// Copyright 2020 The gVisor Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package checklocks import ( "go/token" "go/types" "strings" "golang.org/x/tools/go/ssa" ) func gcd(a, b atomicAlignment) atomicAlignment { for b != 0 { a, b = b, a%b } return a } // typeAlignment returns the type alignment for the given type. func (pc *passContext) typeAlignment(pkg *types.Package, obj types.Object) atomicAlignment { requiredOffset := atomicAlignment(1) if pc.pass.ImportObjectFact(obj, &requiredOffset) { return requiredOffset } switch x := obj.Type().Underlying().(type) { case *types.Struct: fields := make([]*types.Var, x.NumFields()) for i := 0; i < x.NumFields(); i++ { fields[i] = x.Field(i) } offsets := pc.pass.TypesSizes.Offsetsof(fields) for i := 0; i < x.NumFields(); i++ { // Check the offset, and then assuming that this offset // aligns with the offset for the broader type. fieldRequired := pc.typeAlignment(pkg, fields[i]) if offsets[i]%int64(fieldRequired) != 0 { // The offset of this field is not compatible. pc.maybeFail(fields[i].Pos(), "have alignment %d, need %d", offsets[i], fieldRequired) } // Ensure the requiredOffset is the LCM of the offset. requiredOffset *= fieldRequired / gcd(requiredOffset, fieldRequired) } case *types.Array: // Export direct alignment requirements. if named, ok := x.Elem().(*types.Named); ok { requiredOffset = pc.typeAlignment(pkg, named.Obj()) } default: // Use the compiler's underlying alignment. requiredOffset = atomicAlignment(pc.pass.TypesSizes.Alignof(obj.Type().Underlying())) } if pkg == obj.Pkg() { // Cache as an object fact, to subsequent calls. Note that we // can only export object facts for the package that we are // currently analyzing. There may be no exported facts for // array types or alias types, for example. pc.pass.ExportObjectFact(obj, &requiredOffset) } return requiredOffset } // checkTypeAlignment checks the alignment of the given type. // // This calls typeAlignment, which resolves all types recursively. This method // should be called for all types individual to ensure full coverage. func (pc *passContext) checkTypeAlignment(pkg *types.Package, typ *types.Named) { _ = pc.typeAlignment(pkg, typ.Obj()) } // checkAtomicCall checks for an atomic access. // // inst is the instruction analyzed, obj is used only for maybeFail. // // If mustBeAtomic is true, then we assert that the instruction *is* an atomic // fucnction call. If it is false, then we assert that it is *not* an atomic // dispatch. // // If readOnly is true, then only atomic read access are allowed. Note that // readOnly is only meaningful if mustBeAtomic is set. func (pc *passContext) checkAtomicCall(inst ssa.Instruction, obj types.Object, mustBeAtomic, readOnly bool) { switch x := inst.(type) { case *ssa.Call: if x.Common().IsInvoke() { if mustBeAtomic { // This is an illegal interface dispatch. pc.maybeFail(inst.Pos(), "dynamic dispatch with atomic-only field") } return } fn, ok := x.Common().Value.(*ssa.Function) if !ok { if mustBeAtomic { // This is an illegal call to a non-static function. pc.maybeFail(inst.Pos(), "dispatch to non-static function with atomic-only field") } return } pkg := fn.Package() if pkg == nil { if mustBeAtomic { // This is a call to some shared wrapper function. pc.maybeFail(inst.Pos(), "dispatch to shared function or wrapper") } return } var lff lockFunctionFacts // Check for exemption. if obj := fn.Object(); obj != nil && pc.pass.ImportObjectFact(obj, &lff) && lff.Ignore { return } if name := pkg.Pkg.Name(); name != "atomic" && name != "atomicbitops" { if mustBeAtomic { // This is an illegal call to a non-atomic package function. pc.maybeFail(inst.Pos(), "dispatch to non-atomic function with atomic-only field") } return } if !mustBeAtomic { // We are *not* expecting an atomic dispatch. if _, ok := pc.forced[pc.positionKey(inst.Pos())]; !ok { pc.maybeFail(inst.Pos(), "unexpected call to atomic function") } } if !strings.HasPrefix(fn.Name(), "Load") && readOnly { // We are not allowing any reads in this context. if _, ok := pc.forced[pc.positionKey(inst.Pos())]; !ok { pc.maybeFail(inst.Pos(), "unexpected call to atomic write function, is a lock missing?") } return } default: if mustBeAtomic { // This is something else entirely. if _, ok := pc.forced[pc.positionKey(inst.Pos())]; !ok { pc.maybeFail(inst.Pos(), "illegal use of atomic-only field by %T instruction", inst) } return } } } func resolveStruct(typ types.Type) (*types.Struct, bool) { structType, ok := typ.Underlying().(*types.Struct) if ok { return structType, true } ptrType, ok := typ.Underlying().(*types.Pointer) if ok { return resolveStruct(ptrType.Elem()) } return nil, false } func findField(typ types.Type, field int) (types.Object, bool) { structType, ok := resolveStruct(typ) if !ok || field >= structType.NumFields() { return nil, false } return structType.Field(field), true } // almostInst is a generalization over ssa.Field, ssa.FieldAddr, ssa.Global. type almostInst interface { Pos() token.Pos Referrers() *[]ssa.Instruction } // checkGuards checks the guards held. // // This also enforces atomicity constraints for fields that must be accessed // atomically. The parameter isWrite indicates whether this field is used // downstream for a write operation. // // Note that this function is not called if lff.Ignore is true, since it cannot // discover any local anonymous functions or closures. func (pc *passContext) checkGuards(inst almostInst, from ssa.Value, accessObj types.Object, ls *lockState, isWrite bool) { var ( lgf lockGuardFacts guardsFound int guardsHeld = make(map[string]struct{}) // Keyed by resolved string. ) // Load the facts for the object accessed. pc.pass.ImportObjectFact(accessObj, &lgf) // Check guards held. for guardName, fgr := range lgf.GuardedBy { guardsFound++ r := fgr.resolveField(pc, ls, from) if !r.valid() { // See above; this cannot be forced. pc.maybeFail(inst.Pos(), "field %s cannot be resolved", guardName) continue } s, ok := ls.isHeld(r, isWrite) if ok { guardsHeld[s] = struct{}{} continue } if _, ok := pc.forced[pc.positionKey(inst.Pos())]; ok { // Mark this as locked, since it has been forced. All // forces are treated as an exclusive lock. s, _ := ls.lockField(r, true /* exclusive */) guardsHeld[s] = struct{}{} continue } // Note that we may allow this if the disposition is atomic, // and we are allowing atomic reads only. This will fall into // the atomic disposition check below, which asserts that the // access is atomic. Further, len(guardsHeld) < guardsFound // will be true for this case, so we require it to be // read-only. if lgf.AtomicDisposition != atomicRequired { // There is no force key, no atomic access and no lock held. pc.maybeFail(inst.Pos(), "invalid field access, %s (%s) must be locked when accessing %s (locks: %s)", guardName, s, accessObj.Name(), ls.String()) } } // Check the atomic access for this field. switch lgf.AtomicDisposition { case atomicRequired: // Check that this is used safely as an input. readOnly := len(guardsHeld) < guardsFound if refs := inst.Referrers(); refs != nil { for _, otherInst := range *refs { pc.checkAtomicCall(otherInst, accessObj, true, readOnly) } } // Check that this is not otherwise written non-atomically, // even if we do hold all the locks. if isWrite { pc.maybeFail(inst.Pos(), "non-atomic write of field %s, writes must still be atomic with locks held (locks: %s)", accessObj.Name(), ls.String()) } case atomicDisallow: // Check that this is *not* used atomically. if refs := inst.Referrers(); refs != nil { for _, otherInst := range *refs { pc.checkAtomicCall(otherInst, accessObj, false, false) } } } // Check inferred locks. if accessObj.Pkg() == pc.pass.Pkg { oo := pc.observationsFor(accessObj) oo.total++ for s, info := range ls.lockedMutexes { // Is this an object for which we have facts? If there // is no ability to name this object, then we don't // bother with any inferrence. We also ignore any self // references (e.g. accessing a mutex while you are // holding that exact mutex). if info.object == nil || accessObj == info.object { continue } // Has this already been held? if _, ok := guardsHeld[s]; ok { oo.counts[info.object]++ continue } // Is this a global? Record directly. if _, ok := from.(*ssa.Global); ok { oo.counts[info.object]++ continue } // Is the object a sibling to the accessObj? We need to // check all fields and see if they match. We accept // only siblings and globals for this recommendation. structType, ok := resolveStruct(from.Type()) if !ok { continue } for i := 0; i < structType.NumFields(); i++ { if fieldObj := structType.Field(i); fieldObj == info.object { // Add to the maybe list. oo.counts[info.object]++ } } } } } // checkFieldAccess checks the validity of a field access. func (pc *passContext) checkFieldAccess(inst almostInst, structObj ssa.Value, field int, ls *lockState, isWrite bool) { fieldObj, _ := findField(structObj.Type(), field) pc.checkGuards(inst, structObj, fieldObj, ls, isWrite) } // checkGlobalAccess checks the validity of a global access. func (pc *passContext) checkGlobalAccess(g *ssa.Global, ls *lockState, isWrite bool) { pc.checkGuards(g, g, g.Object(), ls, isWrite) } func (pc *passContext) checkCall(call callCommon, lff *lockFunctionFacts, ls *lockState) { // See: https://godoc.org/golang.org/x/tools/go/ssa#CallCommon // // "invoke" mode: Method is non-nil, and Value is the underlying value. if fn := call.Common().Method; fn != nil { var nlff lockFunctionFacts pc.pass.ImportObjectFact(fn, &nlff) nlff.Ignore = nlff.Ignore || lff.Ignore // Inherit ignore. pc.checkFunctionCall(call, fn, &nlff, ls) return } // "call" mode: when Method is nil (!IsInvoke), a CallCommon represents an ordinary // function call of the value in Value, which may be a *Builtin, a *Function or any // other value of kind 'func'. // // Value may be one of: // (a) a *Function, indicating a statically dispatched call // to a package-level function, an anonymous function, or // a method of a named type. // // (b) a *MakeClosure, indicating an immediately applied // function literal with free variables. // // (c) a *Builtin, indicating a statically dispatched call // to a built-in function. // // (d) any other value, indicating a dynamically dispatched // function call. switch fn := call.Common().Value.(type) { case *ssa.Function: nlff := lockFunctionFacts{ Ignore: lff.Ignore, // Inherit ignore. } if obj := fn.Object(); obj != nil { pc.pass.ImportObjectFact(obj, &nlff) nlff.Ignore = nlff.Ignore || lff.Ignore // See above. pc.checkFunctionCall(call, obj.(*types.Func), &nlff, ls) } else { // Anonymous functions have no facts, and cannot be // annotated. We don't check for violations using the // function facts, since they cannot exist. Instead, we // do a fresh analysis using the current lock state. fnls := ls.fork() for i, arg := range call.Common().Args { fnls.store(fn.Params[i], arg) } pc.checkFunction(call, fn, &nlff, fnls, true /* force */) } case *ssa.MakeClosure: // Note that creating and then invoking closures locally is // allowed, but analysis of passing closures is done when // checking individual instructions. pc.checkClosure(call, fn, lff, ls) default: return } } // postFunctionCallUpdate updates all conditions. func (pc *passContext) postFunctionCallUpdate(call callCommon, lff *lockFunctionFacts, ls *lockState, aliases bool) { // Release all locks not still held. for fieldName, fg := range lff.HeldOnEntry { if _, ok := lff.HeldOnExit[fieldName]; ok { continue } if fg.IsAlias && !aliases { continue } r := fg.Resolver.resolveCall(pc, ls, call.Common().Args, call.Value()) if !r.valid() { // See above: this cannot be forced. pc.maybeFail(call.Pos(), "field %s cannot be resolved", fieldName) continue } if s, ok := ls.unlockField(r, fg.Exclusive); !ok && !lff.Ignore { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok && !lff.Ignore { pc.maybeFail(call.Pos(), "attempt to release %s (%s), but not held (locks: %s)", fieldName, s, ls.String()) } } } // Update all held locks if acquired. for fieldName, fg := range lff.HeldOnExit { if _, ok := lff.HeldOnEntry[fieldName]; ok { continue } if fg.IsAlias && !aliases { continue } // Acquire the lock per the annotation. r := fg.Resolver.resolveCall(pc, ls, call.Common().Args, call.Value()) if s, ok := ls.lockField(r, fg.Exclusive); !ok && !lff.Ignore { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok && !lff.Ignore { pc.maybeFail(call.Pos(), "attempt to acquire %s (%s), but already held (locks: %s)", fieldName, s, ls.String()) } } } } // exclusiveStr returns a string describing exclusive requirements. func exclusiveStr(exclusive bool) string { if exclusive { return "exclusively" } return "non-exclusively" } // checkFunctionCall checks preconditions for function calls, and tracks the // lock state by recording relevant calls to sync functions. Note that calls to // atomic functions are tracked by checkFieldAccess by looking directly at the // referrers (because ordering doesn't matter there, so we need not scan in // instruction order). func (pc *passContext) checkFunctionCall(call callCommon, fn *types.Func, lff *lockFunctionFacts, ls *lockState) { // Extract the "receiver" properly. var args []ssa.Value if call.Common().Method != nil { // This is an interface dispatch for sync.Locker. args = append([]ssa.Value{call.Common().Value}, call.Common().Args...) } else { // This matches the signature for the relevant // sync.Lock/sync.Unlock functions below. args = call.Common().Args } // Check all guards required are held. Note that this explicitly does // not include aliases, hence false being passed below. for fieldName, fg := range lff.HeldOnEntry { if fg.IsAlias { continue } r := fg.Resolver.resolveCall(pc, ls, args, call.Value()) if s, ok := ls.isHeld(r, fg.Exclusive); !ok { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok && !lff.Ignore { pc.maybeFail(call.Pos(), "must hold %s %s (%s) to call %s, but not held (locks: %s)", fieldName, exclusiveStr(fg.Exclusive), s, fn.Name(), ls.String()) } else { // Force the lock to be acquired. ls.lockField(r, fg.Exclusive) } } } // Update all lock state accordingly. pc.postFunctionCallUpdate(call, lff, ls, false /* aliases */) // Check if it's a method dispatch for something in the sync package. // See: https://godoc.org/golang.org/x/tools/go/ssa#Function if fn.Pkg() != nil && fn.Pkg().Name() == "sync" && len(args) > 0 { rv := makeResolvedValue(args[0], nil) isExclusive := false switch fn.Name() { case "Lock": isExclusive = true fallthrough case "RLock": if s, ok := ls.lockField(rv, isExclusive); !ok && !lff.Ignore { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok { // Double locking a mutex that is already locked. pc.maybeFail(call.Pos(), "%s already locked (locks: %s)", s, ls.String()) } } case "Unlock": isExclusive = true fallthrough case "RUnlock": if s, ok := ls.unlockField(rv, isExclusive); !ok && !lff.Ignore { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok { // Unlocking something that is already unlocked. pc.maybeFail(call.Pos(), "%s already unlocked or locked differently (locks: %s)", s, ls.String()) } } case "DowngradeLock": if s, ok := ls.downgradeField(rv); !ok { if _, ok := pc.forced[pc.positionKey(call.Pos())]; !ok && !lff.Ignore { // Downgrading something that may not be downgraded. pc.maybeFail(call.Pos(), "%s already unlocked or not exclusive (locks: %s)", s, ls.String()) } } } } } // checkClosure forks the lock state, and creates a binding for the FreeVars of // the closure. This allows the analysis to resolve the closure. func (pc *passContext) checkClosure(call callCommon, fn *ssa.MakeClosure, lff *lockFunctionFacts, ls *lockState) { clls := ls.fork() clfn := fn.Fn.(*ssa.Function) for i, fv := range clfn.FreeVars { clls.store(fv, fn.Bindings[i]) } // Note that this is *not* a call to check function call, which checks // against the function preconditions. Instead, this does a fresh // analysis of the function from source code with a different state. nlff := lockFunctionFacts{ Ignore: lff.Ignore, // Inherit ignore. } pc.checkFunction(call, clfn, &nlff, clls, true /* force */) } // freshAlloc indicates that v has been allocated within the local scope. There // is no lock checking done on objects that are freshly allocated. func freshAlloc(v ssa.Value) bool { switch x := v.(type) { case *ssa.Alloc: return true case *ssa.FieldAddr: return freshAlloc(x.X) case *ssa.Field: return freshAlloc(x.X) case *ssa.IndexAddr: return freshAlloc(x.X) case *ssa.Index: return freshAlloc(x.X) case *ssa.Convert: return freshAlloc(x.X) case *ssa.ChangeType: return freshAlloc(x.X) default: return false } } // isWrite indicates that this value is used as the addr field in a store. // // Note that this may still be used for a write. The return here is optimistic // but sufficient for basic analysis. func isWrite(v ssa.Value) bool { refs := v.Referrers() if refs == nil { return false } for _, ref := range *refs { if s, ok := ref.(*ssa.Store); ok && s.Addr == v { return true } } return false } // callCommon is an ssa.Value that also implements Common. type callCommon interface { Pos() token.Pos Common() *ssa.CallCommon Value() *ssa.Call } // checkInstruction checks the legality the single instruction based on the // current lockState. func (pc *passContext) checkInstruction(inst ssa.Instruction, lff *lockFunctionFacts, ls *lockState) (*ssa.Return, *lockState) { // Record any observed globals, and check for violations. The global // value is not itself an instruction, but we check all referrers to // see where they are consumed. var stackLocal [16]*ssa.Value ops := inst.Operands(stackLocal[:]) for _, v := range ops { if v == nil { continue } g, ok := (*v).(*ssa.Global) if !ok { continue } _, isWrite := inst.(*ssa.Store) pc.checkGlobalAccess(g, ls, isWrite) } // Process the instruction. switch x := inst.(type) { case *ssa.Store: // Record that this value is holding this other value. This is // because at the beginning of each ssa execution, there is a // series of assignments of parameter values to alloc objects. // This allows us to trace these back to the original // parameters as aliases above. // // Note that this may overwrite an existing value in the lock // state, but this is intentional. ls.store(x.Addr, x.Val) case *ssa.Field: if !freshAlloc(x.X) && !lff.Ignore { pc.checkFieldAccess(x, x.X, x.Field, ls, false) } case *ssa.FieldAddr: if !freshAlloc(x.X) && !lff.Ignore { pc.checkFieldAccess(x, x.X, x.Field, ls, isWrite(x)) } case *ssa.Call: pc.checkCall(x, lff, ls) case *ssa.Defer: ls.pushDefer(x) case *ssa.RunDefers: for d := ls.popDefer(); d != nil; d = ls.popDefer() { pc.checkCall(d, lff, ls) } case *ssa.MakeClosure: if refs := x.Referrers(); refs != nil { var ( calls int nonCalls int ) for _, ref := range *refs { switch ref.(type) { case *ssa.Call, *ssa.Defer: // Analysis will be done on the call // itself subsequently, including the // lock state at the time of the call. calls++ default: // We need to analyze separately. Per // below, this means that we'll analyze // at closure construction time no zero // assumptions about when it will be // called. nonCalls++ } } if calls > 0 && nonCalls == 0 { return nil, nil } } // Analyze the closure without bindings. This means that we // assume no lock facts or have any existing lock state. Only // trivial closures are acceptable in this case. clfn := x.Fn.(*ssa.Function) nlff := lockFunctionFacts{ Ignore: lff.Ignore, // Inherit ignore. } pc.checkFunction(nil, clfn, &nlff, nil, false /* force */) case *ssa.Return: return x, ls // Valid return state. } return nil, nil } // checkBasicBlock traverses the control flow graph starting at a set of given // block and checks each instruction for allowed operations. func (pc *passContext) checkBasicBlock(fn *ssa.Function, block *ssa.BasicBlock, lff *lockFunctionFacts, parent *lockState, seen map[*ssa.BasicBlock]*lockState, rg map[*ssa.BasicBlock]struct{}) *lockState { // Check for cached results from entering this block from a *different* // execution path. Note that this is not the same path, which is // checked with the recursion guard below. if oldLS, ok := seen[block]; ok && oldLS.isCompatible(parent) { return nil } // Prevent recursion. If the lock state is constantly changing and we // are a recursive path, then there will never be a return block. if rg == nil { rg = make(map[*ssa.BasicBlock]struct{}) } if _, ok := rg[block]; ok { return nil } rg[block] = struct{}{} defer func() { delete(rg, block) }() // If the lock state is not compatible, then we need to do the // recursive analysis to ensure that it is still sane. For example, the // following is guaranteed to generate incompatible locking states: // // if foo { // mu.Lock() // } // other stuff ... // if foo { // mu.Unlock() // } var ( rv *ssa.Return rls *lockState ) // Analyze this block. seen[block] = parent ls := parent.fork() for _, inst := range block.Instrs { rv, rls = pc.checkInstruction(inst, lff, ls) if rls != nil { failed := false // Validate held locks. for fieldName, fg := range lff.HeldOnExit { r := fg.Resolver.resolveStatic(pc, ls, fn, rv) if !r.valid() { // This cannot be forced, since we have no reference. pc.maybeFail(rv.Pos(), "lock %s cannot be resolved", fieldName) continue } if s, ok := rls.isHeld(r, fg.Exclusive); !ok { if _, ok := pc.forced[pc.positionKey(rv.Pos())]; !ok && !lff.Ignore { pc.maybeFail(rv.Pos(), "lock %s (%s) not held %s (locks: %s)", fieldName, s, exclusiveStr(fg.Exclusive), rls.String()) failed = true } else { // Force the lock to be acquired. rls.lockField(r, fg.Exclusive) } } } // Check for other locks, but only if the above didn't trip. if !failed && rls.count() != len(lff.HeldOnExit) && !lff.Ignore { pc.maybeFail(rv.Pos(), "return with unexpected locks held (locks: %s)", rls.String()) } } } // Analyze all successors. for _, succ := range block.Succs { // Collect possible return values, and make sure that the lock // state aligns with any return value that we may have found // above. Note that checkBasicBlock will recursively analyze // the lock state to ensure that Releases and Acquires are // respected. if pls := pc.checkBasicBlock(fn, succ, lff, ls, seen, rg); pls != nil { if rls != nil && !rls.isCompatible(pls) { if _, ok := pc.forced[pc.positionKey(fn.Pos())]; !ok && !lff.Ignore { pc.maybeFail(fn.Pos(), "incompatible return states (first: %s, second: %s)", rls.String(), pls.String()) } } rls = pls } } return rls } // checkFunction checks a function invocation, typically starting with nil lockState. func (pc *passContext) checkFunction(call callCommon, fn *ssa.Function, lff *lockFunctionFacts, parent *lockState, force bool) { defer func() { // Mark this function as checked. This is used by the top-level // loop to ensure that all anonymous functions are scanned, if // they are not explicitly invoked here. Note that this can // happen if the anonymous functions are e.g. passed only as // parameters or used to initialize some structure. pc.functions[fn] = struct{}{} }() if _, ok := pc.functions[fn]; !force && ok { // This function has already been analyzed at least once. // That's all we permit for each function, although this may // cause some anonymous functions to be analyzed in only one // context. return } // If no return value is provided, then synthesize one. This is used // below only to check against the locks preconditions, which may // include return values. if call == nil { call = &ssa.Call{Call: ssa.CallCommon{Value: fn}} } // Initialize ls with any preconditions that require locks to be held // for the method to be invoked. Note that in the overwhleming majority // of cases, parent will be nil. However, in the case of closures and // anonymous functions, we may start with a non-nil lock state. // // Note that this will include all aliases, which are also released // appropriately below. ls := parent.fork() for fieldName, fg := range lff.HeldOnEntry { // The first is the method object itself so we skip that when looking // for receiver/function parameters. r := fg.Resolver.resolveStatic(pc, ls, fn, call.Value()) if !r.valid() { // See above: this cannot be forced. pc.maybeFail(fn.Pos(), "lock %s cannot be resolved", fieldName) continue } if s, ok := ls.lockField(r, fg.Exclusive); !ok && !lff.Ignore { // This can only happen if the same value is declared // multiple times, and should be caught by the earlier // fact scanning. Keep it here as a sanity check. pc.maybeFail(fn.Pos(), "lock %s (%s) acquired multiple times or differently (locks: %s)", fieldName, s, ls.String()) } } // Scan the blocks. seen := make(map[*ssa.BasicBlock]*lockState) if len(fn.Blocks) > 0 { pc.checkBasicBlock(fn, fn.Blocks[0], lff, ls, seen, nil) } // Scan the recover block. if fn.Recover != nil { pc.checkBasicBlock(fn, fn.Recover, lff, ls, seen, nil) } // Update all lock state accordingly. This will be called only if we // are doing inline analysis for e.g. an anonymous function. if call != nil && parent != nil { pc.postFunctionCallUpdate(call, lff, parent, true /* aliases */) } } // checkInferred checks for any inferred lock annotations. func (pc *passContext) checkInferred() { for obj, oo := range pc.observations { var lgf lockGuardFacts pc.pass.ImportObjectFact(obj, &lgf) for other, count := range oo.counts { // Is this already a guard? if _, ok := lgf.GuardedBy[other.Name()]; ok { continue } // Check to see if this field is used with a given lock // held above the threshold. If yes, provide a helpful // hint that this may something you wish to annotate. const threshold = 0.9 if usage := float64(count) / float64(oo.total); usage >= threshold { pc.maybeFail(obj.Pos(), "may require checklocks annotation for %s, used with lock held %2.0f%% of the time", other.Name(), usage*100) } } } }