![AWS logo] (claws.png)
A comprehensive Clojure client for the entire [Amazon AWS api] 1.
Leiningen coordinates:
[amazonica "0.1.32"]
For Maven users:
add the following repository definition to your pom.xml
:
<repository>
<id>clojars.org</id>
<url>http://clojars.org/repo</url>
</repository>
and the following dependency:
<dependency>
<groupId>amazonica</groupId>
<artifactId>amazonica</artifactId>
<version>0.1.32</version>
</dependency>
- [Autoscaling] (#autoscaling)
- [CloudFormation] (#cloudformation)
- [CloudFront] (#cloudfront)
- [CloudSearch] (#cloudsearch)
- [CloudWatch] (#cloudwatch)
- [DataPipeline] (#datapipeline)
- DirectConnect
- [DynamoDB] (#dynamodb)
- [DynamoDBV2] (#dynamodbv2)
- [EC2] (#ec2)
- ElastiCache
- ElasticBeanstalk
- [ElasticLoadBalancing] (#elasticloadbalancing)
- [ElasticMapReduce] (#elasticmapreduce)
- [Glacier] (#glacier)
- [IdentityManagement] (#identitymanagement)
- [OpsWorks] (#opsworks)
- RDS
- [Redshift] (#redshift)
- [Route53] (#route53)
- [S3] (#s3)
- SimpleDB
- SimpleEmail
- [SNS] (#sns)
- [SQS] (#sqs)
- StorageGateway
[Minimum Viable Snippet] 9:
(ns com.example
(:use [amazonica.aws.ec2]))
(describe-instances)
(create-snapshot :volume-id "vol-8a4857fa"
:description "my_new_snapshot")
Amazonica reflectively delegates to the Java client library, as such it supports the complete set of remote service calls implemented by each of the service-specific AWS client classes (e.g. AmazonEC2Client, AmazonS3Client, etc.), the documentation for which can be found in the [AWS Javadocs] 2.
Reflection is used to create idiomatically named Clojure Vars in the library namespaces corresponding to the AWS service. camelCase Java methods become lower-case, hyphenated Clojure functions. So for example, if you want to create a snapshot of a running EC2 instance, you'd simply
(create-snapshot :volume-id "vol-8a4857fa"
:description "my_new_snapshot")
which delegates to the [createSnapshot()] 3 method of AmazonEC2Client. If the Java method on the AmazonClient takes a parameter, such as [CreateSnapshotRequest] 4 in this case, the bean properties exposed via mutators of the form set can be supplied as key-value pairs passed as arguments to the Clojure function.
All of the AWS Java apis (except S3) follow this pattern, either having a single implementation method which takes an AWS Java bean as its only argument, or being overloaded and having a no-arg implementation. The corresponding Clojure function will either require key-value pairs as arguments, or be variadic and allow a no-arg invocation.
For example, AmazonEC2Client's [describeImages()] 7 method is overloaded, and can be invoked either with no args, or with a [DescribeImagesRequest] 8. So the Clojure invocation would look like
(describe-images)
or
(describe-images :owners ["self"]
:image-ids ["ami-f00f9699" "ami-e0d30c89"])
java.util.Collections
are converted to the corresponding Clojure collection type. java.util.Maps
are converted to clojure.lang.IPersistentMaps
, java.util.Lists
are converted to clojure.lang.IPersistentVectors
, etc.
java.util.Dates
are automatically converted to Joda Time DateTime
instances.
Amazon AWS object types are returned as Clojure maps, with conversion taking place recursively, so, "Clojure data all the way down."
For example, a call to
(describe-instances)
invokes a Java method on AmazonEC2Client which returns a com.amazonaws.services.ec2.model.DescribeInstancesResult
. However, this is recursively converted to Clojure data, yielding a map of Reservations
, like so:
{:owner-id "676820690883",
:group-names ["cx"],
:groups [{:group-name "cx", :group-id "sg-38f45150"}],
:instances
[{:instance-type "m1.large",
:kernel-id "aki-825ea7eb",
:hypervisor "xen",
:state {:name "running", :code 16},
:ebs-optimized false,
:public-dns-name "ec2-154-73-176-213.compute-1.amazonaws.com",
:root-device-name "/dev/sda1",
:virtualization-type "paravirtual",
:root-device-type "ebs",
:block-device-mappings
[{:device-name "/dev/sda1",
:ebs
{:status "attached",
:volume-id "vol-b0e519c3",
:attach-time #<DateTime 2013-03-21T22:00:56.000-07:00>,
:delete-on-termination true}}],
:network-interfaces [],
:public-ip-address "164.73.176.213",
:placement
{:availability-zone "us-east-1a",
:group-name "",
:tenancy "default"},
:private-ip-address "10.116.187.19",
:security-groups [{:group-name "cx", :group-id "sg-38f45150"}],
:state-transition-reason "",
:private-dns-name "ip-10-116-187-19.ec2.internal",
:instance-id "i-cefbe7a2",
:key-name "cxci",
:architecture "x86_64",
:client-token "",
:image-id "ami-baba68d3",
:ami-launch-index 0,
:monitoring {:state "disabled"},
:product-codes [],
:launch-time #<DateTime 2013-03-21T22:00:52.000-07:00>,
:tags [{:value "CXCI_nightly", :key "Name"}]}],
:reservation-id "r-8a23d6f7"}
If you look at the Reservation
[Javadoc] 10 you'll see that getGroups()
returns a java.util.List
of GroupIdentifiers
, which is converted to a vector of maps containing keys :group-name
and :group-id
, under the :groups
key. Ditto for :block-device-mappings and :tags, and so and so on...
Similar in concept to JSON unwrapping in Jackson, Amazonica supports root unwrapping of the returned data. So calling
; dynamodb
(list-tables)
by default would return
{:table-names ["TableOne" "TableTwo" "TableThree"]}
However, if you call
(set-root-unwrapping! true)
then single keyed top level maps will be "unwrapped" like so:
(list-tables)
=> ["TableOne" "TableTwo" "TableThree"]
The returned data can be "round tripped" as well. So the returned Clojure data structures can be supplied as arguments to function calls which delegate to Java methods taking the same object type as an argument. See the section below for more on this.
Coercion of any types that are part of the java.lang wrapper classes happens transparently. So for example, Clojure's preferred longs are automatically converted to ints where required.
Clojure data structures automatically participate in the Java Collections abstractions, and so no explicit coercion is necessary. Typically when service calls take collections as parameter arguments, as in the case above, the values in the collections are most often instances of the Java wrapper classes.
When complex objects consisting of types outside of those in the java.lang
package are required as argument parameters, smart conversions are attempted based on the argument types of the underlying Java method signature. Methods requiring a java.util.Date
argument can take Joda Time org.joda.time.base.AbstractInstants
, longs, or Strings (default pattern is "yyyy-MM-dd"), with conversion happening automatically.
(set-date-format! "MM-dd-yyyy")
can be used to set the pattern supplied to the underlying java.text.SimpleDateFormat
.
In cases where collection arguments contain instances of AWS "model" classes, Clojure maps will be converted to the appropriate AWS Java bean instance. So for example, [describeAvailabilityZones()] 5 can take a [DescribeAvailabilityZonesRequest] 6 which itself has a filters
property, which is a java.util.List
of com.amazonaws.services.ec2.model.Filters
. Passing the filters argument would look like:
(describe-availability-zones :filters [{:name "environment"
:values ["dev" "qa" "staging"]}])
and return the following Clojure collection:
{:availability-zones
[{:state "available",
:region-name "us-east-1",
:zone-name "us-east-1a",
:messages []}
{:state "available",
:region-name "us-east-1",
:zone-name "us-east-1b",
:messages []}
{:state "available",
:region-name "us-east-1",
:zone-name "us-east-1c",
:messages []}
{:state "available",
:region-name "us-east-1",
:zone-name "us-east-1d",
:messages []}
{:state "available",
:region-name "us-east-1",
:zone-name "us-east-1e",
:messages []}]}
Clojure apis built specifically to wrap a Java client, such as this one, often provide "conveniences" for the user of the api, to remove boilerplate. In Amazonica this is accomplished via the IMarshall protocol, which defines the contract for converting the returned Java result from the AWS service call to Clojure data, and the
(amazonica.core/register-coercions)
function, which takes a map of class/function pairs defining how a value should be coerced to a specific AWS Java bean. You can find a good example of this in the amazonica.aws.dynamodb
namespace. Consider the following DynamoDB service call:
(get-item :table-name "MyTable"
:key "foo")
The [GetItemRequest] 11 takes a com.amazonaws.services.dynamodb.model.Key
which is composed of a hash key of type com.amazonaws.services.dynamodb.model.AttributeValue
and optional range key also of type AttributeValue
. Without the coercions registered for Key
and AttributeValue
in amazonica.aws.dynamodb
we would need to write:
(get-item :table-name "TestTable"
:key {:hash-key-element {:s "foo"}})
Note that either form will work. This allows contributors to the library to incrementally evolve the api independently from the core of the library, as well as maintain backward compatibility of existing code written against prior versions of the library which didn't contain the conveniences.
The default authentication scheme is to use the [chained Provider class] 15 from the AWS SDK, whereby authentication is attempted in the following order:
- Environment Variables - AWS_ACCESS_KEY_ID and AWS_SECRET_KEY
- Java System Properties - aws.accessKeyId and aws.secretKey
- Instance profile credentials delivered through the Amazon EC2 metadata service
Note that in order for the Instance Profile Metadata to be found, you must have launched the instance with a provided IAM role, and the same permissions as the IAM Role the instance was launched with will apply.
See the [AWS docs] 14 for reference.
Addtionally, all of the functions may take as their first argument an optional map of credentials, with keys :access-key and :secret-key, and optional :endpoint. (Default endpoint is "us-east-1"). This is primarily for legacy support or to set the region/endpoint. If the value of the :endpoint
key is a lower case, hyphenated translation of one of the [Regions enums] 16, [.setRegion] 17 will be called on the Client, otherwise [.setEndpoint] 18 will be called.
(def cred {:access-key "aws-access-key"
:secret-key "aws-secret-key"
:endpoint "us-west-1"})
(describe-instances cred)
As a convenience, users may call (defcredential)
before invoking any service functions and passing in their AWS key pair and an optional endpoint:
(defcredential "aws-access-key" "aws-secret-key" "us-west-1")
All subsequent API calls will use the specified credential. If you need to execute a service call with alternate credentials, or against a different region than the one passed to (defcredential)
, you can wrap these ad-hoc calls in the (with-credential)
macro, which takes a vector of key pair credentials and an optional endpoint, like so:
(defcredential "account-1-aws-access-key" "aws-secret-key" "us-west-1")
(describe-instances)
; returns instances visible to account-1
(with-credential ["account-2-aws-access-key" "secret" "us-east-1"]
(describe-instances))
; returns EC2 instances visible to account-2 running in US-East region
(describe-images :owners ["self"])
; returns images belonging to account-1
You can supply a :client-config
entry in the credentials map to configure the ClientConfiguration that the Amazon client uses. This is useful if you need to use a proxy.
(describe-images {:client-config {:proxy-host "proxy.address.com" :proxy-port 8080}})
All functions throw com.amazonaws.AmazonServiceExceptions
. If you wish to catch exceptions you can convert the AWS object to a Clojure map like so:
(try
(create-snapshot :volume-id "vol-ahsg23h"
:description "daily backup")
(catch Exception e
(log (ex->map e))))
; {:error-code "InvalidParameterValue",
; :error-type "Unknown",
; :status-code 400,
; :request-id "9ba69e16-ed63-41d4-ac02-1f6032cb64de",
; :service-name "AmazonEC2",
; :message
; "Value (vol-ahsg23h) for parameter volumeId is invalid. Expected: 'vol-...'.",
; :stack-trace "Status Code: 400, AWS Service: AmazonEC2, AWS Request ID: a5b0340a-8f37-4122-941c-ed8d5472b11d, AWS Error Code: InvalidParameterValue, AWS Error Message: Value (vol-ahsg23h) for parameter volumeId is invalid. Expected: 'vol-...'.
; at com.amazonaws.http.AmazonHttpClient.handleErrorResponse(AmazonHttpClient.java:644)
; at com.amazonaws.http.AmazonHttpClient.executeHelper(AmazonHttpClient.java:338)
; at com.amazonaws.http.AmazonHttpClient.execute(AmazonHttpClient.java:190)
; at com.amazonaws.services.ec2.AmazonEC2Client.invoke(AmazonEC2Client.java:6199)
; at com.amazonaws.services.ec2.AmazonEC2Client.createSnapshot(AmazonEC2Client.java:1531)
; .....
Amazonica uses reflection extensively, to generate the public Vars, to set the bean properties passed as arguments to those functions, and to invoke the actual service method calls on the underlying AWS Client class. As such, one may wonder if such pervasive use of reflection will result in unacceptable performance. In general, this shouldn't be an issue, as the cost of reflection should be relatively minimal compared to the latency incurred by making a remote call across the network. Furthermore, typical AWS usage is not going to be terribly concerned with performance, except with specific services such as DynamoDB, RDS, SimpleDB, or SQS. But we have done some basic benchmarking against the excellent DynamoDB [rotary] 13 library, which uses no explicit reflection. Results are shown below. Benchmarking code is available at [https://github.com/mcohen01/amazonica-benchmark] 12
###Autoscaling
(ns com.example
(:use [amazonica.aws.autoscaling]))
(create-launch-configuration :launch-configuration-name "aws_launch_cfg"
:block-device-mappings [
{:device-name "/dev/sda1"
:virtual-name "vol-b0e519c3"
:ebs {:snapshot-id "snap-36295e51"
:volume-size 32}}]
:ebs-optimized true
:image-id "ami-6fde0d06"
:instance-type "m1.large"
:spot-price ".10")
(create-auto-scaling-group :auto-scaling-group-name "aws_autoscale_grp"
:availability-zones ["us-east-1a" "us-east-1b"]
:desired-capacity 3
:health-check-grace-period 300
:health-check-type "EC2"
:launch-configuration-name "aws_launch_cfg"
:min-size 3
:max-size 3)
(describe-auto-scaling-instances)
###CloudFormation
(ns com.example
(:use [amazonica.aws.cloudformation]))
(create-stack :stack-name "my-stack"
:template-url "abcd1234.s3.amazonaws.com")
(describe-stack-resources)
###CloudFront
(ns com.example
(:use [amazonica.aws.cloudfront]))
(create-distribution :distribution-config {
:enabled true
:default-root-object "index.html"
:origins
{:quantity 0
:items []}
:logging
{:enabled false
:include-cookies false
:bucket "abcd1234.s3.amazonaws.com"
:prefix "cflog_"}
:caller-reference 12345
:aliases
{:items ["m.example.com" "www.example.com"]
:quantity 2}
:cache-behaviors
{:quantity 0
:items []}
:comment "example"
:default-cache-behavior
{:target-origin-id "MyOrigin"
:forwarded-values
{:query-string false
:cookies
{:forward "none"}}}
:trusted-signers
{:enabled false
:quantity 0}
:viewer-protocol-policy "allow-all"
:min-ttl 3600}
:price-class "PriceClass_All"})
(list-distributions :max-items 10)
###CloudSearch
(ns com.example
(:use [amazonica.aws.cloudsearch]))
(create-domain :domain-name "my-index")
(index-documents :domain-name "my-index")
###CloudWatch
(ns com.example
(:use [amazonica.aws.cloudwatch]))
(put-metric-alarm :alarm-name "my-alarm"
:actions-enabled true
:evaluation-periods 5
:period 60
:metric-name "CPU"
:threshold "50%")
###DataPipeline
(ns com.example
(:use [amazonica.aws.datapipeline]))
(create-pipeline :name "my-pipeline"
:unique-id "mp")
(put-pipeline-definition :pipeline-id "df-07746012XJFK4DK1D4QW"
:pipeline-objects [{:name "my-pipeline-object"
:id "my-pl-object-id"
:fields [{:key "some-key"
:string-value "foobar"}]}])
(list-pipelines)
(delete-pipeline :pipeline-id pid)
###DynamoDB
(ns com.example
(:use [amazonica.aws.dynamodb]))
(create-table :table-name "TestTable"
:key-schema {:hash-key-element {:attribute-name "id"
:attribute-type "S"}}
:provisioned-throughput {:read-capacity-units 1
:write-capacity-units 1})
(put-item :table-name "TestTable"
:item {:id "foo"
:text "barbaz"})
(get-item :table-name "TestTable"
:key "foo")
(scan :table-name "TestTable")
(delete-table :table-name "TestTable")
###DynamoDBV2
(ns com.example
(:use [amazonica.aws.dynamodbv2]))
(def cred {:access-key "aws-access-key"
:secret-key "aws-secret-key"
:endpoint "http://localhost:8000"})
(create-table cred
:table-name "TestTable"
:key-schema
[{:attribute-name "id" :key-type "HASH"}
{:attribute-name "date" :key-type "RANGE"}]
:attribute-definitions
[{:attribute-name "id" :attribute-type "S"}
{:attribute-name "date" :attribute-type "N"}
{:attribute-name "column1" :attribute-type "S"}
{:attribute-name "column2" :attribute-type "S"}]
:local-secondary-indexes
[{:index-name "column1_idx"
:key-schema
[{:attribute-name "id" :key-type "HASH"}
{:attribute-name "column1" :key-type "RANGE"}]
:projection
{:projection-type "INCLUDE"
:non-key-attributes ["id" "date" "column1"]}}
{:index-name "column2_idx"
:key-schema
[{:attribute-name "id" :key-type "HASH"}
{:attribute-name "column2" :key-type "RANGE"}]
:projection {:projection-type "ALL"}}]
:provisioned-throughput
{:read-capacity-units 1
:write-capacity-units 1})
(put-item cred
:table-name "TestTable"
:return-consumed-capacity "TOTAL"
:return-item-collection-metrics "SIZE"
:item {
:id "foo"
:date 123456
:text "barbaz"
:column1 "first name"
:column2 "last name"})
(get-item cred
:table-name "TestTable"
:key {:id {:s "foo"}
:date {:n 123456}})
(query :table-name "TestTable"
:limit 1
:index-name "column1_idx"
:select "ALL_ATTRIBUTES"
:scan-index-forward true
:key-conditions
{:id {:attribute-value-list ["foo"] :comparison-operator "EQ"}
:column1 {:attribute-value-list ["first na"] :comparison-operator "BEGINS_WITH"}})
(batch-write-item
cred
:return-consumed-capacity "TOTAL"
:return-item-collection-metrics "SIZE"
:request-items
{"TestTable"
[{:delete-request
{:key {:id "foo"
:date 123456}}}
{:put-request
{:item {:id "foobar"
:date 3172671
:text "bunny"
:column1 "funky"}}}]})
(batch-get-item
cred
:return-consumed-capacity "TOTAL"
:request-items {
"TestTable" {:keys [{"id" {:s "foobar"}
"date" {:n 3172671}}
{"id" {:s "foo"}
"date" {:n 123456}}]
:consistent-read true
:attributes-to-get ["id" "text" "column1"]}})
(scan cred :table-name "TestTable")
(describe-table cred :table-name "TestTable")
(delete-table cred :table-name "TestTable")
###EC2
(ns com.example
(:use [amazonica.aws.ec2]))
(describe-images :owners ["self"])
(describe-instances)
(create-image :name "my_test_image"
:instance-id "i-1b9a9f71"
:description "test image - safe to delete"
:block-device-mappings [
{:device-name "/dev/sda1"
:virtual-name "myvirtual"
:ebs {
:volume-size 8
:volume-type "standard"
:delete-on-termination true}}])
(create-snapshot :volume-id "vol-8a4857fa"
:description "my_new_snapshot")
###ElasticLoadBalancing
(ns com.example
(:use [amazonica.aws.elasticloadbalancing]))
(deregister-instances-from-load-balancer :load-balancer-name "my-ELB"
:instances [{:instance-id "i-1ed40bad"}])
(register-instances-with-load-balancer :load-balancer-name "my-ELB"
:instances [{:instance-id "i-1fa370ea"}])
###ElasticMapReduce
(ns com.example
(:use [amazonica.aws
elasticmapreduce
s3]))
(create-bucket :bucket-name "emr-logs"
:access-control-list {:grant-permission ["LogDelivery" "Write"]})
(set-bucket-logging-configuration :bucket-name "emr-logs"
:logging-configuration
{:log-file-prefix "hadoop-job_"
:destination-bucket-name "emr-logs"})
(run-job-flow :name "my-job-flow"
:log-uri "s3n://emr-logs/logs"
:instances
{:instance-groups [
{:instance-type "m1.large"
:instance-role "MASTER"
:instance-count 1
:market "SPOT"
:bid-price "0.10"}]}
:steps [
{:name "my-step"
:hadoop-jar-step
{:jar "s3n://beee0534-ad04-4143-9894-8ddb0e4ebd31/hadoop-jobs/bigml"
:main-class "bigml.core"
:args ["s3n://beee0534-ad04-4143-9894-8ddb0e4ebd31/data" "output"]}}])
(describe-job-flows :job-flow-ids ["j-38BW9W0NN8YGV"])
###Glacier
(ns com.example
(:use [amazonica.aws.glacier]))
(create-vault :vault-name "my-vault")
(describe-vault :vault-name "my-vault")
(list-vaults :limit 10)
(upload-archive :vault-name "my-vault"
:body "upload.txt")
(delete-archive :account-id "-"
:vault-name "my-vault"
:archive-id "pgy30P2FTNu_d7buSVrGawDsfKczlrCG7Hy6MQg53ibeIGXNFZjElYMYFm90mHEUgEbqjwHqPLVko24HWy7DU9roCnZ1djEmT-1REvnHKHGPgkuzVlMIYk3bn3XhqxLJ2qS22EYgzg", :checksum "83a05fd1ce759e401b44fff8f34d40e17236bbdd24d771ec2ca4886b875430f9", :location "/676820690883/vaults/my-vault/archives/pgy30P2FTNu_d7buSVrGawDsfKczlrCG7Hy6MQg53ibeIGXNFZjElYMYFm90mHEUgEbqjwHqPLVko24HWy7DU9roCnZ1djEmT-1REvnHKHGPgkuzVlMIYk3bn3XhqxLJ2qS22EYgzg")
(delete-vault :vault-name "my-vault")
###IdentityManagement
(ns com.example
(:use [amazonica.aws.identitymanagement]))
(def policy "{\"Version\": \"2012-10-17\", \"Statement\": [{\"Action\": [\"s3:*\"], \"Effect\": \"Allow\", \"Resource\": [\"arn:aws:s3:::bucket-name/*\"]}]}")
(create-user :user-name "amazonica")
(create-access-key :user-name "amazonica")
(put-user-policy
:user-name "amazonica"
:policy-name "s3policy"
:policy-document policy)
###OpsWorks
(ns com.example
(:use [amazonica.aws.opsworks]))
(create-stack :name "my-stack"
:region "us-east-1"
:default-os "Ubuntu 12.04 LTS"
:service-role-arn "arn:aws:iam::676820690883:role/aws-opsworks-service-role")
(create-layer :name "webapp-layer"
:stack-id "dafa328e-c529-41af-89d3-12840a31abad"
:enable-auto-healing true
:auto-assign-elastic-ips true
:volume-configurations [
{:mount-point "/data"
:number-of-disks 1
:size 50}])
(create-instance :hostname "node-app-1"
:instance-type "m1.large"
:stack-id "dafa328e-c529-41af-89d3-12840a31abad"
:layer-ids ["660d00da-c533-43d4-8c7f-2df240fd563f"]
:availability-zone "us-east-1a"
:autoscaling-type "LoadBasedAutoScaling"
:os "Ubuntu 12.04 LTS"
:ssh-key-name "admin")
(describe-stacks :stack-ids ["dafa328e-c529-41af-89d3-12840a31abad"])
(describe-layers :stack-id "dafa328e-c529-41af-89d3-12840a31abad")
(describe-instances :stack-id "dafa328e-c529-41af-89d3-12840a31abad"
:layer-id "660d00da-c533-43d4-8c7f-2df240fd563f"
:instance-id "93bc5049-1bd4-49c8-a6ef-e84145807f71")
(start-stack :stack-id "660d00da-c533-43d4-8c7f-2df240fd563f")
(start-instance :instance-id "93bc5049-1bd4-49c8-a6ef-e84145807f71")
###Redshift
(ns com.example
(:use [amazonica.aws.redshift]))
(create-cluster :availability-zone "us-east-1a"
:cluster-type "multi-node"
:db-name "dw"
:master-username "scott"
:master-user-password "tiger"
:number-of-nodes 3)
###Route53
(ns com.example
(:use [amazonica.aws.route53]))
(create-health-check :health-check-config {:port 80,
:type "HTTP",
:ipaddress "127.0.0.1",
:fully-qualified-domain-name "example.com"})
(get-health-check :health-check-id "ce6a4aeb-acf1-4923-a116-cd9ae2c30ee3")
(create-hosted-zone :name "example.com.")
(get-hosted-zone :id "Z3TKY0VR5CH45U")
(list-hosted-zones)
(list-health-checks)
(list-resource-record-sets :hosted-zone-id "ZN8D0HXQLVRRL")
(delete-health-check :health-check-id "99999999-1234-4923-a116-cd9ae2c30ee3")
(delete-hosted-zone :id "my-bogus-hosted-zone")
###S3
(ns com.example
(:use [amazonica.aws.s3]
[amazonica.aws.s3transfer]))
(create-bucket "two-peas")
;; put object with server side encryption
(put-object :bucket-name "two-peas"
:key "foo"
:metadata {:server-side-encryption "AES256"}
:file upload-file)
(copy-object bucket1 "key-1" bucket2 "key-2")
(get-object bucket2 "key-2"))
(generate-presigned-url bucket1 "key-1" (-> 6 hours from-now))
(def file "big-file.jar")
(def down-dir (java.io.File. (str "/tmp/" file)))
(def bucket "my-bucket")
(def key-pair
(let [kg (KeyPairGenerator/getInstance "RSA")]
(.initialize kg 1024 (SecureRandom.))
(.generateKeyPair kg)))
;; put object with client side encryption
(put-object :bucket-name bucket1
:key "foo"
:encryption {:key-pair key-pair}
:file upload-file)
;; get object and decrypt
(get-object :bucket-name bucket1
:encryption {:key-pair key-pair}
:key "foo")))))
;; put object from stream
(def some-bytes (.getBytes "Amazonica" "UTF-8"))
(def input-stream (java.io.ByteArrayInputStream. some-bytes))
(put-object :bucket-name bucket1
:key "stream"
:input-stream input-stream
:metadata {:content-length (count some-bytes)})
(let [upl (upload bucket
file
down-dir)]
((:add-progress-listener upl) #(println %)))
(let [dl (download bucket
file
down-dir)
listener #(if (= :completed (:event %))
(println ((:object-metadata dl)))
(println %))]
((:add-progress-listener dl) listener))
###SNS
(ns com.example
(:use [amazonica.aws.sns]))
(create-topic :name "my-topic")
(list-topics)
(subscribe :protocol "email"
:topic-arn "arn:aws:sns:us-east-1:676820690883:my-topic"
:endpoint "[email protected]")
(clojure.pprint/pprint
(list-subscriptions))
(publish :topic-arn "arn:aws:sns:us-east-1:676820690883:my-topic"
:subject "test"
:message (str "Todays is " (java.util.Date.)))
(unsubscribe :subscription-arn "arn:aws:sns:us-east-1:676820690883:my-topic:33fb2721-b639-419f-9cc3-b4adec0f4eda")
###SQS
(ns com.example
(:use [amazonica.aws.sqs]))
(create-queue :queue-name "my-queue"
:attributes
{:VisibilityTimeout 30 ; sec
:MaximumMessageSize 65536 ; bytes
:MessageRetentionPeriod 1209600 ; sec
:ReceiveMessageWaitTimeSeconds 10}) ; sec
(list-queues)
(send-message :queue-url "https://sqs.us-east-1.amazonaws.com/676820690883/my-queue"
:delay-seconds 0
:message-body (str "test" (java.util.Date.)))
(receive-message :queue-url "https://sqs.us-east-1.amazonaws.com/676820690883/my-queue"
:wait-time-seconds 6
:max-number-of-messages 10
:delete true ;; deletes any received messages after receipt
:attribute-names ["SenderId" "ApproximateFirstReceiveTimestamp" "ApproximateReceiveCount" "SentTimestamp"])
(delete-message :queue-url "https://sqs.us-east-1.amazonaws.com/676820690883/my-queue"
:receipt-handle "0NNAq8PwvXuydXZkpmJu64SnW7tDdNDFpL5gCqwSvdh+yXfzzX7jRTUXOOiSdDfarBtUFmjwjjwYgsKMdmFxWRIEw/tEGV3baAglZ25IT3CMKwFJEDfufjv1sQIM9BMd9LtxSUD1WBkHK3k4Qq5Qf/a4hn2WONRKeelLH0WldkTkX756soBPSc0YHjB6a2zqNVH04iJmZVJCmy2Hd4sOF0cEaT1GRkSiHzNJzQIVpg4sij0swLEwvt68hM5ogLklfRAbd8Aeow1u7Gd9Y+cwWu7deyfVVxwp1z9OdHsr1+4=")
(delete-queue :queue-url "https://sqs.us-east-1.amazonaws.com/676820690883/my-queue")
YourKit is kindly supporting the Amazonica open source project with its full-featured Java Profiler. YourKit, LLC is the creator of innovative and intelligent tools for profiling Java and .NET applications. Take a look at YourKit's leading software products: YourKit Java Profiler and YourKit .NET Profiler.
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Copyright (C) 2013 Michael Cohen
Distributed under the Eclipse Public License, the same as Clojure.