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-rw-r--r--etc/conf.py11
-rw-r--r--requirements/02-use_cases.rst30
-rw-r--r--requirements/03-architecture.rst18
-rw-r--r--requirements/05-implementation.rst69
4 files changed, 52 insertions, 76 deletions
diff --git a/etc/conf.py b/etc/conf.py
index e1303e8a..05dbc4d3 100644
--- a/etc/conf.py
+++ b/etc/conf.py
@@ -2,16 +2,9 @@ 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']
+needs_sphinx = '1.3'
-# numfig:
-number_figures = True
-figure_caption_prefix = "Fig."
+numfig = True
source_suffix = '.rst'
master_doc = 'index'
diff --git a/requirements/02-use_cases.rst b/requirements/02-use_cases.rst
index f69151df..775f0b77 100644
--- a/requirements/02-use_cases.rst
+++ b/requirements/02-use_cases.rst
@@ -48,7 +48,7 @@ Faults
Fault management using ACT-STBY configuration
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
-In :num:`Figure #figure1`, a system-wide view of relevant functional blocks is
+In :numref:`figure1`, a system-wide view of relevant functional blocks is
presented. OpenStack is considered as the VIM implementation (aka Controller)
which has interfaces with the NFVI and the Consumers. The VNF implementation is
represented as different virtual resources marked by different colors. Consumers
@@ -56,7 +56,7 @@ represented as different virtual resources marked by different colors. Consumers
resources (VMs in this example) shown with the same colors.
The first requirement in this use case is that the Controller needs to detect
-faults in the NVFI ("1. Fault Notification" in :num:`Figure #figure1`) affecting
+faults in the NVFI ("1. Fault Notification" in :numref:`figure1`) affecting
the proper functioning of the virtual resources (labelled as VM-x) running on
top of it. It should be possible to configure which relevant fault items should
be detected. The VIM (e.g. OpenStack) itself could be extended to detect such
@@ -66,21 +66,20 @@ element can be considered as a component of VIM from an architectural point of
view.
Once such fault is detected, the VIM shall find out which virtual resources are
-affected by this fault. In the example in :num:`Figure #figure1`, VM-4 is
+affected by this fault. In the example in :numref:`figure1`, VM-4 is
affected by a fault in the Hardware Server-3. Such mapping shall be maintained
in the VIM, depicted as the "Server-VM info" table inside the VIM.
Once the VIM has identified which virtual resources are affected by the fault,
it needs to find out who is the Consumer (i.e. the owner/manager) of the
-affected virtual resources (Step 2). In the example shown in :num:`Figure
-#figure1`, the VIM knows that for the red VM-4, the manager is the red Consumer
+affected virtual resources (Step 2). In the example shown in :numref:`figure1`,
+the VIM knows that for the red VM-4, the manager is the red Consumer
through an Ownership info table. The VIM then notifies (Step 3 "Fault
Notification") the red Consumer about this fault, preferably with sufficient
abstraction rather than detailed physical fault information.
-.. _figure1:
-
.. figure:: images/figure1.png
+ :name: figure1
:width: 100%
Fault management/recovery use case
@@ -96,7 +95,7 @@ components, minimizing Doctor's reaction time is a necessary basic ingredient to
fast failover times in general.
Once the Consumer has switched to STBY configuration, it notifies (Step 5
-"Instruction" in :num:`Figure #figure1`) the VIM. The VIM can then take
+"Instruction" in :numref:`figure1`) the VIM. The VIM can then take
necessary (e.g. pre-determined by the involved network operator) actions on how
to clean up the fault affected VMs (Step 6 "Execute Instruction").
@@ -127,7 +126,7 @@ prediction in the VIM are investigated in the OPNFV project "Data Collection
for Failure Prediction" [PRED]_.
This use case is very similar to :ref:`uc-fault1`. Instead of a fault
-detection (Step 1 "Fault Notification in" :num:`Figure #figure1`), the trigger
+detection (Step 1 "Fault Notification in" :numref:`figure1`), the trigger
comes from a fault prediction module in the VIM, or from a third party module
which notifies the VIM about an imminent fault. From Step 2~5, the work flow is
the same as in the "Fault management using ACT-STBY configuration" use case,
@@ -163,11 +162,11 @@ mark them with an appropriate flag (i.e. "maintenance" state) such that these
servers are not considered for hosting of virtual machines until the maintenance
flag is cleared (i.e. nodes are back in "normal" status).
-A high-level view of the maintenance procedure is presented in :num:`Figure
-#figure2`. VIM/OpenStack, through its northbound interface, receives a
-maintenance notification (Step 1 "Maintenance Request") from the Administrator
-(e.g. a network operator) including information about which hardware is subject
-to maintenance. Maintenance operations include replacement/upgrade of hardware,
+A high-level view of the maintenance procedure is presented in :numref:`figure2`.
+VIM/OpenStack, through its northbound interface, receives a maintenance notification
+(Step 1 "Maintenance Request") from the Administrator (e.g. a network operator)
+including information about which hardware is subject to maintenance.
+Maintenance operations include replacement/upgrade of hardware,
update/upgrade of the hypervisor/host OS, etc.
The consequent steps to enable the Consumer to perform ACT-STBY switching are
@@ -183,9 +182,8 @@ Hardware Servers so that consequent maintenance operations could be performed.
Due to the similarity for Steps 2~6, the maintenance procedure and the fault
management procedure are investigated in the same project.
-.. _figure2:
-
.. figure:: images/figure2.png
+ :name: figure2
:width: 100%
Maintenance use case
diff --git a/requirements/03-architecture.rst b/requirements/03-architecture.rst
index d613d4be..14055485 100644
--- a/requirements/03-architecture.rst
+++ b/requirements/03-architecture.rst
@@ -47,7 +47,7 @@ Architecture Overview
---------------------
NFV and the Cloud platform provide virtual resources and related control
-functionality to users and administrators. :num:`Figure #figure3` shows the high
+functionality to users and administrators. :numref:`figure3` shows the high
level architecture of NFV focusing on the NFVI, i.e., the virtualized
infrastructure. The NFVI provides virtual resources, such as virtual machines
(VM) and virtual networks. Those virtual resources are used to run applications,
@@ -79,12 +79,10 @@ applications (e.g., MME, S/P-GW) and the Network Services:
The time interval between the instant that an event is detected by the
monitoring system and the Consumer notification of unavailable resources shall
-be < 1 second (e.g., Step 1 to Step 4 in :num:`Figure #figure4` and :num:`Figure
-#figure5`).
-
-.. _figure3:
+be < 1 second (e.g., Step 1 to Step 4 in :numref:`figure4` and :numref:`figure5`).
.. figure:: images/figure3.png
+ :name: figure3
:width: 100%
High level architecture
@@ -218,15 +216,14 @@ request/response message exchange allows the Consumer to find out about active
alarms at the VIM. A filter can be used to narrow down the alarms returned in
the response message.
-.. _figure4:
-
.. figure:: images/figure4.png
+ :name: figure4
:width: 100%
High-level message flow for fault management
The high level message flow for the fault management use case is shown in
-:num:`Figure #figure4`.
+:numref:`figure4`.
It consists of the following steps:
1. The VIM monitors the physical and virtual resources and the fault management
@@ -256,15 +253,14 @@ maintenance action to be executed. After the request was executed successfully
error state, the VIM sends a MaintenanceResponse message back to the
Administrator.
-.. _figure5:
-
.. figure:: images/figure5.png
+ :name: figure5
:width: 100%
High-level message flow for NFVI maintenance
The high level message flow for the NFVI maintenance use case is shown in
-:num:`Figure #figure5`.
+:numref:`figure5`.
It consists of the following steps:
1. Maintenance trigger received from administrator.
diff --git a/requirements/05-implementation.rst b/requirements/05-implementation.rst
index 6fbf613c..e7f35158 100644
--- a/requirements/05-implementation.rst
+++ b/requirements/05-implementation.rst
@@ -19,11 +19,10 @@ Functional Blocks
This section introduces the functional blocks to form the VIM. OpenStack was
selected as the candidate for implementation. Inside the VIM, 4 different
-building blocks are defined (see :num:`Figure #figure6`).
-
-.. _figure6:
+building blocks are defined (see :numref:`figure6`).
.. figure:: images/figure6.png
+ :name: figure6
:width: 100%
Functional blocks
@@ -60,10 +59,11 @@ The Controller is responsible for maintaining the resource map (i.e. the mapping
from physical resources to virtual resources), accepting update requests for the
resource state(s) (exposing as provider API), and sending all failure events
regarding virtual resources to the Notifier. Optionally, the Controller has the
-ability to poison the state of virtual resources mapping to physical resources
-for which it has received failure notifications from the Inspector. The
-Controller also re-calculates the capacity of the NVFI when receiving a failure
-notification for a physical resource.
+ability to force the state of a given physical resource to down in the resource
+mapping when it receives failure notifications from the Inspector for that
+given physical resource.
+The Controller also re-calculates the capacity of the NVFI when receiving a
+failure notification for a physical resource.
In a real-world deployment, the VIM may have several controllers, one for each
resource type, such as Nova, Neutron and Cinder in OpenStack. Each controller
@@ -98,8 +98,7 @@ Sequence
Fault Management
^^^^^^^^^^^^^^^^
-The detailed work flow for fault management is as follows (see also :num:`Figure
-#figure7`):
+The detailed work flow for fault management is as follows (see also :numref:`figure7`):
1. Request to subscribe to monitor specific virtual resources. A query filter
can be used to narrow down the alarms the Consumer wants to be informed
@@ -130,22 +129,19 @@ In order to allow for quick reaction to failures, the time interval between
fault detection in step 3 and the corresponding recovery actions in step 7 and 8
shall be less than 1 second.
-.. _figure7:
-
.. figure:: images/figure7.png
+ :name: figure7
:width: 100%
Fault management work flow
-
-.. _figure8:
-
.. figure:: images/figure8.png
+ :name: figure8
:width: 100%
Fault management scenario
-:num:`Figure #figure8` shows a more detailed message flow (Steps 4 to 6) between
+:numref:`figure8` shows a more detailed message flow (Steps 4 to 6) between
the 4 building blocks introduced in :ref:`impl_fb`.
4. The Monitor observed a fault in the NFVI and reports the raw fault to the
@@ -169,7 +165,7 @@ the 4 building blocks introduced in :ref:`impl_fb`.
NFVI Maintenance
^^^^^^^^^^^^^^^^
-The detailed work flow for NFVI maintenance is shown in :num:`Figure #figure9`
+The detailed work flow for NFVI maintenance is shown in :numref:`figure9`
and has the following steps. Note that steps 1, 2, and 5 to 8a in the NFVI
maintenance work flow are very similar to the steps in the fault management work
flow and share a similar implementation plan in Release 1.
@@ -198,22 +194,19 @@ flow and share a similar implementation plan in Release 1.
the queried resource(s). In case the resource is in "maintenance" state,
information about the related maintenance operation is returned.
-.. _figure9:
-
.. figure:: images/figure9.png
+ :name: figure9
:width: 100%
NFVI maintenance work flow
-
-.. _figure10:
-
.. figure:: images/figure10.png
+ :name: figure10
:width: 100%
NFVI Maintenance implementation plan
-:num:`Figure #figure10` shows a more detailed message flow (Steps 4 to 6)
+:numref:`figure10` shows a more detailed message flow (Steps 4 to 6)
between the 4 building blocks introduced in Section 5.1..
3. The Administrator is sending a StateChange request to the Controller residing
@@ -243,7 +236,7 @@ Implementation plan for OPNFV Release 1
Fault management
^^^^^^^^^^^^^^^^
-:num:`Figure #figure11` shows the implementation plan based on OpenStack and
+:numref:`figure11` shows the implementation plan based on OpenStack and
related components as planned for Release 1. Hereby, the Monitor can be realized
by Zabbix. The Controller is realized by OpenStack Nova [NOVA]_, Neutron
[NEUT]_, and Cinder [CIND]_ for compute, network, and storage,
@@ -252,7 +245,7 @@ script querying Nova in order to map between physical and virtual resources. The
Notifier will be realized by Ceilometer [CEIL]_ receiving failure events
on its notification bus.
-:num:`Figure #figure12` shows the inner-workings of Ceilometer. After receiving
+:numref:`figure12` shows the inner-workings of Ceilometer. After receiving
an "event" on its notification bus, first a notification agent will grab the
event and send a "notification" to the Collector. The collector writes the
notifications received to the Ceilometer databases.
@@ -261,8 +254,8 @@ In the existing Ceilometer implementation, an alarm evaluator is periodically
polling those databases through the APIs provided. If it finds new alarms, it
will evaluate them based on the pre-defined alarm configuration, and depending
on the configuration, it will hand a message to the Alarm Notifier, which in
-turn will send the alarm message northbound to the Consumer. :num:`Figure
-#figure12` also shows an optimized work flow for Ceilometer with the goal to
+turn will send the alarm message northbound to the Consumer. :numref:`figure12`
+also shows an optimized work flow for Ceilometer with the goal to
reduce the delay for fault notifications to the Consumer. The approach is to
implement a new notification agent (called "publisher" in Ceilometer
terminology) which is directly sending the alarm through the "Notification Bus"
@@ -276,17 +269,15 @@ data", and "fired". It is representing a persistent alarm database. In order to
realize the Doctor requirements, we need to define new "meters" in the database
(see Section 5.6.1).
-.. _figure11:
-
.. figure:: images/figure11.png
+ :name: figure11
:width: 100%
Implementation plan in OpenStack (OPNFV Release 1 ”Arno”)
-.. _figure12:
-
.. figure:: images/figure12.png
+ :name: figure12
:width: 100%
Implementation plan in Ceilometer architecture
@@ -366,8 +357,8 @@ Simple information elements:
* Metadata (Key-Value-Pairs): provides additional information of a physical
resource in maintenance/error state.
-Complex information elements (see also UML diagrams in :num:`Figure #figure13`
-and :num:`Figure #figure14`):
+Complex information elements (see also UML diagrams in :numref:`figure13`
+and :numref:`figure14`):
* VirtualResourceInfoClass:
@@ -452,15 +443,14 @@ Fault management interface
This interface allows the VIM to notify the Consumer about a virtual resource
that is affected by a fault, either within the virtual resource itself or by the
underlying virtualization infrastructure. The messages on this interface are
-shown in :num:`Figure #figure13` and explained in detail in the following
+shown in :numref:`figure13` and explained in detail in the following
subsections.
Note: The information elements used in this section are described in detail in
Section 5.4.
-.. _figure13:
-
.. figure:: images/figure13.png
+ :name: figure13
:width: 100%
Fault management NB I/F messages
@@ -550,12 +540,11 @@ also allows the Administrator to query the state of physical machines, e.g., in
order to get details in the current status of the maintenance operation like a
firmware update.
-The messages defined in these northbound interfaces are shown in :num:`Figure
-#figure14` and described in detail in the following subsections.
-
-.. _figure14:
+The messages defined in these northbound interfaces are shown in :numref:`figure14`
+and described in detail in the following subsections.
.. figure:: images/figure14.png
+ :name: figure14
:width: 100%
NFVI maintenance NB I/F messages
@@ -690,7 +679,7 @@ Event Publisher for Alarm (Ceilometer) [*]_
send to the Consumer, whereas one requirement of Doctor is to react on faults
as fast as possible.
- The existing message flow is shown in :num:`Figure #figure12`: after receiving
+ The existing message flow is shown in :numref:`figure12`: after receiving
an "event", a "notification agent" (i.e. "event publisher") will send a
"notification" to a "Collector". The "collector" is collecting the
notifications and is updating the Ceilometer "Meter" database that is storing