// Copyright 2018 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 ptrace provides a ptrace-based implementation of the platform // interface. This is useful for development and testing purposes primarily, // and runs on stock kernels without special permissions. // // In a nutshell, it works as follows: // // The creation of a new address space creates a new child processes with a // single thread which is traced by a single goroutine. // // A context is just a collection of temporary variables. Calling Switch on a // context does the following: // // Locks the runtime thread. // // Looks up a traced subprocess thread for the current runtime thread. If // none exists, the dedicated goroutine is asked to create a new stopped // thread in the subprocess. This stopped subprocess thread is then traced // by the current thread and this information is stored for subsequent // switches. // // The context is then bound with information about the subprocess thread // so that the context may be appropriately interrupted via a signal. // // The requested operation is performed in the traced subprocess thread // (e.g. set registers, execute, return). // // Lock order: // // subprocess.mu // context.mu package ptrace import ( "os" "gvisor.dev/gvisor/pkg/abi/linux" pkgcontext "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/sentry/arch" "gvisor.dev/gvisor/pkg/sentry/platform" "gvisor.dev/gvisor/pkg/sentry/platform/interrupt" "gvisor.dev/gvisor/pkg/sync" "gvisor.dev/gvisor/pkg/usermem" ) var ( // stubStart is the link address for our stub, and determines the // maximum user address. This is valid only after a call to stubInit. // // We attempt to link the stub here, and adjust downward as needed. stubStart uintptr = stubInitAddress // stubEnd is the first byte past the end of the stub, as with // stubStart this is valid only after a call to stubInit. stubEnd uintptr // stubInitialized controls one-time stub initialization. stubInitialized sync.Once ) type context struct { // signalInfo is the signal info, if and when a signal is received. signalInfo arch.SignalInfo // interrupt is the interrupt context. interrupt interrupt.Forwarder // mu protects the following fields. mu sync.Mutex // If lastFaultSP is non-nil, the last context switch was due to a fault // received while executing lastFaultSP. Only context.Switch may set // lastFaultSP to a non-nil value. lastFaultSP *subprocess // lastFaultAddr is the last faulting address; this is only meaningful if // lastFaultSP is non-nil. lastFaultAddr usermem.Addr // lastFaultIP is the address of the last faulting instruction; // this is also only meaningful if lastFaultSP is non-nil. lastFaultIP usermem.Addr } // Switch runs the provided context in the given address space. func (c *context) Switch(ctx pkgcontext.Context, mm platform.MemoryManager, ac arch.Context, cpu int32) (*arch.SignalInfo, usermem.AccessType, error) { as := mm.AddressSpace() s := as.(*subprocess) isSyscall := s.switchToApp(c, ac) var ( faultSP *subprocess faultAddr usermem.Addr faultIP usermem.Addr ) if !isSyscall && linux.Signal(c.signalInfo.Signo) == linux.SIGSEGV { faultSP = s faultAddr = usermem.Addr(c.signalInfo.Addr()) faultIP = usermem.Addr(ac.IP()) } // Update the context to reflect the outcome of this context switch. c.mu.Lock() lastFaultSP := c.lastFaultSP lastFaultAddr := c.lastFaultAddr lastFaultIP := c.lastFaultIP // At this point, c may not yet be in s.contexts, so c.lastFaultSP won't be // updated by s.Unmap(). This is fine; we only need to synchronize with // calls to s.Unmap() that occur after the handling of this fault. c.lastFaultSP = faultSP c.lastFaultAddr = faultAddr c.lastFaultIP = faultIP c.mu.Unlock() // Update subprocesses to reflect the outcome of this context switch. if lastFaultSP != faultSP { if lastFaultSP != nil { lastFaultSP.mu.Lock() delete(lastFaultSP.contexts, c) lastFaultSP.mu.Unlock() } if faultSP != nil { faultSP.mu.Lock() faultSP.contexts[c] = struct{}{} faultSP.mu.Unlock() } } if isSyscall { return nil, usermem.NoAccess, nil } si := c.signalInfo if faultSP == nil { // Non-fault signal. return &si, usermem.NoAccess, platform.ErrContextSignal } // Got a page fault. Ideally, we'd get real fault type here, but ptrace // doesn't expose this information. Instead, we use a simple heuristic: // // It was an instruction fault iff the faulting addr == instruction // pointer. // // It was a write fault if the fault is immediately repeated. at := usermem.Read if faultAddr == faultIP { at.Execute = true } if lastFaultSP == faultSP && lastFaultAddr == faultAddr && lastFaultIP == faultIP { at.Write = true } // Unfortunately, we have to unilaterally return ErrContextSignalCPUID // here, in case this fault was generated by a CPUID exception. There // is no way to distinguish between CPUID-generated faults and regular // page faults. return &si, at, platform.ErrContextSignalCPUID } // Interrupt interrupts the running guest application associated with this context. func (c *context) Interrupt() { c.interrupt.NotifyInterrupt() } // Release implements platform.Context.Release(). func (c *context) Release() {} // FloatingPointStateChanged implements platform.Context.FloatingPointStateChanged. func (c *context) FloatingPointStateChanged() {} // PullFullState implements platform.Context.PullFullState. func (c *context) PullFullState(as platform.AddressSpace, ac arch.Context) {} // PTrace represents a collection of ptrace subprocesses. type PTrace struct { platform.MMapMinAddr platform.NoCPUPreemptionDetection } // New returns a new ptrace-based implementation of the platform interface. func New() (*PTrace, error) { stubInitialized.Do(func() { // Initialize the stub. stubInit() // Create the master process for the global pool. This must be // done before initializing any other processes. master, err := newSubprocess(createStub) if err != nil { // Should never happen. panic("unable to initialize ptrace master: " + err.Error()) } // Set the master on the globalPool. globalPool.master = master }) return &PTrace{}, nil } // SupportsAddressSpaceIO implements platform.Platform.SupportsAddressSpaceIO. func (*PTrace) SupportsAddressSpaceIO() bool { return false } // CooperativelySchedulesAddressSpace implements platform.Platform.CooperativelySchedulesAddressSpace. func (*PTrace) CooperativelySchedulesAddressSpace() bool { return false } // MapUnit implements platform.Platform.MapUnit. func (*PTrace) MapUnit() uint64 { // The host kernel manages page tables and arbitrary-sized mappings // have effectively the same cost. return 0 } // MaxUserAddress returns the first address that may not be used by user // applications. func (*PTrace) MaxUserAddress() usermem.Addr { return usermem.Addr(stubStart) } // NewAddressSpace returns a new subprocess. func (p *PTrace) NewAddressSpace(_ interface{}) (platform.AddressSpace, <-chan struct{}, error) { as, err := newSubprocess(globalPool.master.createStub) return as, nil, err } // NewContext returns an interruptible context. func (*PTrace) NewContext() platform.Context { return &context{} } type constructor struct{} func (*constructor) New(*os.File) (platform.Platform, error) { return New() } func (*constructor) OpenDevice() (*os.File, error) { return nil, nil } // Flags implements platform.Constructor.Flags(). func (*constructor) Requirements() platform.Requirements { // TODO(b/75837838): Also set a new PID namespace so that we limit // access to other host processes. return platform.Requirements{ RequiresCapSysPtrace: true, RequiresCurrentPIDNS: true, } } func init() { platform.Register("ptrace", &constructor{}) }