From 61a851845546300cc2f5ee9f3dd6761c9ecd093e Mon Sep 17 00:00:00 2001 From: Jie Hu Date: Wed, 16 Dec 2015 18:52:19 +0800 Subject: ESCALATOR-31 Adjusting documentation JIRA: ESCALATOR-31 Change-Id: I0b83511a542982f07c2ab9d60517f4b5f357569b Signed-off-by: Jie Hu --- docs/requirements/000-Contributors.rst | 16 + docs/requirements/101-Scope.rst | 45 ++ docs/requirements/102-Terminologies.rst | 129 ++++++ docs/requirements/103-Background.rst | 226 ++++++++++ docs/requirements/104-Requirements.rst | 478 +++++++++++++++++++++ docs/requirements/105-Use_Cases.rst | 213 +++++++++ docs/requirements/106-Reference.rst | 18 + .../1A1-Requirements_from_other_Projects.rst | 34 ++ .../1A2-Questionnaire_of_Escalator.rst | 11 + docs/requirements/300-Gap_Analysis_Report.rst | 50 +++ docs/requirements/etc/conf.py | 34 ++ docs/requirements/etc/opnfv-logo.png | Bin 0 -> 2829 bytes docs/requirements/images/figure1.png | Bin 0 -> 118003 bytes docs/requirements/index.rst | 37 ++ 14 files changed, 1291 insertions(+) create mode 100644 docs/requirements/000-Contributors.rst create mode 100644 docs/requirements/101-Scope.rst create mode 100644 docs/requirements/102-Terminologies.rst create mode 100644 docs/requirements/103-Background.rst create mode 100644 docs/requirements/104-Requirements.rst create mode 100644 docs/requirements/105-Use_Cases.rst create mode 100644 docs/requirements/106-Reference.rst create mode 100644 docs/requirements/1A1-Requirements_from_other_Projects.rst create mode 100644 docs/requirements/1A2-Questionnaire_of_Escalator.rst create mode 100644 docs/requirements/300-Gap_Analysis_Report.rst create mode 100644 docs/requirements/etc/conf.py create mode 100644 docs/requirements/etc/opnfv-logo.png create mode 100644 docs/requirements/images/figure1.png create mode 100644 docs/requirements/index.rst (limited to 'docs/requirements') diff --git a/docs/requirements/000-Contributors.rst b/docs/requirements/000-Contributors.rst new file mode 100644 index 0000000..bf70f59 --- /dev/null +++ b/docs/requirements/000-Contributors.rst @@ -0,0 +1,16 @@ +============ +Contributors +============ + +| Jie Hu (ZTE, hu.jie@zte.com.cn) +| Qiao Fu (China Mobile, fuqiao@chinamobile.com) +| Ulrich Kleber (Huawei, Ulrich.Kleber@huawei.com) +| Maria Toeroe (Ericsson, maria.toeroe@ericsson.com) +| Sama, Malla Reddy (DOCOMO, sama@docomolab-euro.com) +| Zhong Chao (ZTE, chao.zhong@zte.com.cn) +| Julien Zhang (ZTE, zhang.jun3g@zte.com.cn) +| Yuri Yuan (ZTE, yuan.yue@zte.com.cn) +| Zhipeng Huang (Huawei, huangzhipeng@huawei.com) +| Jia Meng (ZTE, meng.jia@zte.com.cn) +| Liyi Meng (Ericsson, liyi.meng@ericsson.com) +| Pasi Vaananen (Stratus, pasi.vaananen@stratus.com) diff --git a/docs/requirements/101-Scope.rst b/docs/requirements/101-Scope.rst new file mode 100644 index 0000000..42da7b9 --- /dev/null +++ b/docs/requirements/101-Scope.rst @@ -0,0 +1,45 @@ +===== +Scope +===== + +This document describes the user requirements on the smooth upgrade +function of the NFVI and VIM with respect to the upgrades of the OPNFV +platform from one version to another. Smooth upgrade means that the +upgrade results in no service outage for the end-users. This requires +that the process of the upgrade is automatically carried out by a tool +(code name: Escalator) with pre-configured data. The upgrade process +includes preparation, validation, execution, monitoring and +conclusion. + +.. While it is good to have a tool for the entire upgrade process, + but it is a challenging task, so maybe we shouldn't require automation + for the entire process right away. Automation is essential at + execution. + +.. Maybe we can analysis information flows of the upgrade tool, + abstract the basic / essential actions from the tool (or tools), and + map them to a command set of NFVI / VIM's interfaces. + +The requirements are defined in a stepwise approach, i.e. in the first +phase focusing on the upgrade of the VIM then widening the scope to the +NFVI. + +The requirements may apply to different NFV functions (NFVI, or VIM, or +both of them). They will be classified in the Appendix of this +document. + +The objects being upgraded described in this document are software modules covered by +red box in the picture below which includes: VIM and NFVI. + +The target of the upgrade is to reduce the impact on the applications in the +blue box below as much as possible. + +Please keep in mind that the upgrade tool does not take Vi-Vnfm and Or-Vi into +consideration. In other words, these two interfaces may not provided service normally +during upgrade procedure. + + +.. figure:: images/figure1.png + :name: figure1 + :width: 100% + diff --git a/docs/requirements/102-Terminologies.rst b/docs/requirements/102-Terminologies.rst new file mode 100644 index 0000000..221196b --- /dev/null +++ b/docs/requirements/102-Terminologies.rst @@ -0,0 +1,129 @@ +=========== +Terminology +=========== + +Terminologies +============= + +Operator + The term refers to network service providers and Virtual Network + Function (VNF) providers. + +End-User + The term refers to a subscriber of the Operator's services. + +Network Service + The term refers to a service provided by an Operator to its + end-users using a set of (virtualized) Network Functions + +Infrastructure Services + The term refers to services provided by the NFV Infrastructure to the VNFs + as required by the Management & Orchestration functions and especially the VIM. + I.e. these are the virtual resources as perceived by the VNFs. + +Smooth Upgrade + The term refers to an upgrade that results in no service outage + for the end-users. + +Rolling Upgrade + The term refers to an upgrade strategy, which upgrades a node or a subset + of nodes at a time in a wave style rolling through the data centre. It + is a popular upgrade strategy to maintain service availability. + +Parallel Universe Upgrade + The term refers to an upgrade strategy, which creates and deploys + a new universe - a system with the new configuration - while the old + system continues running. The state of the old system is transferred + to the new system after sufficient testing of the new system. + +Infrastructure Resource Model + The term refers to the representation of infrastructure resources, + namely: the physical resources, the virtualization + facility resources and the virtual resources. + +Physical Resource + The term refers to a piece of hardware in the NFV infrastructure that may + also include firmware enabling this piece of hardware. + +Virtual Resource + The term refers to a resource, which is provided as services built on top + of the physical resources via the virtualization facilities; in particular, + virtual resources are the resources on which VNFs are deployed. Examples of + virtual resources are: VMs, virtual switches, virtual routers, virtual disks. + +Visualization Facility + The term refers to a resource that enables the creation + of virtual environments on top of the physical resources, e.g. + hypervisor, OpenStack, etc. + +Upgrade Campaign + The term refers to a choreography that describes how the upgrade should + be performed in terms of its targets (i.e. upgrade objects), the + steps/actions required of upgrading each, and the coordination of these + steps so that service availability can be maintained. It is an input to an + upgrade tool (Escalator) to carry out the upgrade. + +Upgrade Duration + The duration of an upgrade characterized by the time elapsed between its + initiation and its completion. E.g. from the moment the execution of an + upgrade campaign has started until it has been committed. Depending on + the upgrade strategy, the state of the configuration and the upgrade target + some parts of the system may be in a more vulnerable state with respect to + service availbility. + +Outage + The period of time during which a given service is not provided is referred + as the outage of that given service. If a subsystem or the entire system + does not provide any service, it is the outage of the given subsystem or the + system. Smooth upgrade means upgrade with no outage for the user plane, i.e. + no VNF should experience service outage. + +Rollback + The term refers to a failure handling strategy that reverts the changes + done by a potentially failed upgrade execution one by one in a reverse order. + I.e. it is like undoing the changes done by the upgrade. + +Backup + The term refers to data persisted to a storage, so that it can be used to + restore the system or a given part of it in the same state as it was when the + backup was created assuming a cold restart. Changes made to the system from + the moment the backup was created till the moment it is used to restore the + (sub)system are lost in the restoration process. + +Restore + The term refers to a failure handling strategy that reverts the changes + done, for example, by an upgrade by restoring the system from some backup + data. This results in the loss of any change and data persisted after the + backup was been taken. To recover those additional measures need to be taken + if necessary (e.g. rollforward). + +Rollforward + The term refers to a failure handling strategy applied after a restore + (from a backup) opertaion to recover any loss of data persisted between + the time the backup has been taken and the moment it is restored. Rollforward + requires that data that needs to survive the restore operation is logged at + a location not impacted by the restore so that it can be re-applied to the + system after its restoration from the backup. + +Downgrade + The term refers to an upgrade in which an earlier version of the software + is restored through the upgrade procedure. A system can be downgraded to any + earlier version and the compatibility of the versions will determine the + applicable upgrade strategies and whether service outage can be avoided. + In particular any data conversion needs special attention. + +Abbreviations +============= + +NFVI + The term is an abbreviation for Network Function Virtualization + Infrastructure; sometimes it is also referred as data plane in this + document. The NFVI provides the virtual resources to the virtual + network functions under the control of the VIM. + +VIM + The term is an abbreviation for Virtual Infrastructure Manager; + sometimes it is also referred as control plane in this document. + The VIM controls and manages the NFVI compute, network and storage + resources to provide the required virtual resources to the VNFs. + diff --git a/docs/requirements/103-Background.rst b/docs/requirements/103-Background.rst new file mode 100644 index 0000000..e21e310 --- /dev/null +++ b/docs/requirements/103-Background.rst @@ -0,0 +1,226 @@ +========== +Background +========== + +Upgrade Objects +=============== + +Physical Resource +^^^^^^^^^^^^^^^^^ + +Most cloud infrastructures support the dynamic addition and removal of +hardware. Accordingly a hardware upgrade could be done by adding the new +piece of hardware and removing the old one. From the persepctive of smooth +upgrade the orchestration/scheduling of these actions is the primary concern. + +Upgrading a physical resource may involve as well the upgrade of its firmware +and/or modifying its configuration data. This may require the restart of the +hardware. + +Virtual Resources +^^^^^^^^^^^^^^^^^ + +Addition and removal of virtual resources may be initiated by the users or be +a result of an elasticity action. Users may also request the upgrade of their +virtual resources using a new VM image. + +.. Needs to be moved to requirement section: Escalator should facilitate such an + option and allow for a smooth upgrade. + +On the other hand changes in the infrastructure, namely, in the hardware and/or +the virtualization facility resources may result in the upgrade of the virtual +resources. For example if by some reason the hypervisor is changed and +the current VMs cannot be migrated to the new hypervisor - they are +incompatible - then the VMs need to be upgraded too. This is not +something the NFVI user (i.e. VNFs ) would know about. + + +Virtualization Facility Resources +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +Based on the functionality they provide, virtualization facility +resources could be divided into computing node, networking node, +storage node and management node. + +The possible upgrade objects in these nodes are considered below: +(Note: hardware based virtualization may be considered as virtualization +facility resource, but from escalator perspective, it is better to +consider it as part of the hardware upgrade. ) + +**Computing node** + +1. OS Kernel + +2. Hypvervisor and virtual switch + +3. Other kernel modules, like drivers + +4. User space software packages, like nova-compute agents and other + control plane programs. + +Updating 1 and 2 will cause the loss of virtualzation functionality of +the compute node, which may lead to the interruption of data plane services +if the virtual resource is not redudant. + +Updating 3 might have the same result. + +Updating 4 might lead to control plane services interruption if not an +HA deployment. + +.. I'm not sure why would 4 cause control plane interruption on a + compute node. My understanding is that simply the node cannot be managed. + Redundancy won't help in that either. + + +**Networking node** + +1. OS kernel, optional, not all switches/routers allow the upgrade their + OS since it is more like a firmware than a generic OS. + +2. User space software package, like neutron agents and other control + plane programs + +Updating 1 if allowed will cause a node reboot and therefore leads to +data plane service interruption if the virtual resource is not +redundant. + +Updating 2 might lead to control plane services interruption if not an +HA deployment. + +**Storage node** + +1. OS kernel, optional, not all storage nodes allow the upgrade their OS + since it is more like a firmware than a generic OS. + +2. Kernel modules + +3. User space software packages, control plane programs + +Updating 1 if allowed will cause a node reboot and therefore leads to +data plane services interruption if the virtual resource is not +redundant. + +Update 2 might result in the same. + +Updating 3 might lead to control plane services interruption if not an +HA deployment. + +**Management node** + +1. OS Kernel + +2. Kernel modules, like driver + +3. User space software packages, like database, message queue and + control plane programs. + +Updating 1 will cause a node reboot and therefore leads to control +plane services interruption if not an HA deployment. Updating 2 might +result in the same. + +Updating 3 might lead to control plane services interruption if not an +HA deployment. + +Upgrade Granularity +=================== + +The granularity of an upgrade can be characterized from two perspective: +- the physical dimension and +- the software dimension + +Physical Dimension +^^^^^^^^^^^^^^^^^^ + +The physical dimension characterizes the number of similar upgrade objects +targeted by the upgrade, i.e. whether it is full / partial upgrade of a +data centre, cluster, zone. +Because of the upgrade of a data centre or a zone, it may be divided into +several batches. Thus there is a need for efficiency in the execution of +upgrades of potentially huge number of upgrade objects while still maintain +availability to fulfill the requirement of smooth upgrade. + +The upgrade of a cloud environment (cluster) may also +be partial. For example, in one cloud environment running a number of +VNFs, we may just try to upgrade one of them to check the stability and +performance, before we upgrade all of them. +Thus there is a need for proper organization of the artifacts associated with +the different upgrade objects. Also the different versions should be able +to coextist beyond the upgrade period. + +From this perspective special attention may be needed when upgrading +objects that are collaborating in a redundancy schema as in this case +different versions not only need to coexist but also collaborate. This +puts requirement on the upgrade objects primarily. If this is not possible +the upgrade campaign should be designed in such a way that the proper +isolation is ensured. + +Software Dimension +^^^^^^^^^^^^^^^^^^ + +The software dimension of the upgrade characterizes the upgrade object +type targeted and the combination in which they are upgraded together. + +Even though the upgrade may +initially target only one type of upgrade object, e.g. the hypervisor +the dependency of other upgrade objects on this initial target object may +require their upgrade as well. I.e. the upgrades need to be combined. From this +perspective the main concern is compatibility of the dependent and +sponsor objects. To take into consideration of these dependencies +they need to be described together with the version compatility information. +Breaking dependencies is the major cause of outages during upgrades. + +In other cases it is more efficient to upgrade a combination of upgrade +objects than to do it one by one. One aspect of the combination is how +the upgrade packages can be combined, whether a new image can be created for +them before hand or the different packages can be installed during the upgrade +independently, but activated together. + +The combination of upgrade objects may span across +layers (e.g. software stack in the host and the VM of the VNF). +Thus, it may require additional coordination between the management layers. + +With respect to each upgrade object type and even stacks we can +distingush major and minor upgrades: + +**Major Upgrade** + +Upgrades between major releases may introducing significant changes in +function, configuration and data, such as the upgrade of OPNFV from +Arno to Brahmaputra. + +**Minor Upgrade** + +Upgrades inside one major releases which would not leads to changing +the structure of the platform and may not infect the schema of the +system data. + +Scope of Impact +=============== + +Considering availability and therefore smooth upgrade, one of the major +concerns is the predictability and control of the outcome of the different +upgrade operations. Ideally an upgrade can be performed without impacting any +entity in the system, which means none of the operations change or potentially +change the behaviour of any entity in the system in an uncotrolled manner. +Accordingly the operations of such an upgrade can be performed any time while +the system is running, while all the entities are online. No entity needs to be +taken offline to avoid such adverse effects. Hence such upgrade operations +are referred as online operations. The effects of the upgrade might be activated +next time it is used, or may require a special activation action such as a +restart. Note that the activation action provides more control and predictability. + +If an entity's behavior in the system may change due to the upgrade it may +be better to take it offline for the time of the relevant upgrade operations. +The main question is however considering the hosting relation of an upgrade +object what hosted entities are impacted. Accordingly we can identify a scope +which is impacted by taking the given upgrade object offline. The entities +that are in the scope of impact may need to be taken offline or moved out of +this scope i.e. migrated. + +If the impacted entity is in a different layer managed by another manager +this may require coordination because taking out of service some +infrastructure resources for the time of their upgrade which support virtual +resources used by VNFs that should not experience outages. The hosted VNFs +may or may not allow for the hot migration of their VMs. In case of migration +the VMs placement policy should be considered. + diff --git a/docs/requirements/104-Requirements.rst b/docs/requirements/104-Requirements.rst new file mode 100644 index 0000000..b6e7f57 --- /dev/null +++ b/docs/requirements/104-Requirements.rst @@ -0,0 +1,478 @@ +============ +Requirements +============ + +Upgrade duration +================ + +As the OPNFV end-users are primarily Telecom operators, the network +services provided by the VNFs deployed on the NFVI should meet the +requirement of 'Carrier Grade'.:: + + In telecommunication, a "carrier grade" or"carrier class" refers to a + system, or a hardware or software component that is extremely reliable, + well tested and proven in its capabilities. Carrier grade systems are + tested and engineered to meet or exceed "five nines" high availability + standards, and provide very fast fault recovery through redundancy + (normally less than 50 milliseconds). [from wikipedia.org] + +"five nines" means working all the time in ONE YEAR except 5'15". + +:: + + We have learnt that a well prepared upgrade of OpenStack needs 10 + minutes. The major time slot in the outage time is used spent on + synchronizing the database. [from ' Ten minutes OpenStack Upgrade? Done! + ' by Symantec] + +This 10 minutes of downtime of the OpenStack services however did not impact the +users, i.e. the VMs running on the compute nodes. This was the outage of +the control plane only. On the other hand with respect to the +preparations this was a manually tailored upgrade specific to the +particular deployment and the versions of each OpenStack service. + +The project targets to achieve a more generic methodology, which however +requires that the upgrade objects fulfil certain requirements. Since +this is only possible on the long run we target first the upgrade +of the different VIM services from version to version. + +**Questions:** + +1. Can we manage to upgrade OPNFV in only 5 minutes? + +.. The first question is whether we have the same carrier grade + requirement on the control plane as on the user plane. I.e. how + much control plane outage we can/willing to tolerate? + In the above case probably if the database is only half of the size + we can do the upgrade in 5 minutes, but is that good? It also means + that if the database is twice as much then the outage is 20 + minutes. + For the user plane we should go for less as with two release yearly + that means 10 minutes outage per year. + +.. 10 minutes outage per year to the users? Plus, if we take + control plane into the consideration, then total outage will be + more than 10 minute in whole network, right? + +.. The control plane outage does not have to cause outage to + the users, but it may of course depending on the size of the system + as it's more likely that there's a failure that needs to be handled + by the control plane. + +2. Is it acceptable for end users ? Such as a planed service + interruption will lasting more than ten minutes for software + upgrade. + +.. For user plane, no it's not acceptable in case of + carrier-grade. The 5' 15" downtime should include unplanned and + planned downtimes. + +.. I go agree with Maria, it is not acceptable. + +3. Will any VNFs still working well when VIM is down? + +.. In case of OpenStack it seems yes. .:) + +The maximum duration of an upgrade +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +The duration of an upgrade is related to and proportional with the +scale and the complexity of the OPNFV platform as well as the +granularity (in function and in space) of the upgrade. + +.. Also, if is a partial upgrade like module upgrade, it depends + also on the OPNFV modules and their tight connection entities as well. + +.. Since the maintenance window is shrinking and becoming non-existent + the duration of the upgrade is secondary to the requirement of smooth upgrade. + But probably we want to be able to put a time constraint on each upgrade + during which it must complete otherwise it is considered failed and the system + should be rolled back. I.e. in case of automatic execution it might not be clear + if an upgrade is long or just hanging. The time constraints may be a function + of the size of the system in terms of the upgrade object(s). + +The maximum duration of a roll back when an upgrade is failed +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +The duration of a roll back is short than the corresponding upgrade. It +depends on the duration of restore the software and configure data from +pre-upgrade backup / snapshot. + +.. During the upgrade process two types of failure may happen: + In case we can recover from the failure by undoing the upgrade + actions it is possible to roll back the already executed part of the + upgrade in graceful manner introducing no more service outage than + what was introduced during the upgrade. Such a graceful roll back + requires typically the same amount of time as the executed portion of + the upgrade and impose minimal state/data loss. + +.. Requirement: It should be possible to roll back gracefully the + failed upgrade of stateful services of the control plane. + In case we cannot recover from the failure by just undoing the + upgrade actions, we have to restore the upgraded entities from their + backed up state. In other terms the system falls back to an earlier + state, which is typically a faster recovery procedure than graceful + roll back and depending on the statefulness of the entities involved it + may result in significant state/data loss. + +.. Two possible types of failures can happen during an upgrade + +.. We can recover from the failure that occurred in the upgrade process: + In this case, a graceful rolling back of the executed part of the + upgrade may be possible which would "undo" the executed part in a + similar fashion. Thus, such a roll back introduces no more service + outage during an upgrade than the executed part introduced. This + process typically requires the same amount of time as the executed + portion of the upgrade and impose minimal state/data loss. + +.. We cannot recover from the failure that occurred in the upgrade + process: In this case, the system needs to fall back to an earlier + consistent state by reloading this backed-up state. This is typically + a faster recovery procedure than the graceful roll back, but can cause + state/data loss. The state/data loss usually depends on the + statefulness of the entities whose state is restored from the backup. + +The maximum duration of a VNF interruption (Service outage) +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +Since not the entire process of a smooth upgrade will affect the VNFs, +the duration of the VNF interruption may be shorter than the duration +of the upgrade. In some cases, the VNF running without the control +from of the VIM is acceptable. + +.. Should require explicitly that the NFVI should be able to + provide its services to the VNFs independent of the control plane? + +.. Requirement: The upgrade of the control plane must not cause + interruption of the NFVI services provided to the VNFs. + +.. With respect to carrier-grade the yearly service outage of the + VNF should not exceed 5' 15" regardless whether it is planned or + unplanned outage. Considering the HA requirements TL-9000 requires an + end-to-end service recovery time of 15 seconds based on which the ETSI + GS NFV-REL 001 V1.1.1 (2015-01) document defines three service + availability levels (SAL). The proposed example service recovery times + for these levels are: + +.. SAL1: 5-6 seconds + +.. SAL2: 10-15 seconds + +.. SAL3: 20-25 seconds + +.. my comment was actually that the downtime metrics of the + underlying elements, components and services are small fraction of the + total E2E service availability time. No-one on the E2E service path + will get the whole downtime allocation (in this context it includes + upgrade process related outages for the services provided by VIM etc. + elements that are subject to upgrade process). + +.. So what you are saying is that the upgrade of any entity + (component, service) shouldn't cause even this much service + interruption. This was the reason I brought these figures here as well + that they are posing some kind of upper-upper boundary. Ideally the + interruption is in the millisecond range i.e. no more than a + switch-over or a live migration. + +.. Requirement: Any interruption caused to the VNF by the upgrade + of the NFVI should be in the sub-second range. + +.. In the future we also need to consider the upgrade of the NFVI, + i.e. HW, firmware, hypervisors, host OS etc. + +Pre-upgrading Environment +========================= + +System is running normally. If there are any faults before the upgrade, +it is difficult to distinguish between upgrade introduced and the environment +itself. + +The environment should have the redundant resources. Because the upgrade +process is based on the business migration, in the absence of resource +redundancy,it is impossible to realize the business migration, as well as to +achieve a smooth upgrade. + +Resource redundancy in two levels: + +NFVI level: This level is mainly the compute nodes resource redundancy. +During the upgrade, the virtual machine on business can be migrated to another +free compute node. + +VNF level: This level depends on HA mechanism in VNF, such as: +active-standby, load balance. In this case, as long as business of the target +node on VMs is migrated to other free nodes, the migration of VM might not be +necessary. + +The way of redundancy to be used is subject to the specific environment. +Generally speaking, During the upgrade, the VNF's service level availability +mechanism should be used in higher priority than the NFVI's. This will help +us to reduce the service outage. + +Release version of software components +====================================== + +This is primarily a compatibility requirement. You can refer to Linux/Python +Compatible Semantic Versioning 3.0.0: + +Given a version number MAJOR.MINOR.PATCH, increment the: + +MAJOR version when you make incompatible API changes, + +MINOR version when you add functionality in a backwards-compatible manner, + +PATCH version when you make backwards-compatible bug fixes. + +Some internal interfaces of OpenStack will be used by Escalator indirectly, +such as VM migration related interface between VIM and NFVI. So it is required +to be backward compatible on these interfaces. Refer to "Interface" chapter +for details. + +Work Flows +========== + +Describes the different types of requirements. To have a table to label the source of +the requirements, e.g. Doctor, Multi-site, etc. + +Basic Actions +============= + +This section describes the basic functions may required by Escalator. + +Preparation (offline) +^^^^^^^^^^^^^^^^^^^^^ + +This is the design phase when the upgrade plan (or upgrade campaign) is +being designed so that it can be executed automatically with minimal +service outage. It may include the following work: + +1. Check the dependencies of the software modules and their impact, + backward compatibilities to figure out the appropriate upgrade method + and ordering. +2. Find out if a rolling upgrade could be planned with several rolling + steps to avoid any service outage due to the upgrade some + parts/services at the same time. +3. Collect the proper version files and check the integration for + upgrading. +4. The preparation step should produce an output (i.e. upgrade + campaign/plan), which is executable automatically in an NFV Framework + and which can be validated before execution. + + - The upgrade campaign should not be referring to scalable entities + directly, but allow for adaptation to the system configuration and + state at any given moment. + - The upgrade campaign should describe the ordering of the upgrade + of different entities so that dependencies, redundancies can be + maintained during the upgrade execution + - The upgrade campaign should provide information about the + applicable recovery procedures and their ordering. + - The upgrade campaign should consider information about the + verification/testing procedures to be performed during the upgrade + so that upgrade failures can be detected as soon as possible and + the appropriate recovery procedure can be identified and applied. + - The upgrade campaign should provide information on the expected + execution time so that hanging execution can be identified + - The upgrade campaign should indicate any point in the upgrade when + coordination with the users (VNFs) is required. + +.. Depends on the attributes of the object being upgraded, the + upgrade plan may be slitted into step(s) and/or sub-plan(s), and even + more small sub-plans in design phase. The plan(s) or sub-plan(s) my + include step(s) or sub-plan(s). + +Validation the upgrade plan / Checking the pre-requisites of System( offline / online) +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +The upgrade plan should be validated before the execution by testing +it in a test environment which is similar to the product environment. + +.. However it could also mean that we can identify some properties + that it should satisfy e.g. what operations can or cannot be executed + simultaneously like never take out two VMs of the same VNF. + +.. Another question is if it requires that the system is in a particular + state when the upgrade is applied. I.e. if there's certain amount of + redundancy in the system, migration is enabled for VMs, when the NFVI + is upgraded the VIM is healthy, when the VIM is upgraded the NFVI is + healthy, etc. + +.. I'm not sure what online validation means: Is it the validation of the + upgrade plan/campaign or the validation of the system that it is in a + state that the upgrade can be performed without too much risk?== + +Before the upgrade plan being executed, the system healthy of the +online product environment should be checked and confirmed to satisfy +the requirements which were described in the upgrade plan. The +sysinfo, e.g. which included system alarms, performance statistics and +diagnostic logs, will be collected and analogized. It is required to +resolve all of the system faults or exclude the unhealthy part before +executing the upgrade plan. + + +Backup/Snapshot (online) +^^^^^^^^^^^^^^^^^^^^^^^^ + +For avoid loss of data when a unsuccessful upgrade was encountered, the +data should be back-upped and the system state snapshot should be taken +before the execution of upgrade plan. This would be considered in the +upgrade plan. + +Several backups/Snapshots may be generated and stored before the single +steps of changes. The following data/files are required to be +considered: + +1. running version files for each node. +2. system components' configuration file and database. +3. image and storage, if it is necessary. + +.. Does 3 imply VNF image and storage? I.e. VNF state and data?== + +.. The following text is derived from previous "4. Negotiate + with the VNF if it's ready for the upgrade" + +Although the upper layer, which include VNFs and VNFMs, is out of the +scope of Escalator, but it is still recommended to let it ready for a +smooth system upgrade. The escalator could not guarantee the safe of +VNFs. The upper layer should have some safe guard mechanism in design, +and ready for avoiding failure in system upgrade. + +Execution (online) +^^^^^^^^^^^^^^^^^^ + +The execution of upgrade plan should be a dynamical procedure which is + controlled by Escalator. + +.. Revised text to be general.== + +1. It is required to supporting execution ether in sequence or in + parallel. +2. It is required to check the result of the execution and take the + action according the situation and the policies in the upgrade plan. +3. It is required to execute properly on various configurations of + system object. I.e. stand-alone, HA, etc. +4. It is required to execute on the designated different parts of the + system. I.e. physical server, virtualized server, rack, chassis, + cluster, even different geographical places. + +Testing (online) +^^^^^^^^^^^^^^^^ + +The testing after upgrade the whole system or parts of system to make +sure the upgraded system(object) is working normally. + +.. Revised text to be general. + +1. It is recommended to run the prepared test cases to see if the + functionalities are available without any problem. +2. It is recommended to check the sysinfo, e.g. system alarms, + performance statistics and diagnostic logs to see if there are any + abnormal. + +Restore/Roll-back (online) +^^^^^^^^^^^^^^^^^^^^^^^^^^ + +When upgrade is failure unfortunately, a quick system restore or system +roll-back should be taken to recovery the system and the services. + +.. Revised text to be general. + +1. It is recommend to support system restore from backup when upgrade + was failed. +2. It is recommend to support graceful roll-back with reverse order + steps if possible. + +Monitoring (online) +^^^^^^^^^^^^^^^^^^^ + +Escalator should continually monitor the process of upgrade. It is +keeping update status of each module, each node, each cluster into a +status table during upgrade. + +.. Revised text to be general. + +1. It is required to collect the status of every objects being upgraded + and sending abnormal alarms during the upgrade. +2. It is recommend to reuse the existing monitoring system, like alarm. +3. It is recommend to support pro-actively query. +4. It is recommend to support passively wait for notification. + +**Two possible ways for monitoring:** + +**Pro-Actively Query** requires NFVI/VIM provides proper API or CLI +interface. If Escalator serves as a service, it should pass on these +interfaces. + +**Passively Wait for Notification** requires Escalator provides +callback interface, which could be used by NFVI/VIM systems or upgrade +agent to send back notification. + +.. I am not sure why not to subscribe the notification. + +Logging (online) +^^^^^^^^^^^^^^^^ + +Record the information generated by escalator into log files. The log +file is used for manual diagnostic of exceptions. + +1. It is required to support logging. +2. It is recommended to include time stamp, object id, action name, + error code, etc. + +Administrative Control (online) +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ + +Administrative Control is used for control the privilege to start any +escalator's actions for avoiding unauthorized operations. + +#. It is required to support administrative control mechanism +#. It is recommend to reuse the system's own secure system. +#. It is required to avoid conflicts when the system's own secure system + being upgraded. + +Requirements on Object being upgraded +===================================== + +.. We can develop BPs in future from requirements of this section and + gap analysis for upper stream projects + +Escalator focus on smooth upgrade. In practical implementation, it +might be combined with installer/deplorer, or act as an independent +tool/service. In either way, it requires targeting systems(NFVI and +VIM) are developed/deployed in a way that Escalator could perform +upgrade on them. + +On NFVI system, live-migration is likely used to maintain availability +because OPNFV would like to make HA transparent from end user. This +requires VIM system being able to put compute node into maintenance mode +and then isolated from normal service. Otherwise, new NFVI instances +might risk at being schedule into the upgrading node. + +On VIM system, availability is likely achieved by redundancy. This +impose less requirements on system/services being upgrade (see PVA +comments in early version). However, there should be a way to put the +target system into standby mode. Because starting upgrade on the +master node in a cluster is likely a bad idea. + +.. Revised text to be general. + +1. It is required for NFVI/VIM to support **service handover** mechanism + that minimize interruption to 0.001%(i.e. 99.999% service + availability). Possible implementations are live-migration, redundant + deployment, etc, (Note: for VIM, interruption could be less + restrictive) + +2. It is required for NFVI/VIM to restore the early version in a efficient + way, such as **snapshot**. + +3. It is required for NFVI/VIM to **migration data** efficiently between + base and upgraded system. + +4. It is recommend for NFV/VIM's interface to support upgrade + orchestration, e.g. reading/setting system state. + +Functional Requirements +======================= + +Availability mechanism, etc. + +Non-functional Requirements +=========================== diff --git a/docs/requirements/105-Use_Cases.rst b/docs/requirements/105-Use_Cases.rst new file mode 100644 index 0000000..9f13110 --- /dev/null +++ b/docs/requirements/105-Use_Cases.rst @@ -0,0 +1,213 @@ +========= +Use Cases +========= + +This section describes the use cases in different system configuration +to verify the requirements of Escalator. + +System Configurations +===================== + +HA configuration +^^^^^^^^^^^^^^^^ + +A HA configuration system is very popular in the operator's data centre. +It is a typical product environment. It is always running 7\*24 with VNFs +running on it to provide services to the end users. + + +Non-HA configuration +^^^^^^^^^^^^^^^^^^^^ + +A non-HA configuration system is normally deployed for experimental or +development usages, such as a Vagrant/VM environment. + +Escalator supports the upgrade system in this configuration, but it may +not guarantee a smooth upgrade. + +Use cases +========= + +Use case #1: Smooth upgrade in a HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +For a system with HA configuration, the operator can use Escalator to +smooth-upgrade NFVI/VIM components into a new version without any service +outage. + +When a compute node being upgraded, the VMs on the node may need to be migrated +to other compute nodes to avoid service outage, so it is requred that there are +enough redundant resources to migrate VMs on this compute node. + +Before upgrade, the operator can use Escalator to check whether smooth upgrade +conditions are all satisfied. These conditions include whether there are enough +idle resources to migrate VMs during updrading, and whether the new version is +compatible with the current one, etc. If there are some conditions not +satisfied, Escalator will show them. Escalator can also provide the solutions if +there is any, such as the number and configuration of spare compute nodes which +are needed. + +When upgrade starts, Escalator will also automatically check whether smooth +upgrade conditions are all satisfied. If some smooth upgrade conditions are not +satisfied, Escalator will show the failure of smooth upgrade. + +- Pre-Conditions + + 1. The system is running as normal. + 2. The VNFs are providing services as usual. + +- Upgrading steps + + 1. The VNFs are continually providing services during the upgrade. + 2. The operator successfully logged in the GUI of Escalator to select the + software packages including Linux OS, Hypervisor, OpenStack, ODL and other + OPNFV components, ect. (All or part of components could be selected.) + 3. Select the nodes to be upgraded. i.e. controller node, network node, + storage node and compute node, etc. + 4. Select "Disable Scale-up". It will limit the scale-up operation when + upgrade is in progress to prevent failures due to the shortage of + resources. + 5. Select "Check Smooth Upgrade Conditions". If Escalator shows that there are + some conditions not satisfied, try to resolve them according to the + solutions provided. + 6. Select "Smooth Upgrade", then apply the upgrade operation. + 7. Select "Restore Scale-up" after the upgrade. It will restore scale-up to + the original enabled/disabled state before upgrade. + +- Post-Conditions + + 1. The system is upgraded successfully. + 2. There is no service outage during the upgrade. + 3. The VNFs are providing services as usual after the upgrade. + +Use case #2: Roll-back after a failed smooth upgrade in a HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +For a system with HA configuration, if the upgrade fails when the operator is +smooth-upgrading NFVI/VIM components into a new version using Escalator, the +operator can roll-back the system without any service outage. + +- Pre-Conditions + + 1. The system is running as normal. + 2. The VNFs are providing services as usual. + 3. Scale-up operation is disabled. + 4. Smooth upgrade failed. + +- Roll-back steps + + 1. Escalator concludes that the upgrade has failed and provides the operator + with the reason. + 2. Select the "Roll-back" operation. + 3. If the roll-back is successful, go to step 4, otherwise the operator can + select "Restore Backup" to restore the system from the backup data. + 4. Select "Restore Scale-up" after the roll-back. It will restore scale-up to + the original enabled/disabled state before upgrade. + +- Post-Conditions + + 1. The system is rolled-back successfully when the upgrade failed. + 2. There is no service outage during the roll-back. + 3. The VNFs are providing services as usual after the roll-back. + +Use case #3: Roll-back after a successful smooth upgrade in a HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +When a smooth upgrade in a HA configuration is successful, the operator may want +to roll-back for some reasons, such as performance issues. +Escalator supports roll-back after a successful smooth upgrade without any +service outage. + +- Pre-Conditions + + 1. The system is running as normal. + 2. The VNFs are providing services as usual. + 3. Smooth upgrade succeeded. + +- Roll-back steps + + 1. Select "Disable Scale-up". It will limit the scale-up operation when roll- + back is in progress to prevent failures due to the shortage of resources. + 2. Select "Check Smooth Roll-back Conditions". If Escalator shows that there + are some conditions not satisfied, try to resolve them according to the + solutions provided. + 3. Select "Roll-back", then apply the roll-back operation. + 4. If the roll-back is successful, go to step 5, otherwise the operator can + select "Restore Backup" to restore the system from the backup data. + 5. Select "Restore Scale-up" after the roll-back. It will restore scale-up to + the original enabled/disabled state before roll-back. + +- Post-Conditions + + 1. The system is rolled-back successfully. + 2. There is no service outage during the roll-back. + 3. The VNFs are providing services as usual after the roll-back. + +Use case #4: Non-smooth upgrade in a non-HA/HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +For a system with non-HA configuration, the operator can also use Escalator to +upgrade NFVI/VIM components into a new version. In this case, the upgrade may +result in service outage. In other words, the upgrade is non-smooth. +For a system with HA configuration, if the service outage is acceptable or +inevitable, the operator can also use Escalator to non-smoothly upgrade the +system. + +- Pre-Conditions + + 1. The system is running as normal. + +- Upgrading steps + + 1. The operator successfully logged in the GUI of Escalator to select the + software packages including Linux OS, Hypervisor, OpenStack, ODL and other + OPNFV components, ect. (All or part of components could be selected.) + 2. Select the nodes to be upgraded. i.e. controller node, network node, + storage node and compute node, etc. + 3. Select "Non-Smooth Upgrade", then apply the upgrade operation. + +- Post-Conditions + + 1. The system is upgraded successfully. + +Use case #5: Roll-back after a failed non-smooth upgrade in a non-HA/HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +For a system with non-HA/HA configuration, if the upgrade fails when the +operator is non-smoothly upgrading NFVI/VIM components into a new version using +Escalator, the operator can roll-back the system. In this case, the roll-back +may result in service outage. + +- Pre-Conditions + + 1. The system is running as normal. + 2. Non-smooth upgrade failed. + +- Roll-back steps + + 1. Escalator concludes that the upgrade has failed and provides the operator + with the reason. + 2. Select the "Roll-back" operation. + 3. If the roll-back fails, the operator can select "Restore Backup" to restore + the system from the backup data. + +- Post-Conditions + + 1. The system is rolled-back successfully when the upgrade failed. + +Use case #6: Roll-back after a successful non-smooth upgrade in a non-HA/HA configuration +^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ +When a non-smooth upgrade in a non-HA/HA configuration is successful, the +operator may want to roll-back for some reasons, such as performance issues. +Escalator supports roll-back after a successful non-smooth upgrade. In this +case,the roll-back may result in service outage. + +- Pre-Conditions + + 1. The system is running as normal. + 2. Non-smooth upgrade succeeded. + +- Roll-back steps + + 1. Select the "Roll-back" operation. + 2. If the roll-back fails, the operator can select "Restore Backup" to restore + the system from the backup data. + +- Post-Conditions + + 1. The system is rolled-back successfully when the upgrade failed. diff --git a/docs/requirements/106-Reference.rst b/docs/requirements/106-Reference.rst new file mode 100644 index 0000000..ff087fa --- /dev/null +++ b/docs/requirements/106-Reference.rst @@ -0,0 +1,18 @@ +========= +Reference +========= + +[1] ETSI GS NFV 002 (V1.1.1): “Architectural Framework” + +[2] ETSI GS NFV 003 (V1.1.1): "Terminology for Main Concepts in NFV" + +[3] ETSI GS NFV-SWA001:“Virtual Network Function Architecture” + +[4] ETSI GS NFV-MAN001:“Management and Orchestration” + +[5] ETSI GS NFV-REL001:"Resiliency Requirements" + +[6] QuEST Forum TL-9000:"Quality Management System Requirement +Handbook" + +[7] Service Availability Forum AIS:"Software Management Framework" diff --git a/docs/requirements/1A1-Requirements_from_other_Projects.rst b/docs/requirements/1A1-Requirements_from_other_Projects.rst new file mode 100644 index 0000000..a62405d --- /dev/null +++ b/docs/requirements/1A1-Requirements_from_other_Projects.rst @@ -0,0 +1,34 @@ +================================ +Requirements from other Projects +================================ + +Doctor Project +============== + +.. This scenario could be out of scope in Escalator project, but + having the option to support this should be better to align with + Doctor requirements. + +The scope of Doctor project also covers maintenance scenario in which + +1. The VIM administrator requests host maintenance to VIM. + +2. VIM will notify it to consumer such as VNFM to trigger application level + migration or switching active-standby nodes. + +3. VIM waits response from the consumer for a short while. + +- VIM should send out notification of VM migration to consumer (VNFM) + as abstracted message like "maintenance". + +- VIM could wait VM migration until it receives "VM ready to + maintenance" message from the owner (VNFM) + +HA Project +========== + +Multi-site Project +================== + +- Escalator upgrade one site should at least not lead to the other site + API token validation failed. diff --git a/docs/requirements/1A2-Questionnaire_of_Escalator.rst b/docs/requirements/1A2-Questionnaire_of_Escalator.rst new file mode 100644 index 0000000..c92a391 --- /dev/null +++ b/docs/requirements/1A2-Questionnaire_of_Escalator.rst @@ -0,0 +1,11 @@ +========================== +Questionnaire of Escalator +========================== + +A Questionnaire was created for collecting requirements from other projects. + +Escalator Questionnaire: +https://wiki.opnfv.org/_media/wiki/opnfv_escalator_questionnaire_20150723.pptx + +Answer the questionnaire: https://docs.google.com/forms/d/11o1mt15zcq0WBtXYK0n6lKF8XuIzQTwvv8ePTjmcoF0/viewform?usp=send_form + diff --git a/docs/requirements/300-Gap_Analysis_Report.rst b/docs/requirements/300-Gap_Analysis_Report.rst new file mode 100644 index 0000000..1f1d3fe --- /dev/null +++ b/docs/requirements/300-Gap_Analysis_Report.rst @@ -0,0 +1,50 @@ +=================== +Gap Analysis Report +=================== + +Impact Analysis +=============== + +Upgrading the different software modules may cause different impact on +the availability of the infrastructure resources and even on the service +continuity of the vNFs. + +**Software modules in the computing nodes** + +#. Host OS patch + +#. Hypervisor, such as KVM, QEMU, XEN, libvirt +#. Openstack agent in computing nodes (like Nova agent, Ceilometer + agent...) + +.. As SW module, we should list the host OS and maybe its + drivers as well. From upgrade perspective do we limit host OS + upgrades to patches only? + +**Software modules in network nodes** + +#. Neutron L2/L3 agent +#. OVS, SR-IOV Driver + +**Software modules storage nodes** + +#. Ceph + +The table below analyses such an impact - considering a single instance +of each software module - from the following aspects: + +- the function which will be lost during upgrade, +- the duration of the loss of this specific function, +- if this causes the loss of the vNF function, +- if it causes incompatibility in the different parts of the software, +- what should be backed up before the upgrade, +- the duration of restoration time if the upgrade fails + +These values provided come from internal testing and based on some +assumptions, they may vary depending on the deployment techniques. +Please feel free to add if you find more efficient values during your +testing. + +https://wiki.opnfv.org/_media/upgrade_analysis_v0.5.xlsx + +Note that no redundancy of the software modules is considered in the table. diff --git a/docs/requirements/etc/conf.py b/docs/requirements/etc/conf.py new file mode 100644 index 0000000..0066035 --- /dev/null +++ b/docs/requirements/etc/conf.py @@ -0,0 +1,34 @@ +import datetime +import sys +import os + +try: + __import__('imp').find_module('sphinx.ext.numfig') + extensions = ['sphinx.ext.numfig'] +except ImportError: + # 'pip install sphinx_numfig' + extensions = ['sphinx_numfig'] + +# numfig: +number_figures = True +figure_caption_prefix = "Fig." + +source_suffix = '.rst' +master_doc = 'index' +pygments_style = 'sphinx' +html_use_index = False + +pdf_documents = [('index', u'OPNFV', u'OPNFV Project', u'OPNFV')] +pdf_fit_mode = "shrink" +pdf_stylesheets = ['sphinx','kerning','a4'] +#latex_domain_indices = False +#latex_use_modindex = False + +latex_elements = { + 'printindex': '', +} + +project = u'OPNFV: Template documentation config' +copyright = u'%s, OPNFV' % datetime.date.today().year +version = u'1.0.0' +release = u'1.0.0' diff --git a/docs/requirements/etc/opnfv-logo.png b/docs/requirements/etc/opnfv-logo.png new file mode 100644 index 0000000..1519503 Binary files /dev/null and b/docs/requirements/etc/opnfv-logo.png differ diff --git a/docs/requirements/images/figure1.png b/docs/requirements/images/figure1.png new file mode 100644 index 0000000..5a83842 Binary files /dev/null and b/docs/requirements/images/figure1.png differ diff --git a/docs/requirements/index.rst b/docs/requirements/index.rst new file mode 100644 index 0000000..599f8bd --- /dev/null +++ b/docs/requirements/index.rst @@ -0,0 +1,37 @@ +.. OPNFV Release Engineering documentation, created by + sphinx-quickstart on Tue Jun 9 19:12:31 2015. + You can adapt this file completely to your liking, but it should at least + contain the root `toctree` directive. + +.. image:: etc/opnfv-logo.png + :height: 40 + :width: 200 + :alt: OPNFV + :align: left + +ESCALATOR USER REQUIREMENTS +======================================= + +Contents: + +.. toctree:: + :maxdepth: 4 + :titlesonly: + + + 000-Contributors.rst + 101-Scope.rst + 102-Terminologies.rst + 103-Background.rst + 104-Requirements.rst + 105-Use_Cases.rst + 106-Reference.rst + 1A1-Requirements_from_other_Projects.rst + 1A2-Questionnaire_of_Escalator.rst + + +* :ref:`search` + +Revision: _sha1_ + +Build date: |today| -- cgit 1.2.3-korg