open-nomad/vendor/github.com/cilium/ebpf/collection.go

294 lines
6.9 KiB
Go

package ebpf
import (
"math"
"github.com/cilium/ebpf/asm"
"github.com/cilium/ebpf/internal"
"github.com/cilium/ebpf/internal/btf"
"golang.org/x/xerrors"
)
// CollectionOptions control loading a collection into the kernel.
type CollectionOptions struct {
Programs ProgramOptions
}
// CollectionSpec describes a collection.
type CollectionSpec struct {
Maps map[string]*MapSpec
Programs map[string]*ProgramSpec
}
// Copy returns a recursive copy of the spec.
func (cs *CollectionSpec) Copy() *CollectionSpec {
if cs == nil {
return nil
}
cpy := CollectionSpec{
Maps: make(map[string]*MapSpec, len(cs.Maps)),
Programs: make(map[string]*ProgramSpec, len(cs.Programs)),
}
for name, spec := range cs.Maps {
cpy.Maps[name] = spec.Copy()
}
for name, spec := range cs.Programs {
cpy.Programs[name] = spec.Copy()
}
return &cpy
}
// RewriteMaps replaces all references to specific maps.
//
// Use this function to use pre-existing maps instead of creating new ones
// when calling NewCollection. Any named maps are removed from CollectionSpec.Maps.
//
// Returns an error if a named map isn't used in at least one program.
func (cs *CollectionSpec) RewriteMaps(maps map[string]*Map) error {
for symbol, m := range maps {
// have we seen a program that uses this symbol / map
seen := false
fd := m.FD()
for progName, progSpec := range cs.Programs {
err := progSpec.Instructions.RewriteMapPtr(symbol, fd)
switch {
case err == nil:
seen = true
case asm.IsUnreferencedSymbol(err):
// Not all programs need to use the map
default:
return xerrors.Errorf("program %s: %w", progName, err)
}
}
if !seen {
return xerrors.Errorf("map %s not referenced by any programs", symbol)
}
// Prevent NewCollection from creating rewritten maps
delete(cs.Maps, symbol)
}
return nil
}
// RewriteConstants replaces the value of multiple constants.
//
// The constant must be defined like so in the C program:
//
// static volatile const type foobar;
// static volatile const type foobar = default;
//
// Replacement values must be of the same length as the C sizeof(type).
// If necessary, they are marshalled according to the same rules as
// map values.
//
// From Linux 5.5 the verifier will use constants to eliminate dead code.
//
// Returns an error if a constant doesn't exist.
func (cs *CollectionSpec) RewriteConstants(consts map[string]interface{}) error {
rodata := cs.Maps[".rodata"]
if rodata == nil {
return xerrors.New("missing .rodata section")
}
if rodata.BTF == nil {
return xerrors.New(".rodata section has no BTF")
}
if n := len(rodata.Contents); n != 1 {
return xerrors.Errorf("expected one key in .rodata, found %d", n)
}
kv := rodata.Contents[0]
value, ok := kv.Value.([]byte)
if !ok {
return xerrors.Errorf("first value in .rodata is %T not []byte", kv.Value)
}
buf := make([]byte, len(value))
copy(buf, value)
err := patchValue(buf, btf.MapValue(rodata.BTF), consts)
if err != nil {
return err
}
rodata.Contents[0] = MapKV{kv.Key, buf}
return nil
}
// Collection is a collection of Programs and Maps associated
// with their symbols
type Collection struct {
Programs map[string]*Program
Maps map[string]*Map
}
// NewCollection creates a Collection from a specification.
//
// Only maps referenced by at least one of the programs are initialized.
func NewCollection(spec *CollectionSpec) (*Collection, error) {
return NewCollectionWithOptions(spec, CollectionOptions{})
}
// NewCollectionWithOptions creates a Collection from a specification.
//
// Only maps referenced by at least one of the programs are initialized.
func NewCollectionWithOptions(spec *CollectionSpec, opts CollectionOptions) (coll *Collection, err error) {
var (
maps = make(map[string]*Map)
progs = make(map[string]*Program)
btfs = make(map[*btf.Spec]*btf.Handle)
)
defer func() {
for _, btf := range btfs {
btf.Close()
}
if err == nil {
return
}
for _, m := range maps {
m.Close()
}
for _, p := range progs {
p.Close()
}
}()
loadBTF := func(spec *btf.Spec) (*btf.Handle, error) {
if btfs[spec] != nil {
return btfs[spec], nil
}
handle, err := btf.NewHandle(spec)
if err != nil {
return nil, err
}
btfs[spec] = handle
return handle, nil
}
for mapName, mapSpec := range spec.Maps {
var handle *btf.Handle
if mapSpec.BTF != nil {
handle, err = loadBTF(btf.MapSpec(mapSpec.BTF))
if err != nil && !xerrors.Is(err, btf.ErrNotSupported) {
return nil, err
}
}
m, err := newMapWithBTF(mapSpec, handle)
if err != nil {
return nil, xerrors.Errorf("map %s: %w", mapName, err)
}
maps[mapName] = m
}
for progName, origProgSpec := range spec.Programs {
progSpec := origProgSpec.Copy()
// Rewrite any reference to a valid map.
for i := range progSpec.Instructions {
ins := &progSpec.Instructions[i]
if ins.OpCode != asm.LoadImmOp(asm.DWord) || ins.Reference == "" {
continue
}
if uint32(ins.Constant) != math.MaxUint32 {
// Don't overwrite maps already rewritten, users can
// rewrite programs in the spec themselves
continue
}
m := maps[ins.Reference]
if m == nil {
return nil, xerrors.Errorf("program %s: missing map %s", progName, ins.Reference)
}
fd := m.FD()
if fd < 0 {
return nil, xerrors.Errorf("map %s: %w", ins.Reference, internal.ErrClosedFd)
}
if err := ins.RewriteMapPtr(m.FD()); err != nil {
return nil, xerrors.Errorf("progam %s: map %s: %w", progName, ins.Reference, err)
}
}
var handle *btf.Handle
if progSpec.BTF != nil {
handle, err = loadBTF(btf.ProgramSpec(progSpec.BTF))
if err != nil && !xerrors.Is(err, btf.ErrNotSupported) {
return nil, err
}
}
prog, err := newProgramWithBTF(progSpec, handle, opts.Programs)
if err != nil {
return nil, xerrors.Errorf("program %s: %w", progName, err)
}
progs[progName] = prog
}
return &Collection{
progs,
maps,
}, nil
}
// LoadCollection parses an object file and converts it to a collection.
func LoadCollection(file string) (*Collection, error) {
spec, err := LoadCollectionSpec(file)
if err != nil {
return nil, err
}
return NewCollection(spec)
}
// Close frees all maps and programs associated with the collection.
//
// The collection mustn't be used afterwards.
func (coll *Collection) Close() {
for _, prog := range coll.Programs {
prog.Close()
}
for _, m := range coll.Maps {
m.Close()
}
}
// DetachMap removes the named map from the Collection.
//
// This means that a later call to Close() will not affect this map.
//
// Returns nil if no map of that name exists.
func (coll *Collection) DetachMap(name string) *Map {
m := coll.Maps[name]
delete(coll.Maps, name)
return m
}
// DetachProgram removes the named program from the Collection.
//
// This means that a later call to Close() will not affect this program.
//
// Returns nil if no program of that name exists.
func (coll *Collection) DetachProgram(name string) *Program {
p := coll.Programs[name]
delete(coll.Programs, name)
return p
}