Thursday, 26 August 2021

Latest Cisco 200-301 Certification Exam Sample Questions and Answers

Cisco CCNA Exam Description:

This exam tests a candidate's knowledge and skills related to network fundamentals, network access, IP connectivity, IP services, security fundamentals, and automation and programmability. The course, Implementing and Administering Cisco Solutions (CCNA), helps candidates prepare for this exam.

Cisco 200-301 Exam Overview:

Application Aware Networking with Cisco SD-WAN

Part 2: Optimizing Application Experience

As applications are migrating to the cloud and being offered either as Software-as-a-Service (SaaS) or built as cloud native infrastructure, the network must become more application aware, programmable, and intelligent to deliver the best experience to users. My previous blog post discussed how Cisco Software-Defined WAN (SD-WAN) provides seamless connectivity to applications from anywhere. This blog post explores how applications can take advantage of and work cooperatively with the network to obtain a higher quality of experience through network policy, telemetry, and other features that promote security, reliability, and efficiency.

Application Experience with Cisco SD-WAN

Most enterprise are using SaaS applications for their day-to-day operations and adopting many different cloud environments as their IT infrastructure for business-critical applications. Organizations can custom-select different cloud services for specific functions and to take advantage of flexibility, performance, agility, and cost savings.

These SaaS applications are being consumed by a diverse set of devices, locations, and types of users who are constantly on the move. Enterprises face numerous challenges in terms of automation and management of this multifaceted environment. Meanwhile, application and user requirements are continuously and rapidly evolving. Traditional methods of planning and rollout may not meet current needs. What’s required is a network that is self-learning, aware, and adaptable to address application requirements dynamically and in real-time.

As enterprise application data traverses the internet and encounters congestion, packet loss and high latencies can occur. This results in a sub-optimal experience for users. Cisco SD-WAN, with advanced App Aware Routing based on network and application health telemetry, provides intelligent path selection and policy enforcement. These contribute to an optimal application experience by adopting to the changing needs of an application based on a user’s location, health of the network, and health of the application. Cisco SD-WAN provides best performing SLA for all types of traffic bound to cloud or to on-prem networks.

Application Optimization and Experience for SaaS

Figure 1. Multi Path SaaS Access with Cisco SD-WAN

To provide the most optimal SaaS application experience, the SD-WAN fabric must first classify the application, select the best SaaS point of presence (PoP) to serve users, and then decide the most optimal path to the selected PoP that meets the SLA needs of the user.

Example: Microsoft Office 365 Application Suite Experience


Network Based Application Recognition (NBAR) is used to classify distinct URLs for different applications. Applications can be mapped based on different traffic precedence or sensitivity. Typically, applications are categorized into Optimize, Allow, or Default categories. But with end-to-end telemetry using Application Infused Path Feedback (AIPF) an SD-WAN controller can use telemetry imported from Microsoft to optimize applications more granularly based on best path selection logic.

Figure 2. Transforming User Experience with Microsoft – Cisco SD-WAN Telemetry

The SD-WAN fabric continuously monitors the performance of alternate paths to SaaS and selects the best path based on the performance and network metrics such as loss, latency, etcetera. Here’s how application aware networking with Cisco SD-WAN works.

Step 1: DNS requests to the SaaS applications are sent on all available WAN paths

Figure 3. Cloud Access to SaaS Services with Dual DIA.

Step 2: DNS resolution for the configured SaaS application is completed on all possible path options.

Figure 4. Cisco SD-WAN SaaS adoption options.

Step 3: Periodic HTTP pings to the configured cloud onramp a SaaS application on each Direct Internet Access (DIA) circuit and probe for loss and latency. The best path selected is based on defined policies. When none of the paths are considered optimal, Cisco has added support for the user to either select the suboptimal path (best of worst) or redirect traffic elsewhere. This action is also based on defined policies.

Step 4: Quality of experience is calculated based on loss, latency, and perceived user experience as determined by telemetry data exchanged with SaaS applications.

At the heart of the enhanced application experience is the ability to combine application health perceived by the users in conjunction with the current health of the network as observed by the SD-WAN fabric to select the best path to Office 365.

Example: Application Experience of a Cloud Hosted Application in Google Cloud Platform


One of the fundamental questions of application aware networking is how network application developers can program the network to meet application needs. Cisco has developed a solution working closely with the Google Cloud Platform (GCP) team to allow DevOps teams to denote the traffic profile of an application using Google Cloud Service Directory, which can Inform vManage to set up a network policy to meet an application’s requirements in a programmable manner.

Different traffic profiles can be associated with different services as needed. Application teams deploy Kubernetes workloads with metadata annotations, properly classifying application services according to certain traffic profiles (e.g., video streaming or VoIP). The integration of service directory with Google Cloud Identity and Access Management (IAM) ensures that only those on the application team with the appropriate permissions can modify the traffic profile for a service.

Figure 5. Cisco Google Application Optimization Workflow

Step 1: Application team adds metadata annotation to a workload deployment.

Step 2: -Monitoring engine runs in the Kubernetes cluster and actively monitors the deployed services and publishes the metadata to the service registry.

Figure 6. Containers with Meta Data Annotations published in Service Directory

Step 3: vManage on the SD-WAN side connects to the service registry and periodically polls to keep track of updates regarding the services exposed. SD-WAN policies can be updated when changes are detected.

Step 4: SD-WAN application policy is created and maps the service-associated metadata into the detailed SD-WAN policies programmed by NetOps in the SD-WAN controller. The policies are dynamically updated based on metadata annotations published and polled periodically via the service registry.

These simple four steps allow an application developer to express the needs of the application in a programmable manner. The controller then sets up policies for the SD-WAN fabric to meet the application requirements.

Source: cisco.com

Friday, 20 August 2021

Cisco Ultra Cloud Core Repels Pro Hackers

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Security is critical when developing new technology and that’s never going to change. Those with ill intent work 24 hours per day, seven days per week to discover vulnerabilities in servers, routers, and security devices that can be exploited. Whether it’s to release viruses or collect millions of dollars in ransomware, tech criminals will never stop committing crimes. The best we can do is protect our hardware, software, and firmware with zero trust and the utmost cyber security built in as a foundational concept rather than bolted on later as an afterthought.

With security at the forefront of everything we do, Cisco recently collaborated in a 5G hackathon with Finnish Transport and Communications Agency Traficom and Junction, an international non-profit ethical hacking and tech community which hosts the annual 48-hour event in Helsinki. This hackathon, held June 18-20, 2021, brought together entrepreneurs, developers, designers, and students from around the globe with a goal of helping local and multinational companies build viable, secure solutions to real-world challenges in 5G networks and services.

Cisco participated in this event, alongside Ericsson, Nokia and others, with an offer of 10,000 Euros in prize money to try to hack into the Cisco Ultra Cloud Core. Some of world’s leading cyber security professionals were asked to search for hidden flags and discover/document any vulnerabilities found in our 5G core. We knew going in that collaboration between vendors, researchers, regulatory authorities, solution developers, and the ethical hacker community would benefit everyone involved when building secure networks and services.

To set the stage for this event, appropriately named “I Bet You Can’t Get In”, the Mobility Technical Marketing Engineer (TME) group constructed this challenge in a way that created a bona fide environment in which to work while still protecting our core lab assets from nefarious activity. The mobility TME began by building a VMware cluster fully isolated from the lab with internet connectivity via a Cisco Adaptive Security Virtual Appliance (ASAv) firewall. Once we had a secure, remote-access sandbox environment prepared, a second team worked to bring up the 5G core on the VMware cluster.

More than 80 global participants organized into teams joined the Cisco challenge and were given access to the test lab through Anyconnect VPN. The challenge was then broken up into three primary facets: collecting user traffic to find the “needle” (a motivational quote from Steve Jobs), obtaining Command-Line Interface (CLI) access to the User Plane Function (UPF) to discover administrator account details, and exploiting a REST API to retrieve any information possible.

On a Friday evening (now that’s dedication!), we led the kickoff meeting to lay out the challenge via a live Webex session. The event commenced at 8 pm local time and the teams of hackers worked through the night and into the morning. On Saturday we held a check-in meeting to examine the progress they’d made. At that time, many of the hackers had given up. Aside from port scan results, no one had managed to gain access or even come close to meeting the challenge. Our team then dropped a few hints such as revealing the password of the UPF’s operator account. Following this hint, two teams utilized the monitor interface tool to locate the Steve Jobs quote, thus solving the first challenge.

The second part of the challenge, SSH CLI interfaces on 5G NFs, held its own, as did the third portion involving REST APIs. The only “hardening” involved was to disable SSH access to the Kubernetes (K8s) nodes, and in the end, only the first challenge was solved (buried in http and gtpu).

Finally, Team cKobclz79 was awarded the first prize of 5,000 Euros based on their ability to solve the first challenge and find the quote. Team Steamy Jofa was awarded the second prize of 3,000 Euros based on continued effort and overall tenacity. However, no other teams achieved enough progress to earn the third prize, so we decided to donate that money to a local Finnish charity.

At the conclusion of the event, we had a chance to speak with the winning three-member Team cKobclz79. As alumni of Aalto University in Finland, they frequently receive notifications of various events involving their alma mater. With an interest in misusing APIs and searching for design flaws in network architecture, they felt a 5G cybersecurity hack offered the perfect chance to keep up with the trends and technologies and acquire penetration testing skills in the industry.

The team began by scanning the network to locate an entry point, and once they found some hosts with open ports, they started searching for vulnerabilities. While digging deeper and sniffing internal traffic, they expanded their knowledge of 5G architecture, learning new terms and better understanding connections between nodes. The team found different parts of the challenge difficult due to having divergent backgrounds. One member struggled to understand the architecture and documentation but had no trouble with the tech stack, another wasn’t sure if they were on the right track because of so many hosts, while the third found several attack points that were not required for the challenge but nevertheless interesting.

With an attitude that no technology is truly safe, the team knew most security vulnerabilities reside in misconfigurations and leaked internal tech stack information, but during initial reconnaissance, they gained access through a system design flaw. They found that a websocket in a staging server would allow them to send commands. A check of other ports then revealed a Docker image whose source code provided a window into how commands were sent. By performing remote code execution, they established the reverse shell as root. This allowed them to install tools to scan the network and examine internal traffic. Enumerating the internal network gave them insight into other nodes based on the 5G architecture documentation provided to start the challenge.

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The team then found a Docker registry from which they could pull the image and get the code for CLI access. This websocket GUI allows system administrators to connect to cluster manager and maintain the operation of Ultra Cloud Core.

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Following an internal network scan, they found the K8s master node that could be reached from cluster manager. With no firewall to block communication from cluster manager to K8s master, they discovered that a service account credential to connect to the K8s cluster would have allowed them to run commands using kubectl they installed in cluster manager. They could then disrupt existing services or deploy malicious images to trick customers into connecting to them since all services are deployed, controlled, and managed by K8s master.

This event was a huge success and every participant derived value from it. Although we can’t definitively say that Cisco Ultra Cloud Core can’t possibly be hacked, this experience proved that it’s far more difficult than one might imagine. The event allowed technology vendors to put their 5G core to the test, and although these dedicated hackers did their best, they couldn’t hack our core.

As security becomes an increasing concern with the proliferation of 5G and IoT technologies, this event served as a great learning experience for the Cisco mobility team. As new threats exploit the wider footprint of these emerging technologies, challenges like this serve as one of many methods for gaining insights into future attacks so that we can design and build more resilient networks and services.

Source: cisco.com

Thursday, 19 August 2021

Simply Faster than the Rest, Cisco Wi-Fi 6 + Multigigabit Switching

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It’s a typical day, and as you’re mindlessly scrolling through your phone again, *ding*, a notification reads, “Flying cars will be available for purchase in just one year!”.

Wow, that’s exciting!

But would you be surprised?

The fact is, technology is advancing so fast that before we can adjust to the current innovation, a better version is already available. Just look at where we were with virtual reality, self-driving cars, and IoT smart homes only a few years back. The point is, our expectation for what is possible has never been higher, and as a technology fanatic, life is good!

But while we’re busy geeking out, let’s not forget that all this upcoming innovation requires an equally powerful network infrastructure to support it. For example, let’s look at 8K VR gaming, a technology that’s right around the corner and will require a minimum of 1 Gbps for gameplay and above 2 Gbps for an optimal experience. With a growing thirst for technology to provide a more HD, a more next-gen, and a more seamless experience, we can expect that the required data consumption will skyrocket as well.

The question is no longer whether innovation is coming but if your network can handle it.

Next Level Wireless Speeds with Multigigabit Switching

Wi-Fi 6, with all its glory, has been the star of the networking show since the launch of Cisco’s Catalyst wireless access point (AP) product line. From our flagship Catalyst 9130 Access Point boasting a ridiculous max PHY of 5.37 Gbps down to the small Catalyst 9105, they’re truly the gold standard of enterprise wireless.

But what if I told you there is a way to further enhance their already incredible prowess?

By simply combining Cisco Catalyst APs with Catalyst Multigigabit Switching, we can witness what can only be described as network performance at its finest. A bold statement, but I can prove it by showing you the throughput numbers tested within Cisco’s wireless lab using a Catalyst 9130 Wi-Fi 6 AP on software version 17.5.1 and a Catalyst 9300 multigigabit switch.

Numbers Speak for Themselves

But first, let’s take a step back; if we connect a Catalyst 9130 AP to a gigabit switch, the 5.38 Gbps max PHY is actually significantly bottlenecked as the throughput capabilities become limited from the wired side.  With this topology, we achieved an average throughput of just below 1 Gbps using the IxChariot performance testing tool.

Simply Faster than the Rest, Cisco Wi-Fi 6 + Multigigabit Switching
Figure 1. 3x Intel AX200 endpoints on 2.4 GHz at 20 MHz and 15x Intel AX200 on 5GHz at 80 MHz

Don’t get me wrong; these data rates are fast; it’s just that it could be so much faster!

To properly enjoy the true power of Wi-Fi 6, we connected the same Catalyst 9130 AP to a ten-gigabit port of a multigigabit switch and were able to achieve over 2 Gbps consistently.

Simply Faster than the Rest, Cisco Wi-Fi 6 + Multigigabit Switching
Figure 2. 3x Intel AX200 endpoints on 2.4GHz at 20MHz and 3x Intel AX200 on 5GHz at 80MHz

With the only differing factor being the multigigabit switch, we were able to over double the throughput! With these blazing fast throughput numbers combined with Wi-Fi 6’s OFDMA and MU-MIMO, you’ve got yourself a wireless powerhouse that’s unmatched by any other vendor in the world and is ready for whatever the future throws at it.

Source: cisco.com

Tuesday, 17 August 2021

Cisco Catalyst 8000V, the Cloud-Smart Router, Powers Secure SD-WAN for Multicloud and SaaS

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Cisco Catalyst 8000V Edge Software was launched in November 2020 as an evolution of the widely adopted Cisco Cloud Services Router (CSR) 1000V, which is deployed by more than 5,000  customers globally.  As the successor to the widely adopted CSR 1000V, the Catalyst 8000V offers the next generation of secure multicloud networking and cloud-smart capabilities in software, required by enterprise workloads for the public cloud and SaaS.  As public cloud solutions become more ubiquitous, with Gartner predicting spending on public cloud services to grow 23.1% in 2021 to $332.3 billion, customers will look to accelerate their journey to multicloud with a trusted enterprise-grade and cloud-smart solution.

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Figure 1: Catalyst 8000V, the Cloud-Smart Router

Powering secure multicloud networking, the Catalyst 8000V, can integrate with cloud formation templates, DevOps tools, Cisco’s vManage Controller, and be deployed by enterprises to programmatically connect to multicloud architectures as shown in Figure 1.  Automation tools, such as Terraform, are also widely popular with Catalyst 8000V, allowing customers to easily manage their infrastructure deployment.  Cisco SD-WAN Cloud OnRamp integrates with the Catalyst 8000V to offer an easy-to-use, end-to-end solution.

Evolution of Cisco’s Cloud Router The CSR 1000V was launched to bring the industry-leading Cisco IOS® XE Software networking capabilities to address virtualization and cloud needs.  As customers’ needs evolved, a smarter solution was needed, which is where the Catalyst 8000V was conceived.  A single, ‘cloud-smart’ router which powered customers multicloud networks and interoperates  across disparate deployment environments was needed.

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Figure 2: Evolution of Cisco’s Cloud Router

A simple cloud consumption experience was also foundational to the definition of the Catalyst 8000V, as licensing was simplified with the launch of the Catalyst 8000V using standardized Cisco DNA licenses.

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Figure 3: Catalyst 8000V is the anchor tenant in Secure SD-WAN for Multicloud and SaaS

Catalyst 8000V, the Cloud-Smart Router

Purpose built for the cloud, the Catalyst 8000V provides a smart, enterprise-ready, and simplified experience for easy deployment as shown in Figure 3. Customers with a “Cloud First” mindset should consider Cisco’s cloud-smart router,  which has enjoyed great success with various SD-WAN Cloud OnRamp use cases for site to cloud automation for AWS, Microsoft Azure, Google Cloud, and Ali Cloud.

Acting as the anchor tenant, the Catalyst 8000V underpins forward looking solutions such as software-defined cloud interconnect (SDCI), on-demand global networks, and colocation solutions, with partners like Megaport and Equinix .  Figure 4 shows how Catalyst 8000V, with vManage, can be deployed and managed across the different use cases in a single, intuitive dashboard.  The Catalyst 8000V simplifies the complexities in managing customers varied network requirements and operational approaches.

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Figure 4: Catalyst 8000V Integrates into Multiple Workflows

For insights into the performance of the Catalyst 8000V, Cisco vAnalytics is an option, which can provide customers with contextual network visibility and actionable insights into device and fabric performance and events. The visibility makes it easier than ever to spot anomalies in the network and to perform intelligent capacity planning.

Moving forward, as enterprises workloads evolve to require consistent secure access to public cloud providers, SaaS vendors for application optimization, colocation, SDCI, and traditional on-prem use cases, the Catalyst 8000V has established itself as the cloud-smart router to meet current and future challenges.

Source: cisco.com

Sunday, 15 August 2021

Network analytics: what you can’t see you can’t control

Where should we begin?

Once upon a time, not so long ago, networking teams got by with basic analytics using SNMP events, syslogs, custom scripts, utilization reports, and simple monitoring tools. How things have changed!!

Where are we headed?

1. 60% of transactions either originate or terminate outside of the private enterprise network.1 The Internet has become the new network core.

2. 40% of enterprise workloads will be on public cloud by 2023.2 Applications and services are disaggregated and distributed across a myriad of private and public cloud and edge environments.

3. 58% of employees will continue to work 8 or more days/month from home and more devices are connecting to your network than ever, multiplying your team’s workload.3

And if that wasn’t enough your network has become the vital lifeblood of an increasingly digital organization. Is your budget and time to value keeping up?

Enter AIOps.

The future demands the advanced use of data and artificial intelligence to help accelerate and automate operations in this increasingly complex world. According to IDC, “by 2024, 50% of large enterprises will adopt AIOps solutions for automating major IT system and service management processes.”4

What does this mean for the network?

Given the chance, your network can provide the eyes, ears, and advanced brain to know precisely what’s going on. It can provide visibility into how transactions are doing anywhere along its wildly meandering path–and clear guidance on what to do if anything bad is detected or predicted. What do I mean by given the chance? Well, in my mind there are three main elements to a complete network analytics capability that include:

1. Visibility: Collecting and seeing the data anywhere along the private-public network continuum

2. Insight: Making sense of the data in an intelligent and contextual way, including the use of artificial intelligence and machine learning (AI/ML) to make the data useful and actionable

3. Action: Applying what’s been learned to help activate, prevent, and remediate so that good application experiences are continuously maintained

IT teams are on the path and Gartner predicts that “by 2024, 50% of network operations teams will be required to re-architect their network monitoring stack, due to the impact of hybrid networking.” 5

Where are IT teams in their journey toward advanced network analytics?

Our own data corroborates Gartner’s prediction that IT leaders are recognizing the need for advanced analytics. We surveyed over 2,000 global IT leaders and network strategists for our Global Networking Trends Report on their plans for a more advanced AI-enabled network assurance capability. In our survey, we found that 22% were already well on their way and a massive 72% were planning for it in the next 2 years.

Figure 1. IT leaders and network strategists recognize the need for advanced analytics.

So, how is Cisco helping?


Cisco has adopted an intent-based networking model for network operations, which builds on a closed-loop model between “insights” and “automation” across the full transaction path from user or device to application. That includes analytics capabilities customized to each network domain: access, WAN, and data center & cloud.

Figure 2. End-to-end visibility and insights across private and public networks.

This is facilitated by open platforms that each deliver network insights and automation: Cisco DNA Center, Cisco Meraki, Cisco vManage, and Cisco Nexus Dashboard. But we’ve gone one vital step further by integrating the internet and cloud network visibility capabilities of Cisco ThousandEyes to ensure true end-to-end visibility in a world where the internet has become the network core.

How can you benefit?


By taking a holistic approach with Cisco Network Analytics offerings, you can expect these results.

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What now?


In the end, it’s all about delivering the best application experience. Consider your application needs, priorities and align your network analytics strategies. Cisco partners and services are in a great position to help.

Source: cisco.com

Saturday, 14 August 2021

How To Simplify Cisco ACI Management with Smartsheet

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Have you ever gotten lost in the APIC GUI while trying to configure a feature? Or maybe you are tired of going over the same steps again and again when changing an ACI filter or a contract? Or maybe you have always asked yourself how you can integrate APIC with other systems such as an IT ticketing or monitoring system to improve workflows and making your ACI fabric management life easier. Whatever the case may be, if you are interested in finding out how to create your own GUI for ACI, streamline and simplify APIC GUI configuration steps using smartsheets, and see how extensible and programmable an ACI fabric is, then read on.

Innovations that came with ACI

I have always been a fan of Cisco ACI (Application Centric Infrastructure). Coming from a routing and switching background, my mind was blown when I started learning about ACI. The SDN implementation for data centers from Cisco, ACI, took almost everything I thought I knew about networking and threw it out the window. I was in awe at the innovations that came with ACI: OpFlex, declarative control, End-Point Groups (EPGs), application policies, fabric auto discovery, and so many more.

The holy grail of networking

It felt to me like a natural evolution of classical networking from VLANs and mapped layer-3 subnets into bridge domains and subnets and VRFs. It took a bit of time to wrap my head around these concepts and building underlays and overlays but once you understand how all these technologies come together it almost feels like magic. The holy grail of networking is at this point within reach: centrally defining a set of generic rules and policies and letting the network do all the magic and enforce those policies all throughout the fabric at all times no matter where and how the clients and end points are connecting to the fabric. This is the premise that ACI was built on.

Automating common ACI management activities

So you can imagine when my colleague, Jason Davis (@snmpguy) came up with a proposal to migrate several ACI use cases from Action Orchestrator to full blown Python code I was up for the challenge. Jason and several AO folks have worked closely with Cisco customers to automate and simplify common ACI management workflows. We decided to focus on eight use cases for the first release of our application:

◉ Deploy an application

◉ Create static path bindings

◉ Configure filters

◉ Configure contracts

◉ Associate EPGs to contracts

◉ Configure policy groups

◉ Configure switch and interface profiles

◉ Associate interfaces to policy groups

Using the online smartsheet REST API

You might recognize these as being common ACI fabric management activities that a data center administrator would perform day in and day out. As the main user interface for gathering data we decided to use online smartsheets. Similar to ACI APIC, the online smartsheet platform provides an extensive REST API interface that is just ripe for integrations.

The plan was pretty straight forward:

1. Use smartsheets with a bit of JavaScript and CSS as the front-end components of our application

2. Develop a Python back end that would listen for smartsheet webhooks triggered whenever there are saved Smartsheet changes

3. Process this input data based on this data create, and trigger Ansible playbooks that would perform the configuration changes corresponding to each use case

4. Provide a pass/fail status back to the user.

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The “ACI Provisioning Start Point” screen allows the ACI administrator to select the
Site or APIC controller that needs to be configured.

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Once the APIC controller is selected, a drop down menu displays a list of all the use
cases supported. Select to which tenant the configuration changes will be applied,
and fill out the ACI configuration information in the smartsheet.

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Selecting the checkbox for Ready to Deploy, and saving the smartsheet, will trigger a webhook event that will be intercepted by the backend code and the Ansible configuration playbook will be run.

A big advantage to using Smartsheets compared to the ACI APIC GUI is that several configuration changes can be performed in parallel. In this example, several static path bindings are created at the same time.

Find the details on DevNet Automation Exchange



You can also find hundreds of similar use case examples in the DevNet Automation Exchange covering all Cisco technologies and verticals and all difficulty levels.

Drop me a message in the comments section if you have any questions or suggestions about this automation exchange use case.

Source: cisco.com