Cfhighlander is a feature rich tool and DSL for infrastructure coders working with CloudFormation templates.
It was designed to
-
Abstract AWS resources or sets of resources as components by describing them using Cfhighlander DSL and cfndsl.
-
Produce, validate and publish CloudFormation templates from those components
-
Enable infrastructure coders to use concepts of inheritance and composition when designing components. In other words allowing components to be extended, and allowing components to be built from other components.
-
Allow for easy discovery and consumption of components from different sources (git repository, file system, S3 buckets)
-
Allow component developers and consumers to take more descriptive approach using DSL, compared to instructional approach.
gem install cfhighlander
Passing output value from one substack to another substack within root stack
has to be done manually - either if you build JSON/YAML templates by hand,
or if using Cfndsl
. With cfhighlander, this code is automatically generated for you
## place contents below in file name application.cfhighlander.rb
CfhighlanderTemplate do
# explicit configuration for vpc component
vpc_config = { 'maximum_availability_zones' => 2 }
# declare vpc component, and pass some parameters
# to it
Component name: 'vpc',
template: 'vpc@master.snapshot',
config: vpc_config do
parameter name: 'Az0', value: FnSelect(0,FnGetAZs())
parameter name: 'Az1', value: FnSelect(1,FnGetAZs())
parameter name: 'DnsDomain', value: 'example.com'
parameter name: 'StackMask', value: '16'
end
# Compiled cloudformation template will
# pass Compute subnets from VPC into ECS Cluster
Component name: 'ecs', template:'ecs@master.snapshot' do
parameter name: 'DnsDomain', value: 'example.com'
end
# feed mapping maparameters to components
addMapping('EnvironmentType',{
'development' => {
'MaxNatGateways'=>'1',
'EcsAsgMin' => 1,
'EcsAsgMax' => 1,
'KeyName' => 'default',
'InstanceType' => 't2.large',
'SingleNatGateway' => true
}
})
end
... compile the template with ...
cfcompile application
... and check how the subnets are being passed around ..
$ cat out/yaml/application.compiled.yaml | grep -A3 SubnetCompute0
SubnetCompute0:
Fn::GetAtt:
- vpc
- Outputs.SubnetCompute0
SubnetCompute1:
Fn::GetAtt:
- vpc
As part of theonestack org, there are many publicly available components.
-
vpc - Has separation of public and private subnets, configurable number of NAT Gateways (per AZ or single for all subnets), lays out default subnets (private - compute, storage and cache, public), as well as their route tables
-
ecs - ECS Cluster deployed in VPC Compute Subnets
-
bastion - Deployed into VPC Public subnets Subnets, with configuration for whitelisting IP addresses to access port 22
-
ecs-service - Deploy containerised apps running on ECS Clusters
-
loadbalancer - ALB, ELB or NLB
-
sns - SNS Topics, with implemented Lambda function to post Slack messages
-
efs - Elastic File System, can be used in conjuction with ECS Cluster
-
rds-mysql - RDS Component for MySQL engine
-
rds-postgres - RDS Component for Postgres engine
-
aurora-mysql - Aurora component for MySQL engine
-
aurora-postgres - Aurora component for Postgres engine
-
elasticache-memcache - Aws Elasticache - Memcache engine
-
elasticache-memcache - Aws Elasticache - Redis engine
-
asg - AutoScalingGroup component
-
cognito - Cognito user pools, custom domain names and clients
You can easily test any of these. Automatic component resolver will default to 'https://github.com/theonestack/hl-component-$name' location if component is not found in local sources.
From shell, command below will generate cloudformation for given component in out
folder
cfcompile component_name
Or from outer cfhighlander template, just pull component using Component
DSL statement
CfhighlanderTemplate do
Component component_name
end
Highlander DSL produces CloudFormation templates in 4 phases
- Processing referenced component's configuration and resolving configuration exports
- Wiring parameters from components to their inner components
- Producing CfnDsl templates for all components and subcomponents as intermediary step
- Producing resulting CloudFormation templates using configuration and templates generated in two previous phases.
Each phase (aside from parameter wiring) above is executable as stand-alone through CLI, making development of Highlander templates easier by enabling debugging of produced configuration and cfndsl templates.
Highlander component is located on local file system or S3 location with following files defining them
- Highlander DSL file (
$componentname.highlander.rb
) - (Optional) Configuration files (
*.config.yaml
) - (Optional) CfnDSL file (
componentname.cfnds.rb
) - (Optional) Mappings YAML files
*.mappings.yaml
- this file defines map used within component itself - (Optional) Mappings extension file
componentname.mappings.rb
- see more under Mappings section - (Optional) Ruby extensions consumed by cfndsl templates - placed in
ext/cfndsl/*.rb
- see more under Extensions section
Component is basic building block of highlander systems. Components have following roles
- Define (include) other components
- Provide values for their inner component parameters
- Define how their configuration affects other components
- Define sources of their inner components
- Define publish location for both component source code and compiled CloudFormation templates
- Define cfndsl template used for building CloudFormation resources
Outer component is component that defines other component via cfhighlander dsl Component
statement. Defined component
is called inner component. Components defined under same outer component are sibling components
You can either pull highlander classes in your own code, or more commonly use it via command line interface (cli). For both ways, highlander is distributed as ruby gem
$ gem install cfhighlander
$ cfhighlander help
cfhighlander commands:
cfhighlander cfcompile component[@version] -f, --format=FORMAT # Compile Highlander component to CloudFormation templates
cfhighlander cfpublish component[@version] -f, --format=FORMAT # Publish CloudFormation template for component, and it' referenced subcomponents
cfhighlander configcompile component[@version] # Compile Highlander components configuration
cfhighlander dslcompile component[@version] -f, --format=FORMAT # Compile Highlander component configuration and create cfndsl templates
cfhighlander help [COMMAND] # Describe available commands or one specific command
cfhighlander publish component[@version] [-v published_version] # Publish CloudFormation template for component, and it' referenced subcomponents
All templates and configuration generated are placed in $WORKDIR/out
directory. Optionally, you can alter working directory
via CFHIGHLANDER_WORKDIR
environment variable.
To get full list of options for any of cli commands use highlander help command_name
syntax
$ cfhighlander help publish
Usage:
cfhighlander publish component[@version] [-v published_version]
Options:
[--dstbucket=DSTBUCKET] # Distribution S3 bucket
[--dstprefix=DSTPREFIX] # Distribution S3 prefix
-v, [--version=VERSION] # Distribution component version, defaults to latest
Publish CloudFormation template for component,
and it's referenced subcomponents
Cfhighlander DSL processor has built-in support for packaging and deploying AWS Lambda functions. Some of these lambda functions may require shell command to be executed (e.g. pulling library dependencies) prior their packaging in ZIP archive format. Such commands are potential security risk, as they allow execution of arbitrary code, so for this reason user agreement is required e.g:
Packaging AWS Lambda function logMessage...
Following code will be executed to generate lambda function logMessage:
pip install requests -t lib
Proceed (y/n)?
In order to avoid user prompt pass -q
or --quiet
switch to CLI for commands that require Lambda packaging
(dslcompile
, cfcompile
, cfpublish
)
cfcompile will produce cloudformation templates in specified format (defaults to yaml). You can optionally validate
produced template via --validate
switch. Resulting templates will be placed in $WORKDIR/out/$format
cfcompile will produce cloudformation templates in specified format (defaults to yaml), and publish them to S3 location.
You can optionally validate produced template via --validate
switch. Resulting templates will be placed in $WORKDIR/out/$format
, and
published to s3://$distributionBucket/$distributionPrefix/$distributionVersion
. All S3 path components can be controlled
via CLI (--dstbucket
, --dstprefix
, -v
). Default distribution bucket and prefix can be also be controlled via DSL using
DistributionBucket
, DistributionBucket
, DistributionPrefix
or ComponentDistribution
statements. Check DSL specification
for more details on this statements. Version defaults to latest
if not explicitly given using -v
switch
If no distribution options is given using mentioned CLI options or DSL statements,
bucket will be automatically created for you. Bucket name defaults to
$ACCOUNT.$REGION.cfhighlander.templates
, with /published-templates
prefix.
cfpublish command will give you quick launch CloudFirmation stack URL to assist you in creating your stack:
$ cfpublish vpc@1.2.0
...
...
...
Use following url to launch CloudFormation stack
https://console.aws.amazon.com/cloudformation/home#/stacks/create/review?filter=active&templateURL=https://123456789012.ap-southeast-2.cfhighlander.templates.s3.amazonaws.com/published-templates/vpc/1.2.0/vpc.compiled.yaml&stackName=vpc
configcompile produces configuration yamls that are passed as external configuration when processing cfndsl templates. Check component configuration section for more details.
dslcompile will produce intermediary cfndsl templates. This is useful for debugging cfhighlander components
publish command publishes cfhighlander components source code to s3 location (compared to cfpublish which is publishing
compiled cloudformation templates). Same CLI / DSL options apply as for cfpublish command. Version defaults to latest
Within each template, following configuration values are available by default in both cfhl and cfndsl templates
template_name
- Name of the cfhighlander templatetemplate_verison
- Version of the cfhighlander component template usedtemplate_dir
- Disk location of the cfhighlander template. Can be used to reference local files within component, and does work with component inheritance
There are 4 levels of component configuration
- Component local config file
component.config.yaml
(lowest priority) - Outer component configuration file, under
components
key, like
# some configuration values
components:
vpc:
config:
maximum_availibility_zones: 2
This configuration level overrides component's own config file.
Alternatively, to keep things less nested in configuration hierarchy, creating config file vpc.config.yaml
for component named vpc
works just as well:
# contents of vpc.config.yaml in outer component, defining vpc component
# line below prevents component configuration file being merged with outer component configuration
subcomponent_config_file: true
# there is no need for components/vpc/config structure, it is implied by file name
maximum_availibility_zones: 3
- Outer component explicit configuration. You can pass
config
named parameter toComponent
statement, such as
CfhighlanderTemplate do
# ...
# some dsl code
# ...
Component template:'vpc@latest',config: {'maximum_availibility_zones' => 2}
end
Configuration done this way will override any outer component config coming from configuration file
- Exported configuration from other components. If any component exports configuration using
config_export
configuration key, it may alter configuration of other components. Globally exported configuration is defined underglobal
, while component-oriented configuration is exported undercomponent
key. E.g. following configuration will export global configuration defining name of ecs cluster, and targeted to vpc component configuration, defining subnets
ecs_cluster_name: ApplicationCluster
subnets:
ecs_cluster:
name: ECSCluster
type: private
allocation: 20
config_export:
global:
- ecs_cluster_name
component:
vpc:
- subnets
Configuration is exported AFTER component local config, and outer component configurations are loaded. Outer component configuration takes priority over exported configuration, as this configuration is loaded once more once component exported conifgurations are applied to appropriate components.
To change NAME of targeted component (e.g. from vpc
to vpc1
), you can use export_config
named parameter on Component
dsl method
In addition to configuration in inner component above, wiring of targeted component for export would be done like
Component name: 'vpc1', template: 'vpc'
Component name: 'ecs_cluster', template: 'ecs_cluster@latest', export_config: {'vpc' => 'vpc1'}
CloudFormation Mappings section matches a key to a corresponding set of named values. Highlander allows you to define this mappings in two ways
- By using static maps defined through YAML files. Place
*.mappings.yaml
file alongside with highlander template to define mappings this way. Mappings defined in a static way are automatically rendered withing CloudFormation template E.g.
# Master component mappings
# envtype.mappings.yaml
EnvironmentType:
dev:
InstanceType: t2.medium
prod:
InstanceType: m4.medium
- By defining mappings dynamically through Ruby code. Alongside with mappings, you can define default map name, and default
map key to be used when looking up value within this map. This mappings are usually rendered in outer component when inner
components pulls mapping value as parameter via
MappingParam
statement. Optionally, this mappings can be rendered within component that defines them usingDynamicMappings
DSL statement.
In order to make template more DRY, template developer may reuse ruby functions. It is possible to place
such functions in separate files. Any ruby files placed within ext/cfndsl
directory will get automatically
included via Ruby require
function in compiled Cfndsl template.
Inner components or subcomponents are defined via Component
DSL statement
CfhighlanderTemplate do
# Example1 : Include component by template name only
Component 'vpc'
# Example2 : Include component by template name, version and give it a name
Component template: 'ecs@master.snapshot'
end
Conditional components - If you want to add top level paramater as feature toggle for one of the inner
components, just mark it as conditional, using conditional:
named parameter. In addition to this, default
value for feature toggle can be supplied using enabled:
named parameter. Autogenerated parameter will be named
Enable$COMPONENTNAME
, defaulting to [true,false]
as set of allowed values. Autogenerated condition will
be named same as parameter, and checking if the parameter value equlas true
# Include vpc and 2 ecs clusters with feature flags
CfhighlanderTemplate do
# vpc component
Component 'vpc'
# Ecs Cluster 1 has feature toggle, enabled by default
Component name: 'ecs1', template: 'ecs', conditional: true
# Ecs Cluster 2 has feature toggle, and is explicitly disabled by default
Component name: 'ec2', template: 'ecs', conditional: true, enabled: false
end
Override default behaviour - If you have more than 1 stack you want to control with a single parameter, or you want to change
parameter name, you can supply the condition:
option with a string value on each component you want to control with the condition.
Autogenerated condition can be overriden as well, by defining your own condition with the same name on the highlander
template, as in example below.
CfhighlanderTemplate do
# [Optional - Define your own condition, instead of default true/false one]
Condition 'EnableDevelopmentResources', FnEquals(Ref(:EnvironmentName),'dev')
# Components always required
Component 'vpc'
Component name: 'ecs', template: 'ecs'
# Components only required in development environments with common condition name
Component name: 'linux-bastion', template: 'bastion', conditional: true, condition: 'EnableDevelopmentResources', enabled: false
Component name: 'windows-bastion', template: 'bastion', conditional: true, condition: 'EnableDevelopmentResources', enabled: false
end
Convert config value to parameter - In case of inner component having configuration value you wish to expose as runtime parameter, it is possible to do so with limitation that configuration value is only used in resource declarations, as property value. If configuration value is being used to control the dsl flow, taking part in any control structure statements, and such gets evaluated at compile time, there is no sense of making CloudFormation stack parameter out of it.
Below example demonstrate use of ConfigParameter
statement on simple S3 Bucket component -
it assumes that s3bucket
template exists with bucketName
as configuration value for it.
CfhighlanderTemplate do
Component template: 's3bucket', name: 'parameterizedBucket' do
ConfigParameter config_key: 'bucketName', parameter_name: '', type: 'String'
end
end
Parameters block is used to define CloudFormation template parameters, and metadata on how they are wired with outer or sibling components.
CfhighlanderTemplate do
Parameters do
##
## parameter definitions here
##
end
end
Parameter block supports following parameters
ComponentParam
- Component parameter exposes parameter to be wired from outer component. Cfhighlander's
autowiring mechanism will try and find any stack outputs from other components defined by outer components with name
matching. If there is no explicit value provided, or autowired from outputs, parameter will be propagated to outer component.
Propagated parameter will be prefixed with component name if it is not defined as global parameter. Otherwise, parameter name is kept in full.
Example below demonstrates 3 different ways of providing parameter values from outer to inner component.
- Provide value explicitly
- Provide value explicitly as output of another component
- Autowire value from output of another component with the same name
- Propagate parameter to outer component
# Inner Component 1
CfhighlanderTemplate do
Name 's3'
Parameters do
ComponentParam 'BucketName','highlander.example.com.au'
ComponentParam 'BucketName2',''
ComponentParam 'BucketName3',''
ComponentParam 'BucketName4','', isGlobal: false # default value is false
ComponentParam 'BucketName5','', isGlobal: true
end
end
# Inner Component 2
CfhighlanderTemplate do
Name 'nameproducer'
# has output 'bucket name defined in cfdnsl
end
# -- contents of cfndsl
CloudFormation do
Condition 'AlwaysFalse', FnEquals('true','false')
S3_Bucket :resourcetovalidateproperly do
Condition 'AlwaysFalse'
end
Output('BucketName') do
Value('highlanderbucketautowired.example.com.au')
end
end
# Outer component
CfhighlanderTemplate do
Component 'nameproducer'
Component 's3' do
parameter name: 'BucketName2', value: 'nameproducer.BucketName'
parameter name: 'BucketName3', value: 'mybucket.example.cfhighlander.org'
end
end
Example above translates to following wiring of parameters in cfndsl template
CloudFormation do
# Parameter that was propagated
Parameter('s3BucketName4') do
Type 'String'
Default ''
NoEcho false
end
Parameter('BucketName5') do
Type 'String'
Default ''
NoEcho false
end
CloudFormation_Stack('s3') do
TemplateURL './s3.compiled.yaml'
Parameters ({
# Paramater that was auto-wired
'BucketName' => {"Fn::GetAtt":["nameproducer","Outputs.BucketName"]},
# Parameter that was explicitly wired as output param from another component
'BucketName2' => {"Fn::GetAtt":["nameproducer","Outputs.BucketName"]},
# Paramater that was explicitly provided
'BucketName3' => 'mybucket.example.cfhighlander.org',
# Reference to parameter that was propagated. isGlobal: false when defining
# parameter, so parameter name is prefixed with component name
'BucketName4' => {"Ref":"s3BucketName4"},
# Reference to parameter that was propagated. isGlobal: true when defining
# parameter, so parameter name is not prefixed, but rather propagated as-is
'BucketName5' => {"Ref":"BucketName5"},
})
end
end
Components have pre defined parameters with properties such as Type, AllowedValues, NoEcho etc. These properties can be overridden on the parent component.
CfhighlanderTemplate do
Paramater do
ComponentParam 'EnvironmentType', 'development', allowedValues: ['development','alpha','production']
end
Component 'ecs' do
parameter name: 'EnvironmentType', allowedValues: ['development','alpha','production']
parameter name: 'Ami', value: '/ssm/path/Ami', type: 'AWS::SSM::Parameter::Value<AWS::EC2::Image::Id>'
end
end
MappingParam
- Mapping parameters value is passed as CloudFormation mapping lookup from outer component.
This DSL statements takes a full body, as Mapping name, Map key, and value key need to be specified. key
,
attribute
and map
methods are used to specify these properties. Mapping parameters involve ruby code execution
# Inner component
CfhighlanderTemplate do
Name 's3'
Parameters do
MappingParam 'BucketName' do
map 'AccountId'
attribute 'DnsDomain'
end
end
end
DependsOn
- this will include any globally exported libraries from given
template. E.g.
CfhighlanderTemplate do
Name 's3'
DependsOn 'vpc@1.0.3'
end
Will include any cfndsl libraries present and exported in vpc template so extension methods can be consumed within cfndsl template.
If you require dependencies between nest stacks, this can be defined in the component by using the dependson
attribute with the value of the depend component names. This will take an array of component names or a string with a single component name. This adds the cloudformation DependsOn
property to the stack resource in the master template.
CfhighlanderTemplate do
Name 'test'
Component name: 'vpc', template: 'vpc'
Component name: 'bastion', template: 'bastion'
Component name: 'ecs', template: 'ecs', dependson: ['vpc','bastion']
end
Cfhighlander supports following in terms of lambda source code management
- Package and deploy lambda that has source code published to s3 as zip archive
- Package and deploy lambda that has source code published to http(s) url
- Package and deploy lambda with absolute source code location, or relative to component root directory
- When extending certain highlander component, of
- Execute arbitrary 'package command' before creating final archive. This allows for downloading code dependencies
Lambda functions are defined in cfhighlander templates using LambdaFunctions
DSL statement:
CfhighlanderTemplate do
Name 'my_app'
LambdaFunctions 'highlanderdocoexample'
end
In example above, lambdas
- value passed to LambdaFunctions
dsl statement is actually
cfhighlander component configuration key, under which lambda functions, and their respective
IAM roles are defined. Consider configuration below - all keys are commented with explanation
highlanderdocoexample:
# custom policies can be referenced in roles
custom_policies:
cognito:
action:
- cognito-idp:*
resource: '*'
# at least one role must be defined
roles:
default:
# using one of the default policies, or custom policies defined above
# defined at https://github.com/theonestack/cfhighlander/blob/develop/cfndsl_ext/config/managed_policies.yaml
policies_inline:
- cloudwatch-logs
- cognito
# managed IAM policies are supported as well
policies_managed:
- arn:aws:iam::aws:policy/IAMReadOnlyAccess
- Fn::Sub: 'arn:aws:iam::${AWS::AccountId}:policy/my_app_policy'
# you can have multiple functions defined, each as key under 'functions'
functions:
myapp:
# link to a role key above defined - mandatory
role: default
# code location. Can be file, archive, s3://url or http(s)://url.
# mandatory configuration option
code: src/app.py
# lambda runtime
runtime: python3.6
# functions that are not named are having their name auto generated via cloudformation
# this key defaults to false if not given
named: true
# if function is named, either top level key (myapp) will be used, or explicit name
# this key is optional, and used only if named: is set to true
function_name:
Fn::Sub: '${EnvironmentName}-myapp-${EnvironmentVersion}'
# function timeout (defaults to 30)
timeout: 30
# lambda function entrypoint
handler: app.index
# command to install any dependencies (optional)
# if you don't want to get prompted for every command execution use -q (quiet) option
package_cmd: 'pip3 install -r requirements.txt -t .'
# creates a log group with cloudformation and sets the retention period in days
# if not set lambda will create the log group with a unlimited retention
# note that if lambda has already created a log group, it will need to be deleted
# before this can be updated.
log_retention: 30
# (optional) allowed source. e.g. invocation using SNS
# for every allowed source, source_arn can be provided optionally
allowed_sources:
-
principal: sns.amazonaws.com
-
principal: sns.amazonaws.com
source_arn: arn:aws:sns:us-east-2:123456789012:my-topic
# (optional) invoke function on a schedule, with optional payload
schedules:
- cronExpression: 'rate(1 minute)'
payload: '{ "message": "ping" }'
During cfhighlander compilation process, every defined lambda functio goes through process of packaging:
- If s3 URI or http(s) uri is given as function code, it is being downloaded
- Temporary packaging directory is created
- If
package_cmd
key is given, this command is being executed in temporary directory - Whole temporary directory is compressed and moved to
out/lambdas/$function.$timestamp.zip
- Sha256 hash is calculated for given file and rendered into cloudformation as function version
- Packaging information is rendered into
out/lambdas/$function.$timestamp.zip.info.yaml
and added to final archive
Any archive with *.zip
extension will be uploaded to s3 with cfpublish
command
As all of the lambda functions are rendered as cloudformation resources, they can be referenced in other blocks. E.g. with example above, application component could have following output defined in component's cfndsl file
# myapp.cfndsl.rb
CloudFormation do
Output('MyAppFunctionName') do
Value(Ref('myapp'))
end
end
If you need to publish additonal files along with your cloudformation templates you can use the following DSL:
CfhighlanderTemplate do
Name 'my_app'
PublishArtifact file: "my-apigateway-spec.yaml"
end
This will upload the file my-apigateway-spec.yaml
to the s3 destnation/distribution bucket using the default s3 prefix. If you want to override the s3 key you can use
CfhighlanderTemplate do
Name 'my_app'
PublishArtifact file: "my-apigateway-spec.yaml", key: '/my-custom-path/my-custom-file.yaml'
end
Templates are located by default in following locations
$WD
$WD/$componentname
$WD/components/$componentname
~/.cfhighlander/components/componentname/componentversion
https://github.com/cfhighlander/theonestack/hl-component-$componentname
onmaster
branch
Location of component templates can be given as git/github repo:
CfhighlanderTemplate do
# pulls directly from master branch of https://github.com/theonestack/hl-component-vpc
Component name: 'vpc0', template: 'vpc'
# specify branch github.com: or github: work. You specify branch with hash
Component name: 'vpc1', template: 'github:theonestack/hl-component-vpc#master'
# you can use git over ssh
# Component name: 'vpc2', template: 'git:git@github.com:theonestack/hl-component-vpc.git'
# use git over https
Component name: 'vpc3', template: 'git:https://github.com/theonestack/hl-component-sns.git'
# specify .snapshot to always clone fresh copy
Component name: 'vpc4', template: 'git:https://github.com/theonestack/hl-component-sns.git#master.snapshot'
# by default, if not found locally, highlander will search for https://github.com/theonestack/component-$componentname
# in v${version} branch (or tag for that matter)
Component name: 'vpc5', template: 'vpc@1.0.4'
end
Rendering component resources in resulting cloudformation stack is available in 2 modes. These modes
are controlled using render
keyword of Component
DSL statement
Substack
- creates additional substack for cfhighlander component and points to it using CloudFormation
Stack resource type
This is also default render mode - if no render mode is specified Substack
will be used
Inline
- places all defined resources from inner component in outer component cloudformation template. Resources,
Outputs, Conditions, Parameters and Mappings are all inlined - please note that some of the template elements may be renamed in this
process in order to assure unique names.
There are some limitations when using inline components - Inlined component parameters, having values as outputs from another component (inlined or not) can't be referenced in component conditions. However, conditions referencing mapping values or parameters passed as mapping values, are allowed.
SIDE EFFECTS
Side effect of moving from substack based to fully inlined stack may be revealing some of the implicit dependencies within an environment
Example: Component A defines Hosted Zone, while component B defines Record Set for given hosted zone. Record set is defined by referencing Zone Name (rather than ZoneId), meaning there is no explicit dependency between the resources. When both components are rendered as substack, implicit dependency is created if there is at least one output from component A passed as parameter to component B. Rendering components inlined removes this implicitly defined dependency, as a consequence stack deletion or creation may be halted, as record set is being created/deleted before prior the record set.
WARNING
Be aware of resource, condition, parameter, output and mapping limits on a single template
when rendering inner components inlined.
EXAMPLE
All of the VPC resources will be rendered in outer component template, while bastion
will be referenced as substack in example below.
CfhighlanderTemplate do
Component template:'vpc@1.5.0', name: 'vpc', render: Inline
Component template:'bastion@1.2.0', name: 'bastion', render: Substack
end
$ cfhighlander cfcompile [component] [-v distributedversion]
Any extensions placed within cfndsl_ext
folder in core library code are
available in cfndsl templates of all components. Any extensions placed within hl_ext
in core library code are
available in cfhighlander templates of all components.
CFHIGHLANDER_WORKDIR
- defaults to $PWD, determines location of 'out' folder where all of the
generated files are placed
CFHIGHLANDER_AWS_RETRY_LIMIT
- defaults to 10. Number of retries for AWS SDK before giving up.
AWS SDK uses exponential backoff to make the API calls
Tests are designed for testing different configuration options on components.
They can be defined as my_test.test.yaml
files in the tests/
directory.
Each test file represents a single test configuration which is then compiled
and validated against AWS cloudformation api.
test metadata needs to defined as bellow with at least a name:
. Other key:values are for documentation.
test_metadata:
type: config
name: queues with config overrides
description: Create 2 queues with name and override available config
If you want to test a component with a parameter input you can specify the test-parameters:
key with key:value pairs of parameters
# Define the test parameter
test_parameters:
SecurityGroupId: sg-123456789
# Test configuration
security_group_rules:
-
from: 22
protocol: tcp
security_group_id:
# use the parameter within our test
Ref: SecurityGroupId
desc: ssh access from another security group
$ cfhighlander cftest [component] [options]
Usage:
cfhighlander cftest component[@version] -f, --format=FORMAT
Options:
-d, [--directory=DIRECTORY] # Tests directory
# Default: tests
-t, [--tests=one two three] # Point to specific test files using the relative path
[--dstbucket=DSTBUCKET] # Distribution S3 bucket
[--dstprefix=DSTPREFIX] # Distribution S3 prefix
-f, --format=FORMAT # CloudFormation templates output format
# Default: yaml
# Possible values: yaml, json
[--validate], [--no-validate] # Optionally validate template
# Default: true
-q, [--quiet], [--no-quiet] # Silently agree on user prompts (e.g. Package lambda command)
# Default: true
-r, [--report=REPORT] # report output format in reports directory
# Possible values: json, xml
Test Highlander component with test case config
By default test will print the output to stdout. You can output to a file with a format of xml or json using the -r
option