Tag Archives: AWS

Updated whitepaper available: Architecting for PCI DSS Segmentation and Scoping on AWS

Post Syndicated from Ted Tanner original https://aws.amazon.com/blogs/security/updated-whitepaper-available-architecting-for-pci-dss-segmentation-and-scoping-on-aws/

Amazon Web Services (AWS) has re-published the whitepaper Architecting for PCI DSS Scoping and Segmentation on AWS to provide guidance on how to properly define the scope of your Payment Card Industry (PCI) Data Security Standard (DSS) workloads that are running in the AWS Cloud. The whitepaper has been refreshed to include updated AWS best practices and technologies, and updates that are applicable to the new PCI DSS v4.0 requirements. The whitepaper looks at how to define segmentation boundaries between your in-scope and out-of-scope resources by using cloud-based AWS services.

The whitepaper is intended for engineers and solution builders, but it also serves as a guide for Qualified Security Assessors (QSAs) and internal security assessors (ISAs) to better understand the different segmentation controls that are available within AWS products and services, along with associated scoping considerations.

Compared to on-premises environments, software-defined networking on AWS transforms the scoping process for applications by providing additional segmentation controls beyond network segmentation. Thoughtful design of your applications and selection of security-impacting services for implementing your required controls can reduce the number of systems and services in your cardholder data environment (CDE).

The whitepaper is based on the PCI Council’s Information Supplement: Guidance for PCI DSS Scoping and Network Segmentation.

 
If you have questions or want to learn more, contact your account representative, or leave a comment below.

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Ted Tanner

Ted Tanner

Ted is a Principal Assurance Consultant and PCI DSS Qualified Security Assessor with AWS Security Assurance Services, and has more than 25 years of IT and security experience. He uses this experience to provide AWS customers with guidance on compliance and security, and on building and optimizing their cloud compliance programs. He is co-author of the Payment Card Industry Data Security Standard (PCI DSS) v3.2.1 on AWS Compliance Guide and the soon-to-be-released v4.0 edition.

Author

Avik Mukherjee

Avik is a Senior Security Consultant with more than 15 years of experience in IT governance, security, risk, and compliance. He has background of being a QSA for PCI DSS and point-to-point encryption (P2PE) and has deep knowledge of security advisory and assessment work in various industries, including retail, financial, and technology.

Joseph Okonkwo

Joseph Okonkwo

Joseph is a Senior Security Architect and PCI DSS Professional (PCIP), and has more than a decade of experience in application security, security architecture, and as an Internal Security Assessor (ISA). He works closely with AWS clients to enable digital transformation and migration in the Professional Services team. Joseph earned an MBA from Imperial College, Business School, and a M.S. in Data Telecommunications & Networks from The University of Salford in Manchester.

How to implement multi tenancy with Amazon SES

Post Syndicated from satyaso original https://aws.amazon.com/blogs/messaging-and-targeting/how-to-manage-email-sending-for-multiple-end-customers-using-amazon-ses/

In this blog post, you will learn how to design multi-tenancy with Amazon SES, as well as the fundamental best practices for implementing a multi-tenant architecture that can effectively handle bulk the email sending needs of your downstream customers.

Amazon Simple Email Service (SES) is utilized by customers across various industries to send emails to their recipients. Often, they need to send emails on behalf of their downstream customers or for other business divisions. Organizations commonly refer to these use cases as “multi-tenant email sending practices. To implement email sending multi-tenancy practices (i.e. to send bulk emails on behalf of end customers), Amazon SES customers need to adopt an architecture that enables them to effectively meet the email sending needs of thousands of downstream customers while also ensuring that the email sending reputation of each customer or the tenant is isolated.

Use cases

  1. Onboard multiple brands from different Business units (BUs) with different domains.
  2. Separate marketing and transaction tenants.
  3. ISV Customer’s requirement to segregate email sending reputation of their end customers.
  4. Domain management via configuration sets.
  5. Track individual customer’s email sending repurataion and control their email sending process.

Prerequisites

For this post, you should be familiar with the following:

Solution Overview

In the email ecosystem, domain and IP reputation are critical in getting emails delivered to the inbox. Tenants in a multi-tenant scenario might be unique businesses or an internal team (eg marketing team, customer service team and so on). Because the maturity of each tenant varies greatly, implementing a multi-tenant environment may be increasingly complicated and difficult. While one tenant may have a well-validated and highly-engaged recipient list, another tenant may have an untrusted email recipient list, and sending emails to such email addresses may result in bounces or spam, lowering the IP and domain reputation. So, organizations have to build safe guards to prevent an unsophisticated sender or a bad actor from impacting the other tenants.

To better understand multi-tenancy, let us first look at how Amazon SES sends emails. Any emails sent via Amazon SES to end users are sent using IP addresses that have been mapped within Amazon SES. Amazon SES offers two types of IP addresses: shared IP addresses and dedicated IP addresses. (Currently Amazon SES offers two kinds of dedicated IPs, which are 1/ Standard dedicated IPs, 2/ Managed dedicated IPs). Shared IPs are shared across many SES customers, and all your emails are sent using shared IP addresses by default unless you have requested for dedicated IPs. Dedicated IP addresses/addresses are designated for a single customer or tenant, where the tenant might be a business unit within the customer’s own eco system or a downstream customer of an ISV.

If a customer is using shared IPs to send email via SES and trying to achieve multi tenancy, then they can do so to segregate the business functions of multiple tenants such as tenant tagging, SES event destination routing, cost allocation for each tenant, and so on; but it won’t help to manage or isolate email sending reputation from one tenant to another. This is because; these shared IPs are mapped to an AWS region and incase one rogue tenant is trying to send spam emails then it will impact other customers in the same region who are using same set of shared IPs.

If you are an Amazon SES user and wish to separate the reputation of one end-customer from another then dedicated IPs are the ideal solution. Dedicated IP or Dedicated IPs (also known as dedicated IP pool) can be assigned to a tenant, and the email sending reputation for that tenant can be readily isolated from that of another tenant. If tenant one is a problematic sender and internet service providers (ISPs) such as Gmail, Hotmail, Yahoo and, so on, flags the respective domain or IPs, the reputation of the other tenants’ domains and IPs are unaffected since they are mutually exclusive.

Amazon SES supports multi-tenancy primarily through two constructs: 1/configuration sets, 2/Dedicate IP pools. Configuration sets are setup rules that are applicable to your verified identities, whereas  dedicated IP pool is to group dedicated IPs into a pool, which can then be mapped to a configuration set, such that the respective Identity/Identities may only utilize the same IP Pool without affecting other tenants. Let’s now witness a simplified architecture view.

Amazon SES multi tenancy using a single AWS account

Multi tenancy using a single AWS account

In this architecture, if you notice tenant 1, tenant 2 and tenant 3 are using the distinct configurations with respective dedicated IPs while tenant 4 is using shared IPs. i.e. the tenants can chose which configuration sets needs to be used for their domain. This provides customers capability to achieve multi tenancy.

Amazon SES multi tenancy – best practices

Always proactively reach out to your account team or raise a support case under “service limit increase” category informing that you will be sending on behalf of tens of thousands of customers. This will help AWS in rightly setup limits within your account and be cognizant of your sending patterns.

While the architecture described above will most of the time help Amazon SES users manage multiple end customers effectively, in rare cases; Amazon SES users may receive a notification from AWS support stating that their Amazon SES account is being reviewed. This indicates that your Amazon SES account is being used to send problematic email to end recipients, or that the account has been paused (if you haven’t reacted proactively upon controlling the faulty senders within the review timeframe), which means you can’t send email from your SES account because your spam or complaint rate has exceeded a certain threshold. These type of situations occurs because, Amazon SES sanitization process is implemented at the AWS account level by default. So, even if any of the tenants using a dedicated IP or a dedicated IP pool and their spam or complaint rates exceed the approved SES limit, Amazon SES sends a notification to the account admin, flagging the concern in their account. In such cases, it is recommended to implement a process known as “automatically pausing email sending for a configuration set“. You can configure Amazon SES to export reputation metrics that are specific to emails that are sent using a specific configuration set to Amazon CloudWatch. You can then use these metrics to create CloudWatch alarms that are specific to those configuration sets. When these alarms exceed certain thresholds, you can automatically pause the sending of emails that use the specified configuration sets, without impacting the overall email sending capabilities of your Amazon SES account.

If you are an Enterprise ISV customer and you have tens of thousands of downstream customers then there is a possibility that you will hit Amazon SES provided maximum quota. In those scenarios you have two options; 1/ Ask for an exception for your AWS SES account – In this approach, you need to request AWS to increase your quota applicable for the existing account to a higher threshold and depending upon your previous usage and reputation AWS shall increase your account limit to accommodate more customers/tenants. To do this you need to raise an AWS support case under “service limit increase” and present your requirement on why you want to increase your Amazon SES account quota to a higher limit. There is no guaranty that the exception will always be granted. If your exception request is denied, you must proceed to the second option, which is to 2/ segment your customers across multiple AWS accounts. In this approach, you must calculate your customer base ahead of time and distribute your downstream customers across multiple accounts within the same AWS region in order to set up their email sending mechanism using SES. To better understand option 2, refer to the architecture diagram below.

Amazon SES multi tenancy using multiple AWS account

Multi tenancy using multiple AWS account

In the above architecture various tenants are connecting to Amazon SES in different AWS accounts to implement multi tenancy. Email event responses can be taken back to a central data lake located in the same AWS region or in different region. Furthermore, as shown in the diagram above, all AWS accounts mapped to different tenants are under a Parent AWS account; this hierarchical structure is known as AWS Organizations. it is recommended to use AWS Organizations which enables you to consolidate multiple AWS accounts into an organization that you create and centrally manage. It helps in security and compliance guide lines, managing consolidated billing for all the child accounts.

Conclusion

Appropriate multi-tenancy implementation within Amazon SES not only helps you manage end-customer reputation but also aids in tracking usage of each user independently from one another. In this post, we have showcased how Amazon SES users can utilize Amazon SES to manage large number of end customer, what are the design best practices to implement multi-tenant architecture with Amazon SES.


Satyasovan Tripathy works at Amazon Web Services as a Senior Specialist Solution Architect. He is based in Bengaluru, India, and specialises on the AWS customer developer service product portfolio. He likes reading and travelling outside of work.

 

How to use managed dedicated IPs for email sending

Post Syndicated from Tyler Holmes original https://aws.amazon.com/blogs/messaging-and-targeting/how-to-use-managed-dedicated-ips-for-email-sending/

Starting to use dedicated IPs has always been a long, complicated process driven by factors such as the large effort to monitor and maintain the IPs and the costs, both in infrastructure and management of IP and Domain reputation. The Dedicated IP (Managed) feature in Amazon SES eliminates much of the complexity of sending email via dedicated IPs and allows you to start sending through dedicated IPs much faster and with less management overhead.

What’s the Difference Between standard dedicated IPs and managed dedicated IPs?

You can use SES for dedicated IP addresses in two ways: standard and managed. Both allow you to lease dedicated IP addresses for an additional fee, but differ in how they’re configured and managed. While there are shared commonalities they each have unique advantages dependent on your use case, see here for a comparison.

Standard dedicated IPs are manually set up and managed in SES. They allow you full control over your sending reputation but require you to fully manage your dedicated IPs, including warming them up, scaling them out, and managing your pools.

Managed dedicated IPs are a quick, and easy, way to start using dedicated IP addresses. These dedicated IP addresses leverage machine learning to remove the need to manage the IP warm-up process. The feature also handles the scaling of your IPs up or down as your volume increases (or decreases) to provide a quick, easy, and cost-efficient way to start using dedicated IP addresses that are managed by SES.

How Does the Managed Dedicated IP Feature Automate IP Warming?

Great deliverability through your dedicated IP address requires that you have a good reputation with the receiving ISPs, also known as a mailbox provider. Mailbox providers will only accept a small volume of email from an IP that they don’t recognize. When you’re first allocated an IP, it’s new and won’t be recognized by the receiving mailbox provider because it doesn’t have any reputation associated with it. In order for an IP’s reputation to be established, it must gradually build trust with receiving mailbox providers—this gradual trust building process is referred to as warming-up. Adding to the complexity is that each mailbox provider has their own concept of warming, accepting varying volumes of email as you work through the warm up process.

The concept of IP warming has always been a misnomer, with customers thinking that once their IP is “warm” that it stays that way when in reality the process is an ongoing one, fluctuating as your recipient domain mix changes and your volume changes. Ensuring that you have the best deliverability when sending via dedicated IPs requires monitoring more than just recipient engagement rates (opens, clicks, bounces, complaints, opt-ins, etc.), you also need to manage volume per mailbox provider. Understanding the volumes that recipient mailbox providers will accept is very difficult if not impossible for senders using standard Dedicated IPs. Managing this aspect of the warm up creates risk for sending too little, meaning warm-up takes longer, or too much, which means receiving mailbox providers may throttle, reduce IP reputation, or even filter out email being sent by an IP that is not properly warming up.

This process is a costly, risky, and time consuming one that can be eliminated using the managed feature. Managed dedicated IPs will automatically apportion the right amount of traffic per mailbox provider to your dedicated IPs and any leftover email volume is sent over the shared network of IPs, allowing you to send as you normally would. As time goes on, the proportion of email traffic being sent over your dedicated IPs increases until they are warm, at which point all of your emails will be sent through your dedicated IPs. In later stages, any sending that is in excess of your normal patterns is proactively queued to ensure the best deliverability to each mailbox provider.

As an example, if you’ve been sending all your traffic to Gmail, the IP addresses are considered warmed up only for Gmail and cold for other mailbox providers. If your customer domain mix changes and includes a large proportion of email sends to Hotmail, SES ramps up traffic slowly for Hotmail as the IP addresses are not warmed up yet while continuing to deliver all the traffic to Gmail via your dedicated IPs. The warmup adjustment is adaptive and is based on your actual sending patterns.

The managed feature is great for those that prioritize and want to be in complete control of their reputation while not wanting to spend the time and effort to manage the warm-up process or the scaling of IPs as your volume grows. A full breakdown of the use cases that are a good fit for the managed feature can be found here

How to Configure Managed Pools and Configuration Sets

Enabling managed dedicated IPs can be configured in just a few steps and can be done either from the console or programmatically. The first step is to create a managed IP pool, then the managed dedicated IPs feature will determine how many dedicated IPs you require based on your sending patterns, provision them for you, and then manage how they scale based on your sending requirements. Note that this process is not instantaneous, dependent on your sending patterns it may take more or less time for the dedicated IPs to be provisioned, you need to have consistent email volume coming from your account in order for the feature to provision the correct number of IPs.

Once enabled, you can utilize managed dedicated IPs in your email sending by associating the managed IP pool with a configuration set, and then specifying that configuration set when sending email. The configuration set can also be applied to a sending identity by using a default configuration set, which can simplify your sending, as anytime the associated sending identity is used to send email your managed dedicated IPs will be used.

Instructions

Configure Via The Console

To enable Dedicated IPs (Managed) via the Amazon SES console:

  • Sign in to the AWS Management Console and open the Amazon SES console at https://console.aws.amazon.com/ses/.
  • In the left navigation pane, choose Dedicated IPs.
  • Do one of the following (Note: You will begin to incur charges after creating a Dedicated IPs (Managed) pool below)
    • If you don’t have existing dedicated IPs in your account:
      • The Dedicated IPs onboarding page is displayed. In the Dedicated IPs (Managed) overview panel, choose Enable dedicated IPs. The Create IP Pool page opens.
    • If you have existing dedicated IPs in your account:
      • Select the Managed IP pools tab on the Dedicated IPs page.
      • In the All Dedicated IP (managed) pools panel, choose Create Managed IP pool. The Create IP Pool page opens.
  • In the Pool details panel,
    • Choose Managed (auto managed) in the Scaling mode field.
    • Enter a name for your managed pool in the IP pool name field.
    • Note
      • The IP pool name must be unique. It can’t be a duplicate of a standard dedicated IP pool name in your account.
      • You can have a mix of up to 50 pools split between both Standard and Dedicated IPs (Managed) per AWS Region in your account.
  • (Optional) You can associate this managed IP pool with a configuration set by choosing one from the dropdown list in the Configuration sets field.
    • Note
      • If you choose a configuration set that’s already associated with an IP pool, it will become associated with this managed pool, and no longer be associated with the previous pool.
      • To add or remove associated configuration sets after this managed pool is created, edit the configuration set’s Sending IP pool parameter in the General details panel.
      • If you haven’t created any configuration sets yet, see Using configuration sets in Amazon SES.
  • (Optional) You can add one or more Tags to your IP pool by including a tag key and an optional value for the key.
    • Choose Add new tag and enter the Key. You can also add an optional Value for the tag. You can add up to 50 tags, if you make a mistake, choose Remove.
    • To add the tags, choose Save changes. After you create the pool, you can add, remove, or edit tags by selecting the managed pool and choosing Edit.
  • Select Create pool.
    • Note
      • After you create a managed IP pool, it can’t be converted to a standard IP pool.
      • When using Dedicated IPs (Managed), you can’t have more than 10,000 sending identities (domains and email addresses, in any combination) per AWS Region in your account.
  • After you create your managed IP pool, a link will automatically be generated in the CloudWatch metrics column in the All Dedicated IPs (Managed) pools table in the SES console, that when selected, will open the Amazon CloudWatch console and display your sending reputation at an effective daily rate with specific mailbox providers for the managed pool using the following metrics:

 

Metric Description
1 Available24HourSend Indicates how  much volume the managed pool has available to send towards a specific mailbox provider.
2 SentLast24Hours Indicates how  much volume of email has been sent through the managed pool by dedicated IPs  towards a specific mailbox provider.

You can also track the managed pool’s sending performance by using event publishing.

Configure VIA The API

You can configure your Managed Dedicated IP Pool through the API as well. A dedicated pool can be specified to be managed by setting the scaling-mode to “MANAGED” when creating the dedicated pool.

Configure Via The CLI

You can configure your SES resources through the CLI. A dedicated pool can be specified to be managed by setting the —scaling-mode MANAGED parameter when creating the dedicated pool.

  • # Specify which AWS region to use
    • export AWS_DEFAULT_REGION=’us-east-1′
  • # Create a managed dedicated pool
    • aws sesv2 create-dedicated-ip-pool —pool-name dedicated1 —scaling-mode MANAGED
  • # Create a configuration set that that will send through the dedicated pool
    • aws sesv2 create-configuration-set —configuration-set-name cs_dedicated1 —delivery-options SendingPoolName=dedicated1
  • # Configure the configuration set as the default for your sending identity
    • aws sesv2 put-email-identity-configuration-set-attributes —email-identity {{YOUR-SENDING-IDENTITY-HERE}} —configuration-set-name cs_dedicated1
  • # Send SES email through the API or SMTP without requiring any code changes. Emails will # be sent out through the dedicated pool.
    • aws sesv2 send-email –from-email-address “{YOUR-SENDING-IDENTITY-HERE}}” –destination “[email protected]” —content ‘{“Simple”: {“Subject”: {“Data”: “Sent from a Dedicated IP Managed pool”},”Body”: {“Text”: {“Data”: “Hello”}}}}’

Monitoring

We recommend customers onboard to event destinations and delivery delay events to more accurately track the sending performance of their dedicated sending.

Conclusion

In this blog post we explained the benefits of sending via a Dedicated IPs (Managed) feature as well as how to configure and begin sending through a Managed Dedicated IP. Dedicated IPs (Managed) pricing can be reviewed at the pricing page for SES here.

How to test email sending and monitoring

Post Syndicated from Dustin Taylor original https://aws.amazon.com/blogs/messaging-and-targeting/how-to-test-email-sending/

Introduction

When setting up your email sending infrastructure and connections to APIs it is necessary to ensure proper setup. It is also important to ensure that after making changes to your sending pipeline that you verify that your application is working as expected. Not only is it important to test your sending processes, but it’s also important to test your monitoring to ensure that sending event tracking is working as intended. A common pitfall for email senders is that when they attempt to test their email sending infrastructure or event monitoring they send to invalid addresses and/or test accounts that generate no, or negative, reputation as a result of these sends.

The Amazon Simple Email Service (SES) provides you with an easy-to-use mechanism to accomplish these tests. Amazon SES offers the mailbox simulator feature which enables a sender the ability to test different sending events to ensure your service is working as expected. Using the mailbox simulator you can test: delivery success, bounces, complaints, automated responses (like out of office messages), and when a recipient address is on the suppression list.

In this blog we will outline some information about the mailbox simulator and how to interact with the feature to test your email sending services.

What is the mailbox simulator?

The mailbox simulator is a feature offered to help Amazon SES senders test their sending services to verify normal operation. It provides mechanisms to test their monitoring and event notification services. This feature gives a sender the ability to test their service and email monitoring to verify that it is working as expected without the risk of negatively impacting their sending reputation. The mailbox simulator is an MTA operated by SES that is set to receive mail and to simulate different sending events based on the recipient address used.

Why use the mailbox simulator?

The mailbox simulator provides an easy-to-use mechanism to test your integration with Amazon SES. This gives senders the ability to test their sending environment without triggering actual bounces or complaints, which negatively impact their account sending reputation, as well as not counting against a sender’s email sending quotas.  It is important to test these events to ensure that event monitoring is properly setup and function. A gap in monitoring these events could lead to a decrease in sender reputation from bounces or complaint events going unnoticed. The mailbox simulator gives a sender the ability to programmatically evaluate whether their event monitoring process has been set up properly without the negative impact to their sending reputation that would occur if sending test emails to differing mailbox providers or invalid email addresses.

How do I use the mailbox simulator?

Your first step is setting up a destination for your event notifications. This can be done using Amazon Simple Notification Service (SNS) or by using event publishing depending on your use-case.  Once you have set up an event destination and configured it for your sending identity (either an email address or domain) you are ready to proceed to testing the configuration.

Using the Amazon SES mailbox simulator is simple. In practice, you will be sending an email to an Amazon SES owned mailbox. This mailbox will respond based on the event-type you want to test. Below is a map of the event types and the corresponding email addresses to test the events:

Event Type Email Destination
Delivery Success [email protected]
Bounce [email protected]
Complaint [email protected]
Suppression List [email protected]
Automatic Responses (OOTO) [email protected]

If you are using the Amazon SES console to test these events, SES has already included the addresses to simplify the testing experience and you can find these under the ‘Scenario’ dropdown.

After sending an email to one of the five destinations, you should soon receive a notification, or event, to your publishing destination. This is an example of a success event.

{
    "notificationType": "Delivery",
    "mail": {
        "timestamp": "2023-05-05T21:00:23.244Z",
        "source": "[email protected]",
        "sourceArn": "arn:aws:ses:us-west-2:012345678910:identity/example.com",
        "sourceIp": "192.168.0.1",
        "callerIdentity": "root",
        "sendingAccountId": "012345678910",
        "messageId": "01010187edb7434c-4187f4b8-3e2b-404c-a5f6-72b9b64e5d66-000000",
        "destination": ["[email protected]"]
    },
    "delivery": {
        "timestamp": "2023-05-05T21:00:24.300Z",
        "processingTimeMillis": 1056,
        "recipients": ["[email protected]"],
        "smtpResponse": "250 2.6.0 Message received",
        "remoteMtaIp": "54.165.247.113",
        "reportingMTA": "a62-102.smtp-out.us-west-2.amazonses.com"
    }
}

If you have not received confirmation of the event, it is likely there is a problem with your monitoring configuration. We recommend reviewing the documentation on SNS topic setup and/or event publishing to uncover if an error was made during initial setup.

Note: A sender may have verified an email address and a domain to use for testing. The domain may have the appropriate configuration while the email address does not. When sending an email from SES, SES will use the most specific identity (email address is used before the domain) and will use the configuration associated with that identity. This means that in this instance you can either remove the email address verification for that domain and re-test or set up the same configuration for that email address that is verified.

What next?

Now that your initial setup of event publishing is complete and you have tested your first event through the mailbox simulator, it is time to set up automated testing using the mailbox simulator. Testing email events after a successful update to your application is recommended to confirm that updates have not caused bugs in your event ingestion mechanisms.

Happy sending!

Choosing the Right Domain for Optimal Deliverability with Amazon SES

Post Syndicated from komaio original https://aws.amazon.com/blogs/messaging-and-targeting/choosing-the-right-domain-for-optimal-deliverability-with-amazon-ses/

Choosing the Right Domain for Optimal Deliverability with Amazon SES

As a sender, selecting the right domain for the visible From header of your outbound messages is crucial for optimal deliverability. In this blog post, we will guide you through the process of choosing the best domain to use with Amazon Simple Email Service (SES)

Understanding domain selection and its impact on deliverability

With SES, you can create an identity at the domain level or you can create an email address identity. Both types of verified identities permit SES to use the email address in the From header of your outbound messages. You should only use email address identities for testing purposes, and you should use a domain identity to achieve optimal deliverability.

Choosing the right email domain is important for deliverability for the following reasons:

  • The domain carries a connotation to the brand associated with the content and purpose of the message.
  • Mail receiving organizations are moving towards domain-based reputational models; away from IP-based reputation.
  • Because the email address is a common target for forgery, domain owners are increasingly publishing policies to control who can and cannot use their domains.

The key takeaway from this blog is that you must be aware of the domain owner’s preference when choosing an identity to use with SES. If you do not have a relationship with the domain owner then you should plan on using your own domain for any email you send from SES.

Let’s dive deep into the technical reasons behind these recommendations.

What is DMARC?

Domain-based Message Authentication, Reporting, and Conformance (DMARC) is a domain-based protocol for authenticating outbound email and for controlling how unauthenticated outbound email should be handled by the mail receiving organization. DMARC has been around for over a decade and has been covered by this blog in the past.

DMARC permits the owner of an email author’s domain name to enable verification of the domain’s use. Mail receiving organizations can use this information when evaluating handling choices for incoming mail. You, as a sender, authenticate your email using DKIM and SPF.

  • DKIM works by applying a cryptographic signature to outbound messages. Mail receiving organizations will use the public key associated with the signing key that was used to verify the signature. The public key is stored in the DNS.
  • SPF works by defining the IP addresses permitted to send email as the MAIL FROM domain. The record of IP addresses is stored in the DNS. The MAIL FROM domain is not the same domain as the domain in the From header of messages sent via SES. It is either domain within amazonses.com or it is a custom MAIL FROM domain that is a subdomain of the verified domain identity. Read more about SPF and Amazon SES.

A message passes the domain’s DMARC policy when the evaluation DKIM or SPF indicate that the message is authenticated with an identifier that matches (or is a subdomain of) the domain in the visible From header.

How can I look up the domain’s DMARC policy?

You must be aware of the DMARC policy of the domain in which your SES identities reside. The domain owner may be using DMARC to protect the domain from forgery by unauthenticated sources. If you are the domain owner, you can use this method to confirm your domain’s current DMARC policy.

You can look up the domain’s DMARC policy in the following ways:

  • Perform a DNS query of type TXT against the hostname called _dmarc.<domain>. For example, you can use the ‘dig’ or ‘nslookup’ command on your computer, or make the same query using a web-based public DNS resolver, such as https://dns.google/
  • Use a 3rd party tool such as:

https://tools.wordtothewise.com/dmarc/
https://mxtoolbox.com/dmarc.aspx
https://dmarcian.com/dmarc-inspector/

The “p” tag in the DMARC record indicates the domain’s policy.

How does the domain’s policy affect how I can use it with SES?

This section will cover each policy scenario and provide guidance to your usage of the domain with SES.

Policy How to Interpret You have verified the domain identity with EasyDKIM You have only email address identities with the domain
No DMARC record The domain owner has not published a DMARC policy. They may not yet be aware of DMARC There is no DMARC policy for mail receiving organizations to apply. Your messages are authenticated with DKIM, so mail receiving organization may leverage a domain-based reputational model for your email. There is no DMARC policy for mail receiving organizations to apply. Your messages are not authenticated, so reputation remains solely based on IP.
none The domain owner is evaluating the DMARC reports that the mail receiving organizations send to the domain owner, but has requested the mail receiving organizations not use DMARC policy logic to evaluate incoming email. There is no DMARC policy for mail receiving organizations to apply. Your messages are authenticated with DKIM, so mail receiving organization may leverage a domain-based reputational model for your email. There is no DMARC policy for mail receiving organizations to apply. Your messages are not authenticated, so reputation remains solely based on IP.
quarantine The domain owner has instructed mail receiving organizations to send any non-authenticated email to a quarantine or to the Junk Mail folders of the recipients. Your messages are authenticated with DKIM and will not be subjected to the domain’s DMARC policy. Mail receiving organizations may not deliver your messages to the inboxes of your intended recipients.
reject The domain owner has instructed mail receiving organizations to reject any non-authenticated email sending from the domain. Your messages are authenticated with DKIM and will not be subjected to the domain’s DMARC policy. Mail receiving organizations may reject these messages which will result in ‘bounce’ events within SES.

Other considerations

If the domain has a none or quarantine policy, you must be aware that the domain owner may have a plan to migrate to a more restrictive policy without consulting with you. This will affect your deliverability in the form of low inboxing/open rates, or high bounce rates. You should consult with the domain owner to determine if they recommend an alternative domain for your email use case.

Not all mail receiving organizations enforce DMARC policies. Some may use their own logic, such as quarantining messages that fail a reject policy. Some may use DMARC logic to build a domain-based reputational model based on your sending patterns even if you do not publish a policy. For example, here is a blueprint showing how you can set up custom filtering logic with SES Inbound.

If you have verified the domain identity with the legacy TXT record method, you must sign your email using a DKIM signature. The DKIM records in the DNS must be within the same domain as the domain in the From header of the messages you are signing.

If you have the domain identity verified with EasyDKIM and you also have email address identities verified within the same domain, then the email address identities will inherit the DKIM settings from the domain identity. Your email will be authenticated with DKIM and will not be subjected to the domain’s DMARC policy.

Can I use SPF instead of DKIM to align to the domain’s DMARC policy?

Messages can also pass a DMARC policy using SPF in addition to DKIM. This is enabled through the use of a custom MAIL FROM domain. The custom MAIL FROM domain needs to be a subdomain of the SES identity and the SES domain identity’s DMARC policy must not be set to strict domain alignment due to the way SES handles feedback forwarding. The domain owner enables a custom MAIL FROM domain by publishing records in the DNS. There is no way to authenticate email without publishing records in the DNS. Read Choosing a MAIL FROM domain to learn more.

The recommended approach is to use EasyDKIM primarily, and optionally enable a custom MAIL FROM domain as an additive form of authentication.

What should I do if I am not the domain owner?

The process of enabling DKIM and SPF authentication involves publishing DNS records within the domain. Only the domain owner may modify DNS for their domain. If you are not the domain owner, here are some alternative solutions.

Option 1: Segregate your email sending programs into subdomains.

This option is best for people within large or complex organizations, or vendors who are contracted to send email on behalf of an organization.

Ask the domain owner to delegate a subdomain for your use case (e.g. marketing.domain.example). Many domain owners are willing to delegate use of a subdomain because allowing for multiple use cases on a single domain becomes a very difficult management and governance challenge.

Through the use of subdomains they can segregate your email sending program from the email sent by normal mailbox users and other email sending programs. This also gives mail receiving organizations the ability to create a reputational model that is specific to your sending patterns, which means that you do not need to inherit any negative reputation incurred by others.

Option 2: Use a domain in which you are the domain owner.

This option is best if you have end-customers (or tenants) who have email addresses within domains which have domain owners that will not allow any form of delegation to you.

Use your own domain as the domain identity, and use subdomains within your domain to distinguish your end-customers from each other (e.g. tenant1.yourdomain.example, tenant2.yourdomain.example, tenant3.yourdomain.example, …). Amazon WorkMail uses this strategy for the awsapps.com domain.

This gives you complete control over the domain as well as your reputation. Use subdomains to segregate reputation between your end-customers if you have a multi-tenant business model.

Here are some additional suggestions to make your email more personable while remaining aligned to the domains’ DMARC policies.

  • You may format the From header of your outgoing messages so that the display name clearly reflects the name of the message author.

From: “John Doe via My App” <[email protected]>

  • Set the Reply-to header of your outbound messages so that when recipients reply, the return messages will go to the intended recipient.

Reply-to: [email protected]

What should I do if the domain is already being used for a different email sending program?

From a deliverability perspective, it is beneficial to compartmentalize your sending into different domains, or subdomains, for different email sending programs. That will limit the reputational blast radius if something were to go wrong with one campaign. Consider using different subdomains for each sending program. For example:

  • marketing.domain.example
  • receipts.domain.example

DMARC was designed for marketing and transactional email use cases, so it is good practice to publish ‘reject’ DMARC policies for those subdomains. Having a strong policy doesn’t give a free pass into recipient inboxes, but it allows the mail receiving organization to know what to do with messages that aren’t authenticated, which can lead to better trust. Building trust is the best way to gain a positive reputation.

If the domain is used by normal users for day-to-day correspondences, the domain owner should be very careful about publishing a DMARC policy because it is known to create interoperability issues with mailing lists and other email providers. Many of these email domains may never publish a ‘reject’ DMARC policy. For new email sending programs, you should strongly consider using a subdomain rather than any domain that is being used for user correspondences.

Conclusion

To ensure optimal deliverability with Amazon SES, it’s essential to be aware of the domain owner’s preferences and use a domain identity for outbound messages. Keep in mind that email address identities should only be used for testing purposes or with domains without DMARC policies. Domain owners can use subdomains to segregate email sending programs, making management and governance easier while allowing mail receiving organizations to build isolated reputational models.

By following the recommendations in this blog, you’ll be better prepared to align with the domain owner’s preferences, achieve higher deliverability rates for your authenticated outbound email, and be compatible with future DMARC developments.

Amazon SES – How to set up EasyDKIM for a new domain

Post Syndicated from Vinay Ujjini original https://aws.amazon.com/blogs/messaging-and-targeting/amazon-ses-how-to-set-up-easydkim-for-a-new-domain/

What is email authentication and why is it important?

Amazon Simple Email Service (SES) lets you reach customers confidently without an on-premises Simple Mail Transfer Protocol (SMTP) system. Amazon SES provides built-in support for email authentication protocols, including DKIM, SPF, and DMARC, which help improve the deliverability and authenticity of outgoing emails.

Email authentication is the process of verifying the authenticity of an email message to ensure that it is sent from a legitimate source and has not been tampered with during transmission. Email authentication methods use cryptographic techniques to add digital signatures or authentication headers to outgoing emails, which can be verified by email receivers to confirm the legitimacy of the email.

Email authentication helps establish a sender’s reputation as a trusted sender. Additionally, when email receivers can verify that emails are legitimately sent from a sender’s domain using authentication methods, it also helps establish the sender’s reputation as a trusted sender. Email authentication involves one or more technical processes used by mail systems (sending and receiving) that make certain key information in an email message verifiable. Email authentication generates signals about the email, which can be utilized in decision-making processes related to spam filtering and other email handling tasks.

There are currently two widely used email authentication mechanisms – SPF (Sender Policy Framework) and DKIM (DomainKeys Identified Mail). They provide information that the receiving domain can use to verify that the sending of the message was authorized in some way by the sending domain. DKIM can also help determine that the content was not altered in transit. And the DMARC (Domain-based Message Authentication, Reporting and Conformance) protocol allows sending domains to publish verifiable policies that can help receiving domains decide how best to handle messages that fail authentication by SPF and DKIM.

Email authentication protocols:

  1. SPF (Sender Policy Framework): SPF is an email authentication protocol that checks which IP addresses are authorized to send mail on behalf of the originating domain. Domain owners use SPF to tell email providers which servers are allowed to send email from their domains. This is an email validation standard that’s designed to prevent email spoofing.
  2. DKIM (DomainKeys Identified Mail): DKIM is an email authentication protocol that allows a domain to attach its identifier to a message. This asserts some level of responsibility or involvement with the message. A sequence of messages signed with the same domain name is assumed to provide a reliable base of information about mail associated with the domain name’s owner, which may feed into an evaluation of the domain’s “reputation”. It uses public-key cryptography to sign an email with a private key. Recipient servers can then use a public key published to a domain’s DNS to verify that parts of the emails have not been modified during the transit.
  3. DMARC (Domain-based Message Authentication, Reporting and Conformance): is an email authentication protocol that uses Sender Policy Framework (SPF) and DomainKeys Identified Mail (DKIM) to detect email spoofing. In order to comply with DMARC, messages must be authenticated through either SPF or DKIM, or both.

Let us dive deep into DKIM in this blog. Amazon SES provides three options for signing your messages using a DKIM signature:

  1. Easy DKIM: To set up a sending identity so that Amazon SES generates a public-private key pair and automatically adds a DKIM signature to every message that you send from that identity.
  2. BYODKIM (Bring Your Own DKIM): To provide your own public-private key pair for so SES adds a DKIM signature to every message that you send from that identity, see Provide your own DKIM authentication token (BYODKIM) in Amazon SES.
  3. Manually add DKIM signature: To add your own DKIM signature to email that you send using the SendRawEmail API, see Manual DKIM signing in Amazon SES.

The purpose of EasyDKIM is to simplify the process of generating DKIM keys, adding DKIM signatures to outgoing emails, and managing DKIM settings, making it easier for users to implement DKIM authentication for their email messages. Using EasyDKIM, Amazon SES aims to improve email deliverability, prevent email fraud and phishing attacks, establish sender reputation, enhance brand reputation, and comply with industry regulations or legal requirements. EasyDKIM doubles as domain verification (simplification) and it eliminates the need for customers to worry about DKIM key rotation (managed automation). By automating and simplifying the DKIM process, EasyDKIM helps users ensure the integrity and authenticity of their email communications, while reducing the risk of fraudulent activities and improving the chances of emails being delivered to recipients’ inboxes.

Setting up Easy DKIM in Amazon SES:

When you set up Easy DKIM for a domain identity, Amazon SES automatically adds a 2048-bit DKIM signature to every email that you send from that identity. You can configure EasyDKIM by using the Amazon SES console, or by using the API.

The procedure in this section is streamlined to just show the steps necessary to configure Easy DKIM on a domain identity that you’ve already created. If you haven’t yet created a domain identity or you want to see all available options for customizing a domain identity, such as using a default configuration set, custom MAIL FROM domain, and tags, see Creating a domain identity. Part of creating an Easy DKIM domain identity is configuring its DKIM-based verification where you will have the choice to either accept the Amazon SES default of 2048 bits, or to override the default by selecting 1024 bits. Steps to set up easyDKIM for a verified identity:

  1. Sign in to the AWS Management Console and open the Amazon SES console at https://console.aws.amazon.com/ses/
  2. In the navigation pane, under Configuration, choose Verified identities.
  3. List of verified identities in SES console

    Verified identities

  4. In the list of identities, choose an identity where the Identity type is Domain.
  5. Under the Authentication tab, in the DomainKeys Identified Mail (DKIM) container, choose Edit.
  6. In the Advanced DKIM settings container, choose the Easy DKIM button in the Identity type field.
  7. Choose EasyDKIM as identity type; RSA_2048_BITT in DKIM signing key length; Check Enabled checkbox under DKIM signatures.

    DKIM settings

  8. In the DKIM signing key length field, choose either RSA_2048_BIT or RSA_1024_BIT.
  9. In the DKIM signatures field, check the Enabled box.
  10. Choose Save changes.
  11. After configuring your domain identity with Easy DKIM, you must complete the verification process with your DNS provider – proceed to Verifying a DKIM domain identity with your DNS provider and follow the DNS authentication procedures for Easy DKIM.

Conclusion:

Email authentication, especially DKIM, is crucial in securing your emails, establishing sender reputation, and improving email deliverability. EasyDKIM provides a simplified and automated way to implement DKIM authentication. It removes the hassles of generating DKIM keys and managing settings, while additionally reducing risks and and enhancing sender authenticity. By following the steps outlined in this blog post, you can easily set up easyDKIM in Amazon SES and start using DKIM authentication for your email campaigns.

About the Author

Vinay Ujjini is an Amazon Pinpoint and Amazon Simple Email Service Worldwide Principal Specialist Solutions Architect at AWS. He has been solving customer’s omni-channel challenges for over 15 years. He is an avid sports enthusiast and in his spare time, enjoys playing tennis & cricket.

Amazon Building for Retail Stores with 2000 Cameras and 100K Sensors OCP Regional Summit 2023

Post Syndicated from Patrick Kennedy original https://www.servethehome.com/amazon-building-for-retail-stores-with-2000-cameras-and-100k-sensors-ocp-regional-summit-2023/

Amazon explained the challenge of building retail stores with over 2000 cameras as it unveiled its new Enterprise Edge Gateway OCP specs

The post Amazon Building for Retail Stores with 2000 Cameras and 100K Sensors OCP Regional Summit 2023 appeared first on ServeTheHome.

What is BIMI and how to use it with Amazon SES

Post Syndicated from Matt Strzelecki original https://aws.amazon.com/blogs/messaging-and-targeting/what-is-bimi-and-how-to-use-it-with-amazon-ses/

Introduction

In this blog post I’d like to walk you through how to implement BIMI while using Amazon SES. For your information BIMI can be best described by the following excerpt from bimigroup.org:

Brand Indicators for Message Identification or BIMI (pronounced: Bih-mee) is an emerging email specification that enables the use of brand-controlled logos within supporting email clients. BIMI leverages the work an organization has put into deploying DMARC protection, by bringing brand logos to the customer’s inbox. For the brand’s logo to be displayed, the email must pass DMARC authentication checks, ensuring that the organization’s domain has not been impersonated.

Brands continually need to protect themselves from spoofing and phishing from bad actors who can damage the trust that customers and recipients have in those brands. Brand Indicators for Message Identification (BIMI) is an email specification that enables email inboxes to display a brand’s logo next to the brand’s authenticated email messages within supporting email clients. BIMI is an email specification that’s directly connected to authentication, but it’s not a standalone email authentication protocol as it requires all your email to comply with DMARC authentication. Recipients are more likely to engage with email that displays the logo of the brand associated with the message author. Higher engagement helps deliverability and inbox placement because it indicates that the recipients trust your brand. BIMI is a great brand protector in email and provides a better user experience for the end recipients and customers.

BIMI requires that you authenticate all of your organization’s email with SPF, DKIM and DMARC. In this how-to we will be utilizing Amazon SES to authenticate the emails, Amazon S3 to host the SVG image, and Amazon Route53 to add DNS records. We will be walking through how to accomplish each step until completion.

Note: While we’re using AWS products in this how-to, it is not a requirement to use all AWS products to implement BIMI. Any hosting provider for content or domain can be used however the steps may differ based on the provider you use.

BIMI Implementation

The following are the steps needed to prepare your SES account and domain for BIMI:

Step 1

Note: If you already have SPF, DKIM, and DMARC enabled for your domain (with 100% as the rate for DMARC) you can move on to Step 2.

Enable Easy DKIM for your domain

  1. Sign in to the AWS Management Console and open the Amazon SES console at https://console.aws.amazon.com/ses/.
  2. In the navigation pane, under Configuration, choose Verified identities.
  3. In the list of identities, choose an identity where the Identity type is Domain.

Note: If you need to create or verify a domain, see Creating a domain identity.

  1. Under the Authentication tab, in the DomainKeys Identified Mail (DKIM) container, choose Edit.
  2. In the Advanced DKIM settings container, choose the Easy DKIM button in the Identity type field.
  3. In the DKIM signing key length field, choose either RSA_2048_BIT or RSA_1024_BIT.
  4. In the DKIM signatures field, check the Enabled box.
  5. Choose Save changes.
  6. Now that you’ve configured your domain identity with Easy DKIM, you must complete the verification process with your DNS provider – proceed to Verifying a DKIM domain identity with your DNS provider and follow the DNS authentication procedures for Easy DKIM.

Create a DMARC record for your domain

  1. Sign in to the AWS Management Console and open the Route 53 console at https://console.aws.amazon.com/route53/
  2. In the navigation pane, choose Hosted zones.
  3. On the Hosted zones page, choose the name of the hosted zone that you want to create records in.
  4. Choose and define the applicable routing policy and the following values:
Name Record Type Value
_dmarc.example.com TXT v=DMARC1;p=quarantine;pct=100;rua=mailto:[email protected]
  1. Choose Create records.

Note: The DMARC policy must enforce at 100% and include either a quarantine or reject policy. (i.e. p=reject or p=quarantine) to meet the DMARC authentication requirement. This may mean you will need to update your existing policy and DMARC record.

Configure a Custom Mail From for your sending domain

  1. Open the Amazon SES console at https://console.aws.amazon.com/ses/.
  2. In the left navigation pane, under Configuration, choose Verified identities.
  3. In the list of identities, choose the identity you want to configure where the Identity type is Domain and Status is Verified.

a. If the Status is Unverified, complete the procedures at Verifying a DKIM domain identity with your DNS provider to verify the email address’s domain.

  1. At the bottom of the screen in the in the Custom MAIL FROM domain pane, choose Edit .
  2. In the General details pane, do the following:

a. Select the Use a custom MAIL FROM domain checkbox.

b. For MAIL FROM domain, enter the subdomain that you want to use as the MAIL FROM domain.

c. For Behavior on MX failure, choose one of the following options:

    • Use default MAIL FROM domain – If the custom MAIL FROM domain’s MX record is not set up correctly, Amazon SES uses a subdomain of amazonses.com. The subdomain varies based on the AWS Region that you use Amazon SES in.
    • Reject message – If the custom MAIL FROM domain’s MX record is not set up correctly, Amazon SES returns a MailFromDomainNotVerified error. Emails that you attempt to send from this domain are automatically rejected. If you want to ensure that 100% of your email is BIMI compatible, then you should choose the reject message option.

d. Choose Save changes – you’ll be returned to the previous screen.

  1. Publish the MX and SPF (type TXT) records to the DNS server of the custom MAIL FROM domain:

Note: In the Custom MAIL FROM domain pane, the Publish DNS records table now displays the MX and SPF (type TXT) records in that you have to publish (add) to your domain’s DNS configuration. These records use the formats shown in the following table.

Name Record Type Value
subdomain.example.com MX 10 feedback-smtp.region.amazonses.com
subdomain.example.com TXT v=spf1 include:amazonses.com ~all

Step 2

Produce an SVG Tiny PS version of your official logo

In order to display your logo in the email it must conform to the specifications of the BIMI requirements. To meet these requirements the logo must be a Scalable Vector Graphics (SVG) image and must meet the Tiny PS Specification. Once your image meets this requirement you can move on to the next step.

Note: bimigroup.org outlines this process and includes references to software to assist with this process.

Step 3

Upload your image to an S3 bucket

  1. Sign in to the AWS Management Console and open the Amazon S3 console at https://console.aws.amazon.com/s3/
  2. In the Buckets list, choose the name of the bucket that you want to upload your folders or files to.
  3. Choose Upload.
  4. In the Upload window, do one of the following:
    • Drag and drop files and folders to the Upload window.
    • Choose Add file choose your SVG image to upload, and choose Open.

To configure additional object properties

  1. To change access control list permissions, choose Permissions.
  2. Under Access control list (ACL), edit the permissions.
    • You need to grant read access to your objects to the public (everyone in the world) for the SVG image you are uploading. However, we recommend not changing the default setting for your bucket to public read access.
  1. To configure other additional properties, choose Properties.
  2. To upload your objects, choose Upload.

Note: Amazon S3 uploads your object. When the upload completes, you can see a success message on the Upload: status page.

  1. Choose Exit.

Step 4

Publish a BIMI record for your domain

  1. Sign in to the AWS Management Console and open the Route 53 console at https://console.aws.amazon.com/route53/
  2. In the navigation pane, choose Hosted zones.
  3. On the Hosted zones page, choose the name of the hosted zone that you want to create records in.
  4. Choose and define the applicable routing policy and the following values with the understanding the URLs must be HTTPS:
Name Record Type Value
default._bimi.example.com TXT v=BIMI1; l=[SVG URL]; a=[PEM URL]
  1. Choose Create records.

Note: the a= tag is currently optional and will not be used in this example.

You can validate your BIMI record with a tool like the BIMI Inspector.

Conclusion

All of the steps to set up your SES account and your domain are now complete. The final component in this process is to have regular sending patterns to the mailbox providers that support BIMI logo placement. Your domain should have a regular delivery cadence and needs to have a good reputation with the mailbox providers you are sending mail. BIMI logo placement may take time to populate to mailbox providers where you don’t have an established reputation or sending cadence. The time spent implementing BIMI is well worth it as it will strengthen your sender reputation and create a better and more trusted customer experience for your end recipients.

You can find more information about the BIMI specification here.

Putting the Bare Metal Server in the PhoenixNAP Bare Metal Cloud

Post Syndicated from Patrick Kennedy original https://www.servethehome.com/putting-the-bare-metal-server-in-the-phoenixnap-bare-metal-cloud-intel-xeon-sapphire-rapids-supermicro/

We install a special server into the PhoenixNAP Bare Metal Cloud so we can show an instance’s lifecycle from hardware to operation

The post Putting the Bare Metal Server in the PhoenixNAP Bare Metal Cloud appeared first on ServeTheHome.

How to create a WhatsApp custom channel with Amazon Pinpoint

Post Syndicated from Sparsh Wadhwa original https://aws.amazon.com/blogs/messaging-and-targeting/whatsapp-with-amazon-pinpoint/

How to add WhatsApp as an Amazon Pinpoint Custom Channel

WhatsApp now reports over 2 billion users in 180 countries, making it a prime place for businesses to communicate with their customers. In addition to native channels like SMS, push notifications, and email, Amazon Pinpoint’s custom channels enable you to extend the capabilities of Amazon Pinpoint and send messages to customers through any API-enabled service, like WhatsApp. With these new channels, you have full control over the message delivery to the endpoints associated with each custom channel campaign.

In this post, we provide a quick overview of the features and capabilities of using a custom channel as part of campaigns. We also provide a blueprint that you can use to build your first sandbox integration with WhatsApp as a custom channel.

Note: WhatsApp is a third-party service subject to additional terms and charges. Amazon Web Services isn’t responsible for any third-party service that you use to send messages with custom channels. 

How to add WhatsApp as a custom channel:

Prerequisites

Before creating your new custom channel, you must have the integration ready and an Amazon Identity and Account Management (IAM) User created with the necessary permissions. First set up the following:

  1. Create an IAM administrator. For more information, see Creating your first IAM admin user and group in the IAM User Guide. Specify the credentials of this IAM User when you set up the AWS Command Line Interface (CLI).
  2. Configure the AWS CLI. For more information about setting up the AWS CLI, see Configuring the AWS CLI.
  3. Follow the steps at Meta documentation – https://developers.facebook.com/docs/whatsapp/cloud-api/get-started to register as a Meta Developer and getting started with WhatsApp Business Cloud API provided directly by Meta. By completing step 1 and step 2 of the above documentation, you should be able to
    1. Register as a Meta Developer,
    2. Claim a test phone for sending messages on WhatsApp,
    3. Verify a recipient phone number (since, currently you’re in Sandbox, you can send WhatsApp messages only to the verified phone numbers. You can verify upto 5 phone numbers)
    4. and finally send a test message on Whatsapp using a provided sample POST request. Remember to review the terms of use for WhatsApp.Screenshot of WhatsApp API in Meta console
  4. In the test message sent above, you have used temporary Access Token credentials which expires in 23 hours. In order to get permanent Access Token, generate a ‘System User Access Token’ by following the steps mention here – https://developers.facebook.com/docs/whatsapp/business-management-api/get-started/

Screenshot of WhatsApp test message sent from Meta Console.

Procedure:

Step 1: Create an Amazon Pinpoint project.

In this section, you create and configure a project in Amazon Pinpoint. Later, you use this data to create segments and campaigns.

To set up the Amazon Pinpoint project

  1. Sign in to the Amazon Pinpoint console at http://console.aws.amazon.com/pinpoint/.
  2. On the All projects page, choose Create a project. Enter a name for the project, and then choose Create.
  3. On the Configure features page, under SMS and Voice, choose Configure.
  4. Under General settings, select Enable the SMS channel for this project, and then choose Save changes.
  5. In the navigation pane, under Settings, choose General settings. In the Project details section, copy the value under Project ID. You need this value for later.

Step 2: Create an endpoint.

In Amazon Pinpoint, an endpoint represents a specific method of contacting a customer. This could be their email address (for email messages) or their phone number (for SMS messages) or a custom endpoint type. Endpoints can also contain custom attributes, and you can associate multiple endpoints with a single user. In this step, we create an SMS endpoint that is used to send a WhatsApp message.

To create an endpoint using AWS CLI, at the command line, enter the following command:

aws pinpoint update-endpoint –application-id <project-id> \
–endpoint-id 12456 –endpoint-request “Address='<mobile-number>’, \
ChannelType=’SMS’,Attributes={username=[‘testUser’],integrations=[‘WhatsApp’]}”

In the preceding example, replace <project-id> with the Amazon Pinpoint Project ID that you copied in step 1.

Replace <mobile-number> with your phone number with country code (for example, 12065550142). For the WhatsApp integration to work, you must use the mobile number that are registered on WhatsApp and are already verified on Meta Developer Portal (since your Meta account is currently in sandbox).

Note: WhatsApp Business Cloud message API doesn’t require ‘+’ symbol in the front of the Phone number. So in case you plan to use this segment for both SMS and Custom Channel, you may configure Phone Number in E.164 format (for example, +12065550142) and remove ‘+’ symbol in the Lambda function code that we create in the step 4.

Step 3: Storing WHATSAPP_AUTH_TOKEN, and WHATSAPP_FROM_NUMBER_ID in AWS Secrets Manager.

We can securely store the WhatsApp Auth Token and WhatsApp From Number Id which we have received in the previous steps in AWS Secrets Manager.

  1. Open the AWS Secrets Manager console at https://us-east-1.console.aws.amazon.com/secretsmanager/listsecrets?region=us-east-1 (in the required AWS region), and then click on “Store a new Secret”.
  2. Under “Secret Type”, choose Other type of secret.
  3. Under Key/value Pair, add the following Key-Value pairs:
    1. WHATSAPP_AUTH_TOKEN: <Pass the Auth Token generated previously>
    2. WHATSAPP_FROM_NUMBER_ID : <Pass the From Number Id>.
      AWS Secret Manager Console screenshot storing WHATSAPP_AUTH_TOKEN and WHATSAPP_FROM_NUMBER_ID secrets.
  4. Click Next
  5. Provide the Secret name “MetaWhatsappCreds” and provide a suitable description.
  6. Click Next twice and finally click “Store” button.

Step 4: Create an AWS Lambda.

You must create an AWS Lambda that has the code that calls Meta WhatsApp Business Cloud API and sends a message to the endpoint.

  1. Open the AWS Lambda console at http://console.aws.amazon.com/AWSLambda, and then click on Create Function.
  2. Choose Author from scratch.
  3. For Function Name, enter ‘WhatsAppTest’.
  4. For Runtime, select Python 3.9.
  5. Click Create Function.
  6. For the function code, copy the following and paste into the code editor in your AWS Lambda function:
import base64
import json
import os
import urllib
from urllib import request, parse
import boto3
from botocore.exceptions import ClientError

WhatsApp_messageAPI_URL = "https://graph.facebook.com/v15.0/" 

def get_secret():

    secret_name = "MetaWhatsappCreds"
    region_name = "us-east-1"
    # Pass the required AWS Region in which Secret is stored

    # Create a Secrets Manager client
    session = boto3.session.Session()
    client = session.client(
        service_name='secretsmanager',
        region_name=region_name
    )

    try:
        get_secret_value_response = client.get_secret_value(
            SecretId=secret_name
        )
    except ClientError as e:
        # For a list of exceptions thrown, see
        # https://docs.aws.amazon.com/secretsmanager/latest/apireference/API_GetSecretValue.html
        raise e

    # Decrypts secret using the associated KMS key.
    secret = get_secret_value_response['SecretString']
    return secret
   
def lambda_handler(event, context):
    credentials = get_secret()
    WhatsApp_AUTH_TOKEN = json.loads(credentials)["WHATSAPP_AUTH_TOKEN"]
    WhatsApp_FROM_NUMBER_ID = json.loads(credentials)["WHATSAPP_FROM_NUMBER_ID"]
    if not WhatsApp_AUTH_TOKEN:
        return "Unable to access WhatsApp Auth Token."
    elif not WhatsApp_FROM_NUMBER_ID:
        return "Unable to access WhatsApp From Number Id."
    # Lets print out the event for our logs 
    print("Received event: {}".format(event))

    populated_url = WhatsApp_messageAPI_URL + WhatsApp_FROM_NUMBER_ID + "/messages"

    for key in event['Endpoints'].keys(): 
        to_number = event['Endpoints'][key]['Address']
        # Example body and using an attribute from the endpoint
        username = event['Endpoints'][key]['Attributes']['username'][0]
        body = "Hello {}, here is your weekly 10% discount coupon: SAVE10".format(username)
        post_params = {"messaging_product":"whatsapp","to": to_number ,"recipient_type": "individual","type": "text", "text":{"preview_url": "false","body": body}}
        # encode the parameters for Python's urllib 
        print(post_params)
        data = parse.urlencode(post_params).encode('ascii') 
        req = request.Request(populated_url)
        req.add_header("Authorization", WhatsApp_AUTH_TOKEN ) 
        req.add_header("Content-Type","application/json")
        try:
            # perform HTTP POST request
            with request.urlopen(req, data) as f:
                print("WhatsApp returned {}".format(str(f.read().decode('utf-8')))) 
        except Exception as e:
            # something went wrong!
            print(e)

    return "WhatsApp messages sent successfully"
  1. Add permissions to your AWS Lambda to allow Amazon Pinpoint to invoke it using AWS CLI:

aws lambda add-permission \
–function-name WhatsAppTest \
–statement-id sid \
–action lambda:InvokeFunction \
–principal pinpoint.us-east-1.amazonaws.com \
–source-arn arn:aws:mobiletargeting:us-east-1:<account-id>:apps/<Pinpoint ProjectID>/*

Step 5: Create a segment and campaign in Amazon Pinpoint.

Now that we have an endpoint, we must add it to a segment so that we can use it within a campaign. By sending a campaign, we can verify that our Amazon Pinpoint project is configured correctly, and that we created the endpoint correctly.

To create the segment and campaign:

    1. Open the Amazon Pinpoint console at http://console.aws.amazon.com/pinpoint, and then choose the project that you created in step 1.
    2. In the navigation pane, choose Segments, and then choose Create a segment.
    3. Name the segment “WhatsAppTest.” Under Segment group 1, include all audiences in the Base Segment and add the following Criteria:
    4. For Choose an endpoint attribute, choose integrations, then for values, choose WhatsApp.Amazon Pinpoint Create Segment Console Screenshot showing the various configurations of Pinpoint Segment.
    5. Confirm that the Segment estimate section shows that there is one eligible endpoint, and then choose Create segment.
    6. In the navigation pane, choose Campaigns, and then choose Create a campaign.
    7. Name the campaign “WhatsAppTest.” Under Choose a channel for this campaign, choose Custom, and then choose Next.
    8. On the Choose a segment page, choose the “WhatsAppTest” segment that you just created, and then choose Next.
    9. In Create your message, choose the AWS Lambda function we just created, ‘WhatsAppTest.’ Select SMS in the Endpoint Options. On the Choose when to send the campaign page, keep all of the default values, and then choose Next. On the Review and launch page, choose Launch campaign.

Screenshot of Pinpoint console showing creation of message for Custom Channel.

Within a few seconds, you should receive a WhatsApp message at the phone number that you specified when you created the endpoint and verified on the Meta Developer portal.

Your Custom channel solution for WhatsApp is now ready to use. But first, review and upgrade your WhatsApp sandbox. This post is simply a walkthrough to show you how quickly you can prototype and start sending WhatsApp messages with Pinpoint and Meta. However, for production usage, you need to make sure to review all of the additional terms and charges. Start here to understand more: https://developers.facebook.com/docs/whatsapp/cloud-api/get-started

As a next steps, you can go ahead and claim a Phone number for sending WhatsApp messages in production. You can further configure a Webhook which can help you in receiving WhatsApp message delivery status and other WhatsApp supported events.

There are several ways you can make this solution your own.

  • Customize your messaging: This post used an example message to be sent to your endpoints within the AWS Lambda. You can customize that message to fit your needs. See the various ways in which you can send WhatsApp messages here.
  • Expand endpoints in your application: This post only used one endpoint for the integration. You can use your WhatsApp integration with new endpoints by importing a segment that can be used with a new campaign. Learn how to import a segment here: https://docs.aws.amazon.com/pinpoint/latest/userguide/segments-importing.html
  • Use new integrations: This post focused on integrating your custom channel with WhatsApp but there are many other integrations that are possible when using AWS Lambda.

Amazon Pinpoint is a flexible and scalable outbound and inbound marketing communications service. Learn more here: https://aws.amazon.com/pinpoint/

Send WhatsApp messages via Amazon Pinpoint

Post Syndicated from Pavlos Ioannou Katidis original https://aws.amazon.com/blogs/messaging-and-targeting/send-whatsapp-messages-via-amazon-pinpoint/

In this blog you will deploy a solution that integrates Amazon Pinpoint with WhatsApp for outbound and inbound messages.

Amazon Pinpoint is a multichannel customer engagement platform allowing you to engage with your customers across 6 different channels (push notifications, email, SMS, voice, in-app messages and custom channel). Using Amazon Pinpoint’s custom channel you can extend its capabilities via a webhook or AWS Lambda function. Among many other possibilities, you can use custom channels to send messages to your customers through any API-enabled service, for example WhatsApp.

According to statista, WhatsApp is one of the most used apps in the world and the most popular messaging app in over 100 countries. It reached 2.3 billion active users in 2022 while in January 2022, WhatsApp was the most downloaded chat and messaging app worldwide, amassing approximately 40.6 million downloads across the Apple App Store and the Google Play Store.

Note: WhatsApp is a third-party service subject to additional terms and charges. Amazon Web Services isn’t responsible for any third-party service that you use to send messages with custom channels.

Solution & Architecture

An integration between Amazon Pinpoint and WhatsApp can be achieved for both outbound and inbound messages. The next section dives deeper into the architecture for both outbound and inbound messages. The solution uses Amazon Pinpoint custom channel, AWS Lambda, Amazon API Gateway, AWS Cloudformation and AWS Secrets Manager.

Outbound messages

For outbound messages Amazon Pinpoint integrates with WhatsApp via its custom channel allowing users to send WhatsApp messages using Pinpoint campaigns and journeys. Specifically, Pinpoint invokes an AWS Lambda function and performs an API call to WhatsApp. The API call contains the WhatsApp access token, the customer’s mobile number and the WhatsApp message template name.

outbound-message

  1. Amazon Pinpoint campaign or journey using endpoint type CUSTOM invokes an AWS Lambda function. The payload along with the endpoint data should contain the WhatsApp message template name as part of the Custom Data field.
  2. The AWS Lambda obtains the WhatsApp access token from the AWS Secrets Manager and performs a POST API call to the WhatsApp API.
  3. The WhatsApp message gets delivered to the customer.

Inbound messages

For inbound messages WhatsApp requires a Callback URL. This solution utilizes Amazon API Gateway to create the Callback URL and AWS Lambda to authorize and process inbound messages.

inbound-message

  1. Customer sends a message to your WhatsApp number.
  2. WhatsApp makes a GET API call to the Amazon API Gateway endpoint for verification purposes. All subsequent calls containing the customers’ messages are POST.
  3. If the API call method is GET, the AWS Lambda checks if the verify token matches the one stored as an AWS Lambda Environment Variable. If it’s TRUE, it returns a code called HubChallenge that WhatsApp is expecting in order to verify the connection. For POST API calls, the AWS Lambda loops through the customer messages and retrieves the customer’s phone number, timestamp, message_id and message_body. For each message processed, the AWS Lambda function performs an API call to WhatsApp to mark the message as read.

Considerations

  • Message delivery/engagement events aren’t being recorded.
  • Messages sent aren’t personalized and they are currently using message templates hosted by WhatsApp.
  • It is recommended to use endpoint type CUSTOM and not SMS for the following reasons:
    • WhatsApp’s phone number format doesn’t contain + comparing to Pinpoint SMS address format. If you decide to use the endpoint type SMS you will need to process the endpoint Address by removing the +.
    • Using the endpoint type SMS forces you to send WhatsApp messages with the same throughput (messages per second) as your Pinpoint SMS channel.

Prerequisites

  1. AWS account.
  2. An Amazon Pinpoint project – How to create an Amazon Pinpoint project.
  3. An Amazon Pinpoint CUSTOM endpoint with address a mobile number which is associated to a WhatsApp account. See example CUSTOM endpoint in a CSV here.
  4. A Meta (Facebook) developer account, for more details please go to the Meta for Developers console.

Implementation

Meta for Developers console

  1. Navigate and login into the Meta for Developers console, click My Apps and select Create App (or use an existing app of type Business).
  2. Select Business as an app type, which supports WhatsApp and click Next.
  3. Provide a display name, contact email, choose whether or not to attach Business Account (optional) and select Create App.
  4. Navigate to the Dashboard and select Set Up in the WhatsApp service in the Add product to your app section.
  5. Create or select an existing Meta Business Account and select Continue.
  6. Navigate to WhatsApp/Getting Started and take a note of the Phone number ID, which will be needed in AWS CloudFormation template later on. WhatsAppPhoneNumberId
  7. On the WhatsApp/Getting Started page, add your customer phone number you are going to use for testing in the Select a recipient phone number dropdown. Follow the instructions to add and verify your phone number. Note: You must have WhatsApp registered with the number and the WhatsApp client installed on your mobile device. Verification message could appear in the Archived list in your WhatsApp client and not in the main list of messages.

Create a new user to access WhatsApp via API

  1. Open Meta’s Business Manager and select business you created or associated your app with earlier.
  2. Below Users, select System Users and choose Add to create a new system user.
  3. Give a name to the system user and set their role as Admin and click Create System User.
  4. Use the Add Assets button to associate the new user with your WhatsApp app. From the Select asset type list, select Apps, then in the Select assets, select your WhatsApp app’s name. Enable the Test app Partial access for the user, select Save Changes and Done.
  5. Click on the Generate new token button, select the WhatsApp app created earlier and choose Permanent as Token expiration.
  6. Select whatsapp_business_messaging and whatsapp_business_management from the list of Available Permissions and click Generate token at the bottom.
  7. Copy and save your access token. This will be needed in AWS CloudFormation template later on. Make sure you copied the token before clicking on OK.

For more details on creating the access token, you can navigate to WhatsApp/Configuration and click on Learn how to create a permanent token.

Solution deployment

  1. Download the AWS CloudFormation template and navigate to the AWS CloudFormation console under the AWS region you want to deploy the solution.
  2. Select Create stack and With new resources. Choose Template is ready as Prerequisite – Prepare template and Upload a template file as Specify template. Upload the template downloaded in step 1.
  3. Fill the AWS CloudFormation parameters as shown below:
    1. ApiGatewayName: This is the name of the Amazon API Gateway resource.
    2. PhoneNumberId: This is the WhatsApp phone number Id you obtained from the Meta for Developers console under WhatsApp/Getting Started.
    3. PinpointProjectId: Paste your Amazon Pinpoint’s project Id. This allows Amazon Pinpoint to invoke the AWS Lambda, which sends WhatsApp messages as part of a campaign or journey.
    4. VerifyToken: The verify token is an alphanumeric token that you provide to WhatsApp when setting up the Webhook Callback URL for inbound messages and notifications. You can decide the value of this token e.g. 123abc.
    5. WhatsAppAccessToken: The access token should start with Bearer EEAEAE… and you should have obtained it from the section of this blog Create a new user to access WhatsApp via API.
  4. Once the AWS CloudFormation stack is deployed, copy the Amazon API GateWay endpoint from the AWS CloudFormation outputs tab. Navigate to the Meta for Developers App dashboard, choose Webhooks, select Whatsapp Business Account and subscribe to messages. SubscribeToMessages
  5. Paste the Amazon API Gateway endpoint as a Callback URL. For the Verify token, provide the same value as the AWS CloudFormation template parameter VerfiyToken and select Verify and save. VerifyAndSave

Testing

  • Sending messages: To test sending a message to WhatsApp using Amazon Pinpoint:
    • Navigate to the Amazon Pinpoint Campaigns
    • Create a new Campaign with WhatsAppCampaign as the Campaign name, select Standard campaign as the Campaign type, choose Custom as Channel and select Next.
    • Select a segment that includes the CUSTOM endpoint that you will send the message to
    • Choose the AWS Lambda Function containing the name WhatsAppSendMessageLambda. Under Custom data type hello_world, for Endpoint Options choose Custom and select Next. Note that the hello_world is the WhatsApp default message template.
    • In Step 4 leave everything with the default values, scroll to the bottom of the page and select Next.
    • Choose Launch campaign.
  • Receiving messages: Text or reply to the WhatsApp number. The inbound messages are being printed in the Amazon CloudWatch logs of the AWS Lambda function containing the name WhatsAppWebHookLambda. ReceivedMessage

Next steps

There are several ways to extend this solution’s functionality, see some of them below:

  • Instead of specifying the WhatsApp message template name, provide directly the text you want to send using the Pinpoint’s custom channel Custom data field. To do this, update the AWS Lambda function code responsible for sending messages with the one below:
    import os
    import json
    import boto3
    from urllib import request, parse
    from botocore.exceptions import ClientError
    phone_number_id = os.environ['PHONE_NUMBER_ID']
    secret_name = os.environ['SECRET_NAME']
    def handler(event, context):
        print("Received event: {}".format(event))
        session = boto3.session.Session()
        client = session.client(service_name='secretsmanager')
        try:
            get_secret_value_response = client.get_secret_value(SecretId=secret_name)
        except ClientError as e:
            raise e
        else:
            secret = get_secret_value_response['SecretString']
            url = 'https://graph.facebook.com/v15.0/'+ phone_number_id + '/messages'
            message = event['Data'] # Obtaining the message from the Custom Data field
            for key in event['Endpoints'].keys(): 
                to_number = str(event['Endpoints'][key]['Address'])
                send_message(secret, to_number, url, message_template)
    def send_message(secret, to_number, url, message_template):
        headers = {
            'content-type': 'application/json',
            'Authorization': secret
        }
        # Building the request body and insted of type = template, it's replaced with type = text
        data = parse.urlencode({
            'messaging_product': 'whatsapp',
            'to': to_number,
            'type': 'text',
            'text': {
                'body': message
            }
        }).encode()
        req =  request.Request(url, data=data, headers=headers)
        resp = request.urlopen(req)
  • Use WhatsApp’s message template components to populated dynamically variables. This requires an update on the respective WhatsApp message template and API request body to WhatsApp’s API. The message template should look like this:

PersonalizedMessageTemplate

And the API request body should look like this. Note that the value for each variable should be obtained from the Pinpoint endpoint or user attributes.

{
  "from": from_number,
  "to": to_number,
  "channel": "whatsapp",
  "content": {   
    "contentType": "template",
    "template": {
        "templateId" : "first_pinpoint_message",
        "templateLanguage" : "en",
        "components" : {
            "body" : [
                    {
                        "type": "text",
                        "text": "Pavlos"
                    }
            ]           
        }
   }
  }
}

Clean-up

To delete the solution, navigate to the AWS CloudFormation console and delete the stack deployed.

About the Authors

Pavlos Ioannou Katidis

Pavlos Ioannou Katidis

Pavlos Ioannou Katidis is an Amazon Pinpoint and Amazon Simple Email Service Senior Specialist Solutions Architect at AWS. He enjoys diving deep into customers’ technical issues and help in designing communication solutions. In his spare time, he enjoys playing tennis, watching crime TV series, playing FPS PC games, and coding personal projects.

Customize marketing messages and promotions for personalized outreach

Post Syndicated from binpazho original https://aws.amazon.com/blogs/messaging-and-targeting/customize-marketing-messages-and-promotions-for-personalized-outreach/

Introduction

Amazon Pinpoint is widely used by many customers for their various user engagement use cases like marketing campaigns, scheduled communications (newsletters, reminders, etc.), and transactional messaging. By using the message template feature in Amazon Pinpoint, customers can design messages personalized to the specific end users, by using variable attributes. While Amazon Pinpoint enables customers to include up to 250 attributes for each user, often times there might be need to pick and choose from a wide range of attributes about a user, that can lead to needing more than the allowed number of attributes.

The CampaignHook feature of Amazon Pinpoint can come to rescue for a situation like this. Using the CampainHook feature, we can filter out attributes that are not applicable to a specific user, while allowing to add new attributes, right before of sending the message. In this blog, I will walk you through how I have implemented the CampaignHook feature for a similar use case.

Sample Use-Cases

When setting up your Pinpoint campaign, following are the use cases where a CampaignHook can be enabled:

  • Retrieving data and perform custom compute logic in real time from third party data stores.
  • Filter endpoints out of the send: This is useful if you need to do some type of custom logic that you can’t do in Segmentation (custom opt-out, quiet time, campaign prioritization, etc.)
  • Avoid costly and time consuming Extract, Transform & Load (ETL) processes by accessing the data sources directly and applying custom compute logic in real-time.

Solution overview

CampaignHook Demo Architecture

The diagram above shows the solution that we will setup in this blog. As you can see, the Campaign event will trigger the Amazon Pinpoint Campaign. The event can be triggered from your web or mobile app that are accessed by your end-users, and can be setup to be triggered when the user performs a certain action. You can read more about setting up Amazon Pinpoint campaign in the user guide. By having the CampaignHook enabled on your Amazon Pinpoint campaign, the Lambda function that is configured with the CampaignHook will be triggered. This function will have access to the endpoint attributes passed by the Campaign event, and perform additional logic to derive new attributes for the user. Once all the new fields are derived, the function will update the user endpoint. Amazon pinpoint will then perform the next steps in the Campaign, and substitute the variables in the message template, before the personalized message is sent to the end user.

Prerequisites

  • AWS Account with Console and Programmatic access
  • Access to AWS CloudShell
  • Email channel enabled in Amazon Pinpoint

Building the demo

Build the Amazon Pinpoint Project

From the AWS Management console, go to Amazon Pinpoint and create a new project called “PinpointCampaignHookDemo”, and choose the option to enable the email channel. For more information about creating a project see the user guide, and follow the instructions here to setup your email channel.

If your account is in the Sandbox account, you will need to verify the email address, before you can send the email. You can follow the steps here to upgrade your account to a Production status if you are ready to deploy this solution to production.

Create the segment.

A segment is a group of your users that share certain attributes. For example, a segment might contain all of your users who use version 2.0 of your app on an Android device, or all users who live in the city of Los Angeles. You can send multiple campaigns to a single segment, and you can send a single campaign to multiple segments.

For this demo, let’s create a Dynamic Segment. Let’s call it ‘CampaignHookDemoSegment’.  Follow the steps here to create your Dynamic Segment.

Create a Segment

Setup message template

Let’s create our first template and call it “CampaignHookDemoTemplate”. You can read more about Amazon Pinpoint templates in the user guide.

For this demo, I have used the HTML template shown below, and I have 3 endpoint attribute variables: 2 that are passed from the campaign event trigger, and the third one (Company) that will be generated by the CampaignHook lambda function. For the subject of the email, I used “Campaign Hook Demo Campaign“.

Create eMail Template

The email template can be found in this GitHub repository.

Create Campaign

Next, create your campaign and use the Segment and email Template that you created in the previous steps by following the instructions here.

Select the ‘when an event occurs’ option to trigger the campaign when an event occurs. (This option will trigger the campaign when a specific event occurs). Yoy may also schedule your campaign to run on a scheduled bases as available in the setup screen. I used ‘CampaignHookTrigger’ as my event name.

Create a campaign

Set your Campaign Start date, time and end date. I have left all the other settings to default and saved the campaign. Now that you have successfully created your first Campaign, you are ready for the next steps.

Set Campaign Start and End Times

Create the Lambda function

This is the function that we will configure to trigger the Amazon pinpoint campaign event . From the Lambda console page, create a new function by clicking on the ‘Create function’ button. You can then pick the following options and create the function.

Name: Campaign_event_trigger_function

Runtime: Python 3.9 or higher.

Replace the default script with the code from the GitHub repository, and then deploy your code by clicking on the “Deploy” button.

Assign permissions

In-order for the Lambda function trigger to trigger the Pinpoint Campaign, you will need to add an inline policy to the IAM role that is attached to your Lambda function, by selecting Pinpoint as the service and PutEvents from the Write options. You can select the Lambda function as the resource to which the access will be granted.

{

    "Version" :"2012-10-17",

    "Statement":[

        {

            "Sid": "VisualEditor0",

            "Effect": "Allow",

            "Action": [

                "mobiletargeting:PutEvents"

            ],

            "Resource":"ARN of your Lambda function goes here."

        }

    ]

}

Create the CampaignHook Lambda function

This is the function that we will triggered from the CampaignHook. From your Lambda console, click on “Create function” and enter the basic information as shown below to create your function.

Name: CampaignHookFunction

Runtime: Python 3.9 or higher.

Next replace your default code with the sample GitHub code, and then deploy your code by clicking on the “Deploy” button.

Assign permissions

Next add permissions for Amazon Pinpoint to invoke the Lambda function by running the command below from your Command Shell. Replace the Lambda function name and Account number with yours.

aws lambda add-permission \

--function-name [YourCampaignHookLambdaFunctionName] \

--statement-id my-hook-id1 \

--action lambda:InvokeFunction \

--principal pinpoint.us-east-1.amazonaws.com \

--source-arn 'arn:aws:mobiletargeting:us-east-1:[YourAccountNumber]:apps/*'

You can also do this from the Lambda console, by clicking on “Configuration” and then scrolling down to “Resource based Policy” and by clicking on “Add permissions“.

Update Campaign settings to add the Campaign Hook

Now that you have the Lambda function that needs to act as the hook is created, and granted Amazon Pinpoint service to invoke that function, run the command below to update the Campaign settings to add the Campaign Hook. You can also set a default CampaignHook for ALL campaigns in the project by setting the CampaignHook property on the Project Settings via this API.

Replace the application-id (project id), campaign-id, and the arn of the Campaign Hook lambda function and run the command below. (You can find the Project ID by clicking on All Projects at the top-left of the Pinpoint Console. The Campaign ID can be found by opening your Pinpoint Project and then clicking Campaigns in the Pinpoint Console.)

aws pinpoint   update-campaign --application-id /

[your-application-id-goes-here] –campaign-id /

[your-campaign-id-goes-here] --cli-input-json '{"ApplicationId": /

"","CampaignId": "","WriteCampaignRequest": {"Hook": {"LambdaFunctionName": /

"your-CampaignHook-Function-goes-here","Mode": "FILTER","WebUrl": ""}}}'

You can optionally run the command below to make sure that the campaign settings have been updated:

aws pinpoint get-campaign –application-id [your-application-id-goes-here]  –campaign-id [your-campaign-id-goes-here]

Test your Campaign.

Go back to your Lambda function that you have created to trigger the Campaign in the “Create the Lambda function” step above. I have used the test event as shown below. Update the Application id to reflect your Project id and change the email address to the email you verified earlier and click on “Test” button.

{

    "application_id": "your application id",

    "endpoint_id": "223",

    "event_type": "CampaignHookEvent",

    "nextTestDate": "12/15/2025",

    "FirstName": "Jack",

    "email": "[email protected]",

    "userid": "Jack123"

}

You should now receive an email with the variables replaced with the values that was passed from your json payload. Further you can see the Company name was added to the endpoint from the CampaignHook Lambda, which is passed to the email template. If you have not received the email, please check the following:

  • The Lambda function ran without any errors
  • The LambdaHook function has the proper rights assigned to be invoked from Pinpoint
  • The From and To email id that you have used are verified in SES.

Verify email identity

Clean up resources

Once you are satisfied with your setup and testing, you can now clean up the resources by following the steps below:

  • Delete your Amazon Pinpoint Project, Campaign and Segment.
    • aws pinpoint delete-campaign –application-id [your appl id] –campaign-id [your campaign id]
    • aws pinpoint delete-segment –application-id [your app id]  –segment-id [your segment id]
    • aws pinpoint delete-app –application-id [your app id]
  • Delete you Lambda functions
    • aws lambda delete-function –function-name CampaignHookFunction
    • aws lambda delete-function –function-name Campaign_event_Trigger_Function

Conclusion

By dynamically generating the attributes in real-time, customers can now add greater levels of personalization within a single user message template. By invoking a Lambda function, you can perform custom compute logic, calculate new attribute values, and access external data stores, to modify the campaign’s segment, right before Amazon Pinpoint sends the message. Campaign Hook feature makes this possible as explained in this blog by running few basic CLI commands to enable the feature on your Amazon Pinpoint Campaign. You can read more about Amazon Pinpoint Campaign from the user guide documentation”.

How to build LINE messaging into business communications

Post Syndicated from nnatri original https://aws.amazon.com/blogs/messaging-and-targeting/how-to-build-line-messaging-into-business-communications/

In today’s interconnected world, businesses need to communicate with their customers through multiple channels. This means using a variety of messaging apps, social media platforms, and other communication tools to reach customers where they are. One such platform that has gained immense popularity in select Asian markets is LINE. As the biggest social network in Japan, LINE offers businesses a unique opportunity to connect with customers in this region. Within Japan alone, LINE’s 2021 data shows 86 million users, constituting approximately 85% of Japan’s adult population. However, managing communication through multiple channels can be challenging for businesses.

That’s where Amazon Pinpoint comes in. Amazon Pinpoint is a flexible communication service for businesses that simplifies the process of sending targeted messages to customers across multiple channels. In this blog post, we’ll focus on how to integrate LINE with Amazon Pinpoint. This post is part of a series on integrating different communication channels with Amazon Pinpoint, and it is intended for both marketing operations and communication developers.

If you are already using LINE, this blog post will help you centralize management within Amazon Pinpoint. Additionally, if you are looking to integrate another messaging service with an open API, the steps outlined here will provide a helpful guide. Finally, if you’re a business looking to tap into Asian markets, this blog post is essential reading. By integrating LINE with Amazon Pinpoint, you’ll be able to reach your customers on the platform they are already using, providing seamless end-to-end customer engagements that will greatly enhances customer experience.

Note
Line is a third-party service that is subject to additional terms and charges. Amazon Web Services isn’t responsible for any third-party service that you use to send messages with custom channels.

Why Integrate LINE with Amazon Pinpoint?

Integrating LINE with Amazon Pinpoint has several benefits for businesses:

  • Centralized communication management: With LINE integrated into Amazon Pinpoint, businesses can centralize the management of outbound communication channels and simplify their communication workflows.
  • Increased flexibility for marketing campaigns: With LINE added as a custom channel in Amazon Pinpoint, businesses can create targeted messaging campaigns and reach customers through multiple channels, including LINE. Along with Pinpoint journeys, businesses can craft end-to-end customer engagement journeys that start from one channel and end in another.
  • Access to LINE’s popular messaging platform: With LINE integrated into Amazon Pinpoint, businesses can tap into the app’s massive user base in select Asian markets and engage with their customers through a popular and widely used messaging platform. Having access to LINE’s demographics of approximately 50% office workers with high penetration into 20s-30s age band, brands can tap into this high-spending power segment to drive revenue for their products.

Architecture

This solution uses Amazon Pinpoint,AWS Lambda, Amazon API Gateway, Amazon Simple Storage Service (Amazon S3), AWS Secrets Manager and LINE Messaging API

Line Pinpoint Solution Architecture

The solution architecture can be broken up into two main sections:

  • Steps 1-4 cover handling inbound user events and managing user data within Amazon Pinpoint.
  • Steps 5-8 cover how to send outbound campaigns via Amazon Pinpoint Custom Channel.
  1. The customer subscribes to the business’ LINE channel.
  2. The subscribe/unsubscribe event is received and checked via Amazon API Gateway.
  3. The edge-optimized Amazon API Gateway passes valid requests via a proxy integration to the backend Lambda.
  4. The backend Lambda compares the request body with the x-line-signature request header to confirm that the request was sent from the LINE Platform, as recommended by LINE API document. Afterwards, the Lambda function processes the user events:
    1. If the user subscribes to the channel, a new endpoint will be added to Amazon Pinpoint’s user database.
    2. If the user unsubscribes from the channel, the corresponding endpoint (identified by the LINE User ID) is deleted from Amazon Pinpoint’s user database.
  5. Amazon Pinpoint initiates a call to a Lambda function via Custom Channel with a payload. Of particular importance would be the Data field contained within the payload, which can be specified within the Amazon Pinpoint console to modify the content of the message.
  6. If the message contains image/audio/video files, the Lambda will request the file from the corresponding Amazon S3 buckets to be included for step 7. Amazon S3 then sends back the presigned URL containing the requested file(s).
  7. The Lambda function puts the message in the correct format expected by the LINE Messaging API and sends it over to the LINE Platform.
  8. The LINE Messaging API receives the request and processes the message content. If necessary, it will retrieve and download the file from Amazon S3 using the presigned URLs generated in step 6 then finally send the message to the corresponding user on the LINE Mobile App.

Step-by-Step Deployment Guide

Prerequisites

To deploy this solution, you must have the following:

  1. An AWS account, with the appropriate AWS CLI profile.
    • Named Profile: Run aws configure with the --profile option. The following steps assumed you have created a profile called line-integration to use with AWS CDK.
  2. Minimum Python v3.7, with pip and venv
  3. AWS CDK v2 installed.
  4. Docker Engine installed. You can download and install the appropriate Docker Desktop Distribution for your system via this link
  5. A LINE Account.
    • If you have never worked with LINE Messaging API before, you should login to to LINE Developers Console using one of the following accounts.
      • LINE account
      • Business account
    • Afterwards, you should create a new provider. Create Line provider
    • Within the provider page, you can then choose to create a new channel. For our Integration purposes, we will be choosing Messaging API channel type.
      Create Line channel

Preparation

The source code can be found in this GitHub Repository.

  1. Fork the GitHub Repo into your account. This way you can experiment with changes as necessary to fit your workload.
  2. In your local compute environment, clone the GitHub Repository and cd into the project directory.
  3. Run the following commands to create a virtual environment, activate it and install required dependencies.
python3 -m venv env \
&& source env/bin/activate \
&& python -m pip install -r requirements.txt

Deploy the CDK

  1. We can set the AWS CLI profile in CDK commands by adding the --profile flag. Run the following commands to bootstrap your AWS environment, synthesize the CDK template and deploy to your environment.
cdk bootstrap --profile LINE-integration \
&& cdk synth --profile LINE-integration  \
&& cdk deploy --profile LINE-integration 

Note
Enter y when prompted with Do you wish to deploy these changes (y/n)?

  1. After the deployment is done, the CDK template will output the API Gateway endpoint URL which takes the form of https://[********].execute-api.[region].amazonaws.com/prod/. Copy down this information as you will need it to set up the webhook connection later on.

Getting LINE Official Account Credentials

  1. Log in to LINE developer console.
    Login to Line account
  2. Once inside, choose the channel you’d like to have integrated with Amazon Pinpoint. This assumes that you’ve created a provider and a channel as mentioned in the Prerequisite section.
    Inside Line account console
  3. In the Basic settings tab, scroll down and note down the Channel Secret.
  4. In the Messaging API tab, scroll down and click on Edit under Webhook URL and enter the API Gateway endpoint URL you have noted down in step 5. Click on Update to save the changes.
    Line Webhook settings
    NOTE Once you have finished entering your Channel Secret token in step 14, you can return to this page to Verify your webhook URL is set up correctly).
  5. Finally, issue a Channel Access Token (at the bottom of the Messaging API tab) and note it down.
    Line channel access token settings

Registering Secrets in AWS Secrets Manager

  1. Navigate to the AWS Secrets Manager console. Make sure you’re in the same region as your CDK deployment region.
  2. Click on Secrets in the left side pane. You should find a secret with the name LINE_secrets
  3. Click on Retrieve Secret Value.
    Set Line secrets in Secrets Manager
  4. Then click on Edit:
    • Replace YOUR_CHANNEL_SECRET secret value with the channel secret you issued in step 10.
    • Replace YOUR_CHANNEL_ACCESS_TOKEN secret value with the access token you issued in step 10

Marketing Operations Demonstration

Once you’ve successfully deployed the CDK and configured your secrets, you can immediately get started sending communications campaign to your customers.

LINE supports multimedia messaging formats, meaning that you can choose to send texts, images, audio and even video files to your customers as part of your campaigns. You just need to make sure that your customers have subscribed to your channel.

Create a segment of subscribed users

The deployed solution has integrated user database management with Amazon Pinpoint so once users start subscribing to your LINE channel, they will be added as endpoints. To start filtering out who we should send to, you can create segments of your subscribers.

  1. Navigate to the Amazon Pinpoint console.
  2. On the All projects page, a project named Line-Pinpoint-Project has been created for you.
  3. On the left-side pane, choose Segments and then Create a segment.Create Segment
  4. Give your segment a descriptive name and add the appropriate criteria to filter down to your target audience (E.g.: filter down to customers who have Custom channel type).Set segment attributes
  5. Confirm the number of endpoints that you will be sending in the Segment estimate section matches your expectations and then choose Create segment.

Upload media files for campaign

If you’d like to use your own image, audio and video files for the campaign, follow along with this section. Otherwise, proceed to the Create Campaigns section (step 9).

Note
Depending on the media type, there are restrictions imposed such as maximum file size and file format extensions. You can find more information here.

  1. Navigate to the Amazon S3 console.
  2. Here you will find a list of buckets which corresponds to the type of media files you want to upload:
    • part-1-stack-images3bucket...: contains image files.
    • part-1-stack-audios3bucket...: contains audio files.
    • part-1-stack-videos3bucket...: contains both video and image cover files.
  3. Upload the corresponding files that you want to use for your campaign by choosing Upload.
    Asset bucket image

Create campaigns

  1. In the navigation pane, choose Campaigns, and then choose Create a campaign.
  2. Give your campaign a descriptive name. Under Campaign Type choose Standard campaign and under Channel, choose Custom. Click Next to confirm.
    Campaign Creation
  3. On the Choose a segment page, choose the segment that you created in step 5, and then choose Next.
  4. In Create your message, depending on the type of message that you want to send, choose the corresponding Lambda function. Your function should be named part-1-stack-send[text/image/audio/video]lambda...
    Choose Lambda function
  5. In the custom data section, you can choose to leave it blank, which will trigger the campaign to send the sample message.
  6. Otherwise, depending on the type of message, you can customize your campaigns to send the content that you want by inputting the following values into Custom Data.
    • Text Campaign: Enter the Text Message that you want to send.
    • Image Campaign: Enter the name of the image file you’ve uploaded in step 8 including the extension name (E.g.: sample_image.png)
    • Audio Campaign: Enter the name of the audio file you’ve uploaded in step 8 including the extension name and the duration of the audio file in milliseconds separated by a comma (E.g.: sample_audio.mp3,5000)
    • Video Campaign: Enter the name of the video file you’ve uploaded in step 8 including the extension name and the name of the image file you’ve uploaded in step 8 including the extension name, separated by a comma (E.g.: sample_video.mp4,sample_image.png)
  7. Choose Next and configure when to send the campaign depending on your needs. Once done, choose Next again.
  8. On the Review and launch page, verify all your information is correct and then click on Launch campaign.

That’s it! Your message will be sent through LINE to the designated recipients.

Cleanup

To delete the sample application that you created, use the AWS CDK.


cdk destroy

You’ll be asked:


Are you sure you want to delete: part-1-stack (y/n)?

Hit “y” and you’ll see your stack being destroyed.

What’s Next?

In conclusion, integrating LINE with Amazon Pinpoint provides businesses with a powerful tool to centralize their communication management, create more flexible marketing campaigns, and tap into LINE’s massive user base. With the step-by-step guide and demo provided in this blog post, you can easily get started with integrating LINE with Pinpoint and start leveraging its benefits for your business.

The solution presented in this blog post serves as a template that you can develop and customize to make it your own:

  1. Adding additional message types: The LINE messaging platform is famous for its rich messaging types and format. The deployed solution only utilized a fraction of what is available. You can add additional Lambda functions to send Stickers, Locations, Image Maps, Buttons or Carousel and more.
  2. Orchestrate LINE with other channels: Using Amazon Pinpoint Journeys, you can now meet the customer where they are most likely to see and respond to your message. Create a journey that starts with an SMS, send targeted communications based on yes/no or multivariate splits via emails and seal the deal with LINE. With Pinpoint and journey custom channel input and response support, you can craft the perfect omni-channel journey for your customers.
  3. Watch this space: Do stay tuned for the next blog post in this series, where we’ll show you how to manage inbound communications through LINE using Amazon Connect and Amazon Lex bots.

Push notification engagement metrics tracking

Post Syndicated from Pavlos Ioannou Katidis original https://aws.amazon.com/blogs/messaging-and-targeting/push-notification-engagement-metrics-tracking/

In this blog you will learn how to track and attribute Amazon Pinpoint push notification events for Campaigns and Journeys via API.

Amazon Pinpoint is a multichannel customer engagement platform allowing you to engage with your customers across 6 different channels. Amazon Pinpoint’s push notification channel, can send messages to your mobile app users via Firebase Cloud Messaging (FCM), Apple Push Notification service (APNs), Baidu Cloud Push, Amazon Device Messaging (ADM).

Push notifications is a preferable channel of communication as it notifies your app users even when they are not on your app. This increases app engagement and probability of customers to convert. Additionally, users who download your app but don’t register, can still be targeted and receive your messages.

Using Amazon Pinpoint’s push notification channel you can engage users with highly curated content. The messages can be personalized with customer data stored in Amazon Pinpoint, images, deep links and custom alert sounds – read more here. Amazon Pinpoint Campaigns and Journeys enable marketers to schedule communications, build multichannel experiences and for developers it offers a rich API to send messages. By default, all Amazon Pinpoint accounts are configured to send 25,000 messages per second, which can be increased by requesting a quota increase.

Measuring success of your communications is paramount for optimizing future customer engagements. Amazon Pinpoint push notifications offer the following three events:

  • _opened_notification – This event type indicates that the recipient tapped the notification to open it.
  • _received_foreground – This event type indicates that the recipient received the message as a foreground notification.
  • _received_background – This event type indicates that the recipient received the message as a background notification.

To track the above events from your mobile application, it is recommended using AWS Amplify’s push notification library which is currently available only in React Native.

Solution description

This blog provides an alternative for AWS Amplify for Amazon Pinpoint push notification tracking. Specifically, it utilizes Amazon Pinpoint’s Events API operation, which can be used to record events your customers generate on your mobile or web application. The same API operation can be used to record push notification engagement events.

The Events API operation request body is populated with the Campaign or Journey attributes received via the push notification payload metadata. These attributes help Amazon Pinpoint to attribute the events back to the correct Campaign or Journey

This blog provides examples of campaign, journey & transactional push notification payloads and how to correctly populate the Events API operation. Furthermore it shares an architecture to securely call Amazon Pinpoint’s API from your application’s frontend.

Prerequisites

This post assumes that you already have an Amazon Pinpoint project that is correctly configured to send push notification to your various endpoints using Campaigns or Journeys. Refer to the getting started guide and setting up Amazon Pinpoint mobile push channels for information on how to set up your Amazon Pinpoint project.

You will also need the AWS Mobile SDKs for the respective platform of your apps. The following are the repositories that can be used:

Implementation

The push notification payload received from the application differs between campaign, journey and transactional messages. This blog provides examples for campaign, journey and transactional message payloads as well as how to populate the Amazon Pinpoint Events API request body correctly to report push notification tracking data to Amazon Pinpoint.

Push notification message payload examples:

Campaign payload example:

{
   "pinpoint.openApp":"true",
   "pinpoint.campaign.treatment_id":"0",
   "pinpoint.notification.title":"Message title",
   "pinpoint.notification.body":"Message body",
   "data":"{\"pinpoint\":{\"endpointId\":\"endpoint_id1\",\"userId\":\"user_id1\"}}",
   "pinpoint.campaign.campaign_id":"5befa9dc28b1430cb0469554789e3f99",
   "pinpoint.notification.silentPush":"0",
   "pinpoint.campaign.campaign_activity_id":"613f918c7a4440b69b09c4806d1a9357",
   "receivedAt":"1671009494989",
   "sentAt":"1671009495484"
}

Journey payload example:

{
   "pinpoint.openApp":"true",
   "pinpoint.notification.title":"Message title",
   "pinpoint":{
      "journey":{
         "journey_activity_id":"ibcF4z9lsp",
         "journey_run_id":"5df6dd97f9154cb688afc0b41ab221c3",
         "journey_id":"dc893692ea9848faa76cceef197c5305"
      }
   },
   "pinpoint.notification.body":"Message body",
   "data":"{\"pinpoint\":{\"endpointId\":\"endpoint_id1\",\"userId\":\"user_id1\"}}",
   "pinpoint.notification.silentPush":"0"
}

Transactional payload example:

Note the transactional payload is the same for both messages sent to a push notification token and endpoint-id. Additionally the pinpoint.campaign.campaign_id is always set to _DIRECT.

{
   "pinpoint.openApp":"true",
   "pinpoint.notification.title":"Message title",
   "pinpoint.notification.body":"Message body",
   "pinpoint.campaign.campaign_id":"_DIRECT",
   "pinpoint.notification.silentPush":"0",
   "receivedAt":"1671731433375",
   "sentAt":"1671731433565"
}

Recording push notification events

To record push notification events from your mobile or web application, we will leverage the AWS Mobile SDKs or the Amazon Pinpoint Events API. To prevent inaccurate metrics such as double counting” it is recommended using the appropriate endpoint_id as Pinpoint uses this for de-duplication. Below you can find examples for both Events REST API and put_events AWS Python SDK – Boto3. Visit this page for more information on how to create a signed AWS API request.

Campaign event example – REST API:

Required fields: endpoint_id1, EventType, Timestamp, campaign_id and campaign_activity_id

POST https://pinpoint.us-east-1.amazonaws.com/v1/apps/<Pinpoint-App-id>/events

{
   "BatchItem":{
      "<endpoint_id1>":{
         "Endpoint":{}
       },
      "Events":{
         "<event_id>":{
            "EventType":"_campaign.opened_notification",
            "Timestamp":"2022-12-14T09:50:00.000Z",
            "Attributes":{
               "treatment_id":"0",
               "campaign_id":"5befa9dc28b1430cb0469554789e3f99",
               "campaign_activity_id":"613f918c7a4440b69b09c4806d1a9357"
            }
         }
      }
   }
}

Campaign event example – Python SDK:

Required fields: ApplicationId, endpoint_id, EventType, Timestamp, campaign_id and campaign_activity_id

import boto3 
client = boto3.client("pinpoint")
response = client.put_events(
  ApplicationId = <Pinpoint-App-id>,
  EventsRequest = { 
    "BatchItem": {
      "<event_id>": {
        "Endpoint": {},
        "Events": { 
          "<endpoint_id1>": { 
            "EventType":"_campaign.opened_notification",
            "Timestamp": "2022-12-14T09:50:00.000Z",
            "Attributes": {
              "treatment_id":"0",
              "campaign_id":"5befa9dc28b1430cb0469554789e3f99",
              "campaign_activity_id":"613f918c7a4440b69b09c4806d1a9357"
            }
          }
        }
      }
    }
  }
)
print(response)

Journey event example – REST API:

Required fields: endpoint_id, EventType, Timestamp, journey_id and journey_activity_id

POST https://pinpoint.us-east-1.amazonaws.com/v1/apps/<Pinpoint-App-id>/events

{
   "BatchItem":{
      "<endpoint_id1>":{
         "Endpoint":{}
      },
      "Events":{
         "<event_id>":{
            "EventType":"_journey.opened_notification",
            "Timestamp":"2022-12-14T09:50:00.000Z",
            "Attributes":{
               "journey_id":"5befa9dc28b1430cb0469554789e3f99",
               "journey_activity_id":"613f918c7a4440b69b09c4806d1a9357"
            }
         }
      }
   }
}

Journey event example – Python SDK:

Required fields: ApplicationId, endpoint_id1, EventType, Timestamp, journey_id and journey_activity_id

import boto3 
client = boto3.client("pinpoint")
response = client.put_events(
  ApplicationId = <Pinpoint-App-id>,
  EventsRequest = { 
    "BatchItem": {
      "<endpoint_id1>": {
        "Endpoint": {},
        "Events": { 
          "<event_id>": { 
            "EventType":"_journey.opened_notification",
            "Timestamp": "2022-12-14T09:50:00.000Z",
            "Attributes": {
              "journey_id":"5befa9dc28b1430cb0469554789e3f99",
              "journey_activity_id":"613f918c7a4440b69b09c4806d1a9357"
            }
          }
        }
      }
    }
  }
)
print(response)

Transactional event:

Amazon Pinpoint doesn’t support push notification metrics for transactional messages. Specifically, transactional messages don’t offer a field that can be used to attribute engagement events. These engagement events can still be recorded using the Amazon Pinpoint’s Events API. However, unlike Campaign & Journey events, the transactional push notification message payload doesn’t provide an identifier such as Campaign id or Journey Id that can be used as an Amazon Pinpoint event attribute for data reconciliation purposes.

Next steps

Requests to the Amazon Pinpoint Events API must be signed using AWS Signature version 4. We recommend using the AWS Mobile SDKs which handle request signing on your behalf. You can use the AWS Mobile SDKs with temporary limited-privilege Amazon Cognito credentials. For more information and examples, see Getting credentials.

 

About the Authors

Franklin Ochieng

Franklin Ochieng

Franklin Ochieng is a senior software engineer at the Amazon Pinpoint team. He has attained over 7 years experience at AWS building highly scalable system that solve complex problems for our customers. Outside of work, Frank enjoys getting out in nature and playing basketball or pool.

Pavlos Ioannou Katidis

Pavlos Ioannou Katidis

Pavlos Ioannou Katidis is an Amazon Pinpoint and Amazon Simple Email Service Senior Specialist Solutions Architect at AWS. He enjoys diving deep into customers’ technical issues and help in designing communication solutions. In his spare time, he enjoys playing tennis, watching crime TV series, playing FPS PC games, and coding personal projects.

How to send web push notifications using Amazon Pinpoint

Post Syndicated from arrohan original https://aws.amazon.com/blogs/messaging-and-targeting/how-to-send-web-push-notifications-using-amazon-pinpoint/

How to send push notifications on any website using AWS messaging tools

Web Push Notifications (also known as browser push notifications) are messages from a website you receive in your browser. These messages are intended to be rich, contextual, timely, personalized and best used to engage, re-engage, and retain website visitors. For instance, as a website owner you could use web push notifications to notify users about sales, important updates or new content on your website.

How are web push notifications different from native app push notifications?

Push notifications are short messages that are displayed directly on the user’s screen sent via mobile applications, providing timely information and messages like order status, promotions, or relevant news in the application.

Web push notifications are simply push notifications sent via web browsers (the browser application on the device), and they work across platforms – Desktop, mobile and tablet.  They are a newer channel than push notifications, and have now become a part of the modern marketing strategy alongside native app push notifications, emails and SMS.

In the case of mobile apps, the user must install the application to receive push notifications. In the case of web push, there is no need to download any software—it just takes one click on your website.

Why are Web Push Notifications useful?

Let’s consider a real-world example. Suppose you are an e-commerce website where customers can purchase products. Once, the purchase has been made, customers would be interested in getting real time updates of where the package is in transit, when is it likely to be delivered, a confirmation that the shipment has been delivered and so on. Web push notifications can be an excellent way of providing such updates. Accessing email on mobile devices is often unwieldy, SMS messages cannot support images and are constrained in length (also they typically they cost more money to send!). Push notifications are perfect for such a use case. Till now, the major constraint was that it would require users to install your app on their device. Web push notifications gives website owners and customers the power of push notifications without any need for driving app installs.

Marketers in a variety of sectors like travel, publishing, restaurant & delivery, finance and insurance can use push notifications to improve their down-to-funnel conversions.  From new content alerts to limited-time promotions to upcoming events, push messages are short, crisp and drive engagement, conversion, and retention. A short search on the AWS blogs website gives us a number of examples of businesses who have created value for their customers with the help of push notifications. Some of the key advantages of web push notifications are:

  • Easy opt in model: Unlike other marketing channels like email or SMS, web push notifications offer users a seamless opt-in experience ― Users simply select `Allow’ on a browser permission prompt. Users do not have to worry about sharing their personal data, like their name, email, or phone number nor do they have to go to the play store/app store and install an app on their device.
  • Increased Engagement:  Push notifications appear on a user’s desktop or mobile screen and are quick to grab attention. Since push messages are real time and have high visibility – they typically enjoy higher “Click Through Rate (CTR)” as compared to other channels like SMS or email.
  • Reach users even when they are not on your website: Web Push Notifications from your website are delivered and shown to the customer even if the user is visiting some other site or on some other app. In this respect (and most others), it is quite similar to app push notifications. Even if subscribers were offline when you sent your push campaign, they will get the push message delivered to them the next time they come online.
  • No need for users to install native apps: One of the most compelling reason for installing mobile apps, is because users could stay updated with the latest and the greatest – thanks to app push notifications. The additional cost of going to the play store/app store and installing the app is something which would often discourage users. This is especially true for countries and regions where users are still on lower end phones with limited storage space. Users would often have to uninstall apps (which might include yours too) that they do not use frequently in order to make space for other stuff.
  • Makes websites richer and more memorable: If you ask a room of developers what mobile device features are missing from the web, push notifications are always high on the list. This is no longer the case since browsers are increasingly adding support for web push notifications and this has offered website owners a powerful cross platform (Desktop & Mobile, Android & iOS) alternative as against developing and maintaining different native apps for different platforms. Web push notifications even appear quite similar to native mobile push on most smartphones.
  • Lower Cost: Unlike channels like SMS, sending web push notifications is absolutely free as browsers themselves offer support for it by adhering to the web push protocol. The only costs incurred will be that of sending push notifications as per the Pinpoint pricing policy.
  • Popular browsers support web push: Google Chrome, Firefox, Opera, Edge support web push on both Mobile and Desktop. What’s more the support for web push is continuously getting better. Refer to this link for the latest support status matrix across browsers and form factors.

What is Amazon Pinpoint?

Amazon Pinpoint is an AWS service that provides scalable, targeted multichannel communications. Amazon Pinpoint enables companies to send messages to customers through SMS, push notifications, in-app notifications, email, and voice channels. To learn more about Amazon Pinpoint, visit the website and documentation.

Web Push support on Firebase Cloud Messaging (FCM):

Firebase uses cloud services for its notification services on Android, iOS & Web. Firebase Cloud Messaging or FCM run on basic principles of tokens, which is uniquely generated for each device & later used for sending messages to respective devices. There are two key advantages of using FCM for sending web push notifications:

  • Abstracts away the complexity of onboarding to the web push protocol for push messages: Sending web push notifications directly without any third party in between requires your website to add support for the web push protocol. Adherence to the web push protocol requires website owners to perform some steps specific to wpn like adding VAPID headers and payload encryption of push messages. This would be additional work for website owners, especially for those businesses which are already onboarded to FCM for sending native app push notifications. FCM server side apis for sending web push notifications work pretty much the same way as they work for native apps. They abstract away the additional complexity of sending web push messages.
  • Send push notifications from Amazon Pinpoint via FCM: Amazon Pinpoint already supports integration with FCM, refer to documentation. Similar to how we add a FCM project in Pinpoint to send push messages to native android apps, in this blog post we will see how a similar integration can be leveraged to send web push notifications.

Advantages of sending Web Push Notifications with Amazon Pinpoint:

Now at this point, you might be thinking, Web push notifications can go a long way towards delighting customers and FCM already abstracts the complexities of sending web push. So why do I need Amazon Pinpoint?

Well, integration with Amazon Pinpoint offers a number of advantages. Here are a few:

  • Map FCM tokens to actual users and web app ‘installs’: FCM would give you tokens for each user on your website who subscribes for web push. Roughly speaking, an FCM token for each web app install with permissions to send push messages. To be able to send messages to these users we would need to store the FCM tokens for each user/web app install/browser instance. Amazon Pinpoint treats each browser instance as an endpoint and enables you to save the push tokens in the same way in which we would store native push tokens/mobile numbers/email addresses, i.e., as a primary identifier for that endpoint. This enables us to send messages to Pinpoint endpoints without caring about the underlying complexity of storing and managing push tokens.
  • Intelligently send web push, map user attributes to push tokens: Along with the push token, each pinpoint endpoint can also store other attributes like device characteristics, user Id and user attributes. This helps us to create dynamic and complex segments which can be used to send targeted web push notifications.
  • It is essentially the same as sending android native push: Create an FCM project, create FCM tokens, Create Pinpoint endpoints with the tokens, send push campaigns to those endpoints. Swap out native android code with service workers, JavaScript on the client and you get web push. It really is that simple.
  • Web push, native push, SMS or emails. One stop shop for reaching out to users on all channels: Pinpoint becomes your single backend for reaching out to users across multiple channels. For app users, send them app push, for users who prefer the web, you have web push.
  • Leverage Pinpoint features like Campaign Management, Events, Analytics and Segments: Read up about Amazon Pinpoint. It has a lot of great features which can help you better engage your users.

In this blog we will see how to send web push notifications using Amazon Pinpoint on a website built using AWS Amplify.

 Overview of solution

Enable web push by using FCM as an intermediary service and Pinpoint as an app server (map FCM tokens to actual users) and a push campaign management tool. Integrate web push protocol, FCM and Amazon Pinpoint.

Overview of how to setup Web Push - registering the customer

Overview of how to setup Web Push - sending push notifications

Walkthrough

In this blog post, we will create a simple demo website using Amplify which can be used to create web push subscriptions and also receive web push messages. We will integrate this website with FCM js sdk and Amazon Pinpoint to store the FCM push tokens on Pinpoint. Later we will see how to send web push notifications using Amazon Pinpoint with FCM acting as an intermediary.

The above can be broken down into the below simple and independent steps:

  • Create a project on FCM.
  • Generate web push notifications server keys on FCM.
  • Create a simple web app (website) using Amplify
  • Create an Amazon Pinpoint project. This is a one-line command which will be done as part of Amplify web app setup.
  • Make your amplify website web push capable. In this step we will also integrate with the FCM sdk for web push.
  • Configure the Pinpoint project and integrate it with FCM. It just involves adding the FCM server key to Pinpoint.
  • Go to the Amazon Pinpoint console and send a test web push message from your website. And we are done!

You can see checkout my demo website here.

The source code for this demo website (and the blog) is available here.

Prerequisites – Essentials

For this walkthrough, you should have the following prerequisites:

Prerequisites – Recommended

In addition to the necessary prerequisites mentioned above, I would highly recommend readers to go through the below in order to derive maximum value from this blog post.

  • Web Push fundamentals: Some basic reading up on web push notifications and going through a couple of relevant code samples. It is not compulsory to implement and understand everything, but it would be beneficial to have an elementary understanding of service workers, permissions, push subscriptions and notifications apis.
    • Introduction: Some of the sections are a bit detailed and complex, you need not go through all the sections completely at once. However, at least go through the overview and the how push works sections carefully.
    • Simple Code demo with explanations to help you get started.
  • FCM client-side code : You need not go through the send Message sections since we will not directly use FCM apis or the console. Instead, we will use the Pinpoint console to manage our push campaigns.
  • Building web apps with amplify: By the end of the tutorial, you should get clarity on how to build and host web apps using amplify. It will also help you become familiar with the amplify cli tool.
  • Read up on Amazon Pinpoint.

Setting up the demo web app

Let’s deploy the demo web app using AWS Amplify to see how all the parts come together.

Clone the code for the sample web app

git clone ssh://git.amazon.com/pkg/ArrohanWebPushPoc (branch: PinpointBlog) <github_link>

Create an FCM account and a project on the FCM developer console, on the FCM project add web push as a channel

It is possible that Firebase may change the UI of the console in the future so the given screenshots may not be exactly reflective of the UI, but the broad steps would remain the same.

  • Under “Engage”  click on ‘Cloud Messaging Tab’.  The page url should typically be of the form: https://console.firebase.google.com/u/0/project/<name_of_your_project>/notification.

Setting up web push - Getting the firebase push config

  • Under the option “Add an app to get started”, Click on the “web/javascript” (the one with the </> symbol) app.
  • Once you have created the project,  go to project settings. Click on General Tab. Replace the values in firebaseConfig main.js with the actual values for your project.

Setting up web push - Copying the firebase push config

Setting up web push - Code pointer for the firebase push config

Generate a public-private key pair for the FCM cloud messaging project

  • Under project settings, switch to the cloud messaging tab. Click generate key pair under web push certificates to generate a public-private key pair.

Setting up web push - Generate a public-private vapid key pair

  • Replace the <YOUR PUBLIC KEY> in the file main.js in the source code with the vapid public key you generated in the previous step.

Setting up web push - Copying the FCM server key

  • Note the Server key, you will need it during pinpoint project setup.

Setup an Amplify web app and integrate with pinpoint

  • Clone the code in the given repo, replace your FCM config and keys. Run npm install.
    • In case you face build errors due to package versions getting outdated (firebase, especially gets updated often, sometimes with breaking changes), please update the dependencies to the latest version. This post offers an easy way to identify outdated dependencies and update them.
  • Setup an Amplify web app. Note, for the purpose of this demo, you just need to setup a simple static website. Simply run amplify init. Enter the required details, the default config should work fine.

Setting up the example app for web push using Amazon Pinpoint

  • Create a pinpoint project and integrate with our web app through amplify cli:
    • Create a pinpoint project: Run amplify add analytics. Choose Amazon Pinpoint as the analytics provider and accept all defaults.
    • Please note when you add “analytics” to the project you will get a prompt which says something like – “Apps need authorization to send analytics events. Do you want to allow guests and unauthenticated users to send analytics events? (We recommend you allow this when getting started)” – Please accept and answer Yes when you get this.
    • Push to AWS: Run amplify push. A configuration file (aws-exports.js) will be added to the source directory. Notice, we are calling this file from our main.js file.

Setting up the example app for web push using Amazon Pinpoint

Pinpoint Project setup

  • Get the Server key of the FCM project you created earlier.

Setting up web push - Add FCM key to Pinpoint console

Run the web app and subscribe for push notifications

  • Run npm start, our web app will be running on http://localhost:8080/index.html
  • Click on enable push messages and click allow/accept on the browser permission prompt which follows. Once it is enabled, you will see a FCM token on the page, copy the token.

How the example app looks

Send a web push notification from the Amazon Pinpoint console

  • Open the pinpoint project you created in the previous step on the Pinpoint console. Click on your project and then go to test messaging. The process is exactly the same as the one for native apps described here. Under “destination type” select “Device Tokens” and paste the FCM token you copied in the previous step.

Sending a web push from the Pinpoint console

  • Fill in title, body and optionally URL (“Go to a URL” under “Actions”). Click on Send Message, you should get a push message on your browser.

How an example web push notification looks like on Desktop

Next steps

  • Host your app. Simply run amplify add hosting followed by amplify publish. Remember that for web push (service workers) to work, your site should be https.

Deploying the example app for web push using AWS Amplify

  • Create segments, campaigns and journeys on pinpoint and try sending web push messages through them.

Code Walkthrough

  • Gitfarmlink: https://code.amazon.com/packages/ArrohanWebPushPoc/trees/heads/PinpointBlog
  • File wise description:
    • package.json: Simple npm config file. It includes the list of dependencies and their versions used by our web app. For our use case, all we need is webpack and AWS Amplify.
    • package-lock.json: Auto generated config file generated by npm after resolving modules and package.json.
    • aws-exports.js: Auto generated configuration file created by Amplify cli. This file contains the configuration and endpoint metadata used to link your front end to your backend services. It will be structured similar to the sample config file.
    • webpack.config.js: Simple webpack configuration file
    • src: The folder which contains the source code for our web app. It contains:
      • service-worker.js: The service worker that we register for our website which is used to display push notifications. In the service worker we parse the notification payload sent through pinpoint and call the notification apis to display push notification with the appropriate fields.
      • index.html: The website html.
      • main.js: The heart of the web app. It does permission handling, push subscription management and communicates with FCM and Amazon Pinpoint.
      • images/icon-192×192.png: static icon that we display on our push messages. This would essentially be your website logo.

Conclusion

This small demo shows how we can send web push notifications using Amazon Pinpoint. As next steps to come up with an actual production ready solution, you can look into the following:

  • Develop deeper understanding and expertise on web push
  • Richer and smarter push notification: Add big images, action buttons, replace notifications using tags (for example, sports score updates) and explore other features in the show notifications api.
  • Smart push notifications: add custom business logic in the payload. Hint: use the “body” (“pinpoint.notification.body“) field on the pinpoint console to send a custom json string.
  • Driving more subscriptions: Leverage Amplify Analytics to track how users interact with the push subscribe UI. Think of where and how you might ask users to subscribe to drive maximum engagement.
  • Easy unsubscribe: Allow users an easy option to disable push notifications without having to block you from browser settings. Also, make sure that you are disabling that endpoint on pinpoint. Hint: use the updateEndpoint api and pass optOut from ‘ALL’ as the argument.
  • Targeted and personalised push notifications: Leverage Pinpoint segments to send users push notifications according to their interests and requirements. Hint: add user data to endpoints and use it to filter and create targeted segments.
  • Campaign management: Leverage pinpoint features like segments, analytics, campaigns, journeys and more!

Project Cleanup

In this section we will quickly go over the steps to delete the resources we created for this demo to make sure that we do not incur any charges.

  • Cleaning up all AWS resources including the Amazon Pinpoint project, S3 buckets for hosting (and any other resources you may have added): Simply run amplify delete from the project directory on your command line.
  • Cleaning up the FCM Project: Refer to the FCM support page for the steps to delete a project – https://support.google.com/firebase/answer/9137886 .
    • Open the project settings page: The URL will be of the form https://console.firebase.google.com/u/0/project/<your_project_identifier>/settings/general
    • Click on the delete project button at the bottom of the page.

Build AI and ML into Email & SMS for customer engagement

Post Syndicated from Vinay Ujjini original https://aws.amazon.com/blogs/messaging-and-targeting/build-ai-and-ml-into-email-sms-for-customer-engagement/

Build AI and ML into Email & SMS for customer engagement

Customers engage with businesses through various channels like email, SMS, Push, and in-app. With the availability and ease of usage of mobile phones, businesses can use 2-way Short Service Messages (SMS) to engage with their customers. Text messaging does not need applications and provides immediate interaction with your customers. Amazon Pinpoint enables businesses & organizations to interact in 2-way SMS messages with their customers. Since it is not practical and scalable for organizations to have people responding to millions of their customer’s texts, we can leverage Amazon Lex which helps build the conversational AI into the 2-way SMS. Amazon Lex is a fully managed artificial intelligent (AI) AWS service with advanced natural language models to design, build, test, and deploy conversational interfaces in applications. Machine Learning (ML) is used in digital marketing to help businesses detect patterns in customer bhevaior.

Today, if customers want to know the latest status on their order, they have to send an email, which is hard for businesses to monitor and respond, and time consuming for the customer to call regarding their order status and also expensive for businesses to field the calls.

This blog post shows how you can elevate your customer’s experience using Amazon Pinpoint’s omni-channel capabilities, Amazon Lex’s AI powered chat, and ML-powered personalization using Amazon Personalize.

The solution presented in this blog helps resolve all the above issues. The example I have used to depict this where a customer orders a bike and since the delivery has been delayed, he wants to get timely updates on the progress. He has been given a phone number by the bike company to text them with any questions. This solution elevates the customer’s experience by providing him with timely update by checking the latest from the database and also sending additional product recommendations, predicting what the customer might need.

Architecture

This solution uses Amazon Pinpoint, Amazon Lex, AWS Lambda, Amazon Dynamo DB, Amazon Simple Notification Services, Amazon Personalize.

AWS architecture diagram AI/ML, Email, SMS.

  1. The customer sends a message to the number provided by the store asking about their order status.
  2. Pinpoint 2-way SMS has as SNS topic tied to it.
  3. The SNS topic relays the message to the Lex integration Lambda.
  4. This Lex integration lambda has the integration between Pinpoint & Lex.
  5. When the customer checks on their order status, Lex taps into the fulfillment lambda that is tied to it.
  6. That lambda checks on the order status from the DynamoDB and sends it back to Lex.
  7. Lex sends the order details to Amazon Pinpoint and Amazon Pinpoint delivers the SMS with the order details to the customer’s phone number.
  8. Amazon Lex lets fulfillment Lambda know to send an email to the customer with the order details.
  9. Fulfillment Lambda create an event called ‘Order Status’ for Amazon Pinpoint Journey to consume in its Journey.
  10. Amazon Pinpoint’s message template reaches out to Amazon Personalize to get the 3 recommendations.
  11. Amazon Pinpoint’s Journey triggers an email message to the customer with the order information and recommendations

Prerequisites

To deploy this solution, you must have the following:

  1. An AWS account.
  2. An Amazon Pinpoint project.
  3. An originating identity that supports 2 way SMS in the country you are planning to send SMS to – Supported countries and regions (SMS channel).
  4. A mobile number to send and receive text messages.
  5. An SMS customer segment – Download the example CSV, that contains a sample SMS & email endpoints. Replace the phone number (column C) with yours, and email with your email and import it to Amazon Pinpoint – How to import an Amazon Pinpoint segment.
  6. Add your mobile number in the Amazon Pinpoint SMS sandbox.
  7. Verify your email address that needs to receive messages from this account.
  8. Download the LexIntegration.zip & RE_Order_Validation.zip Lambda files from this Github location.

Preparation:

  1. Download the CloudFormation template.
  2. Go to Amazon S3 console and create a bucket. I created one for this example as ‘pinpointreinventaiml-code’. Under that S3 bucket, create a sub-folder and name it Lambda.
  3. Upload the 2 zip files you downloaded earlier from the Github.
  4. In Amazon Pinpoint > Phone numbers, Check to make sure the phone number you are using is enabled for SMS and its status is active.
  5. Add the machine learning generated product recommendations using Amazon Personalize.
Check if phone number is enabled & active in Pinpoint console

Phone numbers in Pinpoint console

Solution implementation

Create a Lex Chat bot:

  1. Now it’s time to create your bot. To create your bot, sign in to the Lex console at https://console.aws.amazon.com/lex.
  2. For more information about creating bots in Lex, see https://docs.aws.amazon.com/lex/latest/dg/gs-console.html.
  3. Click on Create bot button. Next steps:
    1. Select Create a blank bot radio button.
    2. Give a Bot name ‘Order Status’ under Bot name Configuration. (Use the same Bot name as mentioned here. If you change the Bot name here, your CloudFormation will fail)
    3. Under IAM permissions, select the radio button Create a role with basic Amazon Lex permissions.
    4. For COPPA, choose No. Click Next
    5. Under Language dropdown, choose the language of usage. I chose Language as English in my example.
    6. Click Done, to complete the Bot creation.
  4. You have to create an Intent within the Bot you just created
    1. Click on the Bot you just created. Click on Intents and click the dropdown Add intent and select Add empty intent.
    2. Give an intent name and click Ok.
  5. Once the intent is created, go to the intent and open the Conversation flow section in the intent and create a flow that that has the following info and looks like below image:
    1. Click on Sample utterance and it takes you to Sample Utterance and type in Order status.
    2. Click on initial response and type in Okay, I can help with that. What is your order number?
    3. Click on the slot value and click on Add a slot. Name: OrderNumber and Slot type is AMAZON.AlphaNumeric. In the prompt, enter Please enter your order number.
    4. Click on Save Intent button. The conversation flow should look like the below screenshot:

Amazon Lex intent

6. Go back to the Intent you just created and click on the Build button that is to the right side of the page.

Build intent

7. Once the build is successfully completed, go back to the Bot you created and click on Aliases on the left frame. Click on the Alias that was created earlier, TestBotAlias.

Bot Alias

8. In the Languages section, click on the English language that we created earlier.
9. Open the Lambda function – optional section and point the source to RE_Order_Validation Lambda that we downloaded earlier.
10. For Lambda function version or alias, select $LATEST. Click on Save.

Add Lambda to Alias

11. Go to Intents, choose the intent you just built and click on Build button again. Once build is complete, you can test the intent.

Import and execute CloudFormation:

  1. Navigate to the Amazon CloudFormation console in the AWS region you want to deploy this solution.
  2. Select Create stack and With new resources. Choose Template is ready as Prerequisite – Prepare template and Upload a template file as Specify template. Upload the template downloaded in step 1 under Preparation section of this document. Click Next.
  3. Fill the AWS CloudFormation parameters as shown below:
  4. Stack name: Give a name to this stack.
    1. Under Parameters, for BotAlias: The Bot Alias that you created as part of Amazon Lex above.
    2. BotId: The Bot ID for the bot that you created as part of Amazon Lex above.
    3. CodeS3Bucket: Give the name of the S3 bucket you created in step3 of the Preparation topic above.
    4. OriginationNumber: This is the origination identity phone number you created in step4 of the Preparation topic above.
    5. PinpointProjectId: Use the ProjectID you have from step2 of the Prerequisites phase above.
  5. After entering all the parameter info, it would look something like this below:
  6. CloudFormation parameters
  7. Click Next. Leave the default options on the next page and click Next again.
  8. Check the box I acknowledge that AWS CloudFormation might create IAM resources with custom names. Click Submit.

Set up data in Amazon Dynamo DB

  1. We are using DynamoDB table here as the transactional database that stores order information for the bike store.
  2. Once the solution has been successfully deployed, navigate to the Amazon DynamoDB console and access the OrderStatus DynamoDB table. Each row created in this table represents an order and it’s details. Each row should have a unique Order_Num that holds the order number and it’s related information. You can put additional information about the order like the example below:
  3. {
       "Order_Num":{
          "Value":"ABC123"
       },
       "Delivery_Dt":{
          "Value":"12/01/2022"
       },
       "Order_Dt":{
          "Value":"11/01/2022"
       }
       "Shipping_Dt":{
          "Value":"11/24/2022"
       }
       "UserId":{
          "Value":"example-iser-id-3"
       }
    }
  4. Once you enter the data, it should look like the image below. Click on Create item.
  5. Dynamo DB values

Set up Amazon Simple Notification Service (SNS) topic

  1. We need the Amazon Simple Notification Service here, to provide internal message delivery from publishers (customer’s text message) to subscribers (Amazon Lex in this example). This is used for internal notifications in this use case.
  2. As part of the CloudFormation above, check if you have an SNS topic created by the name LexPinpointIntegrationDemo.
  3. Now, we have successfully created an Amazon SNS topic.

Set up Lambda Functions

  1. Go to AWS Lambda console and open the Lambda function LexIntegration. Under the Function overview, click on the Add trigger. Under Trigger configuration dropdown, select SNS and under SNS Topic select LexPinpointIntegrationDemo topic. Click on Add.
  2. Note: In this example, I used Node.js in a Lambda and Python in another, to show how AWS Lambda functions are flexible to use the scripting language of your choice.

Setting up 2-way SMS in Amazon Pinpoint

  1. Go to Amazon Pinpoint console and click on Phone numbers under SMS & Voice in the left frame. If you don’t see any phone numbers, please refer to #3 under prerequisites section above.
  2. This is how your screen should look like
  3. Phone numbers in Pinpoint
  4. Click on the number.
  5. On the right frame, expand Two-way SMS drop down arrow.
  6. Click on the check box ‘Enable two-way SMS’.
  7. In the ‘Incoming message destination’ select the radio button ‘Choose an existing SNS topic’ and in the drop down below, choose the SNS topic you built above.
  8. The result would look like the screenshot below:
  9. 2-way SMS
  10. Click on Save.

Import Machine Learning model into Pinpoint

  1. Go to Amazon Pinpoint.
  2. Click on Machine Learning Models. Click on Add recommender model.
  3. Give a recommender model name and description under model details.
  4. Under Model configuration, choose the radio button ‘Automatically create a role’ and give an IAM role name in the textbox below.
  5. Under recommender model, choose the recommender model campaign that you created in Amazon Personalize earlier in the project.
    1. If you did not create it, use this Pinpoint workshop to create a recommender model in Amazon Personalize.
    2. The data used in this example is for retail industry, please edit the data as needed for your use case and industry.
  6. Under the settings section:
    1. Select ‘User Id’ as identifier.
    2. Click on the drop down ‘Number of recommendations per message’ and select 3.
  7. For Processing method, choose ‘Use value returned by model’.
  8. Click on Next.
  9. You are presented with attributes section. Give a display name as ‘product_name’ for the attributes and click next.
  10. On the next screen, you can review all the information provided and click on Publish.
  11. The completed model after publishing looks like the screen below:
  12. Personalize model in Pinpoint

Create a Message Template in Amazon Pinpoint

  1. Use chapter 6.4 in this workshop Amazon Pinpoint Workshop to create a message template.
  2. Once the template is created, you need to add recommendations to the message template using this Amazon Pinpoint Workshop details. Change the type of data needed for your use case and industry in this workshop. I used sample retail data.
  3. To create a Amazon Pinpoint Journey, navigate to the Amazon Pinpoint console , select Journeys and click on Create journey.
  4. Give a name, click on Set entry condition in the Journey entry block.
  5. Choose the radio button Add participants when they perform an activity.
  6. Click in the ‘Events’ text box and type in OrderStatus.
  7. Pinpoint Journey entry
  8. Click on Add activity and select Send an email.
  9. Click on choose an email template and select the email message template we created earlier in this blog. Click on choose template button.
  10. Select a Sender email address from the drop down list.
  11. Choose sender email here
  12. Click Save. The final journey should look like this:
  13. This is the final journey
  14. Click on Actions > Settings where you will review the journey settings. There you set the start and end date of the journey if applicable as well as other advanced settings. Configure your journey settings to look like the screenshot below and click Save.
  15. Journey settings
  16. To publish your journey click on Review. On the Review your journey click Next > Mark as reviewed > Publish. A 5 minutes countdown will begin after, which your journey will be live.
  17. Once the journey is live, we need to pass the event OrderStatus and the endpoints will go through that journey and will receive an email.

Testing the solution

  1. Use a phone with a valid number (in this example, I took a US phone number) and send a text ‘Order Status’ to the number generated in Amazon Pinpoint above.
  2. You should get a response “Okay, I can help with that. What is your order number?”
  3. You should type in the order number you generated earlier and stored it in Amazon DynamoDB table.
  4. You should get a response “Your order <order number> was shipped on <shipped_dt> and is expected to be delivered to your address on <delivery_dt>. Your order details have been emailed to you.”
  5. Text message flow
  6. Alternatively, you can test this solution from the Lex bot.
  7. In Amazon Lex, go to the intent you created above and click on the Test button. Next steps:
    1. In the text box, enter Order Status.
    2. Bot should respond with Okay, I can help with that. What is your order number?
    3. You can respond with the order number you entered in the DynamoDB table.
    4. Bot should respond with Your order <Order_Num> was shipped on <Shipping_Dt> and is expected to be delivered to your address on <Delivery_Dt>. Your order details have been emailed to you.
    5. Testing the 2 way messaging in Lex console

Conclusion

Using this blog post, you can elevate your customer’s experience by using Amazon Lex’s AI chat capabilities, Amazon Personalize’s ML recommendation models and trigger a Pinpoint Journey. This blog highlights how organizations can interact in a 2-way SMS with their customers and convert that engagement to a triggered email, with product recommendations, if needed.

Next Steps

You can use the above solution and modify it easily to use it across different verticals and applicable use cases. You can also extend this solution to Amazon Connect to an agent via SMS chat, using this blog.

Clean-up

  1. To delete the solution, go to CloudFormation you created as part od this project. Click on the stack and click Delete.
  2. Navigate to Amazon Pinpoint and stop the Journey you ran in this solution. Delete the Journey, Machine learning models, Message templates you created for this solution. Delete the Project you created for this solution.
  3. In Amazon Lex, delete the intent and bot you created for this solution.
  4. Delete the folder and bucket you created in S3 as part of this project.
  5. Amazon Personalize resources like Dataset groups, datasets, etc. are not created via AWS Cloudformation, thus you have to delete them manually. Please follow the instructions in the AWS documentation on how to clean up the created resources.

Additional resources

Retry delivering failed SMS using Pinpoint

How to target customers using ML, based on their interest in a product

 About the Authors

Vinay Ujjini

Vinay Ujjini is an Amazon Pinpoint and Amazon Simple Email Service Principal Specialist Solutions Architect at AWS. He has been solving customer’s omni-channel challenges for over 15 years. In his spare time, he enjoys playing tennis & cricket.

An elastic deployment of Stable Diffusion with Discord on AWS

Post Syndicated from Steven Warren original https://aws.amazon.com/blogs/architecture/an-elastic-deployment-of-stable-diffusion-with-discord-on-aws/

Stable Diffusion is a state-of-the-art text-to-image model that generates images from text. Deploying text-to-image models such as Stable Diffusion can be difficult. Currently, Stable Diffusion requires specific computer hardware known as graphical processing units (GPUs). You can lower the bar to entry by offloading the text-to-image generation onto Amazon Web Services (AWS).

Discord is a popular voice, video, and text communication service. It provides a user interface that people can use to make text-to-image requests. When deployed, all members of a Discord server can create images by using Discord Slash Commands.

In this post, we discuss how to deploy a highly available solution on AWS. This solution will perform text-to-image generation with Stable Diffusion and use Discord as the user interface.

Solution architecture

Many of the services selected are serverless, which will offer many benefits. At the time of writing, Stable Diffusion requires a GPU for inference. Amazon Elastic Compute Cloud (Amazon EC2) was selected because it provides GPUs. The solution architecture is shown in the Figure 1.

Solution architecture diagram

Figure 1. Solution architecture diagram

Let us walk through the architecture of this solution.

Auto scaling with custom metrics

To properly scale the system, a custom Amazon CloudWatch metric is created. This custom CloudWatch metric calculates the number of Amazon Elastic Container Service (Amazon ECS) tasks required to adequately handle the amount of Amazon Simple Queue Service (Amazon SQS) messages. You should have a high-resolution CloudWatch metric to scale up quickly. For this use case, a high-resolution CloudWatch metric of every 10 seconds was implemented.

Next, let’s create the custom CW metric. Amazon EventBridge rules provide a serverless solution for starting actions on a schedule. Here we use an Amazon EventBridge rule, which initiates an AWS Step Function Express Workflow every minute. With the Express Workflow, we can create serverless workflows that take less than five minutes, which helps us avoid long running AWS Lambda functions. The Express Workflow runs a Lambda function every 10 seconds over a one-minute period, which generates the custom CloudWatch metric.

Two high-resolution CloudWatch alarms scale the system up and down, and are initiated by the custom CloudWatch metric. One CloudWatch alarm increases the ECS tasks and EC2 machines. The other alarm decreases the ECS tasks and EC2 machines.

Handling Discord requests

Someone on Discord sends a request. The Amazon API Gateway HTTP API receives the request and passes the information to an AWS Lambda function. The HTTP API provides a cost-effective option compared to REST APIs and provides tools for authentication and authorization. The HTTP API uses cross-origin resource sharing (CORS), which provides security because it only allows discord.com as an origin.

The AWS Lambda function provides a serverless solution for responding to the HTTP API requests. It transforms the HTTP API request and sends a message to the SQS First-In-First-Out (FIFO) queue. SQS seamelessly decouples the architecture between user requests and backend processing. A FIFO queue ensures that user requests are processed in the order they were requested. The AWS Lambda function sends a response back to the HTTP API within three seconds, which is a requirement of Discord Slash Commands.

When scaling up, an EC2 instance is registered with the ECS cluster. The EC2 instance type was selected because it provides GPU instances. ECS provides a repeatable solution to deploy the container across a variety of instance types. This solution currently only uses the g4dn.xlarge instance type. The ECS service will then place an ECS task onto the eligible EC2 instance. The ECS task will use the Amazon Elastic Container Registry (Amazon ECR) private registry to pull the image,  perform text-to-image processing, and respond to the Discord request. The ECR private registry is a managed container registry that manages the image.

Once there is an ECS task running on an Amazon EC2 instance, the ECS task will consume messages from the queue using long polling. This reduces the amount of ReceiveMessage requests the ECS task needs to send. When the ECS task receives a message from the queue, it will then processes the request.

Estimated monthly cost

The example assumes 1,000 requests per month and each request takes 16 seconds to complete. Extra EC2 time was added for the time to begin processing messages (seven minutes) and auto scaling cooldown time (30 minutes). You can adjust the pricing calculations with the AWS Pricing Calculator to reflect your usage and estimated cost.

Prerequisites

This blog assumes familiarity with Terraform, Docker, Discord, Amazon EC2Amazon Elastic Block Store (Amazon EBS)Amazon Virtual Private Cloud (Amazon VPC), AWS Identity and Access Management (IAM), Amazon API Gateway, AWS Lambda, Amazon SQS, Amazon Elastic Container Registry (Amazon ECR), Amazon ECS, Amazon EventBridge, AWS Step Functions, and Amazon CloudWatch.

For this walkthrough, you should have the following prerequisites:

  • Access to an AWS account, with permissions to create the resources described in the installation steps section
  • A virtual private cloud (VPC) with public subnets that is associated with an internet gateway in the region you are deploying into
    We suggest using the default VPC. The subnets will need the tag of key: Tier and value: Public and be attached to the VPC. If you decided to create your own VPC with subnets, make sure that auto-assign IP settings is enabled.
  • An IAM user with the required permissions to deploy the infrastructure
  • A new Discord application that is registered to a Discord server you own with the scope applications.command. Use this tutorial if you need a starting point on creating a Discord application.
    • Discord Bot token
    • Discord Application ID
    • Discord Public Key
  • A Hugging Face account
  • A computer with the following packages installed:

Walkthrough

Complete the following steps to deploy this solution on AWS.

Increase EC2 limits

This solution uses the g4dn.xlarge instance type, which might require you to request an EC2 limit increase. Check your current limit of Running On-Demand All G and VT instances. Make sure you have more than 4 vCPU; a single g4dn.xlarge requires 4 vCPU. We suggest requesting 8 vCPU so that you can access 2 g4dn.xlarge instances.

Deploy the infrastructure

  1. Ensure you have at least 60 GB of storage available and you’re running on a 64-bit x86 architecture system.
  2. Open a command line on the machine you will be deploying from.
  3. Log in as your AWS user through the AWS CLI with the command aws configure. If you are using an EC2 instance, create and use an instance profile rather than using the AWS CLI.
    The region you select will be the one you will deploy into.
  4. Clone the Terraform repository:
    git clone https://github.com/aws-samples/amazon-scalable-infra-discord-diffusion.git
  5. Navigate into the Terraform repository:
    cd amazon-scalable-infra-discord-diffusion
  6. Customize the variables in terraform.tfvars to match your deployment.
  7. Export the following secrets to the command line:
    • export TF_VAR_discord_bot_secret='DISCORD_BOT_SECRET_HERE'
    • export TF_VAR_huggingface_password='HUGGINGFACE_PASSWORD_HERE'
  8. Initialize the repository:
    terraform init
  9. Apply the infrastructure (this takes about 2 minutes):
    terraform apply
  10. Save the outputs for future use.

Set up Discord

This setup adds the Discord interactions URL to your Discord application. After terraform apply comes back successfully, move onto these steps.

  1. Open Discord Application Page -> General Information.
  2. Copy and paste the value from discord_interactions_endpoint_url into the Interactions Endpoint URL, and then save the changes.

If successful, there should be a green box with All your edits have been carefully recorded.

Docker image and Amazon Elastic Container Registry

In this section, you will create a docker image with the Stable Diffusion model.

  1. Exit the terraform repository:
    cd ..
  2. Clone the Docker build repository:
    git clone https://github.com/aws-samples/amazon-scalable-discord-diffusion.git
  3. Navigate to the Docker repository:
    cd amazon-scalable-discord-diffusion
  4. Build and push the docker image to ECR. This requires docker to be installed on the machine and actively running.
    You can find the commands for your deployment from the Amazon ECR repository.

    View push commands for Amazon ECR

    Figure 2. View push commands for Amazon ECR

This is a large image (10GB) and can take over 20 minutes to push depending on your machine’s internet connection.

Request an image with Discord Slash Commands

This section will describe how to request a text to image response with Discord.

  1. Log in to Discord and navigate to the server with your Discord application deployed.
  2. Navigate to a text channel.
  3. Type the command /sparkle.
    A box with COMMANDS MATCHING /sparkle will appear. Select the /sparkle command box.
    Depending on how you customized your Discord Application, the avatar image shown in Figure 3 might be different from what you have.

    Writing a Discord Slash Command

    Figure 3. Writing a Discord Slash Command

  4. Type in a prompt such as a corgi, style of monet.
    A response from YourBotName should appear with the response Submitted to Sparkle: YourPromptHere, as shown in Figure 4.

    First response from AWS Lambda function

    Figure 4. First response from AWS Lambda function

    It will take 10 minutes for an EC2 instance to start with an ECS Task running on the instance. Once an ECS Task is running on the instance, inference times should reduce to under 30 seconds, depending on the request.
    When an ECS Task is running your request, you will see a Processing your Sparkle message, as shown in Figure 5.

    Amazon ECS task processing a request

    Figure 5. Amazon ECS task processing a request

    The message is complete when it says Completed your Sparkle! as shown in Figure 6.

    Amazon ECS task returning the final response

    Figure 6. Amazon ECS task returning the final response

Cleaning up

To avoid incurring future charges, delete the resources created by the Terraform script.

  1. Return to the directory where you deployed your terraform script.
  2. To destroy the infrastructure in AWS, run the command terraform destroy.
  3. When prompted to confirm that you want to destroy the infrastructure, type yes and press Enter.

Conclusion

In summary, we created a solution that allows members of a Discord server to create images from text with a Stable Diffusion model. With this implementation, the deployment can scale to many Discord Servers and handle over one hundred requests per second.

Create projects on AWS that lower the bar to entry for people wanting to try text to image models.