internal/pkg/onuadaptercore/platform.go - voltha-openonu-adapter-go - Gitiles

 /*
  * Copyright 2018-present Open Networking Foundation

  * 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 adaptercoreonu provides the utility for onu devices, flows and statistics
 package adaptercoreonu

 import "context"

 //Attention: this file is more or less a coopy of file olt_platform.go from the voltha-openolt-adapter
 // which includes system wide definitions and thus normally should be stored more centrally (within some voltha libs)!!

 /*=====================================================================

 @TODO: Looks like this Flow id concept below is not used anywhere
        Propose to remove the below documentation of Flow Id on confirmation
        of the same

 Flow id

     Identifies a flow within a single OLT
     Flow Id is unique per OLT
     Multiple GEM ports can map to same flow id

      13    11              4      0
     +--------+--------------+------+
     | pon id |    onu id    | Flow |
     |        |              | idx  |
     +--------+--------------+------+

     14 bits = 16384 flows (per OLT).

     pon id = 4 bits = 16 PON ports
     onu id = 7 bits = 128 ONUss per PON port
     Flow index = 3 bits = 4 bi-directional flows per ONU
                         = 8 uni-directional flows per ONU


 Logical (OF) UNI port number

     OpenFlow port number corresponding to PON UNI

      20        12              4      0
     +--+--------+--------------+------+
     |0 | pon id |    onu id    |uni id|
     +--+--------+--------------+------+

     pon id = 8 bits = 256 PON ports
     onu id = 8 bits = 256 ONUs per PON port

 Logical (OF) NNI port number

     OpenFlow port number corresponding to PON NNI

      20                             0
     +--+----------------------------+
     |1 |                    intf_id |
     +--+----------------------------+

     No overlap with UNI port number space


 PON OLT (OF) port number

     OpenFlow port number corresponding to PON OLT ports

      31     28                                 0
     +--------+------------------------~~~------+
     |  0x2   |          pon intf id            |
     +--------+------------------------~~~------+
 */

 const (
 	// Number of bits for the physical UNI of the ONUs
 	bitsForUniID = 4
 	// Number of bits for the ONU ID
 	bitsForONUID = 8
 	// Number of bits for PON ID
 	bitsForPONID = 8
 	/*
 		// Number of bits to differentiate between UNI and NNI Logical Port
 		bitsForUNINNIDiff = 1
 	*/
 	//maxOnusPerPon is Max number of ONUs on any PON port
 	maxOnusPerPon = (1 << bitsForONUID)
 	//maxPonsPerOlt is Max number of PON ports on any OLT
 	maxPonsPerOlt = (1 << bitsForPONID)
 	//maxUnisPerOnu is the Max number of UNI ports on any ONU
 	maxUnisPerOnu = (1 << bitsForUniID)
 	/*
 		//Bit position where the differentiation bit is located
 		nniUniDiffPos = (bitsForUniID + bitsForONUID + bitsForPONID)
 		//Bit position where the marker for PON port type of OF port is present
 		ponIntfMarkerPos = 28
 		//Value of marker used to distinguish PON port type of OF port
 		ponIntfMarkerValue = 0x2
 		// Number of bits for NNI ID
 		bitsforNNIID = 20
 		// minNniIntPortNum is used to store start range of nni port number (1 << 20) 1048576
 		minNniIntPortNum = (1 << bitsforNNIID)
 		// maxNniPortNum is used to store the maximum range of nni port number ((1 << 21)-1) 2097151
 		maxNniPortNum = ((1 << (bitsforNNIID + 1)) - 1)
 	*/
 )

 //Mask to indicate which possibly active ONU UNI state  is really reported to the core
 // compare python code - at the moment restrict active state to the first ONU UNI port
 // check is limited to max 16 uni ports - cmp above UNI limit!!!
 var activeUniPortStateUpdateMask = 0x0001

 /*
 //MinUpstreamPortID value
 var minUpstreamPortID = 0xfffd

 //MaxUpstreamPortID value
 var maxUpstreamPortID = 0xfffffffd

 var controllerPorts = []uint32{0xfffd, 0x7ffffffd, 0xfffffffd}
 */

 //mkUniPortNum returns new UNIportNum based on intfID, onuID and uniID
 func mkUniPortNum(ctx context.Context, intfID, onuID, uniID uint32) uint32 {
 	//extended for checks available in the python onu adapter:!!
 	var limit = int(intfID)
 	if limit > maxPonsPerOlt {
 		logger.Warn(ctx, "Warning: exceeded the MAX pons per OLT")
 	}
 	limit = int(onuID)
 	if limit > maxOnusPerPon {
 		logger.Warn(ctx, "Warning: exceeded the MAX ONUS per PON")
 	}
 	limit = int(uniID)
 	if limit > maxUnisPerOnu {
 		logger.Warn(ctx, "Warning: exceeded the MAX UNIS per ONU")
 	}
 	return (intfID << (bitsForUniID + bitsForONUID)) | (onuID << bitsForUniID) | uniID
 }

 /*
 //onuIDFromPortNum returns ONUID derived from portNumber
 func onuIDFromPortNum(portNum uint32) uint32 {
 	return (portNum >> bitsForUniID) & (maxOnusPerPon - 1)
 }

 //intfIDFromUniPortNum returns IntfID derived from portNum
 func intfIDFromUniPortNum(portNum uint32) uint32 {
 	return (portNum >> (bitsForUniID + bitsForONUID)) & (maxPonsPerOlt - 1)
 }

 //uniIDFromPortNum return UniID derived from portNum
 func uniIDFromPortNum(portNum uint32) uint32 {
 	return (portNum) & (maxUnisPerOnu - 1)
 }

 //intfIDToPortNo returns portId derived from intftype, intfId and portType
 func intfIDToPortNo(intfID uint32, intfType voltha.Port_PortType) uint32 {
 	if (intfType) == voltha.Port_ETHERNET_NNI {
 		return (1 << nniUniDiffPos) | intfID
 	}
 	if (intfType) == voltha.Port_PON_OLT {
 		return (ponIntfMarkerValue << ponIntfMarkerPos) | intfID
 	}
 	return 0
 }

 //portNoToIntfID returns portnumber derived from interfaceID
 func portNoToIntfID(portno uint32, intfType voltha.Port_PortType) uint32 {
 	if (intfType) == voltha.Port_ETHERNET_NNI {
 		return (1 << nniUniDiffPos) ^ portno
 	}
 	if (intfType) == voltha.Port_PON_OLT {
 		return (ponIntfMarkerValue << ponIntfMarkerPos) ^ portno
 	}
 	return 0
 }

 //intfIDFromNniPortNum returns Intf ID derived from portNum
 func intfIDFromNniPortNum(portNum uint32) (uint32, error) {
 	if portNum < minNniIntPortNum || portNum > maxNniPortNum {
 		logger.Errorw(ctx,"NNIPortNumber is not in valid range", log.Fields{"portNum": portNum})
 		return uint32(0), errors.New("invalid-port-range") //olterrors.ErrInvalidPortRange
 	}
 	return (portNum & 0xFFFF), nil
 }

 //intfIDToPortTypeName returns port type derived from the intfId
 func intfIDToPortTypeName(intfID uint32) voltha.Port_PortType {
 	if ((ponIntfMarkerValue << ponIntfMarkerPos) ^ intfID) < maxPonsPerOlt {
 		return voltha.Port_PON_OLT
 	}
 	if (intfID & (1 << nniUniDiffPos)) == (1 << nniUniDiffPos) {
 		return voltha.Port_ETHERNET_NNI
 	}
 	return voltha.Port_ETHERNET_UNI
 }

 //extractAccessFromFlow returns AccessDevice information
 func extractAccessFromFlow(inPort, outPort uint32) (uint32, uint32, uint32, uint32) {
 	if isUpstream(outPort) {
 		return inPort, intfIDFromUniPortNum(inPort), onuIDFromPortNum(inPort), uniIDFromPortNum(inPort)
 	}
 	return outPort, intfIDFromUniPortNum(outPort), onuIDFromPortNum(outPort), uniIDFromPortNum(outPort)
 }

 //isUpstream returns true for Upstream and false for downstream
 func isUpstream(outPort uint32) bool {
 	for _, port := range controllerPorts {
 		if port == outPort {
 			return true
 		}
 	}
 	return (outPort & (1 << nniUniDiffPos)) == (1 << nniUniDiffPos)
 }

 //isControllerBoundFlow returns true/false
 func isControllerBoundFlow(outPort uint32) bool {
 	for _, port := range controllerPorts {
 		if port == outPort {
 			return true
 		}
 	}
 	return false
 }

 //onuIDFromUniPortNum returns onuId from give portNum information.
 func onuIDFromUniPortNum(portNum uint32) uint32 {
 	return (portNum >> bitsForUniID) & (maxOnusPerPon - 1)
 }

 //flowExtractInfo fetches uniport from the flow, based on which it gets and returns ponInf, onuID, uniID, inPort and ethType
 func flowExtractInfo(flow *ofp.OfpFlowStats, flowDirection string) (uint32, uint32, uint32, uint32, uint32, uint32, error) {
 	var uniPortNo uint32
 	var ponIntf uint32
 	var onuID uint32
 	var uniID uint32
 	var inPort uint32
 	var ethType uint32

 	if flowDirection == "upstream" {
 		if uniPortNo = flows.GetChildPortFromTunnelId(flow); uniPortNo == 0 {
 			for _, field := range flows.GetOfbFields(flow) {
 				if field.GetType() == flows.IN_PORT {
 					uniPortNo = field.GetPort()
 					break
 				}
 			}
 		}
 	} else if flowDirection == "downstream" {
 		if uniPortNo = flows.GetChildPortFromTunnelId(flow); uniPortNo == 0 {
 			for _, field := range flows.GetOfbFields(flow) {
 				if field.GetType() == flows.METADATA {
 					for _, action := range flows.GetActions(flow) {
 						if action.Type == flows.OUTPUT {
 							if out := action.GetOutput(); out != nil {
 								uniPortNo = out.GetPort()
 							}
 							break
 						}
 					}
 				} else if field.GetType() == flows.IN_PORT {
 					inPort = field.GetPort()
 				} else if field.GetType() == flows.ETH_TYPE {
 					ethType = field.GetEthType()
 				}
 			}
 		}
 	}

 	if uniPortNo == 0 {
 		return 0, 0, 0, 0, 0, 0, errors.New("notFound: pon-interface (flowDirection)")
 		// olterrors.NewErrNotFound("pon-interface", log.Fields{"flow-direction": flowDirection}, nil)
 	}

 	ponIntf = intfIDFromUniPortNum(uniPortNo)
 	onuID = onuIDFromUniPortNum(uniPortNo)
 	uniID = uniIDFromPortNum(uniPortNo)

 	logger.Debugw(ctx,"flow extract info result",
 		log.Fields{"uniPortNo": uniPortNo, "ponIntf": ponIntf,
 			"onuID": onuID, "uniID": uniID, "inPort": inPort, "ethType": ethType})

 	return uniPortNo, ponIntf, onuID, uniID, inPort, ethType, nil
 }
 */
	/*
	* Copyright 2018-present Open Networking Foundation

	* 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 adaptercoreonu provides the utility for onu devices, flows and statistics
	package adaptercoreonu

	import "context"

	//Attention: this file is more or less a coopy of file olt_platform.go from the voltha-openolt-adapter
	// which includes system wide definitions and thus normally should be stored more centrally (within some voltha libs)!!

	/*=====================================================================

	@TODO: Looks like this Flow id concept below is not used anywhere
	Propose to remove the below documentation of Flow Id on confirmation
	of the same

	Flow id

	Identifies a flow within a single OLT
	Flow Id is unique per OLT
	Multiple GEM ports can map to same flow id

	13 11 4 0
	+--------+--------------+------+
	\| pon id \| onu id \| Flow \|
	\| \| \| idx \|
	+--------+--------------+------+

	14 bits = 16384 flows (per OLT).

	pon id = 4 bits = 16 PON ports
	onu id = 7 bits = 128 ONUss per PON port
	Flow index = 3 bits = 4 bi-directional flows per ONU
	= 8 uni-directional flows per ONU


	Logical (OF) UNI port number

	OpenFlow port number corresponding to PON UNI

	20 12 4 0
	+--+--------+--------------+------+
	\|0 \| pon id \| onu id \|uni id\|
	+--+--------+--------------+------+

	pon id = 8 bits = 256 PON ports
	onu id = 8 bits = 256 ONUs per PON port

	Logical (OF) NNI port number

	OpenFlow port number corresponding to PON NNI

	20 0
	+--+----------------------------+
	\|1 \| intf_id \|
	+--+----------------------------+

	No overlap with UNI port number space


	PON OLT (OF) port number

	OpenFlow port number corresponding to PON OLT ports

	31 28 0
	+--------+------------------------~~~------+
	\| 0x2 \| pon intf id \|
	+--------+------------------------~~~------+
	*/

	const (
	// Number of bits for the physical UNI of the ONUs
	bitsForUniID = 4
	// Number of bits for the ONU ID
	bitsForONUID = 8
	// Number of bits for PON ID
	bitsForPONID = 8
	/*
	// Number of bits to differentiate between UNI and NNI Logical Port
	bitsForUNINNIDiff = 1
	*/
	//maxOnusPerPon is Max number of ONUs on any PON port
	maxOnusPerPon = (1 << bitsForONUID)
	//maxPonsPerOlt is Max number of PON ports on any OLT
	maxPonsPerOlt = (1 << bitsForPONID)
	//maxUnisPerOnu is the Max number of UNI ports on any ONU
	maxUnisPerOnu = (1 << bitsForUniID)
	/*
	//Bit position where the differentiation bit is located
	nniUniDiffPos = (bitsForUniID + bitsForONUID + bitsForPONID)
	//Bit position where the marker for PON port type of OF port is present
	ponIntfMarkerPos = 28
	//Value of marker used to distinguish PON port type of OF port
	ponIntfMarkerValue = 0x2
	// Number of bits for NNI ID
	bitsforNNIID = 20
	// minNniIntPortNum is used to store start range of nni port number (1 << 20) 1048576
	minNniIntPortNum = (1 << bitsforNNIID)
	// maxNniPortNum is used to store the maximum range of nni port number ((1 << 21)-1) 2097151
	maxNniPortNum = ((1 << (bitsforNNIID + 1)) - 1)
	*/
	)

	//Mask to indicate which possibly active ONU UNI state is really reported to the core
	// compare python code - at the moment restrict active state to the first ONU UNI port
	// check is limited to max 16 uni ports - cmp above UNI limit!!!
	var activeUniPortStateUpdateMask = 0x0001

	/*
	//MinUpstreamPortID value
	var minUpstreamPortID = 0xfffd

	//MaxUpstreamPortID value
	var maxUpstreamPortID = 0xfffffffd

	var controllerPorts = []uint32{0xfffd, 0x7ffffffd, 0xfffffffd}
	*/

	//mkUniPortNum returns new UNIportNum based on intfID, onuID and uniID
	func mkUniPortNum(ctx context.Context, intfID, onuID, uniID uint32) uint32 {
	//extended for checks available in the python onu adapter:!!
	var limit = int(intfID)
	if limit > maxPonsPerOlt {
	logger.Warn(ctx, "Warning: exceeded the MAX pons per OLT")
	}
	limit = int(onuID)
	if limit > maxOnusPerPon {
	logger.Warn(ctx, "Warning: exceeded the MAX ONUS per PON")
	}
	limit = int(uniID)
	if limit > maxUnisPerOnu {
	logger.Warn(ctx, "Warning: exceeded the MAX UNIS per ONU")
	}
	return (intfID << (bitsForUniID + bitsForONUID)) \| (onuID << bitsForUniID) \| uniID
	}

	/*
	//onuIDFromPortNum returns ONUID derived from portNumber
	func onuIDFromPortNum(portNum uint32) uint32 {
	return (portNum >> bitsForUniID) & (maxOnusPerPon - 1)
	}

	//intfIDFromUniPortNum returns IntfID derived from portNum
	func intfIDFromUniPortNum(portNum uint32) uint32 {
	return (portNum >> (bitsForUniID + bitsForONUID)) & (maxPonsPerOlt - 1)
	}

	//uniIDFromPortNum return UniID derived from portNum
	func uniIDFromPortNum(portNum uint32) uint32 {
	return (portNum) & (maxUnisPerOnu - 1)
	}

	//intfIDToPortNo returns portId derived from intftype, intfId and portType
	func intfIDToPortNo(intfID uint32, intfType voltha.Port_PortType) uint32 {
	if (intfType) == voltha.Port_ETHERNET_NNI {
	return (1 << nniUniDiffPos) \| intfID
	}
	if (intfType) == voltha.Port_PON_OLT {
	return (ponIntfMarkerValue << ponIntfMarkerPos) \| intfID
	}
	return 0
	}

	//portNoToIntfID returns portnumber derived from interfaceID
	func portNoToIntfID(portno uint32, intfType voltha.Port_PortType) uint32 {
	if (intfType) == voltha.Port_ETHERNET_NNI {
	return (1 << nniUniDiffPos) ^ portno
	}
	if (intfType) == voltha.Port_PON_OLT {
	return (ponIntfMarkerValue << ponIntfMarkerPos) ^ portno
	}
	return 0
	}

	//intfIDFromNniPortNum returns Intf ID derived from portNum
	func intfIDFromNniPortNum(portNum uint32) (uint32, error) {
	if portNum < minNniIntPortNum \|\| portNum > maxNniPortNum {
	logger.Errorw(ctx,"NNIPortNumber is not in valid range", log.Fields{"portNum": portNum})
	return uint32(0), errors.New("invalid-port-range") //olterrors.ErrInvalidPortRange
	}
	return (portNum & 0xFFFF), nil
	}

	//intfIDToPortTypeName returns port type derived from the intfId
	func intfIDToPortTypeName(intfID uint32) voltha.Port_PortType {
	if ((ponIntfMarkerValue << ponIntfMarkerPos) ^ intfID) < maxPonsPerOlt {
	return voltha.Port_PON_OLT
	}
	if (intfID & (1 << nniUniDiffPos)) == (1 << nniUniDiffPos) {
	return voltha.Port_ETHERNET_NNI
	}
	return voltha.Port_ETHERNET_UNI
	}

	//extractAccessFromFlow returns AccessDevice information
	func extractAccessFromFlow(inPort, outPort uint32) (uint32, uint32, uint32, uint32) {
	if isUpstream(outPort) {
	return inPort, intfIDFromUniPortNum(inPort), onuIDFromPortNum(inPort), uniIDFromPortNum(inPort)
	}
	return outPort, intfIDFromUniPortNum(outPort), onuIDFromPortNum(outPort), uniIDFromPortNum(outPort)
	}

	//isUpstream returns true for Upstream and false for downstream
	func isUpstream(outPort uint32) bool {
	for _, port := range controllerPorts {
	if port == outPort {
	return true
	}
	}
	return (outPort & (1 << nniUniDiffPos)) == (1 << nniUniDiffPos)
	}

	//isControllerBoundFlow returns true/false
	func isControllerBoundFlow(outPort uint32) bool {
	for _, port := range controllerPorts {
	if port == outPort {
	return true
	}
	}
	return false
	}

	//onuIDFromUniPortNum returns onuId from give portNum information.
	func onuIDFromUniPortNum(portNum uint32) uint32 {
	return (portNum >> bitsForUniID) & (maxOnusPerPon - 1)
	}

	//flowExtractInfo fetches uniport from the flow, based on which it gets and returns ponInf, onuID, uniID, inPort and ethType
	func flowExtractInfo(flow *ofp.OfpFlowStats, flowDirection string) (uint32, uint32, uint32, uint32, uint32, uint32, error) {
	var uniPortNo uint32
	var ponIntf uint32
	var onuID uint32
	var uniID uint32
	var inPort uint32
	var ethType uint32

	if flowDirection == "upstream" {
	if uniPortNo = flows.GetChildPortFromTunnelId(flow); uniPortNo == 0 {
	for _, field := range flows.GetOfbFields(flow) {
	if field.GetType() == flows.IN_PORT {
	uniPortNo = field.GetPort()
	break
	}
	}
	}
	} else if flowDirection == "downstream" {
	if uniPortNo = flows.GetChildPortFromTunnelId(flow); uniPortNo == 0 {
	for _, field := range flows.GetOfbFields(flow) {
	if field.GetType() == flows.METADATA {
	for _, action := range flows.GetActions(flow) {
	if action.Type == flows.OUTPUT {
	if out := action.GetOutput(); out != nil {
	uniPortNo = out.GetPort()
	}
	break
	}
	}
	} else if field.GetType() == flows.IN_PORT {
	inPort = field.GetPort()
	} else if field.GetType() == flows.ETH_TYPE {
	ethType = field.GetEthType()
	}
	}
	}
	}

	if uniPortNo == 0 {
	return 0, 0, 0, 0, 0, 0, errors.New("notFound: pon-interface (flowDirection)")
	// olterrors.NewErrNotFound("pon-interface", log.Fields{"flow-direction": flowDirection}, nil)
	}

	ponIntf = intfIDFromUniPortNum(uniPortNo)
	onuID = onuIDFromUniPortNum(uniPortNo)
	uniID = uniIDFromPortNum(uniPortNo)

	logger.Debugw(ctx,"flow extract info result",
	log.Fields{"uniPortNo": uniPortNo, "ponIntf": ponIntf,
	"onuID": onuID, "uniID": uniID, "inPort": inPort, "ethType": ethType})

	return uniPortNo, ponIntf, onuID, uniID, inPort, ethType, nil
	}
	*/