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package org.checkerframework.dataflow.analysis;
import java.util.Objects;
import java.util.concurrent.atomic.AtomicLong;
import org.checkerframework.checker.initialization.qual.UnknownInitialization;
import org.checkerframework.checker.nullness.qual.Nullable;
import org.checkerframework.dataflow.cfg.node.Node;
import org.plumelib.util.StringsPlume;
import org.plumelib.util.UniqueId;
/**
* {@code TransferInput} is used as the input type of the individual transfer functions of a {@link
* ForwardTransferFunction} or a {@link BackwardTransferFunction}. It also contains a reference to
* the node for which the transfer function will be applied.
*
* A {@code TransferInput} contains one or two stores. If two stores are present, one belongs to
* 'then', and the other to 'else'.
*
* @param type of the abstract value that is tracked
* @param the store type used in the analysis
*/
public class TransferInput, S extends Store> implements UniqueId {
/** The corresponding node. */
// TODO: explain when the node is changed.
protected @Nullable Node node;
/**
* The regular result store (or {@code null} if none is present, because {@link #thenStore} and
* {@link #elseStore} are set). The following invariant is maintained:
*
*
* store == null ⇔ thenStore != null && elseStore != null
*
*/
protected final @Nullable S store;
/**
* The 'then' result store (or {@code null} if none is present). See invariant at {@link #store}.
*/
protected final @Nullable S thenStore;
/**
* The 'else' result store (or {@code null} if none is present). See invariant at {@link #store}.
*/
protected final @Nullable S elseStore;
/** The corresponding analysis class to get intermediate flow results. */
protected final Analysis analysis;
/** The unique ID for the next-created object. */
static final AtomicLong nextUid = new AtomicLong(0);
/** The unique ID of this object. */
final transient long uid = nextUid.getAndIncrement();
@Override
public long getUid(@UnknownInitialization TransferInput this) {
return uid;
}
/**
* Private helper constructor; all TransferInput construction bottoms out here.
*
* @param node the corresponding node
* @param store the regular result store, or {@code null} if none is present
* @param thenStore the 'then' result store, or {@code null} if none is present
* @param elseStore the 'else' result store, or {@code null} if none is present
* @param analysis analysis the corresponding analysis class to get intermediate flow results
*/
private TransferInput(
@Nullable Node node,
@Nullable S store,
@Nullable S thenStore,
@Nullable S elseStore,
Analysis analysis) {
if (store == null) {
assert thenStore != null && elseStore != null;
} else {
assert thenStore == null && elseStore == null;
}
this.node = node;
this.store = store;
this.thenStore = thenStore;
this.elseStore = elseStore;
this.analysis = analysis;
}
/**
* Create a {@link TransferInput}, given a {@link TransferResult} and a node-value mapping.
*
* Aliasing: The stores returned by any methods of {@code to} will be stored
* internally and are not allowed to be used elsewhere. Full control of them is transferred to
* this object.
*
*
The node-value mapping {@code nodeValues} is provided by the analysis and is only read from
* within this {@link TransferInput}.
*
* @param n {@link #node}
* @param analysis {@link #analysis}
* @param to a transfer result
*/
public TransferInput(Node n, Analysis analysis, TransferResult to) {
this(
n,
to.containsTwoStores() ? null : to.getRegularStore(),
to.containsTwoStores() ? to.getThenStore() : null,
to.containsTwoStores() ? to.getElseStore() : null,
analysis);
}
/**
* Create a {@link TransferInput}, given a store and a node-value mapping.
*
* Aliasing: The store {@code s} will be stored internally and is not allowed to be
* used elsewhere. Full control over {@code s} is transferred to this object.
*
*
The node-value mapping {@code nodeValues} is provided by the analysis and is only read from
* within this {@link TransferInput}.
*
* @param n {@link #node}
* @param analysis {@link #analysis}
* @param s {@link #store}
*/
public TransferInput(@Nullable Node n, Analysis analysis, S s) {
this(n, s, null, null, analysis);
}
/**
* Create a {@link TransferInput}, given two stores and a node-value mapping.
*
* Aliasing: The two stores {@code s1} and {@code s2} will be stored internally and
* are not allowed to be used elsewhere. Full control of them is transferred to this object.
*
* @param n a node
* @param analysis {@link #analysis}
* @param s1 {@link #thenStore}
* @param s2 {@link #elseStore}
*/
public TransferInput(@Nullable Node n, Analysis analysis, S s1, S s2) {
this(n, null, s1, s2, analysis);
}
/**
* Copy constructor.
*
* @param from a {@link TransferInput} to copy
*/
@SuppressWarnings("nullness:dereference.of.nullable") // object invariant: store vs thenStore
protected TransferInput(TransferInput from) {
this(
from.node,
from.store == null ? null : from.store.copy(),
from.store == null ? from.thenStore.copy() : null,
from.store == null ? from.elseStore.copy() : null,
from.analysis);
}
/**
* Returns the {@link Node} for this {@link TransferInput}.
*
* @return the {@link Node} for this {@link TransferInput}
*/
public @Nullable Node getNode() {
return node;
}
/**
* Returns the abstract value of node {@code n}, which is required to be a 'sub-node' (that is, a
* direct or indirect child) of the node this transfer input is associated with. Furthermore,
* {@code n} cannot be a l-value node. Returns {@code null} if no value is available.
*
* @param n a node
* @return the abstract value of node {@code n}, or {@code null} if no value is available
*/
public @Nullable V getValueOfSubNode(Node n) {
return analysis.getValue(n);
}
/**
* Returns the regular result store produced if no exception is thrown by the {@link Node}
* corresponding to this transfer function result.
*
* @return the regular result store produced if no exception is thrown by the {@link Node}
* corresponding to this transfer function result
*/
public S getRegularStore() {
if (store == null) {
assert thenStore != null && elseStore != null : "@AssumeAssertion(nullness): invariant";
return thenStore.leastUpperBound(elseStore);
} else {
return store;
}
}
/**
* Returns the result store produced if the {@link Node} this result belongs to evaluates to
* {@code true}.
*
* @return the result store produced if the {@link Node} this result belongs to evaluates to
* {@code true}
*/
public S getThenStore() {
if (store == null) {
assert thenStore != null : "@AssumeAssertion(nullness): invariant";
return thenStore;
}
return store;
}
/**
* Returns the result store produced if the {@link Node} this result belongs to evaluates to
* {@code false}.
*
* @return the result store produced if the {@link Node} this result belongs to evaluates to
* {@code false}
*/
public S getElseStore() {
if (store == null) {
assert elseStore != null : "@AssumeAssertion(nullness): invariant";
return elseStore;
}
// copy the store such that it is the same as the result of getThenStore
// (that is, identical according to equals), but two different objects.
return store.copy();
}
/**
* Returns {@code true} if and only if this transfer input contains two stores that are
* potentially not equal. Note that the result {@code true} does not imply that {@code
* getRegularStore} cannot be called (or vice versa for {@code false}). Rather, it indicates that
* {@code getThenStore} or {@code getElseStore} can be used to give more precise results.
* Otherwise, if the result is {@code false}, then all three methods {@code getRegularStore},
* {@code getThenStore}, and {@code getElseStore} return equivalent stores.
*
* @return {@code true} if and only if this transfer input contains two stores that are
* potentially not equal
*/
public boolean containsTwoStores() {
return store == null;
}
/**
* Returns an exact copy of this store.
*
* @return an exact copy of this store
*/
public TransferInput copy() {
return new TransferInput<>(this);
}
/**
* Compute the least upper bound of two stores.
*
* Important: This method must fulfill the same contract as {@code leastUpperBound} of
* {@link Store}.
*
* @param other a transfer input
* @return the least upper bound of this and {@code other}
*/
public TransferInput leastUpperBound(TransferInput other) {
if (store == null) {
S newThenStore = getThenStore().leastUpperBound(other.getThenStore());
S newElseStore = getElseStore().leastUpperBound(other.getElseStore());
return new TransferInput<>(node, analysis, newThenStore, newElseStore);
} else {
if (other.store == null) {
// make sure we do not lose precision and keep two stores if at
// least one of the two TransferInput's has two stores.
return other.leastUpperBound(this);
}
return new TransferInput<>(node, analysis, store.leastUpperBound(other.getRegularStore()));
}
}
@Override
public boolean equals(@Nullable Object o) {
if (o instanceof TransferInput) {
@SuppressWarnings("unchecked")
TransferInput other = (TransferInput) o;
if (containsTwoStores()) {
if (other.containsTwoStores()) {
return getThenStore().equals(other.getThenStore())
&& getElseStore().equals(other.getElseStore());
}
} else {
if (!other.containsTwoStores()) {
return getRegularStore().equals(other.getRegularStore());
}
}
}
return false;
}
@Override
public int hashCode() {
return Objects.hash(this.analysis, this.node, this.store, this.thenStore, this.elseStore);
}
@Override
public String toString() {
if (store == null) {
return "[then="
+ StringsPlume.indentLinesExceptFirst(2, thenStore)
+ ","
+ System.lineSeparator()
+ " else="
+ StringsPlume.indentLinesExceptFirst(2, elseStore)
+ "]";
} else {
return "[" + store + "]";
}
}
}