## @file # This file is used to parse and evaluate expression in directive or PCD value. # # Copyright (c) 2011 - 2018, Intel Corporation. All rights reserved.
# This program and the accompanying materials # are licensed and made available under the terms and conditions of the BSD License # which accompanies this distribution. The full text of the license may be found at # http://opensource.org/licenses/bsd-license.php # # THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, # WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. ## Import Modules # from Common.GlobalData import * from CommonDataClass.Exceptions import BadExpression from CommonDataClass.Exceptions import WrnExpression from Misc import GuidStringToGuidStructureString, ParseFieldValue import Common.EdkLogger as EdkLogger import copy ERR_STRING_EXPR = 'This operator cannot be used in string expression: [%s].' ERR_SNYTAX = 'Syntax error, the rest of expression cannot be evaluated: [%s].' ERR_MATCH = 'No matching right parenthesis.' ERR_STRING_TOKEN = 'Bad string token: [%s].' ERR_MACRO_TOKEN = 'Bad macro token: [%s].' ERR_EMPTY_TOKEN = 'Empty token is not allowed.' ERR_PCD_RESOLVE = 'PCD token cannot be resolved: [%s].' ERR_VALID_TOKEN = 'No more valid token found from rest of string: [%s].' ERR_EXPR_TYPE = 'Different types found in expression.' ERR_OPERATOR_UNSUPPORT = 'Unsupported operator: [%s]' ERR_REL_NOT_IN = 'Expect "IN" after "not" operator.' WRN_BOOL_EXPR = 'Operand of boolean type cannot be used in arithmetic expression.' WRN_EQCMP_STR_OTHERS = '== Comparison between Operand of string type and Boolean/Number Type always return False.' WRN_NECMP_STR_OTHERS = '!= Comparison between Operand of string type and Boolean/Number Type always return True.' ERR_RELCMP_STR_OTHERS = 'Operator taking Operand of string type and Boolean/Number Type is not allowed: [%s].' ERR_STRING_CMP = 'Unicode string and general string cannot be compared: [%s %s %s]' ERR_ARRAY_TOKEN = 'Bad C array or C format GUID token: [%s].' ERR_ARRAY_ELE = 'This must be HEX value for NList or Array: [%s].' ERR_EMPTY_EXPR = 'Empty expression is not allowed.' ERR_IN_OPERAND = 'Macro after IN operator can only be: $(FAMILY), $(ARCH), $(TOOL_CHAIN_TAG) and $(TARGET).' ## SplitString # Split string to list according double quote # For example: abc"de\"f"ghi"jkl"mn will be: ['abc', '"de\"f"', 'ghi', '"jkl"', 'mn'] # def SplitString(String): # There might be escaped quote: "abc\"def\\\"ghi" Str = String.replace('\\\\', '//').replace('\\\"', '\\\'') RetList = [] InQuote = False Item = '' for i, ch in enumerate(Str): if ch == '"': InQuote = not InQuote if not InQuote: Item += String[i] RetList.append(Item) Item = '' continue if Item: RetList.append(Item) Item = '' Item += String[i] if InQuote: raise BadExpression(ERR_STRING_TOKEN % Item) if Item: RetList.append(Item) return RetList ## ReplaceExprMacro # def ReplaceExprMacro(String, Macros, ExceptionList = None): StrList = SplitString(String) for i, String in enumerate(StrList): InQuote = False if String.startswith('"'): InQuote = True MacroStartPos = String.find('$(') if MacroStartPos < 0: for Pcd in gPlatformPcds.keys(): if Pcd in String: if Pcd not in gConditionalPcds: gConditionalPcds.append(Pcd) continue RetStr = '' while MacroStartPos >= 0: RetStr = String[0:MacroStartPos] MacroEndPos = String.find(')', MacroStartPos) if MacroEndPos < 0: raise BadExpression(ERR_MACRO_TOKEN % String[MacroStartPos:]) Macro = String[MacroStartPos+2:MacroEndPos] if Macro not in Macros: # From C reference manual: # If an undefined macro name appears in the constant-expression of # !if or !elif, it is replaced by the integer constant 0. RetStr += '0' elif not InQuote: Tklst = RetStr.split() if Tklst and Tklst[-1] in ['IN', 'in'] and ExceptionList and Macro not in ExceptionList: raise BadExpression(ERR_IN_OPERAND) # Make sure the macro in exception list is encapsulated by double quote # For example: DEFINE ARCH = IA32 X64 # $(ARCH) is replaced with "IA32 X64" if ExceptionList and Macro in ExceptionList: RetStr += '"' + Macros[Macro] + '"' elif Macros[Macro].strip(): RetStr += Macros[Macro] else: RetStr += '""' else: RetStr += Macros[Macro] RetStr += String[MacroEndPos+1:] String = RetStr MacroStartPos = String.find('$(') StrList[i] = RetStr return ''.join(StrList) # transfer int to string for in/not in expression def IntToStr(Value): StrList = [] while Value > 0: StrList.append(chr(Value & 0xff)) Value = Value >> 8 Value = '"' + ''.join(StrList) + '"' return Value SupportedInMacroList = ['TARGET', 'TOOL_CHAIN_TAG', 'ARCH', 'FAMILY'] class ValueExpression(object): # Logical operator mapping LogicalOperators = { '&&' : 'and', '||' : 'or', '!' : 'not', 'AND': 'and', 'OR' : 'or' , 'NOT': 'not', 'XOR': '^' , 'xor': '^', 'EQ' : '==' , 'NE' : '!=', 'GT' : '>' , 'LT' : '<', 'GE' : '>=' , 'LE' : '<=', 'IN' : 'in' } NonLetterOpLst = ['+', '-', '*', '/', '%', '&', '|', '^', '~', '<<', '>>', '!', '=', '>', '<', '?', ':'] PcdPattern = re.compile(r'[_a-zA-Z][0-9A-Za-z_]*\.[_a-zA-Z][0-9A-Za-z_]*$') HexPattern = re.compile(r'0[xX][0-9a-fA-F]+$') RegGuidPattern = re.compile(r'[0-9a-fA-F]{8}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{4}-[0-9a-fA-F]{12}') SymbolPattern = re.compile("(" "\$\([A-Z][A-Z0-9_]*\)|\$\(\w+\.\w+\)|\w+\.\w+|" "&&|\|\||!(?!=)|" "(?<=\W)AND(?=\W)|(?<=\W)OR(?=\W)|(?<=\W)NOT(?=\W)|(?<=\W)XOR(?=\W)|" "(?<=\W)EQ(?=\W)|(?<=\W)NE(?=\W)|(?<=\W)GT(?=\W)|(?<=\W)LT(?=\W)|(?<=\W)GE(?=\W)|(?<=\W)LE(?=\W)" ")") @staticmethod def Eval(Operator, Oprand1, Oprand2 = None): WrnExp = None if Operator not in ["in", "not in"] and (type(Oprand1) == type('') or type(Oprand2) == type('')): if type(Oprand1) == type(''): if Oprand1[0] in ['"', "'"] or Oprand1.startswith('L"') or Oprand1.startswith("L'")or Oprand1.startswith('UINT'): Oprand1, Size = ParseFieldValue(Oprand1) else: Oprand1,Size = ParseFieldValue('"' + Oprand1 + '"') if type(Oprand2) == type(''): if Oprand2[0] in ['"', "'"] or Oprand2.startswith('L"') or Oprand2.startswith("L'") or Oprand2.startswith('UINT'): Oprand2, Size = ParseFieldValue(Oprand2) else: Oprand2, Size = ParseFieldValue('"' + Oprand2 + '"') if type(Oprand1) == type('') or type(Oprand2) == type(''): raise BadExpression(ERR_STRING_EXPR % Operator) if Operator in ['in', 'not in']: if type(Oprand1) != type(''): Oprand1 = IntToStr(Oprand1) if type(Oprand2) != type(''): Oprand2 = IntToStr(Oprand2) TypeDict = { type(0) : 0, type(0L) : 0, type('') : 1, type(True) : 2 } EvalStr = '' if Operator in ["!", "NOT", "not"]: if type(Oprand1) == type(''): raise BadExpression(ERR_STRING_EXPR % Operator) EvalStr = 'not Oprand1' elif Operator in ["~"]: if type(Oprand1) == type(''): raise BadExpression(ERR_STRING_EXPR % Operator) EvalStr = '~ Oprand1' else: if Operator in ["+", "-"] and (type(True) in [type(Oprand1), type(Oprand2)]): # Boolean in '+'/'-' will be evaluated but raise warning WrnExp = WrnExpression(WRN_BOOL_EXPR) elif type('') in [type(Oprand1), type(Oprand2)] and type(Oprand1)!= type(Oprand2): # == between string and number/boolean will always return False, != return True if Operator == "==": WrnExp = WrnExpression(WRN_EQCMP_STR_OTHERS) WrnExp.result = False raise WrnExp elif Operator == "!=": WrnExp = WrnExpression(WRN_NECMP_STR_OTHERS) WrnExp.result = True raise WrnExp else: raise BadExpression(ERR_RELCMP_STR_OTHERS % Operator) elif TypeDict[type(Oprand1)] != TypeDict[type(Oprand2)]: if Operator in ["==", "!=", ">=", "<=", ">", "<"] and set((TypeDict[type(Oprand1)], TypeDict[type(Oprand2)])) == set((TypeDict[type(True)], TypeDict[type(0)])): # comparison between number and boolean is allowed pass elif Operator in ['&', '|', '^', "and", "or"] and set((TypeDict[type(Oprand1)], TypeDict[type(Oprand2)])) == set((TypeDict[type(True)], TypeDict[type(0)])): # bitwise and logical operation between number and boolean is allowed pass else: raise BadExpression(ERR_EXPR_TYPE) if type(Oprand1) == type('') and type(Oprand2) == type(''): if (Oprand1.startswith('L"') and not Oprand2.startswith('L"')) or \ (not Oprand1.startswith('L"') and Oprand2.startswith('L"')): raise BadExpression(ERR_STRING_CMP % (Oprand1, Operator, Oprand2)) if 'in' in Operator and type(Oprand2) == type(''): Oprand2 = Oprand2.split() EvalStr = 'Oprand1 ' + Operator + ' Oprand2' # Local symbols used by built in eval function Dict = { 'Oprand1' : Oprand1, 'Oprand2' : Oprand2 } try: Val = eval(EvalStr, {}, Dict) except Exception, Excpt: raise BadExpression(str(Excpt)) if Operator in ['and', 'or']: if Val: Val = True else: Val = False if WrnExp: WrnExp.result = Val raise WrnExp return Val def __init__(self, Expression, SymbolTable={}): self._NoProcess = False if type(Expression) != type(''): self._Expr = Expression self._NoProcess = True return self._Expr = ReplaceExprMacro(Expression.strip(), SymbolTable, SupportedInMacroList) if not self._Expr.strip(): raise BadExpression(ERR_EMPTY_EXPR) # # The symbol table including PCD and macro mapping # self._Symb = copy.deepcopy(SymbolTable) self._Symb.update(self.LogicalOperators) self._Idx = 0 self._Len = len(self._Expr) self._Token = '' self._WarnExcept = None # Literal token without any conversion self._LiteralToken = '' # Public entry for this class # @param RealValue: False: only evaluate if the expression is true or false, used for conditional expression # True : return the evaluated str(value), used for PCD value # # @return: True or False if RealValue is False # Evaluated value of string format if RealValue is True # def __call__(self, RealValue=False, Depth=0): if self._NoProcess: return self._Expr self._Depth = Depth self._Expr = self._Expr.strip() if RealValue and Depth == 0: self._Token = self._Expr if self.__IsNumberToken(): return self._Expr Token = '' try: Token = self._GetToken() except BadExpression: pass if type(Token) == type('') and Token.startswith('{') and Token.endswith('}') and self._Idx >= self._Len: if len(Token) != len(self._Expr.replace(' ', '')): raise BadExpression return self._Expr self._Idx = 0 self._Token = '' Val = self._ConExpr() RealVal = Val if type(Val) == type(''): if Val == 'L""': Val = False elif not Val: Val = False RealVal = '""' elif not Val.startswith('L"') and not Val.startswith('{') and not Val.startswith("L'"): Val = True RealVal = '"' + RealVal + '"' # The expression has been parsed, but the end of expression is not reached # It means the rest does not comply EBNF of if self._Idx != self._Len: raise BadExpression(ERR_SNYTAX % self._Expr[self._Idx:]) if RealValue: RetVal = str(RealVal) elif Val: RetVal = True else: RetVal = False if self._WarnExcept: self._WarnExcept.result = RetVal raise self._WarnExcept else: return RetVal # Template function to parse binary operators which have same precedence # Expr [Operator Expr]* def _ExprFuncTemplate(self, EvalFunc, OpLst): Val = EvalFunc() while self._IsOperator(OpLst): Op = self._Token if Op == '?': Val2 = EvalFunc() if self._IsOperator(':'): Val3 = EvalFunc() if Val: Val = Val2 else: Val = Val3 continue try: Val = self.Eval(Op, Val, EvalFunc()) except WrnExpression, Warn: self._WarnExcept = Warn Val = Warn.result return Val # A [? B]* def _ConExpr(self): return self._ExprFuncTemplate(self._OrExpr, ['?', ':']) # A [|| B]* def _OrExpr(self): return self._ExprFuncTemplate(self._AndExpr, ["OR", "or", "||"]) # A [&& B]* def _AndExpr(self): return self._ExprFuncTemplate(self._BitOr, ["AND", "and", "&&"]) # A [ | B]* def _BitOr(self): return self._ExprFuncTemplate(self._BitXor, ["|"]) # A [ ^ B]* def _BitXor(self): return self._ExprFuncTemplate(self._BitAnd, ["XOR", "xor", "^"]) # A [ & B]* def _BitAnd(self): return self._ExprFuncTemplate(self._EqExpr, ["&"]) # A [ == B]* def _EqExpr(self): Val = self._RelExpr() while self._IsOperator(["==", "!=", "EQ", "NE", "IN", "in", "!", "NOT", "not"]): Op = self._Token if Op in ["!", "NOT", "not"]: if not self._IsOperator(["IN", "in"]): raise BadExpression(ERR_REL_NOT_IN) Op += ' ' + self._Token try: Val = self.Eval(Op, Val, self._RelExpr()) except WrnExpression, Warn: self._WarnExcept = Warn Val = Warn.result return Val # A [ > B]* def _RelExpr(self): return self._ExprFuncTemplate(self._ShiftExpr, ["<=", ">=", "<", ">", "LE", "GE", "LT", "GT"]) def _ShiftExpr(self): return self._ExprFuncTemplate(self._AddExpr, ["<<", ">>"]) # A [ + B]* def _AddExpr(self): return self._ExprFuncTemplate(self._MulExpr, ["+", "-"]) # A [ * B]* def _MulExpr(self): return self._ExprFuncTemplate(self._UnaryExpr, ["*", "/", "%"]) # [!]*A def _UnaryExpr(self): if self._IsOperator(["!", "NOT", "not"]): Val = self._UnaryExpr() try: return self.Eval('not', Val) except WrnExpression, Warn: self._WarnExcept = Warn return Warn.result if self._IsOperator(["~"]): Val = self._UnaryExpr() try: return self.Eval('~', Val) except WrnExpression, Warn: self._WarnExcept = Warn return Warn.result return self._IdenExpr() # Parse identifier or encapsulated expression def _IdenExpr(self): Tk = self._GetToken() if Tk == '(': Val = self._ConExpr() try: # _GetToken may also raise BadExpression if self._GetToken() != ')': raise BadExpression(ERR_MATCH) except BadExpression: raise BadExpression(ERR_MATCH) return Val return Tk # Skip whitespace or tab def __SkipWS(self): for Char in self._Expr[self._Idx:]: if Char not in ' \t': break self._Idx += 1 # Try to convert string to number def __IsNumberToken(self): Radix = 10 if self._Token.lower()[0:2] == '0x' and len(self._Token) > 2: Radix = 16 if self._Token.startswith('"') or self._Token.startswith('L"'): Flag = 0 for Index in range(len(self._Token)): if self._Token[Index] in ['"']: Flag += 1 if Flag == 2 and self._Token.endswith('"'): self._Token = ParseFieldValue(self._Token)[0] return True if self._Token.startswith("'") or self._Token.startswith("L'"): Flag = 0 for Index in range(len(self._Token)): if self._Token[Index] in ["'"]: Flag += 1 if Flag == 2 and self._Token.endswith("'"): self._Token = ParseFieldValue(self._Token)[0] return True try: self._Token = int(self._Token, Radix) return True except ValueError: return False except TypeError: return False # Parse array: {...} def __GetArray(self): Token = '{' self._Idx += 1 self.__GetNList(True) Token += self._LiteralToken if self._Idx >= self._Len or self._Expr[self._Idx] != '}': raise BadExpression(ERR_ARRAY_TOKEN % Token) Token += '}' # All whitespace and tabs in array are already stripped. IsArray = IsGuid = False if len(Token.split(',')) == 11 and len(Token.split(',{')) == 2 \ and len(Token.split('},')) == 1: HexLen = [11,6,6,5,4,4,4,4,4,4,6] HexList= Token.split(',') if HexList[3].startswith('{') and \ not [Index for Index, Hex in enumerate(HexList) if len(Hex) > HexLen[Index]]: IsGuid = True if Token.lstrip('{').rstrip('}').find('{') == -1: if not [Hex for Hex in Token.lstrip('{').rstrip('}').split(',') if len(Hex) > 4]: IsArray = True if not IsArray and not IsGuid: raise BadExpression(ERR_ARRAY_TOKEN % Token) self._Idx += 1 self._Token = self._LiteralToken = Token return self._Token # Parse string, the format must be: "..." def __GetString(self): Idx = self._Idx # Skip left quote self._Idx += 1 # Replace escape \\\", \" Expr = self._Expr[self._Idx:].replace('\\\\', '//').replace('\\\"', '\\\'') for Ch in Expr: self._Idx += 1 if Ch == '"' or Ch == "'": break self._Token = self._LiteralToken = self._Expr[Idx:self._Idx] if self._Token.startswith('"') and not self._Token.endswith('"'): raise BadExpression(ERR_STRING_TOKEN % self._Token) if self._Token.startswith("'") and not self._Token.endswith("'"): raise BadExpression(ERR_STRING_TOKEN % self._Token) self._Token = self._Token[1:-1] return self._Token # Get token that is comprised by alphanumeric, underscore or dot(used by PCD) # @param IsAlphaOp: Indicate if parsing general token or script operator(EQ, NE...) def __GetIdToken(self, IsAlphaOp = False): IdToken = '' for Ch in self._Expr[self._Idx:]: if not self.__IsIdChar(Ch) or ('?' in self._Expr and Ch == ':'): break self._Idx += 1 IdToken += Ch self._Token = self._LiteralToken = IdToken if not IsAlphaOp: self.__ResolveToken() return self._Token # Try to resolve token def __ResolveToken(self): if not self._Token: raise BadExpression(ERR_EMPTY_TOKEN) # PCD token if self.PcdPattern.match(self._Token): if self._Token not in self._Symb: Ex = BadExpression(ERR_PCD_RESOLVE % self._Token) Ex.Pcd = self._Token raise Ex self._Token = ValueExpression(self._Symb[self._Token], self._Symb)(True, self._Depth+1) if type(self._Token) != type(''): self._LiteralToken = hex(self._Token) return if self._Token.startswith('"'): self._Token = self._Token[1:-1] elif self._Token in ["FALSE", "false", "False"]: self._Token = False elif self._Token in ["TRUE", "true", "True"]: self._Token = True else: self.__IsNumberToken() def __GetNList(self, InArray=False): self._GetSingleToken() if not self.__IsHexLiteral(): if InArray: raise BadExpression(ERR_ARRAY_ELE % self._Token) return self._Token self.__SkipWS() Expr = self._Expr[self._Idx:] if not Expr.startswith(','): return self._Token NList = self._LiteralToken while Expr.startswith(','): NList += ',' self._Idx += 1 self.__SkipWS() self._GetSingleToken() if not self.__IsHexLiteral(): raise BadExpression(ERR_ARRAY_ELE % self._Token) NList += self._LiteralToken self.__SkipWS() Expr = self._Expr[self._Idx:] self._Token = self._LiteralToken = NList return self._Token def __IsHexLiteral(self): if self._LiteralToken.startswith('{') and \ self._LiteralToken.endswith('}'): return True if self.HexPattern.match(self._LiteralToken): Token = self._LiteralToken[2:] if not Token: self._LiteralToken = '0x0' else: self._LiteralToken = '0x' + Token return True return False def _GetToken(self): return self.__GetNList() @staticmethod def __IsIdChar(Ch): return Ch in '._:' or Ch.isalnum() # Parse operand def _GetSingleToken(self): self.__SkipWS() Expr = self._Expr[self._Idx:] if Expr.startswith('L"'): # Skip L self._Idx += 1 UStr = self.__GetString() self._Token = 'L"' + UStr + '"' self._Token, Size = ParseFieldValue(self._Token) return self._Token elif Expr.startswith("L'"): # Skip L self._Idx += 1 UStr = self.__GetString() self._Token = "L'" + UStr + "'" self._Token, Size = ParseFieldValue(self._Token) return self._Token elif Expr.startswith('"'): UStr = self.__GetString() self._Token = '"' + UStr + '"' self._Token, Size = ParseFieldValue(self._Token) return self._Token elif Expr.startswith("'"): UStr = self.__GetString() self._Token = "'" + UStr + "'" self._Token, Size = ParseFieldValue(self._Token) return self._Token elif Expr.startswith('UINT'): Re = re.compile('(?:UINT8|UINT16|UINT32|UINT64)\((.+)\)') try: RetValue = Re.search(Expr).group(1) except: raise BadExpression('Invalid Expression %s' % Expr) Idx = self._Idx for Ch in Expr: self._Idx += 1 if Ch == '(': Prefix = self._Expr[Idx:self._Idx - 1] Idx = self._Idx if Ch == ')': TmpValue = self._Expr[Idx :self._Idx - 1] TmpValue = ValueExpression(TmpValue)(True) TmpValue = '0x%x' % int(TmpValue) if type(TmpValue) != type('') else TmpValue break self._Token, Size = ParseFieldValue(Prefix + '(' + TmpValue + ')') return self._Token self._Token = '' if Expr: Ch = Expr[0] Match = self.RegGuidPattern.match(Expr) if Match and not Expr[Match.end():Match.end()+1].isalnum() \ and Expr[Match.end():Match.end()+1] != '_': self._Idx += Match.end() self._Token = ValueExpression(GuidStringToGuidStructureString(Expr[0:Match.end()]))(True, self._Depth+1) return self._Token elif self.__IsIdChar(Ch): return self.__GetIdToken() elif Ch == '"': return self.__GetString() elif Ch == '{': return self.__GetArray() elif Ch == '(' or Ch == ')': self._Idx += 1 self._Token = Ch return self._Token raise BadExpression(ERR_VALID_TOKEN % Expr) # Parse operator def _GetOperator(self): self.__SkipWS() LegalOpLst = ['&&', '||', '!=', '==', '>=', '<='] + self.NonLetterOpLst + ['?',':'] self._Token = '' Expr = self._Expr[self._Idx:] # Reach end of expression if not Expr: return '' # Script operator: LT, GT, LE, GE, EQ, NE, and, or, xor, not if Expr[0].isalpha(): return self.__GetIdToken(True) # Start to get regular operator: +, -, <, > ... if Expr[0] not in self.NonLetterOpLst: return '' OpToken = '' for Ch in Expr: if Ch in self.NonLetterOpLst: if '!' == Ch and OpToken: break self._Idx += 1 OpToken += Ch else: break if OpToken not in LegalOpLst: raise BadExpression(ERR_OPERATOR_UNSUPPORT % OpToken) self._Token = OpToken return OpToken # Check if current token matches the operators given from OpList def _IsOperator(self, OpList): Idx = self._Idx self._GetOperator() if self._Token in OpList: if self._Token in self.LogicalOperators: self._Token = self.LogicalOperators[self._Token] return True self._Idx = Idx return False class ValueExpressionEx(ValueExpression): def __init__(self, PcdValue, PcdType, SymbolTable={}): ValueExpression.__init__(self, PcdValue, SymbolTable) self.PcdValue = PcdValue self.PcdType = PcdType def __call__(self, RealValue=False, Depth=0): PcdValue = self.PcdValue try: PcdValue = ValueExpression.__call__(self, RealValue, Depth) if self.PcdType == 'VOID*' and (PcdValue.startswith("'") or PcdValue.startswith("L'")): raise BadExpression elif self.PcdType in ['UINT8', 'UINT16', 'UINT32', 'UINT64', 'BOOLEAN'] and (PcdValue.startswith("'") or \ PcdValue.startswith('"') or PcdValue.startswith("L'") or PcdValue.startswith('L"') or PcdValue.startswith('{')): raise BadExpression except WrnExpression, Value: PcdValue = Value.result except BadExpression: if self.PcdType in ['UINT8', 'UINT16', 'UINT32', 'UINT64', 'BOOLEAN']: PcdValue = PcdValue.strip() if type(PcdValue) == type('') and PcdValue.startswith('{') and PcdValue.endswith('}'): PcdValue = PcdValue[1:-1].split(',') if type(PcdValue) == type([]): TmpValue = 0 Size = 0 for Item in PcdValue: if Item.startswith('UINT16'): ItemSize = 2 elif Item.startswith('UINT32'): ItemSize = 4 elif Item.startswith('UINT64'): ItemSize = 8 else: ItemSize = 0 Item = ValueExpressionEx(Item, self.PcdType, self._Symb)(True) if ItemSize == 0: ItemValue, ItemSize = ParseFieldValue(Item) else: ItemValue = ParseFieldValue(Item)[0] if type(ItemValue) == type(''): ItemValue = int(ItemValue, 16) if ItemValue.startswith('0x') else int(ItemValue) TmpValue = (ItemValue << (Size * 8)) | TmpValue Size = Size + ItemSize else: TmpValue, Size = ParseFieldValue(PcdValue) if type(TmpValue) == type(''): TmpValue = int(TmpValue) else: PcdValue = '0x%0{}X'.format(Size) % (TmpValue) if TmpValue < 0: raise BadExpression('Type %s PCD Value is negative' % self.PcdType) if self.PcdType == 'UINT8' and Size > 1: raise BadExpression('Type %s PCD Value Size is Larger than 1 byte' % self.PcdType) if self.PcdType == 'UINT16' and Size > 2: raise BadExpression('Type %s PCD Value Size is Larger than 2 byte' % self.PcdType) if self.PcdType == 'UINT32' and Size > 4: raise BadExpression('Type %s PCD Value Size is Larger than 4 byte' % self.PcdType) if self.PcdType == 'UINT64' and Size > 8: raise BadExpression('Type %s PCD Value Size is Larger than 8 byte' % self.PcdType) else: try: TmpValue = long(PcdValue) TmpList = [] if TmpValue.bit_length() == 0: PcdValue = '{0x00}' else: for I in range((TmpValue.bit_length() + 7) / 8): TmpList.append('0x%02x' % ((TmpValue >> I * 8) & 0xff)) PcdValue = '{' + ', '.join(TmpList) + '}' except: if PcdValue.strip().startswith('{'): PcdValue = PcdValue.strip()[1:-1].strip() Size = 0 ValueStr = '' TokenSpaceGuidName = '' if PcdValue.startswith('GUID') and PcdValue.endswith(')'): try: TokenSpaceGuidName = re.search('GUID\((\w+)\)', PcdValue).group(1) except: pass if TokenSpaceGuidName and TokenSpaceGuidName in self._Symb: PcdValue = 'GUID(' + self._Symb[TokenSpaceGuidName] + ')' elif TokenSpaceGuidName: raise BadExpression('%s not found in DEC file' % TokenSpaceGuidName) ListItem, Size = ParseFieldValue(PcdValue) elif PcdValue.startswith('DEVICE_PATH') and PcdValue.endswith(')'): ListItem, Size = ParseFieldValue(PcdValue) else: ListItem = PcdValue.split(',') if type(ListItem) == type(0) or type(ListItem) == type(0L): for Index in range(0, Size): ValueStr += '0x%02X' % (int(ListItem) & 255) ListItem >>= 8 ValueStr += ', ' PcdValue = '{' + ValueStr[:-2] + '}' elif type(ListItem) == type(''): if ListItem.startswith('{') and ListItem.endswith('}'): PcdValue = ListItem else: LabelDict = {} ReLabel = re.compile('LABEL\((\w+)\)') ReOffset = re.compile('OFFSET_OF\((\w+)\)') for Index, Item in enumerate(ListItem): # for LABEL parse Item = Item.strip() try: LabelList = ReLabel.findall(Item) for Label in LabelList: if Label not in LabelDict.keys(): LabelDict[Label] = str(Index) Item = ReLabel.sub('', Item) except: pass try: OffsetList = ReOffset.findall(Item) except: pass for Offset in OffsetList: if Offset in LabelDict.keys(): Re = re.compile('OFFSET_OF\(%s\)'% Offset) Item = Re.sub(LabelDict[Offset], Item) else: raise BadExpression('%s not defined before use' % Offset) ValueType = "" if Item.startswith('UINT16'): ItemSize = 1 ValueType = "UINT8" elif Item.startswith('UINT16'): ItemSize = 2 ValueType = "UINT16" elif Item.startswith('UINT32'): ItemSize = 4 elif Item.startswith('UINT64'): ItemSize = 8 else: ItemSize = 0 if ValueType: TmpValue = ValueExpressionEx(Item, ValueType, self._Symb)(True) else: TmpValue = ValueExpressionEx(Item, self.PcdType, self._Symb)(True) Item = '0x%x' % TmpValue if type(TmpValue) != type('') else TmpValue if ItemSize == 0: ItemValue, ItemSize = ParseFieldValue(Item) else: ItemValue = ParseFieldValue(Item)[0] for I in range(0, ItemSize): ValueStr += '0x%02X' % (int(ItemValue) & 255) ItemValue >>= 8 ValueStr += ', ' Size += ItemSize if Size > 0: PcdValue = '{' + ValueStr[:-2] + '}' if PcdValue == 'True': PcdValue = '1' if PcdValue == 'False': PcdValue = '0' if RealValue: return PcdValue if __name__ == '__main__': pass while True: input = raw_input('Input expr: ') if input in 'qQ': break try: print ValueExpression(input)(True) print ValueExpression(input)(False) except WrnExpression, Ex: print Ex.result print str(Ex) except Exception, Ex: print str(Ex)