package ebpf import ( "fmt" "strings" "github.com/cilium/ebpf/internal" "github.com/cilium/ebpf/internal/btf" "github.com/cilium/ebpf/internal/unix" "golang.org/x/xerrors" ) // Errors returned by Map and MapIterator methods. var ( ErrKeyNotExist = xerrors.New("key does not exist") ErrIterationAborted = xerrors.New("iteration aborted") ) // MapID represents the unique ID of an eBPF map type MapID uint32 // MapSpec defines a Map. type MapSpec struct { // Name is passed to the kernel as a debug aid. Must only contain // alpha numeric and '_' characters. Name string Type MapType KeySize uint32 ValueSize uint32 MaxEntries uint32 Flags uint32 // The initial contents of the map. May be nil. Contents []MapKV // Whether to freeze a map after setting its initial contents. Freeze bool // InnerMap is used as a template for ArrayOfMaps and HashOfMaps InnerMap *MapSpec // The BTF associated with this map. BTF *btf.Map } func (ms *MapSpec) String() string { return fmt.Sprintf("%s(keySize=%d, valueSize=%d, maxEntries=%d, flags=%d)", ms.Type, ms.KeySize, ms.ValueSize, ms.MaxEntries, ms.Flags) } // Copy returns a copy of the spec. // // MapSpec.Contents is a shallow copy. func (ms *MapSpec) Copy() *MapSpec { if ms == nil { return nil } cpy := *ms cpy.Contents = make([]MapKV, len(ms.Contents)) copy(cpy.Contents, ms.Contents) cpy.InnerMap = ms.InnerMap.Copy() return &cpy } // MapKV is used to initialize the contents of a Map. type MapKV struct { Key interface{} Value interface{} } // Map represents a Map file descriptor. // // It is not safe to close a map which is used by other goroutines. // // Methods which take interface{} arguments by default encode // them using binary.Read/Write in the machine's native endianness. // // Implement encoding.BinaryMarshaler or encoding.BinaryUnmarshaler // if you require custom encoding. type Map struct { name string fd *internal.FD abi MapABI // Per CPU maps return values larger than the size in the spec fullValueSize int } // NewMapFromFD creates a map from a raw fd. // // You should not use fd after calling this function. func NewMapFromFD(fd int) (*Map, error) { if fd < 0 { return nil, xerrors.New("invalid fd") } bpfFd := internal.NewFD(uint32(fd)) name, abi, err := newMapABIFromFd(bpfFd) if err != nil { bpfFd.Forget() return nil, err } return newMap(bpfFd, name, abi) } // NewMap creates a new Map. // // Creating a map for the first time will perform feature detection // by creating small, temporary maps. func NewMap(spec *MapSpec) (*Map, error) { if spec.BTF == nil { return newMapWithBTF(spec, nil) } handle, err := btf.NewHandle(btf.MapSpec(spec.BTF)) if err != nil && !xerrors.Is(err, btf.ErrNotSupported) { return nil, xerrors.Errorf("can't load BTF: %w", err) } return newMapWithBTF(spec, handle) } func newMapWithBTF(spec *MapSpec, handle *btf.Handle) (*Map, error) { if spec.Type != ArrayOfMaps && spec.Type != HashOfMaps { return createMap(spec, nil, handle) } if spec.InnerMap == nil { return nil, xerrors.Errorf("%s requires InnerMap", spec.Type) } template, err := createMap(spec.InnerMap, nil, handle) if err != nil { return nil, err } defer template.Close() return createMap(spec, template.fd, handle) } func createMap(spec *MapSpec, inner *internal.FD, handle *btf.Handle) (*Map, error) { abi := newMapABIFromSpec(spec) switch spec.Type { case ArrayOfMaps: fallthrough case HashOfMaps: if err := haveNestedMaps(); err != nil { return nil, err } if abi.ValueSize != 0 && abi.ValueSize != 4 { return nil, xerrors.New("ValueSize must be zero or four for map of map") } abi.ValueSize = 4 case PerfEventArray: if abi.KeySize != 0 && abi.KeySize != 4 { return nil, xerrors.New("KeySize must be zero or four for perf event array") } abi.KeySize = 4 if abi.ValueSize != 0 && abi.ValueSize != 4 { return nil, xerrors.New("ValueSize must be zero or four for perf event array") } abi.ValueSize = 4 if abi.MaxEntries == 0 { n, err := internal.PossibleCPUs() if err != nil { return nil, xerrors.Errorf("perf event array: %w", err) } abi.MaxEntries = uint32(n) } } if abi.Flags&(unix.BPF_F_RDONLY_PROG|unix.BPF_F_WRONLY_PROG) > 0 || spec.Freeze { if err := haveMapMutabilityModifiers(); err != nil { return nil, xerrors.Errorf("map create: %w", err) } } attr := bpfMapCreateAttr{ mapType: abi.Type, keySize: abi.KeySize, valueSize: abi.ValueSize, maxEntries: abi.MaxEntries, flags: abi.Flags, } if inner != nil { var err error attr.innerMapFd, err = inner.Value() if err != nil { return nil, xerrors.Errorf("map create: %w", err) } } if handle != nil && spec.BTF != nil { attr.btfFd = uint32(handle.FD()) attr.btfKeyTypeID = btf.MapKey(spec.BTF).ID() attr.btfValueTypeID = btf.MapValue(spec.BTF).ID() } if haveObjName() == nil { attr.mapName = newBPFObjName(spec.Name) } fd, err := bpfMapCreate(&attr) if err != nil { return nil, xerrors.Errorf("map create: %w", err) } m, err := newMap(fd, spec.Name, abi) if err != nil { return nil, err } if err := m.populate(spec.Contents); err != nil { m.Close() return nil, xerrors.Errorf("map create: can't set initial contents: %w", err) } if spec.Freeze { if err := m.Freeze(); err != nil { m.Close() return nil, xerrors.Errorf("can't freeze map: %w", err) } } return m, nil } func newMap(fd *internal.FD, name string, abi *MapABI) (*Map, error) { m := &Map{ name, fd, *abi, int(abi.ValueSize), } if !abi.Type.hasPerCPUValue() { return m, nil } possibleCPUs, err := internal.PossibleCPUs() if err != nil { return nil, err } m.fullValueSize = align(int(abi.ValueSize), 8) * possibleCPUs return m, nil } func (m *Map) String() string { if m.name != "" { return fmt.Sprintf("%s(%s)#%v", m.abi.Type, m.name, m.fd) } return fmt.Sprintf("%s#%v", m.abi.Type, m.fd) } // ABI gets the ABI of the Map func (m *Map) ABI() MapABI { return m.abi } // Lookup retrieves a value from a Map. // // Calls Close() on valueOut if it is of type **Map or **Program, // and *valueOut is not nil. // // Returns an error if the key doesn't exist, see IsNotExist. func (m *Map) Lookup(key, valueOut interface{}) error { valuePtr, valueBytes := makeBuffer(valueOut, m.fullValueSize) if err := m.lookup(key, valuePtr); err != nil { return err } if valueBytes == nil { return nil } if m.abi.Type.hasPerCPUValue() { return unmarshalPerCPUValue(valueOut, int(m.abi.ValueSize), valueBytes) } switch value := valueOut.(type) { case **Map: m, err := unmarshalMap(valueBytes) if err != nil { return err } (*value).Close() *value = m return nil case *Map: return xerrors.Errorf("can't unmarshal into %T, need %T", value, (**Map)(nil)) case Map: return xerrors.Errorf("can't unmarshal into %T, need %T", value, (**Map)(nil)) case **Program: p, err := unmarshalProgram(valueBytes) if err != nil { return err } (*value).Close() *value = p return nil case *Program: return xerrors.Errorf("can't unmarshal into %T, need %T", value, (**Program)(nil)) case Program: return xerrors.Errorf("can't unmarshal into %T, need %T", value, (**Program)(nil)) default: return unmarshalBytes(valueOut, valueBytes) } } // LookupAndDelete retrieves and deletes a value from a Map. // // Returns ErrKeyNotExist if the key doesn't exist. func (m *Map) LookupAndDelete(key, valueOut interface{}) error { valuePtr, valueBytes := makeBuffer(valueOut, m.fullValueSize) keyPtr, err := marshalPtr(key, int(m.abi.KeySize)) if err != nil { return xerrors.Errorf("can't marshal key: %w", err) } if err := bpfMapLookupAndDelete(m.fd, keyPtr, valuePtr); err != nil { return xerrors.Errorf("lookup and delete failed: %w", err) } return unmarshalBytes(valueOut, valueBytes) } // LookupBytes gets a value from Map. // // Returns a nil value if a key doesn't exist. func (m *Map) LookupBytes(key interface{}) ([]byte, error) { valueBytes := make([]byte, m.fullValueSize) valuePtr := internal.NewSlicePointer(valueBytes) err := m.lookup(key, valuePtr) if xerrors.Is(err, ErrKeyNotExist) { return nil, nil } return valueBytes, err } func (m *Map) lookup(key interface{}, valueOut internal.Pointer) error { keyPtr, err := marshalPtr(key, int(m.abi.KeySize)) if err != nil { return xerrors.Errorf("can't marshal key: %w", err) } if err = bpfMapLookupElem(m.fd, keyPtr, valueOut); err != nil { return xerrors.Errorf("lookup failed: %w", err) } return nil } // MapUpdateFlags controls the behaviour of the Map.Update call. // // The exact semantics depend on the specific MapType. type MapUpdateFlags uint64 const ( // UpdateAny creates a new element or update an existing one. UpdateAny MapUpdateFlags = iota // UpdateNoExist creates a new element. UpdateNoExist MapUpdateFlags = 1 << (iota - 1) // UpdateExist updates an existing element. UpdateExist ) // Put replaces or creates a value in map. // // It is equivalent to calling Update with UpdateAny. func (m *Map) Put(key, value interface{}) error { return m.Update(key, value, UpdateAny) } // Update changes the value of a key. func (m *Map) Update(key, value interface{}, flags MapUpdateFlags) error { keyPtr, err := marshalPtr(key, int(m.abi.KeySize)) if err != nil { return xerrors.Errorf("can't marshal key: %w", err) } var valuePtr internal.Pointer if m.abi.Type.hasPerCPUValue() { valuePtr, err = marshalPerCPUValue(value, int(m.abi.ValueSize)) } else { valuePtr, err = marshalPtr(value, int(m.abi.ValueSize)) } if err != nil { return xerrors.Errorf("can't marshal value: %w", err) } if err = bpfMapUpdateElem(m.fd, keyPtr, valuePtr, uint64(flags)); err != nil { return xerrors.Errorf("update failed: %w", err) } return nil } // Delete removes a value. // // Returns ErrKeyNotExist if the key does not exist. func (m *Map) Delete(key interface{}) error { keyPtr, err := marshalPtr(key, int(m.abi.KeySize)) if err != nil { return xerrors.Errorf("can't marshal key: %w", err) } if err = bpfMapDeleteElem(m.fd, keyPtr); err != nil { return xerrors.Errorf("delete failed: %w", err) } return nil } // NextKey finds the key following an initial key. // // See NextKeyBytes for details. // // Returns ErrKeyNotExist if there is no next key. func (m *Map) NextKey(key, nextKeyOut interface{}) error { nextKeyPtr, nextKeyBytes := makeBuffer(nextKeyOut, int(m.abi.KeySize)) if err := m.nextKey(key, nextKeyPtr); err != nil { return err } if nextKeyBytes == nil { return nil } if err := unmarshalBytes(nextKeyOut, nextKeyBytes); err != nil { return xerrors.Errorf("can't unmarshal next key: %w", err) } return nil } // NextKeyBytes returns the key following an initial key as a byte slice. // // Passing nil will return the first key. // // Use Iterate if you want to traverse all entries in the map. // // Returns nil if there are no more keys. func (m *Map) NextKeyBytes(key interface{}) ([]byte, error) { nextKey := make([]byte, m.abi.KeySize) nextKeyPtr := internal.NewSlicePointer(nextKey) err := m.nextKey(key, nextKeyPtr) if xerrors.Is(err, ErrKeyNotExist) { return nil, nil } return nextKey, err } func (m *Map) nextKey(key interface{}, nextKeyOut internal.Pointer) error { var ( keyPtr internal.Pointer err error ) if key != nil { keyPtr, err = marshalPtr(key, int(m.abi.KeySize)) if err != nil { return xerrors.Errorf("can't marshal key: %w", err) } } if err = bpfMapGetNextKey(m.fd, keyPtr, nextKeyOut); err != nil { return xerrors.Errorf("next key failed: %w", err) } return nil } // Iterate traverses a map. // // It's safe to create multiple iterators at the same time. // // It's not possible to guarantee that all keys in a map will be // returned if there are concurrent modifications to the map. func (m *Map) Iterate() *MapIterator { return newMapIterator(m) } // Close removes a Map func (m *Map) Close() error { if m == nil { // This makes it easier to clean up when iterating maps // of maps / programs. return nil } return m.fd.Close() } // FD gets the file descriptor of the Map. // // Calling this function is invalid after Close has been called. func (m *Map) FD() int { fd, err := m.fd.Value() if err != nil { // Best effort: -1 is the number most likely to be an // invalid file descriptor. return -1 } return int(fd) } // Clone creates a duplicate of the Map. // // Closing the duplicate does not affect the original, and vice versa. // Changes made to the map are reflected by both instances however. // // Cloning a nil Map returns nil. func (m *Map) Clone() (*Map, error) { if m == nil { return nil, nil } dup, err := m.fd.Dup() if err != nil { return nil, xerrors.Errorf("can't clone map: %w", err) } return newMap(dup, m.name, &m.abi) } // Pin persists the map past the lifetime of the process that created it. // // This requires bpffs to be mounted above fileName. See http://cilium.readthedocs.io/en/doc-1.0/kubernetes/install/#mounting-the-bpf-fs-optional func (m *Map) Pin(fileName string) error { return bpfPinObject(fileName, m.fd) } // Freeze prevents a map to be modified from user space. // // It makes no changes to kernel-side restrictions. func (m *Map) Freeze() error { if err := haveMapMutabilityModifiers(); err != nil { return xerrors.Errorf("can't freeze map: %w", err) } if err := bpfMapFreeze(m.fd); err != nil { return xerrors.Errorf("can't freeze map: %w", err) } return nil } func (m *Map) populate(contents []MapKV) error { for _, kv := range contents { if err := m.Put(kv.Key, kv.Value); err != nil { return xerrors.Errorf("key %v: %w", kv.Key, err) } } return nil } // LoadPinnedMap load a Map from a BPF file. // // The function is not compatible with nested maps. // Use LoadPinnedMapExplicit in these situations. func LoadPinnedMap(fileName string) (*Map, error) { fd, err := bpfGetObject(fileName) if err != nil { return nil, err } name, abi, err := newMapABIFromFd(fd) if err != nil { _ = fd.Close() return nil, err } return newMap(fd, name, abi) } // LoadPinnedMapExplicit loads a map with explicit parameters. func LoadPinnedMapExplicit(fileName string, abi *MapABI) (*Map, error) { fd, err := bpfGetObject(fileName) if err != nil { return nil, err } return newMap(fd, "", abi) } func unmarshalMap(buf []byte) (*Map, error) { if len(buf) != 4 { return nil, xerrors.New("map id requires 4 byte value") } // Looking up an entry in a nested map or prog array returns an id, // not an fd. id := internal.NativeEndian.Uint32(buf) return NewMapFromID(MapID(id)) } // MarshalBinary implements BinaryMarshaler. func (m *Map) MarshalBinary() ([]byte, error) { fd, err := m.fd.Value() if err != nil { return nil, err } buf := make([]byte, 4) internal.NativeEndian.PutUint32(buf, fd) return buf, nil } func patchValue(value []byte, typ btf.Type, replacements map[string]interface{}) error { replaced := make(map[string]bool) replace := func(name string, offset, size int, replacement interface{}) error { if offset+size > len(value) { return xerrors.Errorf("%s: offset %d(+%d) is out of bounds", name, offset, size) } buf, err := marshalBytes(replacement, size) if err != nil { return xerrors.Errorf("marshal %s: %w", name, err) } copy(value[offset:offset+size], buf) replaced[name] = true return nil } switch parent := typ.(type) { case *btf.Datasec: for _, secinfo := range parent.Vars { name := string(secinfo.Type.(*btf.Var).Name) replacement, ok := replacements[name] if !ok { continue } err := replace(name, int(secinfo.Offset), int(secinfo.Size), replacement) if err != nil { return err } } default: return xerrors.Errorf("patching %T is not supported", typ) } if len(replaced) == len(replacements) { return nil } var missing []string for name := range replacements { if !replaced[name] { missing = append(missing, name) } } if len(missing) == 1 { return xerrors.Errorf("unknown field: %s", missing[0]) } return xerrors.Errorf("unknown fields: %s", strings.Join(missing, ",")) } // MapIterator iterates a Map. // // See Map.Iterate. type MapIterator struct { target *Map prevKey interface{} prevBytes []byte count, maxEntries uint32 done bool err error } func newMapIterator(target *Map) *MapIterator { return &MapIterator{ target: target, maxEntries: target.abi.MaxEntries, prevBytes: make([]byte, int(target.abi.KeySize)), } } // Next decodes the next key and value. // // Iterating a hash map from which keys are being deleted is not // safe. You may see the same key multiple times. Iteration may // also abort with an error, see IsIterationAborted. // // Returns false if there are no more entries. You must check // the result of Err afterwards. // // See Map.Get for further caveats around valueOut. func (mi *MapIterator) Next(keyOut, valueOut interface{}) bool { if mi.err != nil || mi.done { return false } for ; mi.count < mi.maxEntries; mi.count++ { var nextBytes []byte nextBytes, mi.err = mi.target.NextKeyBytes(mi.prevKey) if mi.err != nil { return false } if nextBytes == nil { mi.done = true return false } // The user can get access to nextBytes since unmarshalBytes // does not copy when unmarshaling into a []byte. // Make a copy to prevent accidental corruption of // iterator state. copy(mi.prevBytes, nextBytes) mi.prevKey = mi.prevBytes mi.err = mi.target.Lookup(nextBytes, valueOut) if xerrors.Is(mi.err, ErrKeyNotExist) { // Even though the key should be valid, we couldn't look up // its value. If we're iterating a hash map this is probably // because a concurrent delete removed the value before we // could get it. This means that the next call to NextKeyBytes // is very likely to restart iteration. // If we're iterating one of the fd maps like // ProgramArray it means that a given slot doesn't have // a valid fd associated. It's OK to continue to the next slot. continue } if mi.err != nil { return false } mi.err = unmarshalBytes(keyOut, nextBytes) return mi.err == nil } mi.err = xerrors.Errorf("%w", ErrIterationAborted) return false } // Err returns any encountered error. // // The method must be called after Next returns nil. // // Returns ErrIterationAborted if it wasn't possible to do a full iteration. func (mi *MapIterator) Err() error { return mi.err } // MapGetNextID returns the ID of the next eBPF map. // // Returns ErrNotExist, if there is no next eBPF map. func MapGetNextID(startID MapID) (MapID, error) { id, err := objGetNextID(_MapGetNextID, uint32(startID)) return MapID(id), err } // NewMapFromID returns the map for a given id. // // Returns ErrNotExist, if there is no eBPF map with the given id. func NewMapFromID(id MapID) (*Map, error) { fd, err := bpfObjGetFDByID(_MapGetFDByID, uint32(id)) if err != nil { return nil, err } name, abi, err := newMapABIFromFd(fd) if err != nil { _ = fd.Close() return nil, err } return newMap(fd, name, abi) } // ID returns the systemwide unique ID of the map. func (m *Map) ID() (MapID, error) { info, err := bpfGetMapInfoByFD(m.fd) if err != nil { return MapID(0), err } return MapID(info.id), nil }