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|
package netlink
import (
"fmt"
"io/ioutil"
"strconv"
"strings"
"syscall"
"github.com/vishvananda/netlink/nl"
)
// NOTE function is here because it uses other linux functions
func NewNetem(attrs QdiscAttrs, nattrs NetemQdiscAttrs) *Netem {
var limit uint32 = 1000
var lossCorr, delayCorr, duplicateCorr uint32
var reorderProb, reorderCorr uint32
var corruptProb, corruptCorr uint32
latency := nattrs.Latency
loss := Percentage2u32(nattrs.Loss)
gap := nattrs.Gap
duplicate := Percentage2u32(nattrs.Duplicate)
jitter := nattrs.Jitter
// Correlation
if latency > 0 && jitter > 0 {
delayCorr = Percentage2u32(nattrs.DelayCorr)
}
if loss > 0 {
lossCorr = Percentage2u32(nattrs.LossCorr)
}
if duplicate > 0 {
duplicateCorr = Percentage2u32(nattrs.DuplicateCorr)
}
// FIXME should validate values(like loss/duplicate are percentages...)
latency = time2Tick(latency)
if nattrs.Limit != 0 {
limit = nattrs.Limit
}
// Jitter is only value if latency is > 0
if latency > 0 {
jitter = time2Tick(jitter)
}
reorderProb = Percentage2u32(nattrs.ReorderProb)
reorderCorr = Percentage2u32(nattrs.ReorderCorr)
if reorderProb > 0 {
// ERROR if lantency == 0
if gap == 0 {
gap = 1
}
}
corruptProb = Percentage2u32(nattrs.CorruptProb)
corruptCorr = Percentage2u32(nattrs.CorruptCorr)
return &Netem{
QdiscAttrs: attrs,
Latency: latency,
DelayCorr: delayCorr,
Limit: limit,
Loss: loss,
LossCorr: lossCorr,
Gap: gap,
Duplicate: duplicate,
DuplicateCorr: duplicateCorr,
Jitter: jitter,
ReorderProb: reorderProb,
ReorderCorr: reorderCorr,
CorruptProb: corruptProb,
CorruptCorr: corruptCorr,
}
}
// QdiscDel will delete a qdisc from the system.
// Equivalent to: `tc qdisc del $qdisc`
func QdiscDel(qdisc Qdisc) error {
return pkgHandle.QdiscDel(qdisc)
}
// QdiscDel will delete a qdisc from the system.
// Equivalent to: `tc qdisc del $qdisc`
func (h *Handle) QdiscDel(qdisc Qdisc) error {
return h.qdiscModify(syscall.RTM_DELQDISC, 0, qdisc)
}
// QdiscChange will change a qdisc in place
// Equivalent to: `tc qdisc change $qdisc`
// The parent and handle MUST NOT be changed.
func QdiscChange(qdisc Qdisc) error {
return pkgHandle.QdiscChange(qdisc)
}
// QdiscChange will change a qdisc in place
// Equivalent to: `tc qdisc change $qdisc`
// The parent and handle MUST NOT be changed.
func (h *Handle) QdiscChange(qdisc Qdisc) error {
return h.qdiscModify(syscall.RTM_NEWQDISC, 0, qdisc)
}
// QdiscReplace will replace a qdisc to the system.
// Equivalent to: `tc qdisc replace $qdisc`
// The handle MUST change.
func QdiscReplace(qdisc Qdisc) error {
return pkgHandle.QdiscReplace(qdisc)
}
// QdiscReplace will replace a qdisc to the system.
// Equivalent to: `tc qdisc replace $qdisc`
// The handle MUST change.
func (h *Handle) QdiscReplace(qdisc Qdisc) error {
return h.qdiscModify(
syscall.RTM_NEWQDISC,
syscall.NLM_F_CREATE|syscall.NLM_F_REPLACE,
qdisc)
}
// QdiscAdd will add a qdisc to the system.
// Equivalent to: `tc qdisc add $qdisc`
func QdiscAdd(qdisc Qdisc) error {
return pkgHandle.QdiscAdd(qdisc)
}
// QdiscAdd will add a qdisc to the system.
// Equivalent to: `tc qdisc add $qdisc`
func (h *Handle) QdiscAdd(qdisc Qdisc) error {
return h.qdiscModify(
syscall.RTM_NEWQDISC,
syscall.NLM_F_CREATE|syscall.NLM_F_EXCL,
qdisc)
}
func (h *Handle) qdiscModify(cmd, flags int, qdisc Qdisc) error {
req := h.newNetlinkRequest(cmd, flags|syscall.NLM_F_ACK)
base := qdisc.Attrs()
msg := &nl.TcMsg{
Family: nl.FAMILY_ALL,
Ifindex: int32(base.LinkIndex),
Handle: base.Handle,
Parent: base.Parent,
}
req.AddData(msg)
// When deleting don't bother building the rest of the netlink payload
if cmd != syscall.RTM_DELQDISC {
if err := qdiscPayload(req, qdisc); err != nil {
return err
}
}
_, err := req.Execute(syscall.NETLINK_ROUTE, 0)
return err
}
func qdiscPayload(req *nl.NetlinkRequest, qdisc Qdisc) error {
req.AddData(nl.NewRtAttr(nl.TCA_KIND, nl.ZeroTerminated(qdisc.Type())))
options := nl.NewRtAttr(nl.TCA_OPTIONS, nil)
if prio, ok := qdisc.(*Prio); ok {
tcmap := nl.TcPrioMap{
Bands: int32(prio.Bands),
Priomap: prio.PriorityMap,
}
options = nl.NewRtAttr(nl.TCA_OPTIONS, tcmap.Serialize())
} else if tbf, ok := qdisc.(*Tbf); ok {
opt := nl.TcTbfQopt{}
opt.Rate.Rate = uint32(tbf.Rate)
opt.Peakrate.Rate = uint32(tbf.Peakrate)
opt.Limit = tbf.Limit
opt.Buffer = tbf.Buffer
nl.NewRtAttrChild(options, nl.TCA_TBF_PARMS, opt.Serialize())
if tbf.Rate >= uint64(1<<32) {
nl.NewRtAttrChild(options, nl.TCA_TBF_RATE64, nl.Uint64Attr(tbf.Rate))
}
if tbf.Peakrate >= uint64(1<<32) {
nl.NewRtAttrChild(options, nl.TCA_TBF_PRATE64, nl.Uint64Attr(tbf.Peakrate))
}
if tbf.Peakrate > 0 {
nl.NewRtAttrChild(options, nl.TCA_TBF_PBURST, nl.Uint32Attr(tbf.Minburst))
}
} else if htb, ok := qdisc.(*Htb); ok {
opt := nl.TcHtbGlob{}
opt.Version = htb.Version
opt.Rate2Quantum = htb.Rate2Quantum
opt.Defcls = htb.Defcls
// TODO: Handle Debug properly. For now default to 0
opt.Debug = htb.Debug
opt.DirectPkts = htb.DirectPkts
nl.NewRtAttrChild(options, nl.TCA_HTB_INIT, opt.Serialize())
// nl.NewRtAttrChild(options, nl.TCA_HTB_DIRECT_QLEN, opt.Serialize())
} else if netem, ok := qdisc.(*Netem); ok {
opt := nl.TcNetemQopt{}
opt.Latency = netem.Latency
opt.Limit = netem.Limit
opt.Loss = netem.Loss
opt.Gap = netem.Gap
opt.Duplicate = netem.Duplicate
opt.Jitter = netem.Jitter
options = nl.NewRtAttr(nl.TCA_OPTIONS, opt.Serialize())
// Correlation
corr := nl.TcNetemCorr{}
corr.DelayCorr = netem.DelayCorr
corr.LossCorr = netem.LossCorr
corr.DupCorr = netem.DuplicateCorr
if corr.DelayCorr > 0 || corr.LossCorr > 0 || corr.DupCorr > 0 {
nl.NewRtAttrChild(options, nl.TCA_NETEM_CORR, corr.Serialize())
}
// Corruption
corruption := nl.TcNetemCorrupt{}
corruption.Probability = netem.CorruptProb
corruption.Correlation = netem.CorruptCorr
if corruption.Probability > 0 {
nl.NewRtAttrChild(options, nl.TCA_NETEM_CORRUPT, corruption.Serialize())
}
// Reorder
reorder := nl.TcNetemReorder{}
reorder.Probability = netem.ReorderProb
reorder.Correlation = netem.ReorderCorr
if reorder.Probability > 0 {
nl.NewRtAttrChild(options, nl.TCA_NETEM_REORDER, reorder.Serialize())
}
} else if _, ok := qdisc.(*Ingress); ok {
// ingress filters must use the proper handle
if qdisc.Attrs().Parent != HANDLE_INGRESS {
return fmt.Errorf("Ingress filters must set Parent to HANDLE_INGRESS")
}
}
req.AddData(options)
return nil
}
// QdiscList gets a list of qdiscs in the system.
// Equivalent to: `tc qdisc show`.
// The list can be filtered by link.
func QdiscList(link Link) ([]Qdisc, error) {
return pkgHandle.QdiscList(link)
}
// QdiscList gets a list of qdiscs in the system.
// Equivalent to: `tc qdisc show`.
// The list can be filtered by link.
func (h *Handle) QdiscList(link Link) ([]Qdisc, error) {
req := h.newNetlinkRequest(syscall.RTM_GETQDISC, syscall.NLM_F_DUMP)
index := int32(0)
if link != nil {
base := link.Attrs()
h.ensureIndex(base)
index = int32(base.Index)
}
msg := &nl.TcMsg{
Family: nl.FAMILY_ALL,
Ifindex: index,
}
req.AddData(msg)
msgs, err := req.Execute(syscall.NETLINK_ROUTE, syscall.RTM_NEWQDISC)
if err != nil {
return nil, err
}
var res []Qdisc
for _, m := range msgs {
msg := nl.DeserializeTcMsg(m)
attrs, err := nl.ParseRouteAttr(m[msg.Len():])
if err != nil {
return nil, err
}
// skip qdiscs from other interfaces
if link != nil && msg.Ifindex != index {
continue
}
base := QdiscAttrs{
LinkIndex: int(msg.Ifindex),
Handle: msg.Handle,
Parent: msg.Parent,
Refcnt: msg.Info,
}
var qdisc Qdisc
qdiscType := ""
for _, attr := range attrs {
switch attr.Attr.Type {
case nl.TCA_KIND:
qdiscType = string(attr.Value[:len(attr.Value)-1])
switch qdiscType {
case "pfifo_fast":
qdisc = &PfifoFast{}
case "prio":
qdisc = &Prio{}
case "tbf":
qdisc = &Tbf{}
case "ingress":
qdisc = &Ingress{}
case "htb":
qdisc = &Htb{}
case "netem":
qdisc = &Netem{}
default:
qdisc = &GenericQdisc{QdiscType: qdiscType}
}
case nl.TCA_OPTIONS:
switch qdiscType {
case "pfifo_fast":
// pfifo returns TcPrioMap directly without wrapping it in rtattr
if err := parsePfifoFastData(qdisc, attr.Value); err != nil {
return nil, err
}
case "prio":
// prio returns TcPrioMap directly without wrapping it in rtattr
if err := parsePrioData(qdisc, attr.Value); err != nil {
return nil, err
}
case "tbf":
data, err := nl.ParseRouteAttr(attr.Value)
if err != nil {
return nil, err
}
if err := parseTbfData(qdisc, data); err != nil {
return nil, err
}
case "htb":
data, err := nl.ParseRouteAttr(attr.Value)
if err != nil {
return nil, err
}
if err := parseHtbData(qdisc, data); err != nil {
return nil, err
}
case "netem":
if err := parseNetemData(qdisc, attr.Value); err != nil {
return nil, err
}
// no options for ingress
}
}
}
*qdisc.Attrs() = base
res = append(res, qdisc)
}
return res, nil
}
func parsePfifoFastData(qdisc Qdisc, value []byte) error {
pfifo := qdisc.(*PfifoFast)
tcmap := nl.DeserializeTcPrioMap(value)
pfifo.PriorityMap = tcmap.Priomap
pfifo.Bands = uint8(tcmap.Bands)
return nil
}
func parsePrioData(qdisc Qdisc, value []byte) error {
prio := qdisc.(*Prio)
tcmap := nl.DeserializeTcPrioMap(value)
prio.PriorityMap = tcmap.Priomap
prio.Bands = uint8(tcmap.Bands)
return nil
}
func parseHtbData(qdisc Qdisc, data []syscall.NetlinkRouteAttr) error {
native = nl.NativeEndian()
htb := qdisc.(*Htb)
for _, datum := range data {
switch datum.Attr.Type {
case nl.TCA_HTB_INIT:
opt := nl.DeserializeTcHtbGlob(datum.Value)
htb.Version = opt.Version
htb.Rate2Quantum = opt.Rate2Quantum
htb.Defcls = opt.Defcls
htb.Debug = opt.Debug
htb.DirectPkts = opt.DirectPkts
case nl.TCA_HTB_DIRECT_QLEN:
// TODO
//htb.DirectQlen = native.uint32(datum.Value)
}
}
return nil
}
func parseNetemData(qdisc Qdisc, value []byte) error {
netem := qdisc.(*Netem)
opt := nl.DeserializeTcNetemQopt(value)
netem.Latency = opt.Latency
netem.Limit = opt.Limit
netem.Loss = opt.Loss
netem.Gap = opt.Gap
netem.Duplicate = opt.Duplicate
netem.Jitter = opt.Jitter
data, err := nl.ParseRouteAttr(value[nl.SizeofTcNetemQopt:])
if err != nil {
return err
}
for _, datum := range data {
switch datum.Attr.Type {
case nl.TCA_NETEM_CORR:
opt := nl.DeserializeTcNetemCorr(datum.Value)
netem.DelayCorr = opt.DelayCorr
netem.LossCorr = opt.LossCorr
netem.DuplicateCorr = opt.DupCorr
case nl.TCA_NETEM_CORRUPT:
opt := nl.DeserializeTcNetemCorrupt(datum.Value)
netem.CorruptProb = opt.Probability
netem.CorruptCorr = opt.Correlation
case nl.TCA_NETEM_REORDER:
opt := nl.DeserializeTcNetemReorder(datum.Value)
netem.ReorderProb = opt.Probability
netem.ReorderCorr = opt.Correlation
}
}
return nil
}
func parseTbfData(qdisc Qdisc, data []syscall.NetlinkRouteAttr) error {
native = nl.NativeEndian()
tbf := qdisc.(*Tbf)
for _, datum := range data {
switch datum.Attr.Type {
case nl.TCA_TBF_PARMS:
opt := nl.DeserializeTcTbfQopt(datum.Value)
tbf.Rate = uint64(opt.Rate.Rate)
tbf.Peakrate = uint64(opt.Peakrate.Rate)
tbf.Limit = opt.Limit
tbf.Buffer = opt.Buffer
case nl.TCA_TBF_RATE64:
tbf.Rate = native.Uint64(datum.Value[0:8])
case nl.TCA_TBF_PRATE64:
tbf.Peakrate = native.Uint64(datum.Value[0:8])
case nl.TCA_TBF_PBURST:
tbf.Minburst = native.Uint32(datum.Value[0:4])
}
}
return nil
}
const (
TIME_UNITS_PER_SEC = 1000000
)
var (
tickInUsec float64
clockFactor float64
hz float64
)
func initClock() {
data, err := ioutil.ReadFile("/proc/net/psched")
if err != nil {
return
}
parts := strings.Split(strings.TrimSpace(string(data)), " ")
if len(parts) < 3 {
return
}
var vals [3]uint64
for i := range vals {
val, err := strconv.ParseUint(parts[i], 16, 32)
if err != nil {
return
}
vals[i] = val
}
// compatibility
if vals[2] == 1000000000 {
vals[0] = vals[1]
}
clockFactor = float64(vals[2]) / TIME_UNITS_PER_SEC
tickInUsec = float64(vals[0]) / float64(vals[1]) * clockFactor
hz = float64(vals[0])
}
func TickInUsec() float64 {
if tickInUsec == 0.0 {
initClock()
}
return tickInUsec
}
func ClockFactor() float64 {
if clockFactor == 0.0 {
initClock()
}
return clockFactor
}
func Hz() float64 {
if hz == 0.0 {
initClock()
}
return hz
}
func time2Tick(time uint32) uint32 {
return uint32(float64(time) * TickInUsec())
}
func tick2Time(tick uint32) uint32 {
return uint32(float64(tick) / TickInUsec())
}
func time2Ktime(time uint32) uint32 {
return uint32(float64(time) * ClockFactor())
}
func ktime2Time(ktime uint32) uint32 {
return uint32(float64(ktime) / ClockFactor())
}
func burst(rate uint64, buffer uint32) uint32 {
return uint32(float64(rate) * float64(tick2Time(buffer)) / TIME_UNITS_PER_SEC)
}
func latency(rate uint64, limit, buffer uint32) float64 {
return TIME_UNITS_PER_SEC*(float64(limit)/float64(rate)) - float64(tick2Time(buffer))
}
func Xmittime(rate uint64, size uint32) float64 {
return TickInUsec() * TIME_UNITS_PER_SEC * (float64(size) / float64(rate))
}
|