gotosocial/vendor/github.com/cilium/ebpf/map.go
Daniele Sluijters acc333c40b
[feature] Inherit resource limits from cgroups (#1336)
When GTS is running in a container runtime which has configured CPU or
memory limits or under an init system that uses cgroups to impose CPU
and memory limits the values the Go runtime sees for GOMAXPROCS and
GOMEMLIMIT are still based on the host resources, not the cgroup.

At least for the throttling middlewares which use GOMAXPROCS to
configure their queue size, this can result in GTS running with values
too big compared to the resources that will actuall be available to it.

This introduces 2 dependencies which can pick up resource contraints
from the current cgroup and tune the Go runtime accordingly. This should
result in the different queues being appropriately sized and in general
more predictable performance. These dependencies are a no-op on
non-Linux systems or if running in a cgroup that doesn't set a limit on
CPU or memory.

The automatic tuning of GOMEMLIMIT can be disabled by either explicitly
setting GOMEMLIMIT yourself or by setting AUTOMEMLIMIT=off. The
automatic tuning of GOMAXPROCS can similarly be counteracted by setting
GOMAXPROCS yourself.
2023-01-17 20:59:04 +00:00

1188 lines
30 KiB
Go

package ebpf
import (
"errors"
"fmt"
"io"
"path/filepath"
"reflect"
"strings"
"github.com/cilium/ebpf/internal"
"github.com/cilium/ebpf/internal/btf"
"github.com/cilium/ebpf/internal/unix"
)
// Errors returned by Map and MapIterator methods.
var (
ErrKeyNotExist = errors.New("key does not exist")
ErrKeyExist = errors.New("key already exists")
ErrIterationAborted = errors.New("iteration aborted")
)
// MapOptions control loading a map into the kernel.
type MapOptions struct {
// The base path to pin maps in if requested via PinByName.
// Existing maps will be re-used if they are compatible, otherwise an
// error is returned.
PinPath string
}
// 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
// Automatically pin and load a map from MapOptions.PinPath.
// Generates an error if an existing pinned map is incompatible with the MapSpec.
Pinning PinType
// Specify numa node during map creation
// (effective only if unix.BPF_F_NUMA_NODE flag is set,
// which can be imported from golang.org/x/sys/unix)
NumaNode 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{}
}
func (ms *MapSpec) checkCompatibility(m *Map) error {
switch {
case m.typ != ms.Type:
return fmt.Errorf("expected type %v, got %v", ms.Type, m.typ)
case m.keySize != ms.KeySize:
return fmt.Errorf("expected key size %v, got %v", ms.KeySize, m.keySize)
case m.valueSize != ms.ValueSize:
return fmt.Errorf("expected value size %v, got %v", ms.ValueSize, m.valueSize)
case m.maxEntries != ms.MaxEntries:
return fmt.Errorf("expected max entries %v, got %v", ms.MaxEntries, m.maxEntries)
case m.flags != ms.Flags:
return fmt.Errorf("expected flags %v, got %v", ms.Flags, m.flags)
}
return nil
}
// 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
typ MapType
keySize uint32
valueSize uint32
maxEntries uint32
flags uint32
pinnedPath string
// 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, errors.New("invalid fd")
}
return newMapFromFD(internal.NewFD(uint32(fd)))
}
func newMapFromFD(fd *internal.FD) (*Map, error) {
info, err := newMapInfoFromFd(fd)
if err != nil {
fd.Close()
return nil, fmt.Errorf("get map info: %s", err)
}
return newMap(fd, info.Name, info.Type, info.KeySize, info.ValueSize, info.MaxEntries, info.Flags)
}
// NewMap creates a new Map.
//
// It's equivalent to calling NewMapWithOptions with default options.
func NewMap(spec *MapSpec) (*Map, error) {
return NewMapWithOptions(spec, MapOptions{})
}
// NewMapWithOptions creates a new Map.
//
// Creating a map for the first time will perform feature detection
// by creating small, temporary maps.
//
// The caller is responsible for ensuring the process' rlimit is set
// sufficiently high for locking memory during map creation. This can be done
// by calling unix.Setrlimit with unix.RLIMIT_MEMLOCK prior to calling NewMapWithOptions.
func NewMapWithOptions(spec *MapSpec, opts MapOptions) (*Map, error) {
btfs := make(btfHandleCache)
defer btfs.close()
return newMapWithOptions(spec, opts, btfs)
}
func newMapWithOptions(spec *MapSpec, opts MapOptions, btfs btfHandleCache) (*Map, error) {
switch spec.Pinning {
case PinByName:
if spec.Name == "" || opts.PinPath == "" {
return nil, fmt.Errorf("pin by name: missing Name or PinPath")
}
m, err := LoadPinnedMap(filepath.Join(opts.PinPath, spec.Name))
if errors.Is(err, unix.ENOENT) {
break
}
if err != nil {
return nil, fmt.Errorf("load pinned map: %s", err)
}
if err := spec.checkCompatibility(m); err != nil {
m.Close()
return nil, fmt.Errorf("use pinned map %s: %s", spec.Name, err)
}
return m, nil
case PinNone:
// Nothing to do here
default:
return nil, fmt.Errorf("unsupported pin type %d", int(spec.Pinning))
}
var innerFd *internal.FD
if spec.Type == ArrayOfMaps || spec.Type == HashOfMaps {
if spec.InnerMap == nil {
return nil, fmt.Errorf("%s requires InnerMap", spec.Type)
}
if spec.InnerMap.Pinning != PinNone {
return nil, errors.New("inner maps cannot be pinned")
}
template, err := createMap(spec.InnerMap, nil, opts, btfs)
if err != nil {
return nil, err
}
defer template.Close()
innerFd = template.fd
}
m, err := createMap(spec, innerFd, opts, btfs)
if err != nil {
return nil, err
}
if spec.Pinning == PinByName {
if err := m.Pin(filepath.Join(opts.PinPath, spec.Name)); err != nil {
m.Close()
return nil, fmt.Errorf("pin map: %s", err)
}
}
return m, nil
}
func createMap(spec *MapSpec, inner *internal.FD, opts MapOptions, btfs btfHandleCache) (_ *Map, err error) {
closeOnError := func(closer io.Closer) {
if err != nil {
closer.Close()
}
}
spec = spec.Copy()
switch spec.Type {
case ArrayOfMaps:
fallthrough
case HashOfMaps:
if err := haveNestedMaps(); err != nil {
return nil, err
}
if spec.ValueSize != 0 && spec.ValueSize != 4 {
return nil, errors.New("ValueSize must be zero or four for map of map")
}
spec.ValueSize = 4
case PerfEventArray:
if spec.KeySize != 0 && spec.KeySize != 4 {
return nil, errors.New("KeySize must be zero or four for perf event array")
}
spec.KeySize = 4
if spec.ValueSize != 0 && spec.ValueSize != 4 {
return nil, errors.New("ValueSize must be zero or four for perf event array")
}
spec.ValueSize = 4
if spec.MaxEntries == 0 {
n, err := internal.PossibleCPUs()
if err != nil {
return nil, fmt.Errorf("perf event array: %w", err)
}
spec.MaxEntries = uint32(n)
}
}
if spec.Flags&(unix.BPF_F_RDONLY_PROG|unix.BPF_F_WRONLY_PROG) > 0 || spec.Freeze {
if err := haveMapMutabilityModifiers(); err != nil {
return nil, fmt.Errorf("map create: %w", err)
}
}
attr := bpfMapCreateAttr{
mapType: spec.Type,
keySize: spec.KeySize,
valueSize: spec.ValueSize,
maxEntries: spec.MaxEntries,
flags: spec.Flags,
numaNode: spec.NumaNode,
}
if inner != nil {
var err error
attr.innerMapFd, err = inner.Value()
if err != nil {
return nil, fmt.Errorf("map create: %w", err)
}
}
if haveObjName() == nil {
attr.mapName = newBPFObjName(spec.Name)
}
var btfDisabled bool
if spec.BTF != nil {
handle, err := btfs.load(btf.MapSpec(spec.BTF))
btfDisabled = errors.Is(err, btf.ErrNotSupported)
if err != nil && !btfDisabled {
return nil, fmt.Errorf("load BTF: %w", err)
}
if handle != nil {
attr.btfFd = uint32(handle.FD())
attr.btfKeyTypeID = btf.MapKey(spec.BTF).ID()
attr.btfValueTypeID = btf.MapValue(spec.BTF).ID()
}
}
fd, err := bpfMapCreate(&attr)
if err != nil {
if errors.Is(err, unix.EPERM) {
return nil, fmt.Errorf("map create: RLIMIT_MEMLOCK may be too low: %w", err)
}
if btfDisabled {
return nil, fmt.Errorf("map create without BTF: %w", err)
}
return nil, fmt.Errorf("map create: %w", err)
}
defer closeOnError(fd)
m, err := newMap(fd, spec.Name, spec.Type, spec.KeySize, spec.ValueSize, spec.MaxEntries, spec.Flags)
if err != nil {
return nil, fmt.Errorf("map create: %w", err)
}
if err := m.populate(spec.Contents); err != nil {
return nil, fmt.Errorf("map create: can't set initial contents: %w", err)
}
if spec.Freeze {
if err := m.Freeze(); err != nil {
return nil, fmt.Errorf("can't freeze map: %w", err)
}
}
return m, nil
}
func newMap(fd *internal.FD, name string, typ MapType, keySize, valueSize, maxEntries, flags uint32) (*Map, error) {
m := &Map{
name,
fd,
typ,
keySize,
valueSize,
maxEntries,
flags,
"",
int(valueSize),
}
if !typ.hasPerCPUValue() {
return m, nil
}
possibleCPUs, err := internal.PossibleCPUs()
if err != nil {
return nil, err
}
m.fullValueSize = align(int(valueSize), 8) * possibleCPUs
return m, nil
}
func (m *Map) String() string {
if m.name != "" {
return fmt.Sprintf("%s(%s)#%v", m.typ, m.name, m.fd)
}
return fmt.Sprintf("%s#%v", m.typ, m.fd)
}
// Type returns the underlying type of the map.
func (m *Map) Type() MapType {
return m.typ
}
// KeySize returns the size of the map key in bytes.
func (m *Map) KeySize() uint32 {
return m.keySize
}
// ValueSize returns the size of the map value in bytes.
func (m *Map) ValueSize() uint32 {
return m.valueSize
}
// MaxEntries returns the maximum number of elements the map can hold.
func (m *Map) MaxEntries() uint32 {
return m.maxEntries
}
// Flags returns the flags of the map.
func (m *Map) Flags() uint32 {
return m.flags
}
// Info returns metadata about the map.
func (m *Map) Info() (*MapInfo, error) {
return newMapInfoFromFd(m.fd)
}
// 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 ErrKeyNotExist.
func (m *Map) Lookup(key, valueOut interface{}) error {
valuePtr, valueBytes := makeBuffer(valueOut, m.fullValueSize)
if err := m.lookup(key, valuePtr); err != nil {
return err
}
return m.unmarshalValue(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 := m.marshalKey(key)
if err != nil {
return fmt.Errorf("can't marshal key: %w", err)
}
if err := bpfMapLookupAndDelete(m.fd, keyPtr, valuePtr); err != nil {
return fmt.Errorf("lookup and delete failed: %w", err)
}
return m.unmarshalValue(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 errors.Is(err, ErrKeyNotExist) {
return nil, nil
}
return valueBytes, err
}
func (m *Map) lookup(key interface{}, valueOut internal.Pointer) error {
keyPtr, err := m.marshalKey(key)
if err != nil {
return fmt.Errorf("can't marshal key: %w", err)
}
if err = bpfMapLookupElem(m.fd, keyPtr, valueOut); err != nil {
return fmt.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 := m.marshalKey(key)
if err != nil {
return fmt.Errorf("can't marshal key: %w", err)
}
valuePtr, err := m.marshalValue(value)
if err != nil {
return fmt.Errorf("can't marshal value: %w", err)
}
if err = bpfMapUpdateElem(m.fd, keyPtr, valuePtr, uint64(flags)); err != nil {
return fmt.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 := m.marshalKey(key)
if err != nil {
return fmt.Errorf("can't marshal key: %w", err)
}
if err = bpfMapDeleteElem(m.fd, keyPtr); err != nil {
return fmt.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.keySize))
if err := m.nextKey(key, nextKeyPtr); err != nil {
return err
}
if err := m.unmarshalKey(nextKeyOut, nextKeyBytes); err != nil {
return fmt.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.keySize)
nextKeyPtr := internal.NewSlicePointer(nextKey)
err := m.nextKey(key, nextKeyPtr)
if errors.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 = m.marshalKey(key)
if err != nil {
return fmt.Errorf("can't marshal key: %w", err)
}
}
if err = bpfMapGetNextKey(m.fd, keyPtr, nextKeyOut); err != nil {
return fmt.Errorf("next key failed: %w", err)
}
return nil
}
// BatchLookup looks up many elements in a map at once.
//
// "keysOut" and "valuesOut" must be of type slice, a pointer
// to a slice or buffer will not work.
// "prevKey" is the key to start the batch lookup from, it will
// *not* be included in the results. Use nil to start at the first key.
//
// ErrKeyNotExist is returned when the batch lookup has reached
// the end of all possible results, even when partial results
// are returned. It should be used to evaluate when lookup is "done".
func (m *Map) BatchLookup(prevKey, nextKeyOut, keysOut, valuesOut interface{}, opts *BatchOptions) (int, error) {
return m.batchLookup(internal.BPF_MAP_LOOKUP_BATCH, prevKey, nextKeyOut, keysOut, valuesOut, opts)
}
// BatchLookupAndDelete looks up many elements in a map at once,
//
// It then deletes all those elements.
// "keysOut" and "valuesOut" must be of type slice, a pointer
// to a slice or buffer will not work.
// "prevKey" is the key to start the batch lookup from, it will
// *not* be included in the results. Use nil to start at the first key.
//
// ErrKeyNotExist is returned when the batch lookup has reached
// the end of all possible results, even when partial results
// are returned. It should be used to evaluate when lookup is "done".
func (m *Map) BatchLookupAndDelete(prevKey, nextKeyOut, keysOut, valuesOut interface{}, opts *BatchOptions) (int, error) {
return m.batchLookup(internal.BPF_MAP_LOOKUP_AND_DELETE_BATCH, prevKey, nextKeyOut, keysOut, valuesOut, opts)
}
func (m *Map) batchLookup(cmd internal.BPFCmd, startKey, nextKeyOut, keysOut, valuesOut interface{}, opts *BatchOptions) (int, error) {
if err := haveBatchAPI(); err != nil {
return 0, err
}
if m.typ.hasPerCPUValue() {
return 0, ErrNotSupported
}
keysValue := reflect.ValueOf(keysOut)
if keysValue.Kind() != reflect.Slice {
return 0, fmt.Errorf("keys must be a slice")
}
valuesValue := reflect.ValueOf(valuesOut)
if valuesValue.Kind() != reflect.Slice {
return 0, fmt.Errorf("valuesOut must be a slice")
}
count := keysValue.Len()
if count != valuesValue.Len() {
return 0, fmt.Errorf("keysOut and valuesOut must be the same length")
}
keyBuf := make([]byte, count*int(m.keySize))
keyPtr := internal.NewSlicePointer(keyBuf)
valueBuf := make([]byte, count*int(m.fullValueSize))
valuePtr := internal.NewSlicePointer(valueBuf)
var (
startPtr internal.Pointer
err error
retErr error
)
if startKey != nil {
startPtr, err = marshalPtr(startKey, int(m.keySize))
if err != nil {
return 0, err
}
}
nextPtr, nextBuf := makeBuffer(nextKeyOut, int(m.keySize))
ct, err := bpfMapBatch(cmd, m.fd, startPtr, nextPtr, keyPtr, valuePtr, uint32(count), opts)
if err != nil {
if !errors.Is(err, ErrKeyNotExist) {
return 0, err
}
retErr = ErrKeyNotExist
}
err = m.unmarshalKey(nextKeyOut, nextBuf)
if err != nil {
return 0, err
}
err = unmarshalBytes(keysOut, keyBuf)
if err != nil {
return 0, err
}
err = unmarshalBytes(valuesOut, valueBuf)
if err != nil {
retErr = err
}
return int(ct), retErr
}
// BatchUpdate updates the map with multiple keys and values
// simultaneously.
// "keys" and "values" must be of type slice, a pointer
// to a slice or buffer will not work.
func (m *Map) BatchUpdate(keys, values interface{}, opts *BatchOptions) (int, error) {
if err := haveBatchAPI(); err != nil {
return 0, err
}
if m.typ.hasPerCPUValue() {
return 0, ErrNotSupported
}
keysValue := reflect.ValueOf(keys)
if keysValue.Kind() != reflect.Slice {
return 0, fmt.Errorf("keys must be a slice")
}
valuesValue := reflect.ValueOf(values)
if valuesValue.Kind() != reflect.Slice {
return 0, fmt.Errorf("values must be a slice")
}
var (
count = keysValue.Len()
valuePtr internal.Pointer
err error
)
if count != valuesValue.Len() {
return 0, fmt.Errorf("keys and values must be the same length")
}
keyPtr, err := marshalPtr(keys, count*int(m.keySize))
if err != nil {
return 0, err
}
valuePtr, err = marshalPtr(values, count*int(m.valueSize))
if err != nil {
return 0, err
}
var nilPtr internal.Pointer
ct, err := bpfMapBatch(internal.BPF_MAP_UPDATE_BATCH, m.fd, nilPtr, nilPtr, keyPtr, valuePtr, uint32(count), opts)
return int(ct), err
}
// BatchDelete batch deletes entries in the map by keys.
// "keys" must be of type slice, a pointer to a slice or buffer will not work.
func (m *Map) BatchDelete(keys interface{}, opts *BatchOptions) (int, error) {
if err := haveBatchAPI(); err != nil {
return 0, err
}
if m.typ.hasPerCPUValue() {
return 0, ErrNotSupported
}
keysValue := reflect.ValueOf(keys)
if keysValue.Kind() != reflect.Slice {
return 0, fmt.Errorf("keys must be a slice")
}
count := keysValue.Len()
keyPtr, err := marshalPtr(keys, count*int(m.keySize))
if err != nil {
return 0, fmt.Errorf("cannot marshal keys: %v", err)
}
var nilPtr internal.Pointer
ct, err := bpfMapBatch(internal.BPF_MAP_DELETE_BATCH, m.fd, nilPtr, nilPtr, keyPtr, nilPtr, uint32(count), opts)
return int(ct), err
}
// 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.
// If the original map was pinned, the cloned map will not be pinned by default.
//
// 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, fmt.Errorf("can't clone map: %w", err)
}
return &Map{
m.name,
dup,
m.typ,
m.keySize,
m.valueSize,
m.maxEntries,
m.flags,
"",
m.fullValueSize,
}, nil
}
// Pin persists the map on the BPF virtual file system past the lifetime of
// the process that created it .
//
// Calling Pin on a previously pinned map will override the path.
// You can Clone a map to pin it to a different path.
//
// This requires bpffs to be mounted above fileName. See https://docs.cilium.io/en/k8s-doc/admin/#admin-mount-bpffs
func (m *Map) Pin(fileName string) error {
if err := pin(m.pinnedPath, fileName, m.fd); err != nil {
return err
}
m.pinnedPath = fileName
return nil
}
// Unpin removes the persisted state for the map from the BPF virtual filesystem.
//
// Failed calls to Unpin will not alter the state returned by IsPinned.
//
// Unpinning an unpinned Map returns nil.
func (m *Map) Unpin() error {
if err := unpin(m.pinnedPath); err != nil {
return err
}
m.pinnedPath = ""
return nil
}
// IsPinned returns true if the map has a non-empty pinned path.
func (m *Map) IsPinned() bool {
if m.pinnedPath == "" {
return false
}
return true
}
// 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 fmt.Errorf("can't freeze map: %w", err)
}
if err := bpfMapFreeze(m.fd); err != nil {
return fmt.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 fmt.Errorf("key %v: %w", kv.Key, err)
}
}
return nil
}
func (m *Map) marshalKey(data interface{}) (internal.Pointer, error) {
if data == nil {
if m.keySize == 0 {
// Queues have a key length of zero, so passing nil here is valid.
return internal.NewPointer(nil), nil
}
return internal.Pointer{}, errors.New("can't use nil as key of map")
}
return marshalPtr(data, int(m.keySize))
}
func (m *Map) unmarshalKey(data interface{}, buf []byte) error {
if buf == nil {
// This is from a makeBuffer call, nothing do do here.
return nil
}
return unmarshalBytes(data, buf)
}
func (m *Map) marshalValue(data interface{}) (internal.Pointer, error) {
if m.typ.hasPerCPUValue() {
return marshalPerCPUValue(data, int(m.valueSize))
}
var (
buf []byte
err error
)
switch value := data.(type) {
case *Map:
if !m.typ.canStoreMap() {
return internal.Pointer{}, fmt.Errorf("can't store map in %s", m.typ)
}
buf, err = marshalMap(value, int(m.valueSize))
case *Program:
if !m.typ.canStoreProgram() {
return internal.Pointer{}, fmt.Errorf("can't store program in %s", m.typ)
}
buf, err = marshalProgram(value, int(m.valueSize))
default:
return marshalPtr(data, int(m.valueSize))
}
if err != nil {
return internal.Pointer{}, err
}
return internal.NewSlicePointer(buf), nil
}
func (m *Map) unmarshalValue(value interface{}, buf []byte) error {
if buf == nil {
// This is from a makeBuffer call, nothing do do here.
return nil
}
if m.typ.hasPerCPUValue() {
return unmarshalPerCPUValue(value, int(m.valueSize), buf)
}
switch value := value.(type) {
case **Map:
if !m.typ.canStoreMap() {
return fmt.Errorf("can't read a map from %s", m.typ)
}
other, err := unmarshalMap(buf)
if err != nil {
return err
}
(*value).Close()
*value = other
return nil
case *Map:
if !m.typ.canStoreMap() {
return fmt.Errorf("can't read a map from %s", m.typ)
}
return errors.New("require pointer to *Map")
case **Program:
if !m.typ.canStoreProgram() {
return fmt.Errorf("can't read a program from %s", m.typ)
}
other, err := unmarshalProgram(buf)
if err != nil {
return err
}
(*value).Close()
*value = other
return nil
case *Program:
if !m.typ.canStoreProgram() {
return fmt.Errorf("can't read a program from %s", m.typ)
}
return errors.New("require pointer to *Program")
}
return unmarshalBytes(value, buf)
}
// LoadPinnedMap load a Map from a BPF file.
func LoadPinnedMap(fileName string) (*Map, error) {
fd, err := internal.BPFObjGet(fileName)
if err != nil {
return nil, err
}
m, err := newMapFromFD(fd)
if err == nil {
m.pinnedPath = fileName
}
return m, err
}
// unmarshalMap creates a map from a map ID encoded in host endianness.
func unmarshalMap(buf []byte) (*Map, error) {
if len(buf) != 4 {
return nil, errors.New("map id requires 4 byte value")
}
id := internal.NativeEndian.Uint32(buf)
return NewMapFromID(MapID(id))
}
// marshalMap marshals the fd of a map into a buffer in host endianness.
func marshalMap(m *Map, length int) ([]byte, error) {
if length != 4 {
return nil, fmt.Errorf("can't marshal map to %d bytes", length)
}
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 fmt.Errorf("%s: offset %d(+%d) is out of bounds", name, offset, size)
}
buf, err := marshalBytes(replacement, size)
if err != nil {
return fmt.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 fmt.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 fmt.Errorf("unknown field: %s", missing[0])
}
return fmt.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.maxEntries,
prevBytes: make([]byte, target.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 array-like maps NextKeyBytes returns nil only on after maxEntries
// iterations.
for mi.count <= mi.maxEntries {
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.count++
mi.err = mi.target.Lookup(nextBytes, valueOut)
if errors.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 = mi.target.unmarshalKey(keyOut, nextBytes)
return mi.err == nil
}
mi.err = fmt.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(internal.BPF_MAP_GET_NEXT_ID, 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(internal.BPF_MAP_GET_FD_BY_ID, uint32(id))
if err != nil {
return nil, err
}
return newMapFromFD(fd)
}
// ID returns the systemwide unique ID of the map.
//
// Deprecated: use MapInfo.ID() instead.
func (m *Map) ID() (MapID, error) {
info, err := bpfGetMapInfoByFD(m.fd)
if err != nil {
return MapID(0), err
}
return MapID(info.id), nil
}