.typ) to_type = self.the_type(expr.to_type) if isinstance(from_type, ast.PointerType) and isinstance(to_type, ast.PointerType): expr.typ = expr.to_type return ar elif type(from_type) is ast.BaseType and from_type.name == 'int' and \ isinstance(to_type, ast.PointerType): expr.typ = expr.to_type return ar else: raise SemanticError('Cannot cast {} to {}' .format(from_type, to_type), expr.loc) def gen_function_call(self, expr): """ Generate code for a function call """ # Evaluate the arguments: args = [self.genExprCode(e) for e in expr.args] # Check arguments: tg = self.resolveSymbol(expr.proc) if type(tg) is not ast.Function: raise SemanticError('cannot call {}'.format(tg)) ftyp = tg.typ fname = tg.name ptypes = ftyp.parametertypes if len(expr.args) != len(ptypes): raise SemanticError('{} requires {} arguments, {} given' .format(fname, len(ptypes), len(expr.args)), expr.loc) for arg, at in zip(expr.args, ptypes): if not self.equalTypes(arg.typ, at): raise SemanticError('Got {}, expected {}' .format(arg.typ, at), arg.loc) # determine return type: expr.typ = ftyp.returntype return ir.Call(fname, args) def evalConst(self, c): if isinstance(c, ir.Const): return c else: raise SemanticError('Cannot evaluate constant {}'.format(c)) def resolveSymbol(self, sym): if type(sym) is ast.Member: base = self.resolveSymbol(sym.base) if type(base) is not ast.Package: raise SemanticError('Base is not a package', sym.loc) scope = base.innerScope name = sym.field elif type(sym) is ast.Identifier: scope = sym.scope name = sym.target else: raise NotImplementedError(str(sym)) if name in scope: s = scope[name] else: raise SemanticError('{} undefined'.format(name), sym.loc) assert isinstance(s, ast.Symbol) return s def size_of(self, t): """ Determine the byte size of a type """ t = self.the_type(t) if type(t) is ast.BaseType: return t.bytesize elif type(t) is ast.StructureType: return sum(self.size_of(mem.typ) for mem in t.mems) else: raise NotImplementedError(str(t)) def the_type(self, t): """ Recurse until a 'real' type is found """ if type(t) is ast.DefinedType: t = self.the_type(t.typ) elif type(t) in [ast.Identifier, ast.Member]: t = self.the_type(self.resolveSymbol(t)) elif type(t) is ast.StructureType: # Setup offsets of fields. Is this the right place?: offset = 0 for mem in t.mems: mem.offset = offset offset = offset + self.size_of(mem.typ) elif isinstance(t, ast.Type): pass else: raise NotImplementedError(str(t)) assert isinstance(t, ast.Type) return t def equalTypes(self, a, b): """ Compare types a and b for structural equavalence. """ # Recurse into named types: a = self.the_type(a) b = self.the_type(b) if type(a) is type(b): if type(a) is ast.BaseType: return a.name == b.name elif type(a) is ast.PointerType: return self.equalTypes(a.ptype, b.ptype) elif type(a) is ast.StructureType: if len(a.mems) != len(b.mems): return False return all(self.equalTypes(am.typ, bm.typ) for am, bm in zip(a.mems, b.mems)) else: raise NotImplementedError('{} not implemented'.format(type(a))) return False