Saturday, 26 September 2020

Automated response with Cisco Stealthwatch

Cisco Stealthwatch provides enterprise-wide visibility by collecting telemetry from all corners of your environment and applying best in class security analytics by leveraging multiple engines including behavioral modeling and machine learning to pinpoint anomalies and detect threats in real-time. Once threats are detected, events and alarms are generated and displayed within the user interface. The system also provides the ability to automatically respond to, or share alarms by using the Response Manager. In release 7.3 of the solution, the Response Management module has been modernized and is now available from the web-based user interface to facilitate data-sharing with third party event gathering and ticketing systems. Additional enhancements include a range of customizable action and rule configurations that offer numerous new ways to share and respond to alarms to improve operational efficiencies by accelerating incident investigation efforts. In this post, I’ll provide an overview of new enhancements to this capability.

Benefits: 

◉ The new modernized Response Management module facilitates data-sharing with third party event gathering and ticketing systems through a range of action options.

◉ Save time and reduce noise by specifying which alarms are shared with SecureX threat response.

◉ Automate responses with pre-built workflows through SecureX orchestration capabilities.

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The Response Management module allows you to configure how Stealthwatch responds to alarms. The Response Manager uses two main functions:

◉ Rules: A set of one or multiple nested condition types that define when one or multiple response actions should be triggered.

◉ Actions: Response actions that are associated with specific rules and are used to perform specific types of actions when triggered.

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Response Management module Rule types consist of the six alarms depicted above.

Alarms generally fall into two categories:


Threat response-related alarms:

◉ Host: Alarms associated with core and custom detections for hosts or host groups such as C&C alarms, data hoarding alarms, port scan alarms, data exfiltration alarms, etc.

◉ Host Group Relationship: Alarms associated with relationship policies or network map-related policies such as, high traffic, SYN flood, round rip time, and more.

Stealthwatch appliance management-related alarms:

◉ Flow Collector System: Alarms associated with the Flow Collector component of the solution such as database alarms, raid alarms, management channel alarms, etc.

◉ Stealthwatch Management Console (SMC) System: Alarms associated with the SMC component of the solution such as Raid alarms, Cisco Identity Services Engine (ISE) connection and license status alarms.

◉ Exporter or Interface: Alarms associated with exporters and their interfaces such as interface utilization alarms, Flow Sensor alarms, flow data exporter alarms, and longest duration alarms.

◉ UDP Director: Alarms associated with the UDP Collector component of the solution such as Raid alarms, management channel alarms, high availability Alarms, etc.

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Choose from the above Response Management module Action options.
 
Available types of response actions consist of the following:

◉ Syslog Message: Allows you to configure your own customized formats based off of alarm variables such as alarm type, source, destination, category, and more for Syslog messages to be sent to third party solutions such as SIEMs and management systems.

◉ Email: Sends email messages with configurable formats including alarm variables such as alarm type, source, destination, category, and more.

◉ SNMP Trap: Sends SNMP Traps messages with configurable formats including alarm variables such as alarm type, source, destination, category, etc.
ISE ANC Policy: Triggers Adaptive Network Control (ANC) policy changes to modify or limit an endpoint’s level of access to the network when Stealthwatch is integrated with ISE.

◉ Webhook: Uses webhooks exposed by other solutions which could vary from an API call to a web triggered script to enhance data sharing with third-party tools.

◉ Threat Response Incident: Sends Stealthwatch alarms to SecureX threat response with the ability to specify incident confidence levels and host information.

The combination of rules and actions gives numerous possibilities on how to share or respond to alarms generated from Cisco Stealthwatch. Below is an example of a usage combination that triggers a response for employees connected locally or remotely in case their devices triggers a remote access breach alarm or a botnet infected host alarm. The response actions include isolating the device via ISE, sharing the incident to SecureX threat response and opening up a ticket with webhooks.

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1) Set up rules to trigger when an alarm fires, and 2) Configure specific actions or responses that will take place once the above rule is triggered.

The ongoing growth of critical security and network operations continues to increase the need to reduce complexity and automate response capabilities. Cisco Stealthwatch release 7.3.0’s modernized Response Management module helps to cut down on noise by eliminating repetitive tasks, accelerate incident investigations, and streamline remediation operations through its industry leading high fidelity and easy to configure automated response rules and actions.

Friday, 25 September 2020

New Technology for Cable Operators to Consider

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In the last several years, the role of compute resources has increased the demands upon modern cable regional and access networks. Computation has quickly become part of network infrastructure itself, beyond just supporting services, over-the-top applications, and management tasks. At the same time, advancements in silicon and optical technology allow for a re-examination of cable network topology and service placement. This blog examines some key decision points the cable industry needs to consider as we work together to build the next generation of a Modern Cable Network.

The Growing Role of Compute

Computing has always played an important role in Internet systems. Network services such as DNS and SMTP, as well as applications such as web services, video cache, and the control planes of routers themselves, all depend on general-purpose compute systems being distributed in the network. Some of these compute resources are discrete servers, some are in large cloud computing environments, and still others are co-resident in routing devices. But they all share the same fundamental trait – they keep and maintain application and/or network state, they run generally available operating systems, and today, all use common x86-based CPU’s.

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As computational power has grown, the ability for compute resource to perform stateful transformation of data has highly useful applications. In other words, the ability for a resource to take input from an app or the network, transform that input in some way, and return it in a more useful state. Examples of this could be real-time face recognition, such as identifying individuals in video streams. Raw video is fed into a resource, software analyzes the raw video, and returns a structured set of data. Or real-time speech to text, such as that present on modern smartphones. Raw audio is fed into an application, software deciphers the language present, and returns ordered text to be fed into additional applications.

The key is that as computation is used for more real-time, stateful transformation of data, the ability to access those resources quickly and reliably becomes paramount. And this directly translates into the latency, or the amount of time on a wire, between the end-user and that, compute resource. Ultimately, we’re talking about the speed of light.

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Low latent access to real-time computation is among the most lucrative, and untapped, resources present on cable networks. Network technology is advancing to make the placement of computation in cable networks much more advantageous to this new opportunity.

Advent of New Network Technology


While demand for low latent computing starts to grow, the cable industry faces some decision points to make. New network technology is permitting a massive disaggregation, and re-architecture, of cable access and metro networks.

Distributed Access Architecture (DAA) systems, such as Remote PHY, enable the pervasive use of IP and Ethernet transport in the access layer, where the previous legacy HFC analog transmission was used.

Virtualized CCAP, such as Cisco’s Cloud Native Broadband Router (cnBR), leverages Remote PHY technology to build a scale-out, software-oriented, microservices-based analogy to a contemporary CMTS. A key point of the cloud native software architecture of the cnBR is the use of the network to place all, or parts, of the system’s functionality to anywhere the network topology extends.

Next-generation silicon, optics, software. New routing platforms, such as the Cisco 8000 series, leverage next-generation forwarding ASIC technology to deliver unprecedented capacity and systems simplicity, all in a power and space-efficient package. Coupled with emerging Digital Coherent Optic (DCO) technology such as 400G-ZR and ZR+ pluggables, it is possible to build a cable metro topology that is much more interconnected, with traffic patterns that follow the value of a dollar and not strictly the path of a wavelength. What this means is, compute can be placed in arbitrary locations, to where packet latency to it is optimal for the application.

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A key compute resource that needs consideration for placement is the cnNR or Virtualized CCAP itself. A centralized vCCAP gains efficiency in software economies of scale. But a distributed vCCAP permits the opportunity to offload routable traffic closer to subscribers, which means closer to an edge compute or low latent access to compute architecture. Careful thought needs to be applied when designing the cnBR or vCCAP as a portion of overall network design and goals.

DOCSIS 4.0 also plays a role in a Modern Cable Network.  To learn the latest with this standard, attend our webinar:  DOCSIS 4.0 Evolution in the Cable Plant, Are You Ready.  If you would like to chat more about architecting and designing the next generation of a Modern Cable Network, stop by our virtual exhibit at SCTE-IBSE Cable Tec Virtual Expo.

Thursday, 24 September 2020

Detecting and Mitigating Loops in VXLAN Networks

The Problem with Looping

First-generation Layer-2 Ethernet networks could not natively detect or mitigate looped topologies, while modern Layer-2 Overlays implicitly build loop-free topologies. Overlays do not have any need for loop detection and mitigation as long as no first-gen Layer-2 network is attached, which is common in complex data center networks. When loops occur, data frames can exist indefinitely, disrupting network stability and degrading performance. Loops introduce broadcast radiation, increasing utilization of CPU and network bandwidth, which results in a degradation of user application access experience. In multi-site networks a loop can span multiple data centers, causing disruptions that are difficult to pinpoint. In other words, loops are bad news. Before we look at how a modern network fabric minimizes looping, let’s examine previous attempts at preventing loops in topologies.

Spanning Tree Protocols (STP) counteract the loop problem in first-gen Layer-2 Ethernet network. Over time, other approaches evolved by moving networks from “looped topologies” to “loop-free topologies”. This evolution reduced the dependence on Loop Prevention protocols, so they are now employed mostly as a failsafe mechanism. Today with Network Virtualization Overlays, the dependency on Loop Prevention protocols is almost entirely eliminated. However, even though virtualized overlay networks such as VXLAN EVPN are loop free, having a failsafe loop detection and mitigation method is still desirable because loops can be introduced by topologies connected to the overlay network.

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Loop-free VXLAN overlays may be connected to an Ethernet segment that can result in network loops, requiring detection and mitigation in conjunction with the overlay.

Many Solutions to Loop Prevention, But Which is the Best?


The Spanning Tree Protocol enables network designs that include redundant links to provide fault tolerance but avoid the presence of bridging loops. STP builds a single tree that calculates the relationship of network nodes and bridges within a layer 2 network to avoid creating loops.

An alternate approach to prevent loops in layer 2 networks uses link bundles between two neighboring bridges. This technique improves performance (Link Aggregation – LAG) and provides link redundancy (member link failure in a LAG). When multiple bridges exist, link bundles are extended to provide peering between multiple bridges (Multi-Chassis Link Aggregation – MLAG), increasing bridge node resiliency along with link redundancy and performance. In both of these cases, the link bundles are treated by STP as a single logical link and the creation of a loop is prevented (loop free). In each of these cases, STP acts as a failsafe.

While LAG and MLAG were in use for many years, other approaches for building loop free topologies arose by using ECMP (Equal Cost Multi-Path), either at the MAC layer or IP layer. FabricPath or TRILL (Transparent Interconnect of Lots of Links) are MAC layer ECMP approaches that emerged in the last decade. More recently, Network Virtualization Overlays that build loop free topologies on top of IP layer ECMP became the state-of-the-art. VXLAN is the most prevalent network virtualization protocol in use today that builds loop free topologies.

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A loop-free VXLAN overlay network.

While a VXLAN Overlay provides a loop free layer 2 service over IP ECMP, a layer 2 loop may still be introduced by connecting an L2 Ethernet network. VXLAN Edge-Devices act as bridges between VXLAN and Ethernet, known as Layer 2 Gateways (L2GW). A loop on the Ethernet network side can still introduce harmful broadcast radiation to the loop-free overlay network. If a loop is accidentally configured, physically or logically, the absence of a Loop Prevention protocol in VXLAN could allow the existence of a loop. While the layer 2 service in the VXLAN overlay network does not participate in the Spanning Tree Protocol, even if it could, blocking of a link in a loop-free overlay network would not prevent a loop but might cause additional harm, such as loss of service.

While proposals exist to integrate the overlay network with STP, these proposals are considering all Edge-Devices representing a single STP root bridge – Layer 2 Gateway STP (L2G-STP). While this approach is valid, it introduces rigidity into the deployment of modern overlay networks, reducing flexibility. With L2G-STP or similar approaches, the location of the STP root is predefined and hence can’t adjust to network designs that require a different location for this function. While L2G-STP can be used as a separate feature, the same functionality can be configured with a common STP root priority on the Edge-Device and the use of STP Root Guard.

In order to maintain the flexibility of overlay network deployments with VXLAN but have the ability to detect and protect against potential loops, Cisco provides an innovation: VXLAN EVPN Southbound Loop Detection and Mitigation.

Southbound Loop Detection and Mitigation


Let’s look at a VXLAN network in a spine/leaf topology to define “southbound looping”. The leaf is acting as Network Virtualization Edge-Device that is hosting the VXLAN Tunnel Endpoint (VTEP) function. In this topology, the VXLAN network represents the “northbound” portion of the network. The network from the leaf or Edge-Device to the “south” is most commonly the Ethernet network. As loops are potentially formed in this “southbound” network, the goal is to detect and mitigate loops that are introduced by the “southbound” network.

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North and south network topology.

Operations, Administration, and Maintenance (OAM) provides a framework for Connectivity Fault Management (CFM) defined in IEEE 802.1ag. Within this protocol framework and specifications, a continuous check message traverses intermediate bridges. This is a key criteria for enabling uninterrupted transfer of signaling across north-south borders. Based on well-defined triggers that span from initial port up to duplicate MAC detection (RFC7432 Section 15.1), check message probes are sent in a focused manner to detect if and where loops exist.

Loop detection is provided exclusively by the Edge-Devices that form the “northbound” VXLAN and bridge to the “southbound” Ethernet network. If the probe is not returned to the sending Edge-Devices, then no southbound Loop exists. If a southbound probe is returned, the existence of a loop is validated. As Edge-Devices become aware of a detected loop, notifications are shared with network operators and mitigation actions initiated.  

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A probe uncovers a loop in a southbound Ethernet network.

Loop Mitigation and Recovery


As part of the mitigation, the “southbound” Ethernet interfaces that participate in a loop are identified. As loops can exist in some VLANs but not in others, the granularity of control on a Port, VLAN basis is significant. In the action of mitigation, only the specific offending combination of VLAN and port is suppressed to break the detected loop and stop traffic radiation without disrupting other traffic on the port. Breaking the loop updates the topology which can affect the accuracy of the MAC address table. Therefore, a MAC-flush is initiated in the VLAN with the detected loop to enable proper re-learning and forwarding subsequent to the loop mitigation.

Once a loop has been mitigated, it can be difficult to know if the recovery—the unsuspending of a Port,VLAN combination—will reintroduce the loop. In order to prevent a false-recovery and loop reintroduction, a probe is sent prior to initiating the recovery while the Port,VLAN combination stays suspended (doesn’t forward traffic). If the probe still reports an indication of an existing southbound loop, the recovery process is stopped and the Port,VLAN stays suspended. After a given interval, loop detection is reinitiated. The recovery process continues until no loop is detected. Appropriate configuration, notification, and override commands are available to the Network Operator.

VXLAN EVPN with Built-In Southbound Loop Detection and Mitigation


Cisco NX-OS 9.3(5) provides native southbound loop detection and mitigation for VXLAN EVPN fabrics. The functionality extends the loop-free behavior of VXLAN EVPN’s Network Virtualization Overlay with existing Ethernet networks. While there are many use-cases that require loop detection and mitigation in a single fabric, the same functionality is available for VXLAN EVPN Multi-Site deployments. For these Multi-Site deployments, loop detection and mitigation supports the detection of backdoor links, the most prevalent cause of multi-site outages during extension or migrations.  

While many loop protection solutions support detecting the existence of loops in the overall topology and shutting down the offending ports, VXLAN EVPN Loop Detection and Mitigation defines the topology at the “VLAN-level”. Similar to Per-VLAN Spanning Tree variations (PVST+ and PVRST/802.1w) the functionality of VXLAN EVPN Loop Detection and Mitigation acts with comparable granularity. Differing from Spanning Tree, no pro-active calculation of a forwarding tree is built, but precautions are made to avoid the existence of loops and introducing them into the Overlay. VXLAN EVPN southbound loop detection and mitigation aims to ensure network uptime and avoid unnecessary risks due to loop creation, whether it is within a single fabric or across multiple fabrics with VXLAN EVPN Multi-Site.

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Looping can be accidentally introduced into multi-site fabrics through backdoor links.

Innovative Solutions for Increasing Data Center Resiliency


Increasing the stability of data center fabrics is key to supporting business resiliency — whether for a single on-premise brownfield fabric or when adding new multi-site greenfield fabrics. In order to optimize application performance and network stability, modern networks need to build upon a consistent, up-to-date platform instead of relying on a patchwork of technologies that can cause more conflicts than resolutions.

Even though modern VXLAN EVPN overlays prevent most looping scenarios natively, combining them with older network topologies can still introduce the risk of corrosive loops. Even carefully designed multi-site VXLAN EVPN data center fabrics can still accidentally create backdoor links, leading to looping-related performance issues. Cisco Nexus 9000 Series based NX-OS VXLAN implementation addresses the most prevalent loop scenarios within and among multi-site data centers to build and maintain a stable and resilient network architecture for your organization.

Wednesday, 23 September 2020

Why SOAR Is the Future of Your IT Security

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The threat landscape evolves constantly, with new and increasingly sophisticated cyberattacks launching with growing frequency across network, cloud, and software-as-a-service environments.

As threats continue to stack up against organizations, IT teams face the challenge of managing heterogeneous end-user device environments composed of various network-connected devices, operating systems, and applications. They must ensure that consistent, organizationally-sanctioned controls are applied across these environments.

While this is achievable with the right security expertise, there is also a global cybersecurity skills shortage. In fact, 3.5 million cybersecurity positions are expected to remain unfulfilled by 2021.

These challenges are not insurmountable. They can be conquered with the security operations and incident response approach called SOAR.

What is SOAR?

SOAR refers to a solution stack of compatible software that allows organizations to orchestrate and automate different parts of security management and operations to improve the accuracy, consistency, and efficiency of security processes and workflows with automated responses to threats.

How does SOAR work?

Security orchestration

The first component of SOAR, security orchestration, involves leveraging the different, compatible products for use within a solution stack to orchestrate the management and operations activities through standardized workflows. These security solutions automatically aggregate data from multiple sources, add context to that data to identify potential weaknesses, and use risk modeling scenarios to enable automated threat detection.  Recognizing this, more and more organizations are prioritizing the need for effective integration between security technologies to enable rapid threat detection and response.

Security automation

The second component is security automation, which involves automating many of the repetitive actions involved in the threat detection process.

Traditionally, security analysts within an organization would handle threat alerts manually, usually multi-tasking to size up alerts from numerous point solutions. This increases the likelihood of human error, inconsistent threat response, and high severity threats being overlooked.

SOAR, on the other hand, automates gathering enrichment and intelligence data on an event, can perform common investigative steps on behalf of the analyst to help triage events, and consistently delivers on the orchestration and response of the incident response lifecycle.

Security response

The third component, security response, involves triage, containment, and eradication of threats.

Response methods depend on the type and scope of the threat. Some threat responses can be automated for faster results, such as quarantining files, blocking file hashes across the organization, isolating a host or disabling access to compromised accounts.

However, sophisticated cyber-attacks require sophisticated responses. This is where security playbooks come in.

With Cisco Managed Detection and Response (MDR), automation is supported by defined investigation and response playbooks, containing overviews of known threat scenarios and best practices for responding to different types of threats. The role of automation is to rapidly execute these playbooks.

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What does a threat detection and response process look like with SOAR?

Let’s start with an example based on AMP for Endpoints identifying a file as potentially malicious. SOAR would be able to begin the investigation process, start answering questions, and performing tasks automatically such as:

◉ Was the file quarantined?
◉ Was the file executed?
◉ Where else has this file been seen in the network?
◉ Detonate the file in a Cisco Threat Grid sandboxing environment
◉ Investigate using available context related to connection, file, and source at relevant technologies, such as Umbrella and Stealthwatch Cloud
◉ Retrieve any available threat intelligence information on the file and check for occurrences of known indicators of compromise (IOCs)
◉ Collect identification information on the host and username

The answers to these questions provide contextual information to the investigator to aid in determining the legitimacy, impact, urgency, and scope of the incident. This information in turn determines appropriate response actions, which may include:

◉ Quarantining the host on the network
◉ Blocking the file hash across the network
◉ Blocking IOCs
◉ Scanning and cleaning any devices with occurrences of IOCs

Betting on SOAR

The cybersecurity skills shortage, tight IT budgets, the dynamic nature of the threat landscape, and the need to optimize security operations make SOAR a compelling proposition.

With Cisco MDR, security alerts, correlation, and enrichment are automated; blocked items are propagated for instant containment; and indicators of compromise are reported near-instantly for blocking, hunting, and follow-up.

The result is streamlined security operations and a stronger security posture without breaking the IT budget or having to recruit a team of security analysts.

Tuesday, 22 September 2020

Threat Landscape Trends: Endpoint Security, Part 1

Part 1: Critical severity threats and MITRE ATT&CK tactics

In the ongoing battle to defend your organization, deciding where to dedicate resources is vital. To do so efficiently, you need to have a solid understanding of your local network topology, cloud implementations, software and hardware assets, and the security policies in place. On top of that, you need to have an understanding of what’s traveling through and residing in your environment, and how to respond when something is found that shouldn’t be there.

This is why threat intelligence is so vital. Not only can threat intelligence help to defend what you have, it can tell you where you’re potentially vulnerable, as well as where you’ve been attacked in the past. It can ultimately help inform where to dedicate your security resources.

What threat intelligence can’t tell you is exactly where you’ll be attacked next. The fact is that  there’s no perfect way to predict an attacker’s next move. The closest you can come is knowing what’s happening out in the larger threat landscape—how attackers are targeting organizations across the board. From there it’s possible to make those critical, informed decisions based on the data at hand.

This is the purpose of this new blog series, Threat Landscape Trends. In it, we’ll be taking a look at activity in the threat landscape and sharing the latest trends we see. By doing so, we hope to shed light on areas where you can quickly have an impact defending your assets, especially if dealing with limited security resources.

To do this, we’ll dive into various Cisco Security technologies that monitor, alert, and block suspected malicious activity. Each release will focus on a different product, given the unique view of activity each can provide, informing you on different aspects of the threat landscape.

Beginning at the endpoint

To kick off the series, we’ll begin with Cisco’s Endpoint Security solution. Over the course of two blog posts we’ll examine what sort of activity we’ve seen on the endpoint in the first half of 2020. In the first, we’ll look at critical severity threats and the MITRE ATT&CK framework. In part two, to be published in the coming weeks, we’ll dive deeper into the data, providing more technical detail on threat types and the tools used by attackers.

To protect an endpoint, Cisco’s Endpoint Security solution leverages a protection lattice comprised of several technologies that work together. We’ll drill down into telemetry from one of these technologies here: the Cloud Indication of Compromise (IoC) feature, which can detect suspicious behaviors observed on endpoints and look for patterns related to malicious activity.

In terms of methodology for the analysis that follows, the data is similar to alerts you would see within the dashboard of Cisco’s Endpoint Security solution, only aggregated across organizations to get the percentage of organizations that have encountered particular IoCs as a baseline. The data set covers the first half of 2020, from January 1st through June 30th. We’ll cover this in more detail in the Methodology section at the end of this post, but for now, let’s dive into the data.

Threat severity

When using Cisco’s Endpoint Security solution, one of the first things you’ll notice in the dashboards is that alerts are sorted into four threat severity categories: low, medium, high, and critical. Here is a breakdown of these severity categories in terms of the frequency that organizations encountered IoC alerts:

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Percentage of low, medium, high, and critical severity IoCs

As you might expect, the vast majority of alerts fall into the low and medium categories. There’s a wide variety of IoCs within these severities. How serious a threat the activity leading to these alerts pose depends on a number of factors, which we’ll look at more broadly in part two of this blog series.

For now, let’s start with the most serious IoCs that Cisco’s Endpoint Security solution will alert on: the critical severity IoCs. While these make up a small portion of the overall IoC alerts, they’re arguably the most destructive, requiring immediate attention if seen.

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Critical severity IoCs

Sorting the critical IoCs into similar groups, the most common threat category seen was fileless malware. These IoCs indicate the presence of fileless threats—malicious code that runs in memory after initial infection, rather than through files stored on the hard drive. Here, Cisco’s Endpoint Security solution detects activity such as suspicious process injections and registry activity. Some threats often seen here include Kovter, Poweliks, Divergent, and LemonDuck.

Coming in second are dual-use tools leveraged for both exploitation and post-exploitation tasks. PowerShell Empire, CobaltStrike, Powersploit, and Metasploit are four such tools currently seen here. While these tools can very well be used for non-malicious activity, such as penetration testing, bad actors frequently utilize them. If you receive such an alert, and do not have any such active cybersecurity exercises in play, an immediate investigation is in order.

The third–most frequently seen IoC group is another category of dual-used tools. Credential dumping is the process used by malicious actors to scrape login credentials from a compromised computer. The most commonly seen of these tools in the first half of 2020 is Mimikatz, which Cisco’s Endpoint Security solution caught dumping credentials from memory.

All told, these first three categories comprise 75 percent of the critical severity IoCs seen. The remaining 25 percent contains a mix of behaviors known to be carried out by well-known threat types:
  • Ransomware threats like Ryuk, Maze, BitPaymer, and others
  • Worms such as Ramnit and Qakbot
  • Remote access trojans like Corebot and Glupteba
  • Banking trojans like Cridex, Dyre, Astaroth, and Azorult
  • …and finally, a mix of downloaders, wipers, and rootkits

MITRE ATT&CK tactics


Another way to look at the IoC data is by using the tactic categories laid out in the MITRE ATT&CK framework. Within Cisco’s Endpoint Security solution, each IoC includes information about the MITRE ATT&CK tactics employed. These tactics can provide context on the objectives of different parts of an attack, such as moving laterally through a network or exfiltrating confidential information.

Multiple tactics can also apply to a single IoC. For example, an IoC that covers a dual-use tool such as PowerShell Empire covers three tactics:
  • Defense Evasion: It can hide its activities from being detected.
  • Execution: It can run further modules to carry out malicious tasks.
  • Credential Access: It can load modules that steal credentials.
With this overlap in mind, let’s look at each tactic as a percentage of all IoCs seen:

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IoCs grouped by MITRE ATT&CK tactics

By far the most common tactic, Defensive Evasion appears in 57 percent of IoC alerts seen. This isn’t surprising, as actively attempting to avoid detection is a key component of most modern attacks.

Execution also appears frequently, at 41 percent, as bad actors often launch further malicious code during multi-stage attacks. For example, an attacker that has established persistence using a dual-use tool may follow up by downloading and executing a credential dumping tool or ransomware on the compromised computer.

Two tactics commonly used to gain a foothold, Initial Access and Persistence, come in third and fourth, showing up 11 and 12 percent of the time, respectively. Communication through Command and Control rounds out the top 5 tactics, appearing in 10 percent of the IoCs seen.

Critical tactics

While this paints an interesting picture of the threat landscape, things become even more interesting when combining MITRE ATT&CK tactics with IoCs of a critical severity.

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Critical severity IoCs grouped by MITRE ATT&CK tactics

For starters, two of the tactics were not seen in the critical severity IoCs at all, and two more registered less than one percent. This effectively removes a third of the tactics from focus.

What’s also interesting is how the frequency has been shuffled around. The top three remains the same, but Execution is more common amongst critical severity IoCs than Defense Evasion. Other significant moves when filtering by critical severity include:

  • Persistence appears in 38 percent of critical IoCs, as opposed to 12 percent of IoCs overall.
  • Lateral Movement jumps from 4 percent of IoCs seen to 22 percent.
  • Credential Access moves up three spots, increasing from 4 percent to 21 percent.
  • The Impact and Collections tactics both see modest increases.
  • Privilege Escalation plummets from 8 percent to 0.3 percent.
  • Initial Access drops off the list entirely, previously appearing fourth.

Defending against the critical


This wraps up our high-level rundown of the IoC data. So armed with this information about the common threat categories and tactics, what can you do to defend your endpoints? Here are a few suggestions about things to look at:

Limit execution of unknown files

If malicious files can’t be executed, they can’t carry out malicious activity. Use group policies and/or “allow lists” for applications that are permitted to run on endpoints in your environment. That’s not to say that every control available should be leveraged in order to completely lock an endpoint down—limiting end-user permissions too severely can create entirely different usability problems.

If your organization utilizes dual-use tools for activities like remote management, do severely limit the number of accounts that are permitted to run the tools, only granting temporary access when the tools are needed.

Monitor processes and the registry

Registry modification and process injection are two primary techniques used by fileless malware to hide its activity. Monitoring the registry for unusual changes and looking for strange process injection attempts will go a long way towards preventing such threats from gaining a foothold.

Monitor connections between endpoints

Keep an eye on the connections between different endpoints, as well as connections to servers within the environment. Investigate if two machines are connecting that shouldn’t, or an endpoint is talking to a server in a way that it doesn’t normally. This could be a sign that bad actors are attempting to move laterally across a network.

Monday, 21 September 2020

How to Prepare for Cisco CCNP Enterprise 350-401 Certification?


Cisco ENCOR Exam Description:

This exam tests a candidate's knowledge of implementing core enterprise network technologies including dual stack (IPv4 and IPv6) architecture, virtualization, infrastructure, network assurance, security and automation. The course, Implementing Cisco Enterprise Network Core Technologies, helps candidates to prepare for this exam.

Cisco 350-401 Exam Overview:


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Sunday, 20 September 2020

Extend secure, automated branch office networking to AWS with Cisco SD-WAN Cloud OnRamp

Extend secure, automated branch office networking to AWS with Cisco SD-WAN Cloud OnRamp

According to a Cisco study, by 2021, there will be 20 zettabytes of traffic between the DC/branch to the clouds, as companies use popular public cloud platforms like Amazon Web Services (AWS). Meanwhile, “IaaS is forecast to grow 24% year over year, which is the highest growth rate across all market segments,” according to Gartner.

However, while a cloud strategy creates more agility, it also presents challenges for IaaS deployments. Below are three primary concerns cloud users face regularly:

Inconsistent connectivity

Large-scale networks may traverse multiple slow public and/or expensive private connections to get to the cloud deployments, while smaller networks may need to battle out a slow, jittery internet to get to the clouds. In either case, customers will need to find the fastest and most reliable link while confirming a secure transport.

Complexity with governance

No real uniformity exists as to how different platforms handle their governance and compliance. This maze of rules and frameworks can create consistency problems with companies trying to utilize more than one cloud platform, especially with (but not exclusive to) IaaS. Finally, each cloud vendor has its own policy, security and segmentation process. These variances from vendor to vendor add another layer of complexity that must be managed.

Visibility problems

Different cloud platforms also use various protocols for analytics, metrics and insights. This variance can effectively reduce visibility for companies, making it more challenging to optimize usage across the network.

Cisco’s SD-WAN Cloud OnRamp automates and optimizes the enterprise SD-WAN to IaaS and SaaS

Cloud OnRamp is a cloud networking solution and a functionality of Cisco SD-WAN through which enterprises can network their branch sites to workloads deployed in cloud environments. Cloud OnRamp provides seamless, secure and automated networking for IaaS as well as an optimized experience for various SaaS applications.

One proven way to overcome the challenges of a cloud strategy is by implementing a consistent fabric across a company’s entire WAN network using Cisco SD-WAN Cloud OnRamp. Cisco SD-WAN provides a secure WAN architecture that can extend consistent policy enforcement, segmentation and security across both on-premises and cloud networks. Cloud OnRamp simplifies the experience further through the power of automation, using vManage as the single pane of glass management platform to create a SD-WAN transit network in the cloud provider’s environment.

Advantages of Cisco SD-WAN Cloud OnRamp

◉ Greater automation — With Cloud OnRamp, users can expect to automate SD-WAN extension to the cloud in minutes with just a few clicks.

◉ Improved security – Cloud OnRamp reduces security risks by leveraging graular segmentation and streamlined policy enforcement that can control and segment the traffic that flows through the network, guarding against external and internal threats to the data.

◉ Ease of management – Cloud OnRamp provides end-to-end data sharing between cloud and branch and establishes inter-regional visibility across transit data and network telemetry.

Cisco SD-WAN Cloud OnRamp Integration with AWS Transit Gateway

Cisco has partnered with AWS to provide end-to-end solutions for joint customers to create the best possible user experience. Customers benefit from fully automated networking to workloads in AWS Cloud and native integration between Cisco SD-WAN and AWS Transit Gateway and Transit Gateway Network Manager.

Extend secure, automated branch office networking to AWS with Cisco SD-WAN Cloud OnRamp

Sneak peek of the new features and benefits:

◉ Fully automated Cisco SD-WAN fabric extension to AWS Cloud: instead of spending hours of time per region and going through error-prone manual processes, now enterprise customers can bridge their branches to AWS workloads through a fully secure Cisco SD-WAN network in just minutes.

◉ Single pane of glass management through Cloud OnRamp: jumping back and forth between different management consoles of Cisco and AWS to orchestrate networking resources can be challenging and ineffective. With this new integration, enterprise customers will be able to manage both the Cisco SD-WAN virtual router and AWS Transit Gateway through Cloud OnRamp.

◉ Extending enterprise segmentation to AWS Cloud: one important aspect of secure networking is to ensure consistent enterprise segmentation across the entire network. By using the GUI-based Intent Management feature in Cloud OnRamp, enterprise customers can easily manage VPN to VPC and VPC to VPC communications through simple clicks.

◉ End-to-end visibility: by populating elements of both the SD-WAN network and AWS cloud network into AWS Network Manager, enterprise customers will have a unified and visualized view of both branch and cloud sites.

Watch AWS, Cisco and joint customer ENGIE discuss the benefits of integrating Cisco SD-WAN with AWS Transit Gateway Network Manager in a recent webinar and learn how to get started.

With more than half of enterprise workloads expected to be deployed in public clouds within the next year, cloud computing is a growing opportunity and challenge for today’s enterprises. By deploying an integrated solution like Cisco’s Cloud OnRamp for IaaS, companies will stay competitive by making their cloud strategy more productive, consistent and secure.