Clear-text protocols such as ftp
, telnet
, or http
lack encryption of transported data, as well as the
capability to build an authenticated connection. It means that an attacker able to sniff traffic from the network can read, modify, or corrupt the
transported content. These protocols are not secure as they expose applications to an extensive range of risks:
- sensitive data exposure
- traffic redirected to a malicious endpoint
- malware-infected software update or installer
- execution of client-side code
- corruption of critical information
Even in the context of isolated networks like offline environments or segmented cloud environments, the insider threat exists. Thus, attacks
involving communications being sniffed or tampered with can still happen.
For example, attackers could successfully compromise prior security layers by:
- bypassing isolation mechanisms
- compromising a component of the network
- getting the credentials of an internal IAM account (either from a service account or an actual person)
In such cases, encrypting communications would decrease the chances of attackers to successfully leak data or steal credentials from other network
components. By layering various security practices (segmentation and encryption, for example), the application will follow the
defense-in-depth principle.
Note that using the http
protocol is being deprecated by major web browsers.
In the past, it has led to the following vulnerabilities:
Ask Yourself Whether
- Application data needs to be protected against falsifications or leaks when transiting over the network.
- Application data transits over an untrusted network.
- Compliance rules require the service to encrypt data in transit.
- Your application renders web pages with a relaxed mixed content policy.
- OS-level protections against clear-text traffic are deactivated.
There is a risk if you answered yes to any of those questions.
Recommended Secure Coding Practices
- Make application data transit over a secure, authenticated and encrypted protocol like TLS or SSH. Here are a few alternatives to the most
common clear-text protocols:
- Use
ssh
as an alternative to telnet
.
- Use
sftp
, scp
, or ftps
instead of ftp
.
- Use
https
instead of http
.
- Use
SMTP
over SSL/TLS
or SMTP
with STARTTLS
instead of clear-text SMTP.
- Enable encryption of cloud components communications whenever it is possible.
- Configure your application to block mixed content when rendering web pages.
- If available, enforce OS-level deactivation of all clear-text traffic.
It is recommended to secure all transport channels, even on local networks, as it can take a single non-secure connection to compromise an entire
application or system.
Sensitive Code Example
For AWS Kinesis Data Streams, server-side encryption is disabled by default:
AWSTemplateFormatVersion: 2010-09-09
Resources:
KinesisStream: # Sensitive
Type: AWS::Kinesis::Stream
Properties:
ShardCount: 1
# No StreamEncryption
For Amazon ElastiCache:
AWSTemplateFormatVersion: 2010-09-09
Resources:
Example:
Type: AWS::ElastiCache::ReplicationGroup
Properties:
ReplicationGroupId: "example"
TransitEncryptionEnabled: false # Sensitive
For Amazon ECS:
AWSTemplateFormatVersion: 2010-09-09
Resources:
EcsTask:
Type: AWS::ECS::TaskDefinition
Properties:
Family: "service"
Volumes:
-
Name: "storage"
EFSVolumeConfiguration:
FilesystemId: !Ref FS
TransitEncryption: "DISABLED" # Sensitive
For AWS Load Balancer Listeners:
AWSTemplateFormatVersion: 2010-09-09
Resources:
HTTPlistener:
Type: "AWS::ElasticLoadBalancingV2::Listener"
Properties:
DefaultActions:
- Type: "redirect"
RedirectConfig:
Protocol: "HTTP"
Protocol: "HTTP" # Sensitive
For Amazon OpenSearch domains:
AWSTemplateFormatVersion: 2010-09-09
Resources:
Example:
Type: AWS::OpenSearchService::Domain
Properties:
DomainName: example
DomainEndpointOptions:
EnforceHTTPS: false # Sensitive
NodeToNodeEncryptionOptions:
Enabled: false # Sensitive
For Amazon MSK communications between clients and brokers:
AWSTemplateFormatVersion: 2010-09-09
Resources:
MSKCluster:
Type: 'AWS::MSK::Cluster'
Properties:
ClusterName: MSKCluster
EncryptionInfo:
EncryptionInTransit:
ClientBroker: TLS_PLAINTEXT # Sensitive
InCluster: false # Sensitive
Compliant Solution
For AWS Kinesis Data Streams server-side encryption:
AWSTemplateFormatVersion: 2010-09-09
Resources:
KinesisStream:
Type: AWS::Kinesis::Stream
Properties:
ShardCount: 1
StreamEncryption:
EncryptionType: KMS
For Amazon ElastiCache:
AWSTemplateFormatVersion: 2010-09-09
Resources:
Example:
Type: AWS::ElastiCache::ReplicationGroup
Properties:
ReplicationGroupId: "example"
TransitEncryptionEnabled: true
For Amazon ECS:
AWSTemplateFormatVersion: 2010-09-09
Resources:
EcsTask:
Type: AWS::ECS::TaskDefinition
Properties:
Family: "service"
Volumes:
-
Name: "storage"
EFSVolumeConfiguration:
FilesystemId: !Ref FS
TransitEncryption: "ENABLED"
For AWS Load Balancer Listeners:
AWSTemplateFormatVersion: 2010-09-09
Resources:
HTTPlistener:
Type: "AWS::ElasticLoadBalancingV2::Listener"
Properties:
DefaultActions:
- Type: "redirect"
RedirectConfig:
Protocol: "HTTPS"
Protocol: "HTTP"
For Amazon OpenSearch domains:
AWSTemplateFormatVersion: 2010-09-09
Resources:
Example:
Type: AWS::OpenSearchService::Domain
Properties:
DomainName: example
DomainEndpointOptions:
EnforceHTTPS: true
NodeToNodeEncryptionOptions:
Enabled: true
For Amazon MSK communications between clients and brokers, data in transit is encrypted by default,
allowing you to omit writing the EncryptionInTransit
configuration. However, if you need to configure it explicitly, this configuration
is compliant:
AWSTemplateFormatVersion: 2010-09-09
Resources:
MSKCluster:
Type: 'AWS::MSK::Cluster'
Properties:
ClusterName: MSKCluster
EncryptionInfo:
EncryptionInTransit:
ClientBroker: TLS
InCluster: true
See
Documentation
Articles & blog posts
Standards