// 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 marshal_test contains manual tests for the marshal interface. These // are intended to test behaviour not covered by the automatically generated // tests. package marshal_test import ( "bytes" "encoding/binary" "fmt" "reflect" "runtime" "testing" "unsafe" "github.com/google/go-cmp/cmp" "gvisor.dev/gvisor/pkg/marshal" "gvisor.dev/gvisor/pkg/syserror" "gvisor.dev/gvisor/pkg/usermem" "gvisor.dev/gvisor/tools/go_marshal/analysis" "gvisor.dev/gvisor/tools/go_marshal/test" ) var simulatedErr error = syserror.EFAULT // mockCopyContext implements marshal.CopyContext. type mockCopyContext struct { taskMem usermem.BytesIO } // populate fills the task memory with the contents of val. func (t *mockCopyContext) populate(val interface{}) { var buf bytes.Buffer // Use binary.Write so we aren't testing go-marshal against its own // potentially buggy implementation. if err := binary.Write(&buf, usermem.ByteOrder, val); err != nil { panic(err) } t.taskMem.Bytes = buf.Bytes() } func (t *mockCopyContext) setLimit(n int) { if len(t.taskMem.Bytes) < n { grown := make([]byte, n) copy(grown, t.taskMem.Bytes) t.taskMem.Bytes = grown return } t.taskMem.Bytes = t.taskMem.Bytes[:n] } // CopyScratchBuffer implements marshal.CopyContext.CopyScratchBuffer. func (t *mockCopyContext) CopyScratchBuffer(size int) []byte { return make([]byte, size) } // CopyOutBytes implements marshal.CopyContext.CopyOutBytes. The implementation // completely ignores the target address and stores a copy of b in its // internally buffer, overriding any previous contents. func (t *mockCopyContext) CopyOutBytes(_ usermem.Addr, b []byte) (int, error) { return t.taskMem.CopyOut(nil, 0, b, usermem.IOOpts{}) } // CopyInBytes implements marshal.CopyContext.CopyInBytes. The implementation // completely ignores the source address and always fills b from the begining of // its internal buffer. func (t *mockCopyContext) CopyInBytes(_ usermem.Addr, b []byte) (int, error) { return t.taskMem.CopyIn(nil, 0, b, usermem.IOOpts{}) } // unsafeMemory returns the underlying memory for m. The returned slice is only // valid for the lifetime for m. The garbage collector isn't aware that the // returned slice is related to m, the caller must ensure m lives long enough. func unsafeMemory(m marshal.Marshallable) []byte { if !m.Packed() { // We can't return a slice pointing to the underlying memory // since the layout isn't packed. Allocate a temporary buffer // and marshal instead. var buf bytes.Buffer if err := binary.Write(&buf, usermem.ByteOrder, m); err != nil { panic(err) } return buf.Bytes() } // reflect.ValueOf(m) // .Elem() // Unwrap interface to inner concrete object // .Addr() // Pointer value to object // .Pointer() // Actual address from the pointer value ptr := reflect.ValueOf(m).Elem().Addr().Pointer() size := m.SizeBytes() var mem []byte hdr := (*reflect.SliceHeader)(unsafe.Pointer(&mem)) hdr.Data = ptr hdr.Len = size hdr.Cap = size return mem } // unsafeMemorySlice returns the underlying memory for m. The returned slice is // only valid for the lifetime for m. The garbage collector isn't aware that the // returned slice is related to m, the caller must ensure m lives long enough. // // Precondition: m must be a slice. func unsafeMemorySlice(m interface{}, elt marshal.Marshallable) []byte { kind := reflect.TypeOf(m).Kind() if kind != reflect.Slice { panic("unsafeMemorySlice called on non-slice") } if !elt.Packed() { // We can't return a slice pointing to the underlying memory // since the layout isn't packed. Allocate a temporary buffer // and marshal instead. var buf bytes.Buffer if err := binary.Write(&buf, usermem.ByteOrder, m); err != nil { panic(err) } return buf.Bytes() } v := reflect.ValueOf(m) length := v.Len() * elt.SizeBytes() var mem []byte hdr := (*reflect.SliceHeader)(unsafe.Pointer(&mem)) hdr.Data = v.Pointer() // This is a pointer to the first elem for slices. hdr.Len = length hdr.Cap = length return mem } func isZeroes(buf []byte) bool { for _, b := range buf { if b != 0 { return false } } return true } // compareMemory compares the first n bytes of two chuncks of memory represented // by expected and actual. func compareMemory(t *testing.T, expected, actual []byte, n int) { t.Logf("Expected (%d): %v (%d) + (%d) %v\n", len(expected), expected[:n], n, len(expected)-n, expected[n:]) t.Logf("Actual (%d): %v (%d) + (%d) %v\n", len(actual), actual[:n], n, len(actual)-n, actual[n:]) if diff := cmp.Diff(expected[:n], actual[:n]); diff != "" { t.Errorf("Memory buffers don't match:\n--- expected only\n+++ actual only\n%v", diff) } } // limitedCopyIn populates task memory with src, then unmarshals task memory to // dst. The task signals an error at limit bytes during copy-in, which should // result in a truncated unmarshalling. func limitedCopyIn(t *testing.T, src, dst marshal.Marshallable, limit int) { var cc mockCopyContext cc.populate(src) cc.setLimit(limit) n, err := dst.CopyIn(&cc, usermem.Addr(0)) if n != limit { t.Errorf("CopyIn copied unexpected number of bytes, expected %d, got %d", limit, n) } if err != simulatedErr { t.Errorf("CopyIn returned unexpected error, expected %v, got %v", simulatedErr, err) } expectedMem := unsafeMemory(src) defer runtime.KeepAlive(src) actualMem := unsafeMemory(dst) defer runtime.KeepAlive(dst) compareMemory(t, expectedMem, actualMem, n) // The last n bytes should be zero for actual, since actual was // zero-initialized, and CopyIn shouldn't have touched those bytes. However // we can only guarantee we didn't touch anything in the last n bytes if the // layout is packed. if dst.Packed() && !isZeroes(actualMem[n:]) { t.Errorf("Expected the last %d bytes of copied in object to be zeroes, got %v\n", dst.SizeBytes()-n, actualMem) } } // limitedCopyOut marshals src to task memory. The task signals an error at // limit bytes during copy-out, which should result in a truncated marshalling. func limitedCopyOut(t *testing.T, src marshal.Marshallable, limit int) { var cc mockCopyContext cc.setLimit(limit) n, err := src.CopyOut(&cc, usermem.Addr(0)) if n != limit { t.Errorf("CopyOut copied unexpected number of bytes, expected %d, got %d", limit, n) } if err != simulatedErr { t.Errorf("CopyOut returned unexpected error, expected %v, got %v", simulatedErr, err) } expectedMem := unsafeMemory(src) defer runtime.KeepAlive(src) actualMem := cc.taskMem.Bytes compareMemory(t, expectedMem, actualMem, n) } // copyOutN marshals src to task memory, requesting the marshalling to be // limited to limit bytes. func copyOutN(t *testing.T, src marshal.Marshallable, limit int) { var cc mockCopyContext cc.setLimit(limit) n, err := src.CopyOutN(&cc, usermem.Addr(0), limit) if err != nil { t.Errorf("CopyOut returned unexpected error: %v", err) } if n != limit { t.Errorf("CopyOut copied unexpected number of bytes, expected %d, got %d", limit, n) } expectedMem := unsafeMemory(src) defer runtime.KeepAlive(src) actualMem := cc.taskMem.Bytes t.Logf("Expected: %v + %v\n", expectedMem[:n], expectedMem[n:]) t.Logf("Actual : %v + %v\n", actualMem[:n], actualMem[n:]) compareMemory(t, expectedMem, actualMem, n) } // TestLimitedMarshalling verifies marshalling/unmarshalling succeeds when the // underyling copy in/out operations partially succeed. func TestLimitedMarshalling(t *testing.T) { types := []reflect.Type{ // Packed types. reflect.TypeOf((*test.Type2)(nil)), reflect.TypeOf((*test.Type3)(nil)), reflect.TypeOf((*test.Timespec)(nil)), reflect.TypeOf((*test.Stat)(nil)), reflect.TypeOf((*test.InetAddr)(nil)), reflect.TypeOf((*test.SignalSet)(nil)), reflect.TypeOf((*test.SignalSetAlias)(nil)), // Non-packed types. reflect.TypeOf((*test.Type1)(nil)), reflect.TypeOf((*test.Type4)(nil)), reflect.TypeOf((*test.Type5)(nil)), reflect.TypeOf((*test.Type6)(nil)), reflect.TypeOf((*test.Type7)(nil)), reflect.TypeOf((*test.Type8)(nil)), } for _, tyPtr := range types { // Remove one level of pointer-indirection from the type. We get this // back when we pass the type to reflect.New. ty := tyPtr.Elem() // Partial copy-in. t.Run(fmt.Sprintf("PartialCopyIn_%v", ty), func(t *testing.T) { expected := reflect.New(ty).Interface().(marshal.Marshallable) actual := reflect.New(ty).Interface().(marshal.Marshallable) analysis.RandomizeValue(expected) limitedCopyIn(t, expected, actual, expected.SizeBytes()/2) }) // Partial copy-out. t.Run(fmt.Sprintf("PartialCopyOut_%v", ty), func(t *testing.T) { expected := reflect.New(ty).Interface().(marshal.Marshallable) analysis.RandomizeValue(expected) limitedCopyOut(t, expected, expected.SizeBytes()/2) }) // Explicitly request partial copy-out. t.Run(fmt.Sprintf("PartialCopyOutN_%v", ty), func(t *testing.T) { expected := reflect.New(ty).Interface().(marshal.Marshallable) analysis.RandomizeValue(expected) copyOutN(t, expected, expected.SizeBytes()/2) }) } } // TestLimitedMarshalling verifies marshalling/unmarshalling of slices of // marshallable types succeed when the underyling copy in/out operations // partially succeed. func TestLimitedSliceMarshalling(t *testing.T) { types := []struct { arrayPtrType reflect.Type copySliceIn func(cc marshal.CopyContext, addr usermem.Addr, dstSlice interface{}) (int, error) copySliceOut func(cc marshal.CopyContext, addr usermem.Addr, srcSlice interface{}) (int, error) unsafeMemory func(arrPtr interface{}) []byte }{ // Packed types. { reflect.TypeOf((*[20]test.Stat)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[20]test.Stat)[:] return test.CopyStatSliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[20]test.Stat)[:] return test.CopyStatSliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[20]test.Stat)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, { reflect.TypeOf((*[1]test.Stat)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[1]test.Stat)[:] return test.CopyStatSliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[1]test.Stat)[:] return test.CopyStatSliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[1]test.Stat)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, { reflect.TypeOf((*[5]test.SignalSetAlias)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[5]test.SignalSetAlias)[:] return test.CopySignalSetAliasSliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[5]test.SignalSetAlias)[:] return test.CopySignalSetAliasSliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[5]test.SignalSetAlias)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, // Non-packed types. { reflect.TypeOf((*[20]test.Type1)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[20]test.Type1)[:] return test.CopyType1SliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[20]test.Type1)[:] return test.CopyType1SliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[20]test.Type1)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, { reflect.TypeOf((*[1]test.Type1)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[1]test.Type1)[:] return test.CopyType1SliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[1]test.Type1)[:] return test.CopyType1SliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[1]test.Type1)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, { reflect.TypeOf((*[7]test.Type8)(nil)), func(cc marshal.CopyContext, addr usermem.Addr, dst interface{}) (int, error) { slice := dst.(*[7]test.Type8)[:] return test.CopyType8SliceIn(cc, addr, slice) }, func(cc marshal.CopyContext, addr usermem.Addr, src interface{}) (int, error) { slice := src.(*[7]test.Type8)[:] return test.CopyType8SliceOut(cc, addr, slice) }, func(a interface{}) []byte { slice := a.(*[7]test.Type8)[:] return unsafeMemorySlice(slice, &slice[0]) }, }, } for _, tt := range types { // The body of this loop is generic over the type tt.arrayPtrType, with // the help of reflection. To aid in readability, comments below show // the equivalent go code assuming // tt.arrayPtrType = typeof(*[20]test.Stat). // Equivalent: // var x *[20]test.Stat // arrayTy := reflect.TypeOf(*x) arrayTy := tt.arrayPtrType.Elem() // Partial copy-in of slices. t.Run(fmt.Sprintf("PartialCopySliceIn_%v", arrayTy), func(t *testing.T) { // Equivalent: // var x [20]test.Stat // length := len(x) length := arrayTy.Len() if length < 1 { panic("Test type can't be zero-length array") } // Equivalent: // elem := new(test.Stat).(marshal.Marshallable) elem := reflect.New(arrayTy.Elem()).Interface().(marshal.Marshallable) // Equivalent: // var expected, actual interface{} // expected = new([20]test.Stat) // actual = new([20]test.Stat) expected := reflect.New(arrayTy).Interface() actual := reflect.New(arrayTy).Interface() analysis.RandomizeValue(expected) limit := (length * elem.SizeBytes()) / 2 // Also make sure the limit is partially inside one of the elements. limit += elem.SizeBytes() / 2 analysis.RandomizeValue(expected) var cc mockCopyContext cc.populate(expected) cc.setLimit(limit) n, err := tt.copySliceIn(&cc, usermem.Addr(0), actual) if n != limit { t.Errorf("CopyIn copied unexpected number of bytes, expected %d, got %d", limit, n) } if n < length*elem.SizeBytes() && err != simulatedErr { t.Errorf("CopyIn returned unexpected error, expected %v, got %v", simulatedErr, err) } expectedMem := tt.unsafeMemory(expected) defer runtime.KeepAlive(expected) actualMem := tt.unsafeMemory(actual) defer runtime.KeepAlive(actual) compareMemory(t, expectedMem, actualMem, n) // The last n bytes should be zero for actual, since actual was // zero-initialized, and CopyIn shouldn't have touched those bytes. However // we can only guarantee we didn't touch anything in the last n bytes if the // layout is packed. if elem.Packed() && !isZeroes(actualMem[n:]) { t.Errorf("Expected the last %d bytes of copied in object to be zeroes, got %v\n", (elem.SizeBytes()*length)-n, actualMem) } }) // Partial copy-out of slices. t.Run(fmt.Sprintf("PartialCopySliceOut_%v", arrayTy), func(t *testing.T) { // Equivalent: // var x [20]test.Stat // length := len(x) length := arrayTy.Len() if length < 1 { panic("Test type can't be zero-length array") } // Equivalent: // elem := new(test.Stat).(marshal.Marshallable) elem := reflect.New(arrayTy.Elem()).Interface().(marshal.Marshallable) // Equivalent: // var expected, actual interface{} // expected = new([20]test.Stat) // actual = new([20]test.Stat) expected := reflect.New(arrayTy).Interface() analysis.RandomizeValue(expected) limit := (length * elem.SizeBytes()) / 2 // Also make sure the limit is partially inside one of the elements. limit += elem.SizeBytes() / 2 analysis.RandomizeValue(expected) var cc mockCopyContext cc.populate(expected) cc.setLimit(limit) n, err := tt.copySliceOut(&cc, usermem.Addr(0), expected) if n != limit { t.Errorf("CopyIn copied unexpected number of bytes, expected %d, got %d", limit, n) } if n < length*elem.SizeBytes() && err != simulatedErr { t.Errorf("CopyIn returned unexpected error, expected %v, got %v", simulatedErr, err) } expectedMem := tt.unsafeMemory(expected) defer runtime.KeepAlive(expected) actualMem := cc.taskMem.Bytes compareMemory(t, expectedMem, actualMem, n) }) } }