def __init__(self):
     self._entry = None
     self._exit = None
     self._blocks = CustomVector()
     self._numBlockID = -1
     self._indirectGotoBlock = None  # special block to contain collective
     # dispatch for indirect gotos
     self._syntheticDeclStmts = []
    def __init__(self):
        self._succ = None
        self._block = None
        self._badCFG = False
        self._cfg = CFG()
        self._sv = CustomVector()
        # For stmt
        self._breakJumpTarget = BlockScopePosPair()
        self._continueJumpTarget = None
        self._saveBreak = CustomVector()
        self._saveBlock = CustomVector()
        self._saveSucc = CustomVector()
        self._saveContinue = CustomVector()
        # switch stmt
        self._defaultCaseBlock = None
        self._switchTerminatedBlock = None
        self._switchExclusivelyCovered = None
        self._switchCond = None
        # labels
        self._labels = {}
        self._backPatchBlocks = CustomVector()
        self._addressTakenLabels = CustomVector()

        # for graph
        self.graph = GraphBuilder()
        self.curNode = -1
Exemplo n.º 3
0
    def __init__(self, blockID, C, CFGparent):
        # Set of statements in the basic block, list of CFGElement
        self._elements = C

        # TODO: label = stmt()
        self._label = None

        # The terminator for a basic block that indicates the type of control-flow
        # that accours between a bloack and its successors.
        self._terminator = None

        # LoopTarget- some blocks are used to represent the "loop edge" to the start
        # of a loop from within the loop body. This stmt will be refer to the loop stmt
        # for such blocks (and be null otherwise)
        self._loopTarget = None

        self._blockID = blockID

        # Predecessors/Sucessors - Keep track of the predecessor / sucessor CFG Blocks
        self._preds = CustomVector()
        self._succs = CustomVector()

        # This shit makes no sense
        # self._preds.push_back(C)
        # self._succs.push_back(C)

        # NoReturn - this bit is set when basic block contains a function call
        # that is attributed as 'noreturn'. In that case, control cannot technically
        # ever proceed past this block. All such blocks will have a immediate successor:
        # the exit block. This allows them to be easily reached from the exit block and
        # using this bit quickly recognized without scanning the contents of the block
        self._hasNoReturnElement = False

        # Parent CFG that owns the CFGBlock
        self._parent = CFGparent

        # Control do stmt
        self._doBodyBlock = False
    def createBlock(self):
        """Creates a new block in the CFG. The CFG owns the block.
		Returns
		-------
		:obj: `CFGBlock`
		"""
        first_block = False
        if not (self.front) and not (self.back):
            first_block = True
        # Create a new block
        self._numBlockID += 1
        # Instantiate the elements of the block
        elements = CustomVector()
        B = CFGBlock(self._numBlockID, elements, self)
        # Insert the block
        self._blocks.push_back(B)
        if (first_block):
            self._entry = self._exit = B
        return self._blocks.back()
Exemplo n.º 5
0
]
adjoint_snapshots = [
    CustomVecHandle('%s/adjoint_snap%d.pkl' % (out_dir, i), scale=np.pi)
    for i in mr.range(10)
]

# Create random snapshot data
nx = 50
ny = 30
nz = 20
x = np.linspace(0, 1, nx)
y = np.logspace(1, 2, ny)
z = np.linspace(0, 1, nz)**2
if parallel.is_rank_zero():
    for snap in direct_snapshots + adjoint_snapshots:
        snap.put(CustomVector([x, y, z], np.random.random((nx, ny, nz))))
parallel.barrier()

# Compute and save balanced POD modes
my_BPOD = mr.BPODHandles(inner_product)
my_BPOD.sanity_check(direct_snapshots[0])
sing_vals, L_sing_vecs, R_sing_vecs = my_BPOD.compute_decomp(
    direct_snapshots, adjoint_snapshots)

# Choose modes so that BPOD projection has less than 10% error
sing_vals_norm = sing_vals / np.sum(sing_vals)
num_modes = np.nonzero(np.cumsum(sing_vals_norm) > 0.9)[0][0] + 1
mode_nums = list(mr.range(num_modes))
direct_modes = [
    CustomVecHandle('%s/direct_mode%d.pkl' % (out_dir, i)) for i in mode_nums
]
class CFG:
    def __init__(self):
        self._entry = None
        self._exit = None
        self._blocks = CustomVector()
        self._numBlockID = -1
        self._indirectGotoBlock = None  # special block to contain collective
        # dispatch for indirect gotos
        self._syntheticDeclStmts = []

    def createBlock(self):
        """Creates a new block in the CFG. The CFG owns the block.
		Returns
		-------
		:obj: `CFGBlock`
		"""
        first_block = False
        if not (self.front) and not (self.back):
            first_block = True
        # Create a new block
        self._numBlockID += 1
        # Instantiate the elements of the block
        elements = CustomVector()
        B = CFGBlock(self._numBlockID, elements, self)
        # Insert the block
        self._blocks.push_back(B)
        if (first_block):
            self._entry = self._exit = B
        return self._blocks.back()

    def buildCFG(self, declaration, statement):
        """ Builds a CFG from an AST
		:param declaration: DeclDecorator
		:param statement: StmtDecorator
		:return: CFG
		"""
        builder = CFGBuilder()
        return builder.buildCFG(declaration, statement)

    def setEntry(self, block):
        """ Set the entry block of the CFG. This is typically used
		only during the CFG construction.
		:param block: CFGBlock
		:return: None
		"""
        self._entry = block

    def setIndirectGotoBlock(self, block):
        """ Set the block used for indirect goto jumps.
		This is typically used only during CFG construction.
		:param block: CFGBlock
		:return: block
		"""
        self._indirectGotoBlock = block

    #
    # Block Iterators
    #

    @property
    def front(self):
        return self._blocks.front()

    @property
    def back(self):
        return self._blocks.back()

    def begin(self):
        return self._blocks.begin()

    def rbegin(self):
        return self._blocks.rbegin()

    def getEntry(self):
        return self._entry

    def getExit(self):
        return self._exit

    def getIndirectGotoBlock(self):
        return self._indirectGotoBlock

    def addSyntheticDeclStmt(self, synthetic, source):
        """ Records a synthetic DeclStmt and the DeclStmt it was constructed from.
		The CFG uses synthetic DeclStmt when a single AST DeclStmt contains multiple decls
		:return:
		"""
        assert synthetic.isSingleDeclaration(
        ), "Can handle single declaration only"

        self._syntheticDeclStmts.append([source, synthetic])

    def synthetic_stmt_begin(self):
        """ Iterates over synthetic DeclStmts in the CFG
		Each element is a [synthetic statement, source statement] pair
		:return: [synthetic statement, source statement]
		"""
        for key, value in self._syntheticDeclStmts.iteritems():
            yield [key, value]

    #
    # CFG Introspection
    #

    def getNumBlocIDs(self):
        """ Returns the total number of BlockIDs allocated (start at 1)
		:return: int
		"""
        return self._numBlockID

    def size(self):
        """ Returns the total number of CFGBlocks within the CFG
		:return: int
		"""
        return self._numBlockID

    def printer(self):
        output = ""
        for b in self._blocks.begin():
            output += b.printer()
        output += '=>Entry: ' + str(self._entry.getBlockID()) + '\n'
        output += '<=Exit: ' + str(self._exit.getBlockID()) + '\n'

        return output
class CFGBuilder:
    def __init__(self):
        self._succ = None
        self._block = None
        self._badCFG = False
        self._cfg = CFG()
        self._sv = CustomVector()
        # For stmt
        self._breakJumpTarget = BlockScopePosPair()
        self._continueJumpTarget = None
        self._saveBreak = CustomVector()
        self._saveBlock = CustomVector()
        self._saveSucc = CustomVector()
        self._saveContinue = CustomVector()
        # switch stmt
        self._defaultCaseBlock = None
        self._switchTerminatedBlock = None
        self._switchExclusivelyCovered = None
        self._switchCond = None
        # labels
        self._labels = {}
        self._backPatchBlocks = CustomVector()
        self._addressTakenLabels = CustomVector()

        # for graph
        self.graph = GraphBuilder()
        self.curNode = -1

    def addPrefix(self, ch):
        self.graph.prefixString.append(ch)

    def removePrefix(self):
        self.graph.prefixString = self.graph.prefixString[:-1]

    def buildCFG(self, Decl, statement=None):
        """ Constructs a CFG from an AST (a Stmt). The ownership of the
		returned CFG is transferred to the caller.
		Parameters
		----------
		statement : :obj:`statement`
			This is the AST, and can represent any arbitrary statement. For
			a single expression or a function body (compound statement).
		Returns
		-------
		:obj:`CFG`
			A cfg object.
		None
			If the CFG construction fails.
		"""
        self.graph.prefixString = []
        if not statement:
            return None

        # print self.graph
        # print self.curNode
        # Create an empty block that will serve as the exit block for the CFG.
        # Is the first block added to the CFG and registered as exit block

        self._succ = self.createBlock()
        # Exit block is empty (None) create the next blocks lazily
        self._block = None
        # Visit the statements and create the CFG
        B = self.accepts(statement)
        # if self._badCFG:
        # 	return None
        # if B:
        # 	self._succ = B
        # backpatch the gotos whose label -> block mappings we didn't know when we
        # encountered them
        for e in self._backPatchBlocks.begin():
            b = e.block
            g = b.getTerminator()
            try:
                li = self._labels[g.getLabel()]
            except KeyError:
                continue

            self.addSucessor(b, li.block)

        # Add successor to the Indirect Goto Dispatch block (if we have one)
        b = self._cfg.getIndirectGotoBlock()
        if (b is not None):
            for l in self._addressTakenLabels.begin():
                # Look the target block
                try:
                    li = self._labels[l]
                except KeyError:
                    # If there is no target block that contains label, then we are looking
                    # at an incomplete AST. Handle this by not registering a successor
                    continue

                self.addSucessor(b, li.block)

        self._cfg.setEntry(self.createBlock())
        self.graph.printGraph()
        return self._cfg

    def createBlock(self, add_sucessor=True):
        """Used to lazily create blocks that are connected to the current
		(global) succesor.
		Parameters
		----------
		add_sucessor : bool
			Variable that indicates whether or not a sucessor is added.
		Returns
		-------
		:obj:`CFGBlock`
			Returns the CFG block object.
		"""
        B = self._cfg.createBlock()
        if add_sucessor and self._succ:
            self.addSucessor(B, self._succ)
        return B

    def addSucessor(self, B, S, IsReachable=True):
        B.addSuccessor(CFGBlock.AdjacentBlock(S, IsReachable))

    def accepts(self, S):
        if not S:
            return
        return self.visit(S)

    def visit(self, S=None):
        """Visit - Walk the subtree of a statement and add extra
		blocks for ternary operators, &&, and ||.  We also process "," and
		DeclStmts (which may contain nested control-flow).
		Paramaters
		----------
		S :
			Cursor to the statement in the AST.
		Returns
		-------
		:obj:`CFGBlock`
			Returns the CFG block object.
		"""
        if not S:
            return None

        kind = S.kind()

        if (type_stmt.COMPOUND_STMT == kind):
            # self.graph.addNode(S)
            return self.visitCompoundStmt(S)

        elif (type_stmt.DECL_STMT == kind):
            return self.visitDeclStmt(S)

        elif (type_stmt.IF_STMT == kind):
            return self.visitIfStmt(S)

        elif (type_stmt.BINARY_OPERATOR == kind):
            return self.visitBinaryOperator(S)

        elif (type_stmt.COMPOUND_ASSIGMENT_OP == kind):
            return self.visitCompoundAssignmentOp(S)

        elif (type_stmt.FOR_STMT == kind):
            return self.visitForStmt(S)

        elif (type_stmt.NULL_STMT == kind):
            return self.visitNullStmt()

        elif (type_stmt.WHILE_STMT == kind):
            return self.visitWhileStmt(S)

        elif (type_stmt.IMPL_CAST_EXPR == kind):
            return self.visitImplicitCastExpr(S)

        elif (type_stmt.CSTYLE_CAST_EXPR == kind):
            return self.visitCstyleCastExpr(S)

        elif (type_stmt.SWITCH_STMT == kind):
            return self.visitSwitchStmt(S)

        elif (type_stmt.CASE_STMT == kind):
            return self.visitCaseStmt(S)

        elif (type_stmt.BREAK_STMT == kind):
            return self.visitBreakStmt(S)

        elif (type_stmt.DEFAULT_STMT == kind):
            return self.visitDefaultStmt(S)

        elif (type_stmt.ADDR_LABEL_EXPR == kind):
            return self.visitAddrLabelExpr(S)

        elif (type_stmt.CALL_EXPR == kind):
            return self.visitCallExpr(S)

        elif (type_stmt.DO_STMT == kind):
            return self.visitDoStmt(S)

        elif (type_stmt.CONTINUE_STMT == kind):
            return self.visitContinueStmt(S)

        elif (type_stmt.GOTO_STMT == kind):
            return self.visitGoToStmt(S)

        elif (type_stmt.LABEL_STMT == kind):
            return self.visitLabelStmt(S)

        elif (type_stmt.CONDITIONAL_OPERATOR == kind
              or type_stmt.BINARY_CONDITIONAL_OPERATOR == kind):
            return self.visitConditionalOperator(S)

        elif (type_stmt.RETURN_STMT == kind):
            return self.visitReturnStmt(S)

        elif (type_stmt.PAREN_EXPR == kind):
            return self.visitParenExpr(S)

        elif (type_stmt.MEMBER_REF_EXPR == kind):
            return self.visitMemberRefExpr(S)

        elif (type_stmt.INDIRECT_GOTO_STMT == kind):
            return self.visitIndirectGoToStmt(S)

        elif (type_stmt.STMT_EXPR == kind):
            return self.visitStmtExpr(S)

        elif (type_stmt.COMPOUND_LITERAL_EXPR == kind):
            return self.visitCompoundLiteralExpr(S)

        elif (type_stmt.UNARY_OPERATOR == kind):
            self.visitUnaryStmt(S)

        elif (type_stmt.DECL_REF_EXPR == kind):
            # print S.printer()
            self.graph.addVariables(self.curNode, S.value())

        elif (type_stmt.INTEGER_LITERAL == kind):
            self.graph.addConstant(self.curNode, S.value())

        elif (type_stmt.CHARACTER_LITERAL == kind):
            self.graph.addConstant(self.curNode, S.value())

        elif (type_stmt.FLOATING_LITERAL == kind):
            self.graph.addConstant(self.curNode, S.value())

        elif (type_stmt.STRING_LITERAL == kind):
            self.graph.addConstant(self.curNode, S.value())

        elif (type_stmt.VAR_DECL == kind):
            for v in S.value():
                print v
                self.graph.addVariables(self.curNode, v)

        # elif (type_stmt.BLOCK_EXPR == kind):
        #   return self.visitBlockExpr(S)

        # elif (type_stmt.LAMBDA_EXPR == kind):
        #   return self.visitLambdaExpr(S)

        else:
            return self.visitStmt(S)

    def visitCompoundLiteralExpr(self, S):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, S)

        se = S.getSubExpr()
        if (se is not None):
            return self.accepts(se)

    def visitStmtExpr(self, S):
        """ Utility method to handle (nested) statements expressions (a GCC extension)
		:param S: Statement
		:return: visit
		"""
        # self.autoCreateBlock()
        # self.appendStmt(self._block, S)

        return self.visitCompoundStmt(S.getSubStmt())

    def visitIndirectGoToStmt(self, I):
        # Lazily create the indirect-goto dispatch block if there isn't one already
        IBlock = self._cfg.getIndirectGotoBlock()

        if (IBlock is None):
            IBlock = self.createBlock(False)
            self._cfg.setIndirectGotoBlock(IBlock)

        # IndirectGoto is a control-flow statement. Thus we stop processing the current
        # block and create a new one
        if (self._badCFG):
            return None

        self._block = self.createBlock(False)
        self._block.setTerminator(I)
        self.addSucessor(self._block, IBlock)

        return self.accepts(I.getTarget())

    def visitMemberRefExpr(self, M):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, M)
        return self.visit(M.getBase())

    def visitParenExpr(self, P):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, P)

        return self.visit(P.getSubExpr())

    def visitReturnStmt(self, R):
        """If we were in the middle of a block we stop processing that block.
		Notes
		-----
		If a 'return' appears in the middle of a block, this means that the
		code afterwards is DEAD (unreachable). We still keep a basic block for that code;
		a simple 'mark-and-sweep' from the entry block will be able to resport such dead blocks.
		"""
        # Create the new block
        self.graph.addFeature(self.curNode, 'return')
        # Add the return statement to the block. This may create a new blocks if R contains
        # control-flow (shor-circuit operations)
        return self.visitStmt(R)

    def visitNoRecurse(self, E):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, E)
        return None

    # def visitBlockExpr(self, E):
    #   lastBlock = self.visitNoRecurse(E)

    def visitConditionalOperator(self, C):
        if (C.kind() == type_stmt.BINARY_CONDITIONAL_OPERATOR):
            opaqueValue = C.getOpaqueValue()
        else:
            opaqueValue = None

        trueExpr = C.getTrueExpr()
        falseExpr = C.getFalseExpr()
        cond = C.getCond()

        self.accepts(opaqueValue)
        self.accepts(cond)
        self.accepts(trueExpr)
        self.accepts(falseExpr)

    def visitLabelStmt(self, L):
        # Get the block of the labeled statement. Add it to our map (self._labels)
        self.accepts(L.getSubStmt())
        labelBlock = self._block

        if not labelBlock:
            labelBlock = self.createBlock(
            )  # This can happen when the body is empty

        self._labels[L.value()] = BlockScopePosPair(labelBlock)
        # labels partition blocks, so this is the end of the basic block we were
        # processing (L is the blocks label). Because this is label (and we have
        # already processed the substatement) there is no extra control-flow to worry
        # about
        labelBlock.setLabel(L)
        if self._badCFG:
            return None
        # We set Block to NULL to allow lazy creation of a new block (if necessary);
        self._block = None
        # This block is now the implicit successor of other blocks
        self._succ = labelBlock
        return labelBlock

    def visitGoToStmt(self, G):
        """Goto is a control-flow statement. Thus we stop processing the current block and
		create a new one."""
        if self._badCFG:
            return None
        self._block = self.createBlock(False)
        self._block.setTerminator(G)
        # If we already know the mapping to the label block add the sucessor now
        try:
            b = self._labels[G.getLabel()]
        except KeyError:
            b = None
        if not b:
            # We will need to backpatch this block later.
            self._backPatchBlocks.push_back(BlockScopePosPair(self._block))
        else:
            self.addSucessor(self._block, b.block)
        return self._block

    def visitContinueStmt(self, C):
        """"continue" is a control-flow statement. Thus we stop processing the current block."""

        self.graph.addFeature(self.curNode, 'continue')

    def visitDoStmt(self, D):

        loopSuccessor = None
        # "do ... while" is a control-flow statement. Thus we stop processing the current
        # block
        prevNode = self.graph.lastNode

        cond = D.getCond()
        body = D.getBody()

        self.accepts(cond)
        self.accepts(body)

    # TODO: REVISAR Y MEJORAR
    def visitCallExpr(self, C):
        """Compute de callee type.
		TODO
		----
		calleType = C.getCalle().getType() #TODO TODO
		If this is a call to a no-return function, this stops the block here bool
		"""
        params = C.getParams()
        callee = C.getCallee()
        for param in params:
            self.accepts(param)

        return self.accepts(C.getCallee())

    def visitAddrLabelExpr(self, A):
        # self._addressTakenLabels.push_back(A.getLabel())
        # self.autoCreateBlock()
        # self.appendStmt(self._block, A)
        return self._block

    def visitStmt(self, S):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, S)
        # I don't want the index of the array subscript in the CFG
        # if(S.kind() == type_stmt.ARRAY_SUBSCRIPT_EXPR):
        # return self.accepts(S.getSubExpr())
        return self.visitChildren(S)

    def visitChildren(self, S):
        B = self._block
        # Visit the children in their reverse order so that they appear in left-to-right (natural)
        # order in the CFG
        childrens = S.get_children()
        it = childrens.begin()
        for c in it:
            # if(self.isStmt(c)):
            R = self.visit(c)
        # if R:
        # 	B = R
        return B

    def visitCstyleCastExpr(self, S):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, S)
        if (S.getSubExpr() and hasattr(S.getSubExpr(), 'value')):
            self.graph.addVariables(self.curNode, S.getSubExpr().value())
        return self.accepts(S.getSubExpr())

    def visitImplicitCastExpr(self, S):
        # self.autoCreateBlock()
        # self.appendStmt(self._block, S)
        # print S.getSubExpr().kind()
        return self.accepts(S.getSubExpr())

    def isStmt(self, S):
        type = S.kind()
        if (type == type_stmt.COMPOUND_STMT or type == type_stmt.IF_STMT
                or type == type_stmt.FOR_STMT or type == type_stmt.DECL_STMT):
            return True
        else:
            return False

    def visitCompoundStmt(self, compoundStatement):
        """visitCompoundStmt - when a compound statement is reached visit the stmts
		inside it.
		:param S: StmtDecorator
		:return: CFGBlock
		"""
        # creating a binding to block object
        lastBlock = self._block
        # iterating through the compound statement
        elements = compoundStatement.child_iterator()
        for e in elements:
            # lastNode = self.graph.lastNode

            curNode = self.graph.createNode('data2')
            self.curNode = curNode
            if (len(e.printer()) < 40):
                self.graph.addString(self.curNode, e.printer())
            newBlock = self.accepts(e)
        # if newBlock:
        # 	lastBlock = newBlock
        # if self._badCFG:
        # 	return None
        return lastBlock

    def visitDeclStmt(self, DS):
        # TODO: check if the declaration is label, if so elude it (return block)
        # If the DS refers to a single declaration

        if DS.isSingleDeclaration():
            self.visitDeclSubExpr(DS)
            return

        elements = DS.child_iterator()
        for e in elements:
            newStmt = SyntheticDeclStmt(DS.get_cursor(), e)
            B = self.visitDeclSubExpr(newStmt)

    def visitDeclSubExpr(self, DS):
        """Utility method to add block-level expressions for DeclStmts
		and initializers in them
		:param DS: StmtDecorator
		:return:
		"""

        assert DS.isSingleDeclaration(), "Can handle single declarations only"

        VD = DS.getSingleDeclaration()
        # print VD.kind()

        init = None
        # print VD.printer()
        # if not VD:
        # 	init = VD.getInit()

        # self.accepts(DS)
        if (VD is None): return
        childs = VD.get_children().begin()
        val = VD.value()
        if (len(val) > 1):
            self.graph.addVariables(self.curNode, val[0])
        for child in childs:
            print child
            self.accepts(child)

    def visitIfStmt(self, if_stmt):
        """ We may see an if stmt in the middle of a basic block, or it may be the
		first statement we are processing. In either case, we create a new basic block.
		First, we create the blocks for the then...else statements, and then we create the
		block containing the if stmt. If we were in the middle of a block, we stop processing
		that block. That block is then the implicit successor for the then and else clauses.
		"""
        # The block we were processing is now finished. Make it the successor block

        ifNode = self.curNode
        # print if_stmt.printer()
        self.graph.addFeature(ifNode, "icn")

        cond = if_stmt.getCond()
        then = if_stmt.getThen()
        elseBody = if_stmt.getElse()

        self.graph.addString(ifNode, cond.printer()[:40])
        self.accepts(cond)

        self.addPrefix('if')
        self.accepts(then)
        self.removePrefix()

        self.accepts(elseBody)

    def visitLogicalOperator(self,
                             bOperator,
                             stmt=None,
                             trueBlock=None,
                             falseBlock=None):
        # Introspect the RHS. if it is a nested logical operation, we recursively build te
        # CFG using this funcrion. Otherwise, resort to default CFG construction behaviour
        # print bOperator.value()
        # self.graph.addOperator(self.curNode, bOperator.value())
        rhs = bOperator.getRHS()
        self.accepts(rhs)
        lhs = bOperator.getLHS()
        self.accepts(lhs)

    # def tryEvaluateBool(self, S):
    # 	""" Try and evaluate the Stmt and return 0 or 1 if we can evaluate to know value
    # 	otherwise return -1.
    # 	"""
    # 	# TODO: Build options
    # 	if S.kind() is type_stmt.BINARY_OPERATOR:
    # 		bop = S
    # 		if bop.isLogicalOp():
    # 			# Todo: comprobar si esta en cache
    # 			result = self.evaluateAsBooleanCondition(S)  # TODO
    # 			# Todo: guardar en cache
    # 			return result
    # 		else:
    # 			# For 'x & 0' and 'x * 0' we can determine that the value is
    # 			# always false
    # 			if(bop.value() == '*' or bop.value() == '&'):
    # 				# If either operand is 0 value must be false
    # 				if(bop.getLHS.kind() == type_stmt.INTEGER_LITERAL and bop.getLHS.value() == 0):
    # 					return TryResult(False)
    # 				if(bop.getHS.kind() == type_stmt.INTEGER_LITERAL and bop.getRHS.value() == 0):
    # 					return TryResult(False)
    # 	return self.evaluateAsBooleanCondition(S)
    #
    # def evaluateAsBooleanCondition(self, expression):
    # 	if expression.kind() is type_stmt.BINARY_OPERATOR:
    # 		bop = expression
    # 		if bop.isLogicalOp():
    # 			lhs = self.tryEvaluateBool(bop.getLHS())
    # 			if lhs.isKnown():
    # 				# We were able to evaluate the LHS, see if we can get away with not
    # 				# evaluating the RHS: '0 && X' => 0, '1 || X' => 1
    # 				if lhs.isTrue() and bop.value() == '||':
    # 					return lhs.isTrue()
    # 				rhs = self.tryEvaluateBool(bop.getRHS())
    # 				if rhs.isKnown():
    # 					if bop.value() == '||':
    # 						return lhs.isTrue() or rhs.isTrue()
    # 					else:
    # 						return lhs.isTrue() and rhs.isTrue()
    # 			else:
    # 				rhs = self.tryEvaluateBool(bop.getRHS())
    # 				if rhs.isKnown():
    # 					# We can't evaluate the LHS; however, sometimes the result
    # 					# is determined by RHS: 'X && 0' => 0, 'X || 1' => 1
    # 					if rhs.isTrue() and bop.value() == '||':
    # 						return rhs.isTrue()
    # 					else:
    # 						# bopRes = self.checkIncorrectLogicOperator(bop) # TODO: HACERLA
    # 						# if(bopRes.isKnown()):
    # 						return TryResult()  # bopRes.isTrue() FIXME
    # 			return TryResult()
    # 		elif bop.value() == '==' or bop.value() == '!=':
    # 			#bopRes = self.checkIncorrectEqualityOperator(bop)
    # 			# if (bopRes.isKnown()):
    # 			return TryResult()  # bopRes.isTrue() FIXME
    # 		elif bop.value() == '<' or bop.value() == '>' or bop.value() == '>=' or bop.value() == '<=':
    # 			#bopRes = self.checkIncorrectRelationaloperator(bop)
    # 			# if(bopRes.isKnown()):
    # 			# bopRes.isTrue() #FIXME: De momento lo todomo todo como uknown, hay que hacerla bien
    # 			return TryResult()
    # 	# result = None
    # 	# if(expression.EvaluateAsBooleanCondition(result) == True): # TODO(Optional)
    # 	  #  return result
    # 	return TryResult()

    def visitBinaryOperator(self, B):
        # && or ||

        self.graph.addString(self.curNode, B.printer())
        if (B.value() is not None):
            self.graph.addOperator(self.curNode, B.value())
        # print B.value()

        if B.isLogicalOp():
            return self.visitLogicalOperator(B)
        if B.value() == ',':
            # self.autoCreateBlock()
            # self.appendStmt(self._block, B)
            self.accepts(B.getRHS())
            return self.accepts(B.getLHS())
        if B.isAssignmentOp():
            # self.autoCreateBlock()
            # self.appendStmt(self._block, B)
            self.graph.inLHS = True
            self.accepts(B.getLHS())
            self.graph.inLHS = False

            return self.accepts(B.getRHS())
        # TODO: ALWAYS ADD
        # self.autoCreateBlock()
        # self.appendStmt(self._block, B)
        # print B.getLHS().getSubExpr().value()

        numOfOps = B.getLen()
        if (numOfOps > 1):
            oldNode = self.curNode

            rhNode = self.graph.createNode('graph')
            self.curNode = rhNode
            rBlock = self.accepts(B.getRHS())

            lhNode = self.graph.createNode('data2')
            self.curNode = lhNode
            lBlock = self.accepts(B.getLHS())

            self.graph.addLink(oldNode, rhNode)
            self.graph.addLink(oldNode, lhNode)
        else:
            rBlock = self.accepts(B.getRHS())
            lBlock = self.accepts(B.getLHS())

    def visitCompoundAssignmentOp(self, C):
        # TODO: ALWAYS ADD
        # self.autoCreateBlock()
        # self.appendStmt(self._block, C)
        self.graph.addOperator(self.curNode, C.specific_kind())
        rBlock = self.accepts(C.getRHS())
        lBlock = self.accepts(C.getLHS())
        # If visiting RHS causes us to finish 'Block' eg: the RHS is a StmtExpr
        # containing a DoStmt, and the LHS doesn't create a new block, the we should
        # return RBlock. Otherwise we'll incorrectly recur Null
        if lBlock:
            return lBlock
        else:
            return rBlock

    def visitForStmt(self, F):
        # 'For' is a control flow statement, thus we stop processing the current block
        #
        i = F.getInit()
        # print i.printer()
        cond = F.getCond()
        body = F.getBody()
        inc = F.getInc()

        # self.accepts(i)
        # self.graph.createNode('data2', 'cn')
        # self.accepts(cond)
        # self.addPrefix('lp')
        # self.accepts(body)
        # self.accepts(inc)
        # self.removePrefix()

        # if i:
        # 	self._block = self.createBlock()
        # 	initBlock =  self.accepts(i)

        condNode = self.graph.createNode('data2')

        self.graph.addFeature(condNode, 'cn')
        self.accepts(i)
        self.accepts(cond)

        self.addPrefix('lp')
        IncNode = self.graph.createNode('data2')
        self.curNode = IncNode
        self.accepts(inc)
        self.accepts(body)
        self.removePrefix()
        return None

    def visitNullStmt(self):
        return None

    def visitWhileStmt(self, W):

        whileCnNode = self.curNode
        cond = W.getCond()
        body = W.getBody()
        self.graph.addFeature(whileCnNode, 'cn')
        self.graph.addFeature(whileCnNode, 'loop')
        self.accepts(cond)
        self.addPrefix('lp')
        self.accepts(body)
        self.removePrefix()

        return None

    # switchFlag = 0

    def visitSwitchStmt(self, terminator):
        # 'Switch' is a control-flow statment. Thus we stop processing the current block

        tmBody = terminator.getBody()
        tmCond = terminator.getCond()

        self.graph.addFeature(self.curNode, 'switch')
        self.accepts(tmCond)

        self.addPrefix('sb')
        self.accepts(tmBody)
        self.removePrefix()

    # def tryEvaluate(self, S):
    # 	return self.evaluateAsRValue(S)
    #
    # def evaluateAsRValue(self, expr):
    # 	field = self.fastEvaluateAsRValue(expr)[1]
    # 	isConst = field is not False
    # 	if isConst:
    # 		return self.fastEvaluateAsRValue(expr)
    # 	return[False, False]
    #
    # def fastEvaluateAsRValue(self, expr):
    # 	# Fast evaluation of integer literals, since we sometimes see files
    # 	# containing vast quantities of these
    # 	if expr.kind() is type_stmt.INTEGER_LITERAL:
    # 		return [True, expr.value()]
    # 	# This case should be rare
    # 	if expr.kind() is type_stmt.NULL_STMT:
    # 		return [True, False]
    # 	# TODO: FOR ARRAY TYPES
    # 	return[False, False]
    #
    # # caseExit = 0

    def visitCaseStmt(self, CS):
        # CaseStmts are essentially labels, so they are the first statement in a block

        sub = CS.getSubStmt()
        val = CS.value()

        self.graph.addFeature(self.curNode, val)
        self.graph.addFeature(self.curNode, 'case')
        self.accepts(sub)

    def visitUnaryStmt(self, S):
        self.graph.addOperator(self.curNode, S.value())
        self.visit(S.getOperand())

    # def shouldAddCase(self, switchExclusivelyCovered, switchCond, CS):
    # 	if not switchCond:
    # 		return True
    # 	addCase = False
    # 	if not switchExclusivelyCovered:
    # 		if type(switchCond) is int:
    # 			# Evaluate the LHS of the case value
    # 			lhsInt = self.evaluateAsRValue(CS.getLHS())  # TODO
    # 			condInt = switchCond
    # 			if condInt == lhsInt:
    # 				addCase = True
    # 				self._switchExclusivelyCovered = True
    # 			elif condInt > lhsInt:
    # 				rhs = CS.getRHS()
    # 				if rhs:
    # 					# Evaluate the RHS of the case value
    # 					v2 = self.evaluateKnownConstInt(rhs)
    # 					if v2 >= condInt:
    # 						addCase = True
    # 						self._switchExclusivelyCovered = True
    # 		else:
    # 			addCase = True
    # 	return addCase

    def evaluateKnownConstInt(self, S):
        """ Call EvaluateAsRValue and return the folded integer. This must be called on an expression
		that constant folds to an integer
		"""
        result = self.evaluateAsRValue(S)
        if result[0]:
            return result[1]

    def visitBreakStmt(self, B):
        # Break is a control-flow stmt. Thus we stop processsing the current block

        self.graph.addFeature(self.curNode, 'break')

    # Now create a new block that ends with the break stmt

    # return self._block

    def visitDefaultStmt(self, terminator):
        substmt = terminator.getSubStmt()

    def appendStmt(self, CFGBlock, stmt):
        """Interface to CFGBlock - adding CFGElements."""
        CFGBlock.appendStmt(stmt)
Exemplo n.º 8
0
    def print_succs(self):
        l = CustomVector()
        for e in self._succs.begin():
            l.push_back(e.getReachableBlock().getBlockID())

        l.printer()
Exemplo n.º 9
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class CFGBlock:
    class AdjacentBlock:
        """This class represents a potential adjacent block in the CFG.
        It encodes whether or ont the block is actually reachable, or
        can be proved to be tribially unreachable. For some cases it
        allows one to encode scenarios where a block was substituted
        because the original (now alternate) block is unreachable."""
        class Kind(Enum):
            AB_Normal = 0
            AB_Unreachable = 1
            AB_Alternate = 2

        def __init__(self, CFGBlock, isReachable=None, alternateBlock=None):
            self._reachableBlock = None
            self._unreachableBlock = [None, None]
            if isReachable and not (alternateBlock):
                self.reachable(CFGBlock, isReachable)
            elif not (isReachable) and alternateBlock:
                self.alternate(CFGBlock, alternateBlock)

        def reachable(self, block, isReachable):
            if isReachable:
                self._reachableBlock = block
            else:
                self._reachableBlock = None
            # Inicialization of _unreachableBlock
            if not isReachable:
                self._unreachableBlock[0] = block
            else:
                self._unreachableBlock[0] = None
            if block and isReachable:
                self._unreachableBlock[1] = self.Kind.AB_Normal
            else:
                self._unreachableBlock[1] = self.Kind.AB_Unreachable

        def alternate(self, block, alternateBlock):
            self._reachableBlock = block
            if block == alternateBlock:
                self._unreachableBlock[0] = None
                self._unreachableBlock[1] = self.Kind.AB_Alternate
            else:
                self._unreachableBlock[0] = alternateBlock
                self._unreachableBlock[1] = self.Kind.AB_Normal

        def getReachableBlock(self):
            """Get the reachable block if one exists."""
            return self._reachableBlock

        def getPossiblyUnreachableBlock(self):
            """Get potentially unreachable block."""
            return self._unreachableBlock

        def isReachable(self):
            kind = self._unreachableBlock[1]
            return kind is self.Kind.AB_Normal or kind is self.Kind.AB_Alternate

    def __init__(self, blockID, C, CFGparent):
        # Set of statements in the basic block, list of CFGElement
        self._elements = C

        # TODO: label = stmt()
        self._label = None

        # The terminator for a basic block that indicates the type of control-flow
        # that accours between a bloack and its successors.
        self._terminator = None

        # LoopTarget- some blocks are used to represent the "loop edge" to the start
        # of a loop from within the loop body. This stmt will be refer to the loop stmt
        # for such blocks (and be null otherwise)
        self._loopTarget = None

        self._blockID = blockID

        # Predecessors/Sucessors - Keep track of the predecessor / sucessor CFG Blocks
        self._preds = CustomVector()
        self._succs = CustomVector()

        # This shit makes no sense
        # self._preds.push_back(C)
        # self._succs.push_back(C)

        # NoReturn - this bit is set when basic block contains a function call
        # that is attributed as 'noreturn'. In that case, control cannot technically
        # ever proceed past this block. All such blocks will have a immediate successor:
        # the exit block. This allows them to be easily reached from the exit block and
        # using this bit quickly recognized without scanning the contents of the block
        self._hasNoReturnElement = False

        # Parent CFG that owns the CFGBlock
        self._parent = CFGparent

        # Control do stmt
        self._doBodyBlock = False

    def front(self):
        return self._elements.front()

    def back(self):
        return self._elements.back()

    def begin(self):
        return self._elements.begin()

    def rbegin(self):
        return self._elements.rbegin()

    def size(self):
        return self._elements.size()

    def empty(self):
        return self._elements.empty()

    def removeElement(self, index):
        self._elements.popAtIndex(index)

    # CFG ITERATORS

    def pred_begin(self):
        return self._preds.begin()

    def preds_rbegin(self):
        return self._preds.rbegin()

    def succs_begin(self):
        return self._succs.begin()

    def succs_rbegin(self):
        return self._succs.rbegin()

    def succs_size(self):
        return self._succs.size()

    def succs_empty(self):
        return self._succs.empty()

    def preds_size(self):
        return self._preds.size()

    def preds_empty(self):
        return self._preds.empty()

    def removeSucc(self, index):
        return self._succs.popAtIndex(index)

    def removeAllSuccs(self):

        for s in range(self._succs.size()):
            self._succs.pop_back()

    def removePred(self, index):
        return self._preds.popAtIndex(index)

    # MANIPULATION OF BLOCK CONTENTS

    def setTerminator(self, term):
        self._terminator = term

    def setLabel(self, statement):
        self._label = statement

    def setDoBodyBlock(self):
        self._doBodyBlock = True

    def isDoBodyBlock(self):
        return self._doBodyBlock

    def setLoopTarget(self, stmtLoopTarjet):
        self._loopTarget = stmtLoopTarjet

    def setHasNoReturnElement(self):
        self._hasNoReturnElement = True

    def getTerminator(self):
        return self._terminator

    def getLoopTarjet(self):
        return self._loopTarget

    def getLabel(self):
        return self._label

    def hasNoReturnElement(self):
        return self._hasNoReturnElement

    def getBlockID(self):
        return self._blockID

    def getParent(self):
        return self._parent

    # TODO: METODOS DE SALIDA POR PANTALLA
    def print_preds(self):
        l = CustomVector()
        for e in self._preds.begin():
            l.push_back(e.getReachableBlock().getBlockID())

        l.printer()

    def print_succs(self):
        l = CustomVector()
        for e in self._succs.begin():
            l.push_back(e.getReachableBlock().getBlockID())

        l.printer()

    def printer(self):
        """ Pretty-print a block

        :return: String
        """
        output = ""

        # Printing the block ID
        output += colored("[B" + str(self._blockID) + "]\n", "red")

        # Printing the statements
        i = 0
        for e in self._elements.rbegin():
            output += str(i) + ": " + e.printer() + "\n"
            i += 1

        # Printing predecessors
        for e in self._preds.begin():
            if (e.getReachableBlock() is not None):
                output += colored(
                    "Preds " + "(" + str(self._preds.size()) + ")" + ": " +
                    "B" + str(e.getReachableBlock().getBlockID()) + "\n",
                    "cyan")

        # Printing predecessors
        for e in self._succs.begin():
            if (e.getReachableBlock() is not None):
                output += colored(
                    "Succs " + "(" + str(self._succs.size()) + ")" + ": " +
                    "B" + str(e.getReachableBlock().getBlockID()) + "\n",
                    "magenta")

        output += "\n"
        return output

    def addSuccessor(self, succ):
        """Adds a (potentially unreachable) sucessor block to the current block.

        Parameters
        ----------
        succ : :obj:`AdjacentBlock`

        """
        # The block is reachable
        B = succ.getReachableBlock()
        if B:
            B._preds.push_back(
                self.AdjacentBlock(self, isReachable=succ.isReachable()))
        # The block is unreachable
        unreachableB = succ.getPossiblyUnreachableBlock()
        if unreachableB[0]:
            unreachableB[0]._preds.push_back(
                self.AdjacentBlock(self, isReachable=False))
        # Adding the block as a sucessor
        self._succs.push_back(succ)

    def appendStmt(self, stmt):
        self._elements.push_back(stmt)