/* * Copyright (c) 2017 - present Facebook, Inc. * All rights reserved. * * This source code is licensed under the BSD style license found in the * LICENSE file in the root directory of this source tree. An additional grant * of patent rights can be found in the PATENTS file in the same directory. */ package codetoanalyze.java.checkers; import java.lang.annotation.ElementType; import java.lang.annotation.Retention; import java.lang.annotation.RetentionPolicy; import java.lang.annotation.Target; import java.util.Collections; import java.util.HashMap; import java.util.Map; import android.support.annotation.UiThread; import com.facebook.infer.annotation.Functional; import com.facebook.infer.annotation.ReturnsOwnership; import com.facebook.infer.annotation.SynchronizedCollection; import com.facebook.infer.annotation.ThreadConfined; import com.facebook.infer.annotation.ThreadSafe; /** tests for classes and method annotations that are meaningful w.r.t thread-safety */ @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface OnBind { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface OnEvent { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface OnMount { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface OnUnbind { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface OnUnmount { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface MyThreadSafeAlias1 { } @Target(ElementType.METHOD) @Retention(RetentionPolicy.CLASS) @interface MyThreadSafeAlias2 { } @Target(ElementType.PARAMETER) @Retention(RetentionPolicy.CLASS) @interface InjectProp { } interface Interface { @Functional Object functionalMethod(); @ReturnsOwnership Obj returnsOwnershipMethod(); } @ThreadSafe(enableChecks = false) class AssumedThreadSafe { Object field; public void writeOk() { this.field = new Object(); } } // this annotation is defined as an alias for @ThreadSafe in .inferconfig class ThreadSafeAlias { Object field; @MyThreadSafeAlias1 void threadSafeAliasBad1() { this.field = new Object(); } @MyThreadSafeAlias2 void threadSafeAliasBad2() { this.field = new Object(); } } @ThreadSafe class Annotations implements Interface { Object f; boolean b; @UiThread public void setF(Object newF) { this.f = newF; // shouldn't report here } public void callSetFOnMethodOk(Annotations obj) { obj.setF(new Object()); // or here } public void mutateOffUiThreadBad() { this.f = new Object(); } // anything annotated with OnEvent is modeled as running on the UI thread, should not warn @OnEvent public void onClick() { this.f = new Object(); } Confined con; public void confinedCallerOk(){ con.foo(); } public void writeFieldOfConfinedClassOk() { con.x = 7; } @ThreadConfined(ThreadConfined.UI) class Confined { Integer x; void foo(){ x = 22; } } @ThreadConfined(ThreadConfined.ANY) Obj encapsulatedField; public void mutateConfinedFieldDirectlyOk() { this.encapsulatedField = new Obj(); } public static void mutateConfinedFieldIndirectlyOk(Annotations a) { a.encapsulatedField = new Obj(); } public void mutateSubfieldOfConfinedBad() { this.encapsulatedField.f = new Object(); } Integer zz; @ThreadConfined("some_custom_string") public void threadConfinedMethodOk() { this.f = new Object(); zz = 22; } public void read_from_non_confined_method_Bad(){ Integer i; i = zz; } /* Like in RaceWithMainThread.java with assertMainThread() */ void conditional1_ok(boolean b){ if (b) { write_on_main_thread_ok(); } } Integer ii; @ThreadConfined(ThreadConfined.UI) void write_on_main_thread_ok(){ ii = 22; } void conditional2_bad(boolean b){ if (b) { write_on_main_thread_ok(); } else { ii = 99; // this might or might not run on the main thread; warn } } @OnBind public void onBindMethodOk() { this.f = new Object(); } public void read_off_UI_thread_Bad(){ Object o = f; } @OnMount public void onMountMethodOk() { this.f = new Object(); } @OnUnmount public void onUnmountMethodOk() { this.f = new Object(); } @OnUnbind public void onUnbindMethodOk() { this.f = new Object(); } @ThreadSafe(enableChecks = false) public void assumeThreadSafeOk() { this.f = new Object(); } @Functional native Object returnFunctional1(); @Functional Object returnFunctional2() { return null; } // marked @Functional in interface @Override public Object functionalMethod() { return null; } Object mAssignToFunctional; public Object functionalOk1() { if (mAssignToFunctional == null) { mAssignToFunctional = returnFunctional1(); } return mAssignToFunctional; } public Object functionalOk2() { if (mAssignToFunctional == null) { mAssignToFunctional = returnFunctional2(); } return mAssignToFunctional; } public Object functionalOk3() { if (mAssignToFunctional == null) { mAssignToFunctional = functionalMethod(); } return mAssignToFunctional; } @Functional native double returnDouble(); @Functional native long returnLong(); double mDouble; long mLong; int mInt1; int mInt2; public int functionalAcrossUnboxingAndCast1Ok() { if (b) { mInt1 = (int) returnDouble(); } return 0; } public int functionalAcrossUnboxingAndCast2Ok() { if (b) { mInt2 = (int) returnLong(); } return 0; } // writes to doubles are not atomic on all platforms, so this is not a benign race public double functionalDoubleBad() { if (b) { mDouble = returnDouble(); } return 0.0; } // writes to longs are not atomic on all platforms, so this is not a benign race public long functionaLongBad() { if (b) { mLong = returnLong(); } return 2; } Boolean mBoxedBool; @Functional native boolean returnBool(); public boolean functionalAcrossBoxingOk() { if (b) { mBoxedBool = returnBool(); } return b; } boolean mBool; @Functional native Boolean returnBoxedBool(); boolean mBool2; public boolean FP_functionalAcrossUnboxingOk() { if (b) { mBool2 = returnBoxedBool(); } return b; } Long mBoxedLong; @Functional native Long returnBoxedLong(); public int functionalBoxedLongOk() { if (b) { mBoxedLong = returnBoxedLong(); } return 22; } long mLong2; public int functionalAcrossUnboxingLongBad() { if (b) { mLong2 = returnBoxedLong(); } return 2; } long mBoxedLong2; public int FP_functionalAcrossBoxingLongOk() { if (b) { mBoxedLong2 = returnLong(); } return 2; } public boolean propagateFunctional() { return returnBool(); } // show that we can handle indirect returns of procedures marked @Functional public void propagateFunctionalOk() { boolean returnedFunctional = propagateFunctional(); mBool = returnedFunctional; } @Functional native int returnInt(); int mInt; public void functionalAcrossLogicalOpsOk() { boolean functionalBool = returnBool(); int functionalInt = returnInt(); boolean propagated = functionalBool && true || 2 < returnInt() && 3 == functionalInt; mBool = propagated; } public void functionalAcrossArithmeticOpsOk() { int functional = returnInt(); int propagated = functional + 1 - returnInt() * 7 % 2; mInt = functional; } native int returnNonFunctionalInt(); public void functionalAndNonfunctionalBad() { mInt = returnNonFunctionalInt() + returnInt(); } @ReturnsOwnership native Obj returnsOwned(); @Override public native Obj returnsOwnershipMethod(); // marked @ReturnsOwnership in interface void mutateAnnotatedOwnedOk() { Obj owned = returnsOwned(); owned.f = new Object(); } void mutateAnnotatedOverrideOwnedOk() { Obj owned = returnsOwnershipMethod(); owned.f = new Object(); } public void writeToAssumedThreadSafeClassOk(AssumedThreadSafe c) { c.writeOk(); } @SynchronizedCollection private final Map mSynchronizedMap = Collections.synchronizedMap(new HashMap()); public void synchronizedMapOk1() { mSynchronizedMap.put(new Object(), new Object()); } public void synchronizedMapOk2(Annotations a) { a.mSynchronizedMap.put(new Object(), new Object()); } public void injectPropOk(@InjectProp Obj o) { o.f = 7; } }