public class UpperBoundTransfer extends IndexAbstractTransfer
int[] array = new
int[expr];
, the type of expr is @LTEqLength("array")
.
other * node
has type typeOfMultiplication
, then if other
is
positive, then node
is typeOfMultiplication
.
other * node
has type typeOfMultiplication
, if other
is
greater than 1, then node
is typeOfMultiplication
plus 1.
node
, that is known to have type typeOfSubtraction
. An offset can be applied to the left node (i.e. the left node has the
same type, but with an offset based on the right node).
@LTLengthOf(value="x", offset="-b")
. If b is known to be less than the
length of some other array, y, then the type of a + b is @LTLengthOf(value={"x",
"y"}, offset={"-b", "-a"})
.
@LTLengthOf(value="x", offset="o"))
, then the type of a + b is
@LTLengthOf(value="x",offset="o - b")
. (Note, if "o - b" can be computed, then it
is and the result is used in the annotation.)
@LTLengthOf(value = "f2", offset = "f1.length")
int
and expression j is less than or equal to the length of f1, then the type of i + j is
@LTLengthOf("f2")
.
@LTLengthOf(value="x", offset="b")
.
@LTLength(value={"array"...}, offset="-1")
where "array"... is the set of all
sequences that are the same length (via the SameLen checker) as "array"
@LTEqLengthOf("a")
and the value of a.length in the store.
@LTEqLengthOf("s")
and the value of s.length() in the store.
analysis, sequentialSemantics
Constructor and Description |
---|
UpperBoundTransfer(CFAnalysis analysis)
Creates a new UpperBoundTransfer.
|
Modifier and Type | Method and Description |
---|---|
protected void |
refineGT(Node larger,
AnnotationMirror largerAnno,
Node smaller,
AnnotationMirror smallerAnno,
CFStore store,
TransferInput<CFValue,CFStore> in)
Case 8: if x < y, and y has a type that is related to the length of an array, then x has the
same type, with an offset that is one less.
|
protected void |
refineGTE(Node left,
AnnotationMirror leftAnno,
Node right,
AnnotationMirror rightAnno,
CFStore store,
TransferInput<CFValue,CFStore> in)
Case 9: if x ≤ y, and y has a type that is related to the length of an array, then x has the
same type.
|
protected TransferResult<CFValue,CFStore> |
strengthenAnnotationOfEqualTo(TransferResult<CFValue,CFStore> res,
Node firstNode,
Node secondNode,
CFValue firstValue,
CFValue secondValue,
boolean notEqualTo)
Implements case 11.
|
TransferResult<CFValue,CFStore> |
visitAssignment(AssignmentNode node,
TransferInput<CFValue,CFStore> in)
Case 1: Refine the type of expressions used as an array dimension to be less than length of the
array to which the new array is assigned.
|
TransferResult<CFValue,CFStore> |
visitCase(CaseNode n,
TransferInput<CFValue,CFStore> in)
A case produces no value, but it may imply some facts about the argument to the switch
statement.
|
TransferResult<CFValue,CFStore> |
visitFieldAccess(FieldAccessNode n,
TransferInput<CFValue,CFStore> in)
If n is an array length field access, then the type of a.length is the glb
of @LTEqLengthOf("a") and the value of a.length in the store.
|
TransferResult<CFValue,CFStore> |
visitIntegerLiteral(IntegerLiteralNode n,
TransferInput<CFValue,CFStore> pi) |
TransferResult<CFValue,CFStore> |
visitMethodInvocation(MethodInvocationNode n,
TransferInput<CFValue,CFStore> in)
If n is a String.length() method invocation, then the type of s.length() is the glb
of @LTEqLengthOf("s") and the value of s.length() in the store.
|
TransferResult<CFValue,CFStore> |
visitNumericalAddition(NumericalAdditionNode n,
TransferInput<CFValue,CFStore> in)
If some Node a is known to be less than the length of some array, x, then, the type of a + b,
is @LTLengthOf(value="x", offset="-b").
|
TransferResult<CFValue,CFStore> |
visitNumericalSubtraction(NumericalSubtractionNode n,
TransferInput<CFValue,CFStore> in)
If some Node a is known to be less than the length of some sequence x, then the type of a - b
is @LTLengthOf(value="x", offset="b").
|
visitGreaterThan, visitGreaterThanOrEqual, visitLessThan, visitLessThanOrEqual
addInformationFromPreconditions, createTransferResult, finishValue, finishValue, getNarrowedValue, getValueFromFactory, getWidenedValue, initialStore, insertIntoStores, isNotFullyInitializedReceiver, moreSpecificValue, processCommonAssignment, processConditionalPostconditions, processPostconditions, recreateTransferResult, setFixedInitialStore, splitAssignments, usesSequentialSemantics, visitArrayAccess, visitClassName, visitConditionalNot, visitEqualTo, visitInstanceOf, visitLambdaResultExpression, visitLocalVariable, visitNarrowingConversion, visitNode, visitNotEqual, visitObjectCreation, visitReturn, visitStringConcatenateAssignment, visitStringConversion, visitTernaryExpression, visitThis, visitVariableDeclaration, visitWideningConversion
visitArrayCreation, visitArrayType, visitAssertionError, visitBitwiseAnd, visitBitwiseComplement, visitBitwiseOr, visitBitwiseXor, visitBooleanLiteral, visitCharacterLiteral, visitClassDeclaration, visitConditionalAnd, visitConditionalOr, visitDoubleLiteral, visitExplicitThis, visitFloatingDivision, visitFloatingRemainder, visitFloatLiteral, visitImplicitThis, visitIntegerDivision, visitIntegerRemainder, visitLeftShift, visitLongLiteral, visitMarker, visitMemberReference, visitMethodAccess, visitNullChk, visitNullLiteral, visitNumericalMinus, visitNumericalMultiplication, visitNumericalPlus, visitPackageName, visitParameterizedType, visitPrimitiveType, visitShortLiteral, visitSignedRightShift, visitStringConcatenate, visitStringLiteral, visitSuper, visitSynchronized, visitThrow, visitTypeCast, visitUnsignedRightShift, visitValueLiteral
clone, equals, finalize, getClass, hashCode, notify, notifyAll, toString, wait, wait, wait
visitArrayCreation, visitArrayType, visitAssertionError, visitBitwiseAnd, visitBitwiseComplement, visitBitwiseOr, visitBitwiseXor, visitBooleanLiteral, visitCharacterLiteral, visitClassDeclaration, visitConditionalAnd, visitConditionalOr, visitDoubleLiteral, visitExplicitThis, visitFloatingDivision, visitFloatingRemainder, visitFloatLiteral, visitImplicitThis, visitIntegerDivision, visitIntegerRemainder, visitLeftShift, visitLongLiteral, visitMarker, visitMemberReference, visitMethodAccess, visitNullChk, visitNullLiteral, visitNumericalMinus, visitNumericalMultiplication, visitNumericalPlus, visitPackageName, visitParameterizedType, visitPrimitiveType, visitShortLiteral, visitSignedRightShift, visitStringConcatenate, visitStringLiteral, visitSuper, visitSynchronized, visitThrow, visitTypeCast, visitUnsignedRightShift
public UpperBoundTransfer(CFAnalysis analysis)
analysis
- the analysis for this transfer functionpublic TransferResult<CFValue,CFStore> visitAssignment(AssignmentNode node, TransferInput<CFValue,CFStore> in)
visitAssignment
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitAssignment
in class CFAbstractTransfer<CFValue,CFStore,CFTransfer>
protected void refineGT(Node larger, AnnotationMirror largerAnno, Node smaller, AnnotationMirror smallerAnno, CFStore store, TransferInput<CFValue,CFStore> in)
refineGT
in class IndexAbstractTransfer
protected void refineGTE(Node left, AnnotationMirror leftAnno, Node right, AnnotationMirror rightAnno, CFStore store, TransferInput<CFValue,CFStore> in)
refineGTE
in class IndexAbstractTransfer
protected TransferResult<CFValue,CFStore> strengthenAnnotationOfEqualTo(TransferResult<CFValue,CFStore> res, Node firstNode, Node secondNode, CFValue firstValue, CFValue secondValue, boolean notEqualTo)
strengthenAnnotationOfEqualTo
in class CFAbstractTransfer<CFValue,CFStore,CFTransfer>
res
- the previous resultfirstNode
- the node that might be more precisesecondNode
- the node whose type to possibly refinefirstValue
- the abstract value that might be more precisesecondValue
- the abstract value that might be less precisenotEqualTo
- if true, indicates that the logic is flipped (i.e., the information is added
to the elseStore
instead of the thenStore
) for a not-equal comparison.null
public TransferResult<CFValue,CFStore> visitNumericalAddition(NumericalAdditionNode n, TransferInput<CFValue,CFStore> in)
Alternatively, if a is known to be less than the length of x when some offset, o, is added to a (the type of a is @LTLengthOf(value="x", offset="o")), then the type of a + b is @LTLengthOf(value="x",offset="o - b"). (Note, if "o - b" can be computed, then it is and the result is used in the annotation.)
In addition, If expression i has type @LTLengthOf(value = "f2", offset = "f1.length") int and expression j is less than or equal to the length of f1, then the type of i + j is .@LTLengthOf("f2").
These three cases correspond to cases 13-15.
visitNumericalAddition
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitNumericalAddition
in class AbstractNodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
public TransferResult<CFValue,CFStore> visitNumericalSubtraction(NumericalSubtractionNode n, TransferInput<CFValue,CFStore> in)
visitNumericalSubtraction
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitNumericalSubtraction
in class AbstractNodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
public TransferResult<CFValue,CFStore> visitFieldAccess(FieldAccessNode n, TransferInput<CFValue,CFStore> in)
visitFieldAccess
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitFieldAccess
in class CFAbstractTransfer<CFValue,CFStore,CFTransfer>
public TransferResult<CFValue,CFStore> visitMethodInvocation(MethodInvocationNode n, TransferInput<CFValue,CFStore> in)
visitMethodInvocation
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitMethodInvocation
in class CFAbstractTransfer<CFValue,CFStore,CFTransfer>
public TransferResult<CFValue,CFStore> visitCase(CaseNode n, TransferInput<CFValue,CFStore> in)
CFAbstractTransfer
visitCase
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitCase
in class CFAbstractTransfer<CFValue,CFStore,CFTransfer>
public TransferResult<CFValue,CFStore> visitIntegerLiteral(IntegerLiteralNode n, TransferInput<CFValue,CFStore> pi)
visitIntegerLiteral
in interface NodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>
visitIntegerLiteral
in class AbstractNodeVisitor<TransferResult<CFValue,CFStore>,TransferInput<CFValue,CFStore>>