This repo contains scripts designed to automate [Blockscout](https://github.com/poanetwork/blockscout) deployment builds. Currently it supports only [AWS](#AWS) as a cloud provider.
In the root folder you can find an Ansible Playbooks that will create all necessary infrastructure and deploy BlockScout. Please refer to the following sections of the README for details:
1. [Deploying the Infrastructure](#deploying-the-infrastructure). This section describes all the steps to deploy the virtual hardware that is required for production instance of BlockScout. Skip this section if you do have an infrastructure and simply want to install or update your BlockScout.
2. [Deploying BlockScout](#deploying-blockscout). Follow this section to install or update your BlockScout.
3. [Destroying Provisioned Infrastructure](#destroying-provisioned-infrastructure). Refer to this section if you want to destroy your BlockScout installation.
Playbooks relies on Terraform under the hood, which is the stateful infrastructure-as-a-code software tool. It allows to keep a hand on your infrastructure - modify and recreate single and multiple resources depending on your needs.
During deployment you will have to provide credentials to your AWS account. Deployment process requires a wide set of permissions to do the job, so it would work best of all if you specify the administrator account credentials.
Each configured chain will receive its own ASG (autoscaling group) and deployment group, when application updates are pushed to CodeDeploy, all autoscaling groups will deploy the new version using a blue/green strategy. Currently, there is only one EC2 host to run, and the ASG is configured to allow scaling up, but no triggers are set up to actually perform the scaling yet. This is something that may come in the future.
The deployment process goes in two stages. First, Ansible creates S3 bucket and DynamoDB table that are required for Terraform state management. It is needed to ensure that Terraforms state is stored in a centralized location, so that multiple people can use Terraform on the same infra without stepping on each others toes. Terraform prevents this from happening by holding locks (via DynamoDB) against the state data (stored in S3).
The single point of configuration in this script is a `group_vars/all.yml` file. First, copy it from `group_vars/all.yml.example` template by executing `cp group_vars/all.yml.example group_vars/all.yml` command and then modify it via any text editor you want (vim example - `vim group_vars/all.yml`). The subsections describe the variable you may want to adjust.
-`backend` variable defines whether deployer should keep state files remote or locally. Set `backend` variable to `true` if you want to save state file to the remote S3 bucket;
-`upload_config_to_s3` - set to `true` if you want to upload config `all.yml` file to the S3 bucket automatically after the deployment. Will not work if `backend` is set to false;
-`upload_debug_info_to_s3` - set to `true` if you want to upload full log output to the S3 bucket automatically after the deployment. Will not work if `backend` is set to false. *IMPORTANT*: Locally logs are stored at `log.txt` which is not cleaned automatically. Please, do not forget to clean it manually or using the `clean.yml` playbook;
-`bucket` represents a globally unique name of the bucket where your configs and state will be stored. It will be created automatically during the deployment;
*Note*: a chain name shouldn't be more than 5 characters. Otherwise, it causing the error, because the aws load balancer name should not be greater than 32 characters.
- If `ec2_ssh_key_content` variable is not empty, Terraform will try to create EC2 SSH key with the `ec2_ssh_key_name` name. Otherwise, the existing key with `ec2_ssh_key_name` name will be used;
-`instance_type` defines a size of the Blockscout instance that will be launched during the deployment process;
-`vpc_cidr`, `public_subnet_cidr`, `db_subnet_cidr` represents the network configuration for the deployment. Usually you want to leave it as is. However, if you want to modify it, please, expect that `db_subnet_cidr` represents not a single network, but a group of networks started with defined CIDR block increased by 8 bits.
- The `root_block_size` is the amount of storage on your EC2 instance. This value can be adjusted by how frequently logs are rotated. Logs are located in `/opt/app/logs` of your EC2 instance;
- The `pool_size` defines the number of connections allowed by the RDS instance;
-`secret_key_base` is a random password used for BlockScout internally. It is highly recommended to gernerate your own `secret_key_base` before the deployment. For instance, you can do it via `openssl rand -base64 64 | tr -d '\n'` command;
-`new_relic_app_name` and `new_relic_license_key` should usually stay empty unless you want and know how to configure New Relic integration;
-`elixir_version` - is an Elixir version used in BlockScout release;
-`chain_trace_endpoint` - maps chains to the URLs of HTTP RPC endpoints, which represents a node where state pruning is disabled (archive node) and tracing is enabled. If you don't have a trace endpoint, you can simply copy values from `chains` variable;
-`chain_ws_endpoint` - maps chains to the URLs of HTTP RPCs that supports websockets. This is required to get the real-time updates. Can be the same as `chains` if websocket is enabled there (but make sure to use`ws(s)` instead of `htpp(s)` protocol);
-`chain_jsonrpc_variant` - a client used to connect to the network. Can be `parity`, `geth`, etc;
-`chain_logo` - maps chains to the it logos. Place your own logo at `apps/block_scout_web/assets/static` and specify a relative path at `chain_logo` variable;
-`chain_coin` - a name of the coin used in each particular chain;
-`chain_network` - usually, a name of the organization keeping group of networks, but can represent a name of any logical network grouping you want;
-`chain_subnetwork` - a name of the network to be shown at BlockScout;
-`chain_network_path` - a relative URL path which will be used as an endpoint for defined chain. For example, if we will have our BlockScout at `blockscout.com` domain and place `core` network at `/poa/core`, then the resulting endpoint will be `blockscout.com/poa/core` for this network.
-`chain_network_icon` - maps the chain name to the network navigation icon at apps/block_scout_web/lib/block_scout_web/templates/icons without .eex extension
-`chain_graphiql_transaction` - is a variable that maps chain to a random transaction hash on that chain. This hash will be used to provide a sample query in the GraphIQL Playground.
-`chain_block_transformer` - will be `clique` for clique networks like Rinkeby and Goerli, and `base` for the rest;
-`chain_heart_beat_timeout`, `chain_heart_command` - configs for the integrated heartbeat. First describes a timeout after the command described at the second variable will be executed;
- Each of the `chain_db_*` variables configures the database for each chain. Each chain will have the separate RDS instance.
-`chain_blockscout_version` - is a text at the footer of BlockScout instance. Usually represents the current BlockScout version.
-`blockscout_repo` - a direct link to the Blockscout repo;
-`chain_branch` - maps branch at `blockscout_repo` to each chain;
- Specify the `chain_merge_commit` variable if you want to merge any of the specified `chains` with the commit in the other branch. Usually may be used to update production branches with the releases from master branch;
-`skip_fetch` - if this variable is set to `true` , BlockScout repo will not be cloned and the process will start from building the dependencies. Use this variable to prevent playbooks from overriding manual changes in cloned repo;
-`ps_*` variables represents a connection details to the test Postgres database. This one will not be installed automatically, so make sure `ps_*` credentials are valid before starting the deployment;
The configuration variable `db_storage` can be used to define the amount of storage allocated to your RDS instance. The chart below shows an estimated amount of storage that is required to index individual chains. The `db_storage` can only be adjusted 1 time in a 24 hour period on AWS.
- During the deployment the ["diffs didn't match"](#error-applying-plan-diffs-didnt-match) error may occur, it will be ignored automatically. If Ansible play recap shows 0 failed plays, then the deployment was successful despite the error.
- Optionally, you may want to check the variables the were uploaded to the [Parameter Store](https://console.aws.amazon.com/systems-manager/parameters) at AWS Console.
**Note!** All three configuration files are compatible to each other, so you can simply `cat group_vars/blockscout.yml.example >> group_vars/all.yml` if you already do have the `all.yml` file after the deploying of infrastructure.
**Note!** Use `chain_custom_environment` to update the variables in each deployment. Map each deployed chain with variables as they should appear at the Parameter Store. Check the example at `group_vars/blockscout.yml.example` config file. `chain_*` variables will be ignored during BlockScout software deployment.
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objc[12816]: +[__NSPlaceholderDate initialize] may have been in progress in another thread when fork() was called. We cannot safely call it or ignore it in the fork() child process. Crashing instead. Set a breakpoint on objc_initializeAfterForkError to debug.
```
error and crashing of Python follow the next steps:
- Open terminal: `nano .bash_profile`;
- Add the following line to the end of the file: `export OBJC_DISABLE_INITIALIZE_FORK_SAFETY=YES`;
- Save, exit, close terminal and re-open the terminal. Check to see that the environment variable is now set: `env`
6. When the prompt appears, check that server is running and there is no visual artifacts. The server will be launched at port 4000 at the same machine where you run the Ansible playbooks. If you face any errors you can either fix it or cancel the deployment by pressing **Ctrl+C** and then pressing **A** when additionally prompted.
7. When server is ready to be deployed simply press enter and deployer will upload Blockscout to the appropriate S3.
8. Two other prompts will appear to ensure your will on updating the Parameter Store variables and deploying the BlockScout through the CodeDeploy. Both **yes** and **true** will be interpreted as the confirmation.
9. Monitor and manage your deployment at [CodeDeploy](https://console.aws.amazon.com/codesuite/codedeploy/applications) service page at AWS Console.
First of all you have to remove autoscaling groups (ASG) deployed via CodeDeploy manually since Terraform doesn't track them and will miss them during the automatic destroy process. Once ASG is deleted you can use `ansible-playbook destroy.yml` playbook to remove the rest of generated infrastructure. Make sure to check the playbook output since in some cases it might not be able to delete everything. Check the error description for details.
**Note!** While Terraform is stateful, Ansible is stateless, so if you modify `bucket` or `dynamodb_table` variables and run `destroy.yml` or `deploy_infra.yml` playbooks, it will not alter the current S3/Dynamo resources names, but create a new resources. Moreover, altering `bucket` variable will make Terraform to forget about existing infrastructure and, as a consequence, redeploy it. If it absolutely necessary for you to alter the S3 or DynamoDB names you can do it manually and then change the appropriate variable accordingly.
Also note, that changing `backend` variable will force Terraform to forget about created infrastructure also, since it will start searching the current state files locally instead of remote.
Despite the fact that Terraform cache is automatically cleared automatically before each deployment, you may also want to force the cleaning process manually. To do this simply run the `ansible-playbook clean.yml` command, and Terraform cache will be cleared.
You can easily manipulate your deployment from any machine with sufficient prerequisites. If `upload_debug_info_to_s3` variable is set to true, the deployer will automatically upload your `all.yml` file to the s3 bucket, so you can easily download it to any other machine. Simply download this file to your `group_vars` folder and your new deployer will pick up the current deployment instead of creating a new one.
In some cases you may want not to create a new database, but to add the existing one to use within the deployment. In order to do that configure all the proper values at `group_vars/all.yml` including yours DB ID and name and execute the `ansible-playbook attach_existing_rds.yml` command. This will add the current DB instance into Terraform-managed resource group. After that run `ansible-playbook deploy_infra.yml` as usually.
**Note 1**: while executing `ansible-playbook attach_existing_rds.yml` the S3 and DynamoDB will be automatically created (if `backend` variable is set to `true`) to store Terraform state files.
Usually appears if S3 bucket already exists. Remember, S3 bucket has globally unique name, so if you don't have it, it doesn't mean, that it doesn't exists at all. Login to your AWS console and try to create S3 bucket with the same name you specified at `bucket` variable to ensure.
* module.stack.aws_autoscaling_group.explorer: aws_autoscaling_group.explorer: diffs didn't match during apply. This is a bug with Terraform and should be reported as a GitHub Issue.
Please include the following information in your report:
This is due to a bug in Terraform, however the fix is to just rerun `ansible-playbook deploy_infra.yml` again, and Terraform will pick up where it left off. This does not always happen, but this is the current workaround if you see it.
Even if server is configured correctly, sometimes it may not bind the appropriate 4000 port due to unknown reason. If so, simply go to the appropriate nested blockscout folder, kill and rerun server. For example, you can use the following command: `pkill beam.smp && pkill node && sleep 10 && mix phx.server`.