This post is the third one of a series on Nickel, a new configuration language that I’ve been working on. In this post, I explore the design of Nickel’s type system, which mixes static and dynamic typing, and the reasons behind this choice.

1. Presenting Nickel: better configuration for less
2. Programming with contracts in Nickel
3. Types à la carte in Nickel

When other constraints allow it (the right tool for the job and all that), I personally go for a statically typed language whenever I can. But the Nickel language is a tad different, for it is a configuration language. You usually run a terminating program once on fixed inputs to generate a static text file. In this context, any type error will most likely either be triggered at evaluation anyway, typechecker or not, or be irrelevant (dead code). Even more if you add data validation, which typing can seldom totally replace: statically enforcing that a string is a valid URL, for example, would require a powerful type system. If you have to validate anyway, checking that a value is a number at run-time on the other hand is trivial.

Nickel also aims at being as interoperable with JSON as possible, and dealing with JSON values in a typed manner may be painful. For all these reasons, being untyped¹ in configuration code is appealing.

But this is not true of all code. Library code is written to be reused many times in many different settings. Although specialised in configuration, Nickel is a proper programming language, and one of its value propositions is precisely to provide abstractions to avoid repeating yourself. For reusable code, static typing sounds like the natural choice, bringing in all the usual benefits.

How to get out of this dilemma?

Gradual typing

Gradual typing reconciles the two belligerents by allowing both typed code and untyped code to coexist. Not only to coexist, but most importantly, to interact.

One common use-case of gradual typing is to retrofit static typing on top of an existing dynamically typed language, allowing to gradually — hence the name — type an existing codebase. In the case of Nickel, gradual typing is used on its own, because optional typing makes sense. In both situations, gradual typing provides a formal and principled framework to have both typed and untyped code living in a relative harmony.

Promises, promises!

Since configuration code is to be untyped, and make for the majority of Nickel code, untyped is the default. A basic configuration looks like JSON, up to minor syntactic differences:

{
  host = "google.com",
  port = 80,
  protocol = "http",
}

Typechecking is triggered by a type annotation, introduced by :. Annotations can either be apposed to a variable name or to an expression:

let makePort : Str -> Num = fun protocol =>
  if protocol == "http" then
    80
  else if protocol == "ftp" then
    21
  else
    null in
let unusedBad = 10 ++ "a" in
{
  port = makePort protocol,
  protocol = ("ht" ++ "tp" : Str),
}

In this example, makePort is a function taking a string and returning a number. It is annotated, causing the typechecker to kick in. It makes sure that each sub-expression is well-typed. Notice that subterms don’t need any other annotation: Nickel is able to guess most of the types using unification-based type inference.

Such a static type annotation is also called a promise, as you make a firm promise to the typechecker about the type of an expression.

Static typechecking ends with makePort, and although unusedBad is clearly ill-typed (concatenating a number and a string), it won’t cause any typechecking error.

Can you guess the result of trying to run this program?

error: Incompatible types
  ┌─ repl-input-1:7:5
  │
7 │     null in
  │     ^^^^ this expression
  │
  = The type of the expression was expected to be `Num`
  = The type of the expression was inferred to be `Dyn`
  = These types are not compatible

The typechecker rightly complains than null is not a number. If we fix this (for now, substituting it with -1), the programs runs correctly:

$nickel export <<< ...
{
  "port": 80,
  "protocol": "http"
}

unusedBad doesn’t cause any error at run-time. Due to laziness, it is never evaluated. If we were to add a type annotation for it though, the typechecker would reject our program.

To recap, the typechecker is a lurker by default, letting us do pretty much what we want. It is triggered by a type annotation exp : Type, in which case it switches on and statically typechecks the expression.

Who’s to be blamed

So far, so good. Now, consider the following example:

let add : Num -> Num -> Num = fun x y => x + y in
add "a" 0

As far as typechecking goes, only the body of add is to be checked, and it is well-typed. However, add is called with a parameter of the wrong type by an untyped chunk. Without an additional safety mechanism, one would get this runtime type error:

error: Type error
  ┌─ repl-input-0:1:26
  │
1 │ let add : Num -> Num -> Num = fun x y => x + y
  │                                              ^ This expression has type Str, but Num was expected
  │
[..]

The error first points to a location inside the body of add. It doesn’t feel right, and kinda defeats the purpose of typing: while our function should be guaranteed to be well-behaved, any untyped code calling to it can sneak in ill-typed terms via the parameters. In turn, this raises errors that are located in well behaving code. In this case, which is deliberately trivial, the end of the error message elided as [..] turns out to give us enough information to diagnose the actual issue. This is not necessarily the case for more complex real life functions.

There’s not much we can do statically. The whole point of gradual typing being to accommodate for untyped code, we can’t require the call site to be statically typed. Otherwise, types would contaminate everything and we might as well make our language fully statically typed.

We can do something at run-time, though. Assuming type soundness, no type error should arise in the body of a well-typed function at evaluation. The only sources of type errors are the parameters provided by the caller.

Thus, we just have to control the boundary between typed and untyped blocks by checking the validity of the parameters provided by the caller. If we actually input the previous example in the Nickel REPL, we don’t get the above error message, but this one instead:

nickel> let add : Num -> Num = fun x y => x + y in
add 5 "a"

error: Blame error: contract broken by the caller.
  ┌─ :1:8
  │
1 │ Num -> Num -> Num
  │        --- expected type of the argument provided by the caller
  │
  ┌─ repl-input-6:1:31
  │
1 │ let add : Num -> Num -> Num = fun x y => x + y
  │                               ^^^^^^^^^^^^^^^^ applied to this expression
  │
[..]
note:
  ┌─ repl-input-7:1:1
  │
1 │ add 5 "a"
  │ --------- (1) calling <func>
[..]

This error happens before the body of add is even entered. The Nickel interpreter wraps add in a function that first checks the parameters to be of the required type before actually calling add. Sounds familiar? This is exactly what we described in the post on contracts. That is, typed functions are automatically guarded by a higher-order contract. This ensures that type errors are caught before entering well-typed land, which greatly improves error locality.

In summary, to avoid sneaking ill-typed value in well-typed blocks, the Nickel interpreter automatically protects typed functions by inserting appropriate contracts.

A contract with the devil

We have dealt with the issue of calling typed code from untyped code. A natural follow-up is to examine the dual case: how can one use definitions living in untyped code inside a statically typed context? Consider the following example:

// this example does NOT typecheck
let f = fun x => if x then 10 else "a" in
let doStuffToNum: Num -> Num = fun arg =>
  arg + (f true) in

doStuffToNum 1

The typed function doStuffToNum calls to an untyped function f. f true turns out to be a number indeed, but f itself is not well-typed, because the types of the if and the else branch don’t match. No amount of additional type annotations can make this program accepted.

See what happens in practice:

error: Incompatible types
  ┌─ repl-input-1:3:10
  │
3 │   arg + (f true) in
  │          ^ this expression
  │
  = The type of the expression was expected to be `_a -> Num`
  = The type of the expression was inferred to be `Dyn`
  = These types are not compatible

f not being annotated, the typechecker can’t do much better than to give f the dynamic type Dyn (although in some trivial cases, it can infer a better type). Since it was expecting a function returning Num, it complains. It seems we are doomed to restrict our usage of untyped variables to trivial expressions, or to type them all.

Or are we? One more time, contracts come to the rescue. Going back to the post on contracts again, contracts are enforced similarly to types, but using | instead of :. Let us fix our example:

let doStuffToNum: Num -> Num = fun arg =>
  arg + (f true | Num) in

We just applied a Num contract to f true, and surprise, this code typechecks! Our typechecker didn’t get magically smarter. By adding this contract check, we ensure the fundamental property that f true will either evaluate to a number or fail at run-time with an appropriate contract error. In particular, no value of type Str, for example, can ever enter our well-typed paradise add. When writing exp | Type in a typed block, two things happen:

1. The typechecker switches back to the default mode inside exp, where it doesn’t enforce anything until the next promise (annotation).
2. The typechecker blindly assumes that the type of exp | Type is Type. Hence, contract checks are also called assume.

Put differently, a contract check is considered a type cast by the static type system, whose correctness check is delayed to run-time.

Behold: this implies that something like (5 | Bool) : Bool typechecks. How outrageous, for a typed functional language proponent. But even languages like Haskell have some side conditions to type soundness: b :: Bool doesn’t guarantee that b evaluate to a boolean, for it can loop, or raise an exception. Minimizing the amount of such possibilities is surely for the better, but the important point remains that b never silently evaluates to a string.

To conclude, we can use contracts as delayed type casts, to make the typechecker accept untyped terms in a typed context. This is useful to import values from untyped code, or to write expressions that we know are correct but that the typechecker wouldn’t accept.

Conclusion

There is more to say about Nickel’s type system, that features parametric polymorphism or structural typing with row polymorphism for records, to cite some interesting aspects. The purpose of this post is rather to explain the essence of gradual typing, why it makes sense in the context of Nickel, and how it is implemented. We’ve seen that contracts are a fundamental ingredient for the interaction between typed and untyped code in both ways.

• The MySQL DBMS container can manage multiple databases deployed by Disnix.
• The Apache Tomcat servlet container can manage multiple Java web applications deployed by Disnix.
• systemd can act as a container that manages multiple systemd units deployed by Disnix.

• NixOps can deploy networks of NixOS machines, both physical and virtual machines (in the cloud), such as Amazon EC2.
  
  As part of a NixOS configuration, the Disnix service can be deployed that facilitates multi-user installations. The Dysnomia NixOS module can expose all relevant container services installed by NixOS as container deployment targets.
• disnixos-deploy-network is a tool that is included with the DisnixOS extension toolset. Since services in Disnix can be any kind of deployment unit, it is also possible to deploy an entire NixOS configuration as a service. This tool is mostly developed for demonstration purposes.
  
  A limitation of this tool is that it cannot instantiate virtual machines and bootstrap Disnix.
• Disnix itself. The above solutions are all NixOS-based, a software distribution that is Linux-based and fully managed by the Nix package manager.
  
  Although NixOS is very powerful, it has two drawbacks for Disnix:
  
  
  • NixOS uses the NixOS module system for configuring system aspects. It is very powerful but you can only deploy one instance of a system service -- Disnix can also work with multiple container instances of the same type on a machine.
  • Services in NixOS cannot be deployed to other kinds software distributions: conventional Linux distributions, and other operating systems, such as macOS and FreeBSD.
  
  To overcome these limitations, Disnix can also be used as a container deployment solution on any operating system that is capable of running Nix and Disnix. Services deployed by Disnix can automatically be exposed as container providers.
  
  Similar to disnix-deploy-network, a limitation of this approach is that it cannot be used to bootstrap Disnix.

• The infrastructure parts and service parts can be managed by different people with different specializations. For example, configuring and tuning an application server is a different responsibility than developing a Java web application.
• The service parts typically change more frequently than the infrastructure parts. As a result, they typically have different kinds of update cycles.
• The infrastructure components can typically be reused between projects (e.g. many systems use a database backend such as PostgreSQL or MySQL), whereas the service components are typically very project specific.

Deploying and exposing the Disnix service with the Nix process management framework

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, spoolDir ? "${stateDir}/spool"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  ids = if builtins.pathExists ./ids-bare.nix then (import ./ids-bare.nix).ids else {};

  constructors = import ../../services-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };
in
rec {
  sshd = {
    pkg = constructors.sshd {
      extraSSHDConfig = ''
        UsePAM yes
      '';
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  dbus-daemon = {
    pkg = constructors.dbus-daemon {
      services = [ disnix-service ];
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  disnix-service = {
    pkg = constructors.disnix-service {
      inherit dbus-daemon;
    };

    requiresUniqueIdsFor = [ "gids" ];
  };
}

• sshd is the OpenSSH server that makes it possible to remotely connect to the machine by using the SSH protocol.
• dbus-daemon runs a D-Bus system daemon, that is a requirement for the Disnix service. The disnix-service is propagated as a parameter, so that its service directory gets added to the D-Bus system daemon configuration.
• disnix-service is a service that executes deployment operations on behalf of an authorized unprivileged user. The disnix-service has a dependency on the dbus-service making sure that the latter gets activated first.

$ nixproc-supervisord-switch processes.nix

$ supervisorctl 
dbus-daemon                      RUNNING   pid 2374, uptime 0:00:34
disnix-service                   RUNNING   pid 2397, uptime 0:00:33
sshd                             RUNNING   pid 2375, uptime 0:00:34

{
  test1.properties.hostname = "192.168.2.1";
}

$ disnix-capture-infra infra-bootstrap.nix

{
  "test1" = {
    properties = {
      "hostname" = "192.168.2.1";
      "system" = "x86_64-linux";
    };
    containers = {
      echo = {
      };
      fileset = {
      };
      process = {
      };
      supervisord-program = {
        "supervisordTargetDir" = "/etc/supervisor/conf.d";
      };
      wrapper = {
      };
    };
    "system" = "x86_64-linux";
  };
}

• The echo, fileset and process container services are built-in container providers that any Dysnomia installation includes.
  
  The process container can be used to automatically deploy services that daemonize. Services that daemonize themselves do not require the presence of any external service.
• The supervisord-program container refers to the process supervisor that manages the services deployed by the Nix process management framework. It can also be used as a container for processes deployed by Disnix.
  

{ system, distribution, invDistribution, pkgs
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager ? "supervisord"
, nix-processmgmt ? ../../../nix-processmgmt
}:

let
  customPkgs = import ../top-level/all-packages.nix {
    inherit system pkgs stateDir logDir runtimeDir tmpDir forceDisableUserChange processManager nix-processmgmt;
  };

  ids = if builtins.pathExists ./ids.nix then (import ./ids.nix).ids else {};

  processType = import "${nix-processmgmt}/nixproc/derive-dysnomia-process-type.nix" {
    inherit processManager;
  };
in
rec {
  hello_world_server = rec {
    name = "hello_world_server";
    port = ids.ports.hello_world_server or 0;
    pkg = customPkgs.hello_world_server { inherit port; };
    type = processType;
    requiresUniqueIdsFor = [ "ports" ];
  };

  hello_world_client = {
    name = "hello_world_client";
    pkg = customPkgs.hello_world_client;
    dependsOn = {
      inherit hello_world_server;
    };
    type = "package";
  };
}

• The hello_world_server service is a simple service that listens on a TCP port for a "hello" message and responds with a "Hello world!" message.
• The hello_world_client service is a package providing a client executable that automatically connects to the hello_world_server.

{infrastructure}:

{
  hello_world_client = [ infrastructure.test1 ];
  hello_world_server = [ infrastructure.test1 ];
}

$ disnix-env -s services-without-proxy.nix \
  -i infrastructure.nix \
  -d distribution.nix \
  --extra-params '{ processManager = "supervisord"; }'

$ supervisorctl 
dbus-daemon                      RUNNING   pid 2374, uptime 0:09:39
disnix-service                   RUNNING   pid 2397, uptime 0:09:38
hello-world-server               RUNNING   pid 2574, uptime 0:00:06
sshd                             RUNNING   pid 2375, uptime 0:09:39

$ /nix/var/nix/profiles/disnix/default/bin/hello-world-client 
Trying 192.168.2.1...
Connected to 192.168.2.1.
Escape character is '^]'.
hello
Hello world!

Deploying container providers and exposing them

• The StaffTracker service is the front-end web application that shows an overview of staff members and their locations.
• The StaffService service is web service with a SOAP interface that provides read and write access to the staff records. The staff records are stored in the staff database.
• The RoomService service provides read access to the rooms records, that are stored in a separate rooms database.
• The ZipcodeService service provides read access to zip codes, that are stored in a separate zipcodes database.
• The GeolocationService infers the location of a staff member from its IP address using the GeoIP service.

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, spoolDir ? "${stateDir}/spool"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  ids = if builtins.pathExists ./ids-tomcat-mysql.nix then (import ./ids-tomcat-mysql.nix).ids else {};

  constructors = import ../../services-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };

  containerProviderConstructors = import ../../service-containers-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };
in
rec {
  sshd = {
    pkg = constructors.sshd {
      extraSSHDConfig = ''
        UsePAM yes
      '';
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  dbus-daemon = {
    pkg = constructors.dbus-daemon {
      services = [ disnix-service ];
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  tomcat = containerProviderConstructors.simpleAppservingTomcat {
    commonLibs = [ "${pkgs.mysql_jdbc}/share/java/mysql-connector-java.jar" ];
    webapps = [
      pkgs.tomcat9.webapps # Include the Tomcat example and management applications
    ];

    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  mysql = containerProviderConstructors.mysql {
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  disnix-service = {
    pkg = constructors.disnix-service {
      inherit dbus-daemon;
      containerProviders = [ tomcat mysql ];
    };

    requiresUniqueIdsFor = [ "gids" ];
  };
}

• tomcat is the Apache Tomcat server. The constructor function: simpleAppServingTomcat composes a configuration for a supported process manager, such as supervisord.
  
  Moreover, it bundles a Dysnomia container configuration file, and a Dysnomia module: tomcat-webapplication that can be used to manage the life-cycles of Java web applications embedded in the servlet container.
• mysql is the MySQL DBMS server. The constructor function also creates a process manager configuration file, and bundles a Dysnomia container configuration file and module that manages the life-cycles of databases.
• The container services above are propagated as containerProviders to the disnix-service. This function parameter is used to update the search paths for container configuration and modules, so that services can be deployed to these containers by Disnix.

$ disnix-capture-infra infra-bootstrap.nix
{
  "test1" = {
    properties = {
      "hostname" = "192.168.2.1";
      "system" = "x86_64-linux";
    };
    containers = {
      echo = {
      };
      fileset = {
      };
      process = {
      };
      supervisord-program = {
        "supervisordTargetDir" = "/etc/supervisor/conf.d";
      };
      wrapper = {
      };
      tomcat-webapplication = {
        "tomcatPort" = "8080";
        "catalinaBaseDir" = "/var/tomcat";
      };
      mysql-database = {
        "mysqlPort" = "3306";
        "mysqlUsername" = "root";
        "mysqlPassword" = "";
        "mysqlSocket" = "/var/run/mysqld/mysqld.sock";
      };
    };
    "system" = "x86_64-linux";
  };
}

$ disnix-env -s services.nix -i infrastructure.nix -d distribution.nix

Deploying multiple container provider instances

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, spoolDir ? "${stateDir}/spool"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  ids = if builtins.pathExists ./ids-tomcat-mysql-multi-instance.nix then (import ./ids-tomcat-mysql-multi-instance.nix).ids else {};

  constructors = import ../../services-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };

  containerProviderConstructors = import ../../service-containers-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };
in
rec {
  sshd = {
    pkg = constructors.sshd {
      extraSSHDConfig = ''
        UsePAM yes
      '';
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  dbus-daemon = {
    pkg = constructors.dbus-daemon {
      services = [ disnix-service ];
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  tomcat-primary = containerProviderConstructors.simpleAppservingTomcat {
    instanceSuffix = "-primary";
    httpPort = 8080;
    httpsPort = 8443;
    serverPort = 8005;
    ajpPort = 8009;
    commonLibs = [ "${pkgs.mysql_jdbc}/share/java/mysql-connector-java.jar" ];
    webapps = [
      pkgs.tomcat9.webapps # Include the Tomcat example and management applications
    ];
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  tomcat-secondary = containerProviderConstructors.simpleAppservingTomcat {
    instanceSuffix = "-secondary";
    httpPort = 8081;
    httpsPort = 8444;
    serverPort = 8006;
    ajpPort = 8010;
    commonLibs = [ "${pkgs.mysql_jdbc}/share/java/mysql-connector-java.jar" ];
    webapps = [
      pkgs.tomcat9.webapps # Include the Tomcat example and management applications
    ];
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  mysql-primary = containerProviderConstructors.mysql {
    instanceSuffix = "-primary";
    port = 3306;
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  mysql-secondary = containerProviderConstructors.mysql {
    instanceSuffix = "-secondary";
    port = 3307;
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  disnix-service = {
    pkg = constructors.disnix-service {
      inherit dbus-daemon;
      containerProviders = [ tomcat-primary tomcat-secondary mysql-primary mysql-secondary ];
    };

    requiresUniqueIdsFor = [ "gids" ];
  };
}

• We have configured two Apache Tomcat instances: tomcat-primary and tomcat-secondary. Both instances can co-exist because they have been configured in such a way that they listen to unique TCP ports and have a unique instance name composed from the instanceSuffix.
• We have configured two MySQL instances: mysql-primary and mysql-secondary. Similar to Apache Tomcat, they can both co-exist because they listen to unique TCP ports (e.g. 3306 and 3307) and have a unique instance name.
• Both the primary and secondary instances of the above services are propagated to the disnix-service (with the containerProviders parameter) making it possible for a client to discover them.

$ disnix-capture-infra infra-bootstrap.nix
{
  "test1" = {
    properties = {
      "hostname" = "192.168.2.1";
      "system" = "x86_64-linux";
    };
    containers = {
      echo = {
      };
      fileset = {
      };
      process = {
      };
      supervisord-program = {
        "supervisordTargetDir" = "/etc/supervisor/conf.d";
      };
      wrapper = {
      };
      tomcat-webapplication-primary = {
        "tomcatPort" = "8080";
        "catalinaBaseDir" = "/var/tomcat-primary";
      };
      tomcat-webapplication-secondary = {
        "tomcatPort" = "8081";
        "catalinaBaseDir" = "/var/tomcat-secondary";
      };
      mysql-database-primary = {
        "mysqlPort" = "3306";
        "mysqlUsername" = "root";
        "mysqlPassword" = "";
        "mysqlSocket" = "/var/run/mysqld-primary/mysqld.sock";
      };
      mysql-database-secondary = {
        "mysqlPort" = "3307";
        "mysqlUsername" = "root";
        "mysqlPassword" = "";
        "mysqlSocket" = "/var/run/mysqld-secondary/mysqld.sock";
      };
    };
    "system" = "x86_64-linux";
  };
}

{infrastructure}:

{
  GeolocationService = {
    targets = [
      { target = infrastructure.test1;
        container = "tomcat-webapplication-primary";
      }
    ];
  };
  RoomService = {
    targets = [
      { target = infrastructure.test1;
        container = "tomcat-webapplication-secondary";
      }
    ];
  };
  StaffService = {
    targets = [
      { target = infrastructure.test1;
        container = "tomcat-webapplication-primary";
      }
    ];
  };
  StaffTracker = {
    targets = [
      { target = infrastructure.test1;
        container = "tomcat-webapplication-secondary";
      }
    ];
  };
  ZipcodeService = {
    targets = [
      { target = infrastructure.test1;
        container = "tomcat-webapplication-primary";
      }
    ];
  };
  rooms = {
    targets = [
      { target = infrastructure.test1;
        container = "mysql-database-primary";
      }
    ];
  };
  staff = {
    targets = [
      { target = infrastructure.test1;
        container = "mysql-database-secondary";
      }
    ];
  };
  zipcodes = {
    targets = [
      { target = infrastructure.test1;
        container = "mysql-database-primary";
      }
    ];
  };
}

$ disnix-env -s services.nix -i infrastructure.nix -d distribution.nix

Using the Disnix web service for executing remote deployment operations

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, spoolDir ? "${stateDir}/spool"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  ids = if builtins.pathExists ./ids-tomcat-mysql.nix then (import ./ids-tomcat-mysql.nix).ids else {};

  constructors = import ../../services-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };

  containerProviderConstructors = import ../../service-containers-agnostic/constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir cacheDir spoolDir forceDisableUserChange processManager ids;
  };
in
rec {
  sshd = {
    pkg = constructors.sshd {
      extraSSHDConfig = ''
        UsePAM yes
      '';
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  dbus-daemon = {
    pkg = constructors.dbus-daemon {
      services = [ disnix-service ];
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  tomcat = containerProviderConstructors.disnixAppservingTomcat {
    commonLibs = [ "${pkgs.mysql_jdbc}/share/java/mysql-connector-java.jar" ];
    webapps = [
      pkgs.tomcat9.webapps # Include the Tomcat example and management applications
    ];
    enableAJP = true;
    inherit dbus-daemon;

    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  apache = {
    pkg = constructors.basicAuthReverseProxyApache {
      dependency = tomcat;
      serverAdmin = "admin@localhost";
      targetProtocol = "ajp";
      portPropertyName = "ajpPort";

      authName = "DisnixWebService";
      authUserFile = pkgs.stdenv.mkDerivation {
        name = "htpasswd";
        buildInputs = [ pkgs.apacheHttpd ];
        buildCommand = ''
          htpasswd -cb ./htpasswd admin secret
          mv htpasswd $out
        '';
      };
      requireUser = "admin";
    };

    requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  mysql = containerProviderConstructors.mysql {
    properties.requiresUniqueIdsFor = [ "uids" "gids" ];
  };

  disnix-service = {
    pkg = constructors.disnix-service {
      inherit dbus-daemon;
      containerProviders = [ tomcat mysql ];
      authorizedUsers = [ tomcat.name ];
      dysnomiaProperties = {
        targetEPR = "https://$(hostname)/DisnixWebService/services/DisnixWebService";
      };
    };

    requiresUniqueIdsFor = [ "gids" ];
  };
}

• The Apache Tomcat process instance is constructed with the containerProviderConstructors.disnixAppservingTomcat constructor function automatically deploying the DisnixWebService and providing the required configuration settings so that it can communicate with the disnix-service over the D-Bus system bus.
  
  Because the DisnixWebService requires the presence of the D-Bus system daemon, it is configured as a dependency for Apache Tomcat ensuring that it is started before Apache Tomcat.
• Connecting to the Apache Tomcat server including the DisnixWebService requires no authentication. To secure the web applications and the DisnixWebService, I have configured an apache reverse proxy that forwards connections to Apache Tomcat using the AJP protocol.
  
  Moreover, the reverse proxy protects incoming requests by using HTTP basic authentication requiring a username and password.

{
  test1.properties.targetEPR = "https://192.168.2.1/DisnixWebService/services/DisnixWebService";
}

$ export DISNIX_CLIENT_INTERFACE=disnix-soap-client
$ export DISNIX_TARGET_PROPERTY=targetEPR

$ export DISNIX_SOAP_CLIENT_USERNAME=admin
$ export DISNIX_SOAP_CLIENT_PASSWORD=secret

$ disnix-capture-infra infra-bootstrap.nix
{
  "test1" = {
    properties = {
      "hostname" = "192.168.2.1";
      "system" = "x86_64-linux";
      "targetEPR" = "https://192.168.2.1/DisnixWebService/services/DisnixWebService";
    };
    containers = {
      echo = {
      };
      fileset = {
      };
      process = {
      };
      supervisord-program = {
        "supervisordTargetDir" = "/etc/supervisor/conf.d";
      };
      wrapper = {
      };
      tomcat-webapplication = {
        "tomcatPort" = "8080";
        "catalinaBaseDir" = "/var/tomcat";
        "ajpPort" = "8009";
      };
      mysql-database = {
        "mysqlPort" = "3306";
        "mysqlUsername" = "root";
        "mysqlPassword" = "";
        "mysqlSocket" = "/var/run/mysqld/mysqld.sock";
      };
    };
    "system" = "x86_64-linux";
  }
  ;
}

Miscellaneous: using Docker containers as light-weight virtual machines

let
  pkgs = import <nixpkgs> {};

  createMutableMultiProcessImage = import ../nix-processmgmt/nixproc/create-image-from-steps/create-mutable-multi-process-image-universal.nix {
    inherit pkgs;
  };
in
createMutableMultiProcessImage {
  name = "disnix";
  tag = "test";
  contents = [ pkgs.mc pkgs.disnix ];
  exprFile = ./processes.nix;
  interactive = true;
  manpages = true;
  processManager = "supervisord";
}

$ nix-build
$ docker load -i result

$ docker network create --subnet=192.168.2.0/8 disnixnetwork

$ docker run --network disnixnetwork --ip 192.168.2.1 \
  --name containervm disnix:test

$ ssh-keygen -t ed25519 -f id_test -N ""

$ docker exec containervm mkdir -m0700 -p /root/.ssh
$ docker cp id_test.pub containervm:/root/.ssh/authorized_keys
$ docker exec containervm chmod 600 /root/.ssh/authorized_keys
$ docker exec containervm chown root:root /root/.ssh/authorized_keys

$ ssh-add id_test
$ export DISNIX_REMOTE_CLIENT=disnix-client

Conclusion

• Because every process instance is constructed from a constructor function that makes all instance parameters explicit, you are guarded against common configuration errors such as undeclared dependencies.
  
  For example, the DisnixWebService-enabled Apache Tomcat service requires access to the dbus-service providing the system bus. Not having this service in the processes model, causes a missing function parameter error.
• Function parameters in the processes model make it more clear that a process depends on another process and what that relationship may be. For example, with the containerProviders parameter it becomes IMO really clear that the disnix-service uses them as potential deployment targets for services deployed by Disnix.
  
  In comparison, the implementations of the Disnix and Dysnomia NixOS modules are far more complicated and monolithic -- the Dysnomia module has to figure for all potential container services deployed as part of a NixOS configuration, their properties, convert them to Dysnomia configuration files, and configure the systemd configuration for the disnix-service for proper activation ordering.
  
  The wants parameter (used for activation ordering) is just a list of strings, not knowing whether it contains valid references to services that have been deployed already.

Availability

Future work

I’m very pleased to announce Gomod2nix, a new tool to create Go packages with Nix!

Gomod2nix is a code generation tool whose main focus is addressing the correctness and usability concerns I have with the current Go packaging solutions. It offers a composable override interface, which allows overrides to be shared across projects, simplifying the packaging of complex packages. As a bonus, it also boasts much better cache hit rates than other similar solutions, owing to not abusing fixed-output derivations.

I also took the opportunity of this new package to address some long-standing annoyances with existing Go Nix tooling. For instance Gomod2nix disables CGO by default, this let me enable static Go binaries by default. Changing the defaults in existing tooling would be very difficult as it would break a lot of existing packages, especially those maintained outside of Nixpkgs, which depend on the present behavior.

In order to motivate this new tool, let’s take a look at how Go dependency management evolved.

The developmentent of Trustix (which Gomod2nix was developed for) is funded by NLNet foundation and the European Commission’s Next Generation Internet programme through the NGI Zero PET (privacy and trust enhancing technologies) fund.

A history of Go packaging

In Go you don’t add dependencies to a manifest, but instead you add a dependency to your project by simply adding an import to a source file:

package main

import (
    "fmt"
    "github.com/tweag/foo"
)

func main() {
    fmt.Println(foo.SomeVar)
}

and the go tool will figure out how to fetch this dependency.

From the beginning Go didn’t have package management in the traditional sense. Instead it enforced a directory structure that mimics the import paths. A project called github.com/tweag/foo that depends on github.com/tweag/bar expects to be located in a directory structure looking like:

$GOPATH/github.com/tweag/foo
$GOPATH/github.com/tweag/foo/main.go
$GOPATH/github.com/tweag/bar
$GOPATH/github.com/tweag/bar/main.go

This may not look so bad in this very simple example, but since this structure is not only enforced for your packages but also your dependencies, this quickly becomes messy. The $GOPATH mechanism has been one of the truly sore spots of Go development. Under this packaging paradigm you are expected to always use the latest Git master of all your dependencies and there is no version locking.

Dep was the first official packaging experiment for Go. This tool improved upon $GOPATH not by removing it, but by hiding that complexity from the user entirely. Besides that, it added lock files and a SAT dependency solver.

Finally, armed with the learnings and some critique of Dep, the Go team decided to develop a new simpler solution — Go modules. It addressed a number of perceived problems with Dep, like the fact that the use of semver and SAT solvers are far too complicated for the requirements Go has. As of now, Dep is deprecated, and Go modules is the solution I developed against.

A tale of two lock files

Originally, I set out to design gomod2nix in the same way as poetry2nix, a Python packaging solution for Nix. In poetry2nix one refers directly to a Poetry lock file from Nix, and poetry2nix does all the job needed to create the Nix package, which is very convenient.

However, this wasn’t possible here because of the design of Go modules, for reasons that I will explain below. As a consequence, gomod2nix is a Nix code generation tool. One feeds lock files to it, and it generates Nix expressions defining the corresponding packages.

In the following, I will compare the Poetry and Go lock files, and show which limitations the Go file format and import mechanism imposes upon us.

Exposed dependency graphs

First, let’s look at an excerpt of Poetry’s lock file:

[[package]]
name = "cachecontrol"
version = "0.12.6"
description = "httplib2 caching for requests"
category = "main"
optional = false
python-versions = ">=2.7, !=3.0.*, !=3.1.*, !=3.2.*, !=3.3.*"

[package.dependencies]
lockfile = {version = ">=0.9", optional = true, markers = "extra == \"filecache\""}
msgpack = ">=0.5.2"
requests = "*"

And also at go.sum:

github.com/davecgh/go-spew v1.1.0 h1:ZDRjVQ15GmhC3fiQ8ni8+OwkZQO4DARzQgrnXU1Liz8=
github.com/davecgh/go-spew v1.1.0/go.mod h1:J7Y8YcW2NihsgmVo/mv3lAwl/skON4iLHjSsI+c5H38=
github.com/pmezard/go-difflib v1.0.0 h1:4DBwDE0NGyQoBHbLQYPwSUPoCMWR5BEzIk/f1lZbAQM=
github.com/pmezard/go-difflib v1.0.0/go.mod h1:iKH77koFhYxTK1pcRnkKkqfTogsbg7gZNVY4sRDYZ/4=
github.com/stretchr/objx v0.1.0 h1:4G4v2dO3VZwixGIRoQ5Lfboy6nUhCyYzaqnIAPPhYs4=
github.com/stretchr/objx v0.1.0/go.mod h1:HFkY916IF+rwdDfMAkV7OtwuqBVzrE8GR6GFx+wExME=
gopkg.in/check.v1 v0.0.0-20161208181325-20d25e280405 h1:yhCVgyC4o1eVCa2tZl7eS0r+SDo693bJlVdllGtEeKM=
gopkg.in/check.v1 v0.0.0-20161208181325-20d25e280405/go.mod h1:Co6ibVJAznAaIkqp8huTwlJQCZ016jof/cbN4VW5Yz0=
gopkg.in/yaml.v3 v3.0.0-20200313102051-9f266ea9e77c h1:dUUwHk2QECo/6vqA44rthZ8ie2QXMNeKRTHCNY2nXvo=
gopkg.in/yaml.v3 v3.0.0-20200313102051-9f266ea9e77c/go.mod h1:K4uyk7z7BCEPqu6E+C64Yfv1cQ7kz7rIZviUmN+EgEM=

After squinting at these files for a while we can already see some radical differences in semantics, most notably that go.sum is structured as a flat list rather than a graph. Of course, all dependencies to the build are listed in go.sum, but we don’t know what depends on what. What this means for us in Nix is that we have no good unit of incrementality — everything has to be built together — while Poetry can build dependencies separately.

Bespoke formats

Go modules use its own Go-like file format, while Poetry uses TOML to serialize both its manifest and lock files.

While this format is simple and writing a parser for it isn’t hard, it makes the lives of tooling authors harder. It would be much easier if a standard format for data interchange was used, rather than a custom format.

Bespoke hashes

The next problem with Go modules is its use of a custom hashing mechanism that’s fundamentally incompatible with how Nix hashes paths.

As explained in Eelco Dolstra’s thesis The Purely Functional Software Deployment Model Nix uses it’s own reproducible archive format NAR, which is used for both uploading build results and for directory hashing.

The Go developers faced with similar concerns created their own directory hashing scheme, which unfortunately is fundamentally incompatible with Nix hashes. I don’t see how Go modules could have done this any better, but the situation is unfortunate.

Dynamic package name resolving

In the previous example, I showed how a Go import path looks like. Sadly it turns out that the surface simplicity of those paths hide a lot of underlying logic.

Internally, these import paths are handled by the RepoRootForImport family of functions in the vcs (version control system) package, which maps import paths to repository URLs and VCS types. Some of these are matched statically using regex but others use active probing.

This is a true showstopper for a pure-Nix Go packaging solution, and the reason why Gomod2nix is a code generation tool — we don’t have network access in the Nix evaluator, making it impossible to correctly resolve VCS from a Nix evaluation.

Solutions to go modules packaging

The points above make our limitations clear. With these in mind, let’s discuss how Go packaging solutions were conceived.

Code generation: vgo2nix

My first attempt at creating a tool for packaging Go modules was vgo2nix, another code generation tool. It was written very shortly after modules were announced, and at the time the tooling support for them wasn’t good. For example, there wasn’t a parser for go.mod published back then.

It was based on the older Nixpkgs Go abstraction buildGoPackage, emulating a $GOPATH based build unfortunately with some assumptions that are not true.

Let’s again look at an excerpt from go.sum:

github.com/Azure/go-autorest/autorest v0.9.0/go.mod h1:xyHB1BMZT0cuDHU7I0+g046+BFDTQ8rEZB0s4Yfa6bI=
github.com/Azure/go-autorest/autorest v0.9.3/go.mod h1:GsRuLYvwzLjjjRoWEIyMUaYq8GNUx2nRB378IPt/1p0=
github.com/Azure/go-autorest/autorest/adal v0.5.0/go.mod h1:8Z9fGy2MpX0PvDjB1pEgQTmVqjGhiHBW7RJJEciWzS0=
github.com/Azure/go-autorest/autorest/adal v0.8.0/go.mod h1:Z6vX6WXXuyieHAXwMj0S6HY6e6wcHn37qQMBQlvY3lc=
github.com/Azure/go-autorest/autorest/adal v0.8.1/go.mod h1:ZjhuQClTqx435SRJ2iMlOxPYt3d2C/T/7TiQCVZSn3Q=
github.com/Azure/go-autorest/autorest/date v0.1.0/go.mod h1:plvfp3oPSKwf2DNjlBjWF/7vwR+cUD/ELuzDCXwHUVA=
github.com/Azure/go-autorest/autorest/date v0.2.0/go.mod h1:vcORJHLJEh643/Ioh9+vPmf1Ij9AEBM5FuBIXLmIy0g=

These packages are all developed in the same repository but have different tags, and in this case vgo2nix would incorrectly only clone one version of the repository and sacrifice the correctness we get from modules because of how $GOPATH is set up.

Fixed-output derivations: buildGoModule

The buildGoModule tool is the most popular solution for Go packaging right now in Nixpkgs. A typical buildGoModule package looks something like:

{ buildGoModule, fetchFromGitHub, lib }:

buildGoModule {
  pname = "someName";
  version = "0.0.1";

  src = fetchFromGitHub { ... };

  vendorSha256 = "1500vim2lmkkls758pwhlx3piqbw6ap0nnhdwz9pcxih4s4as2nk";
}

The buildGoModule package is designed around fixed-output derivations, which means that a single derivation is created where all the dependencies of the package you want to build are wrapped, and only a single hash of the derivation is specified. It fetches all dependencies in the fixed output, creating a vendor directory which is used for the build.

This has several issues, most notably there is no sharing of dependencies between packages that depend on the same Go module.

The other notable issue is that it forces developers to remember editing the vendorSha256 attribute separately from the already existing hash/sha256 attribute on the derivation. Forgetting to do so can not only lead to incorrect builds but also be frustrating when working with larger packages that takes a long time to build, and only very late in the build notice that something was broken so you have to start over from scratch.

Because of the lack of hash granularity the build needs to clone every dependency every time the vendorSha256 is invalidated, and cannot use the cache from previous builds.

Fixed-output derivations can also be considered an impurity, and there is a push to restrict them.

My solution: gomod2nix

Approach-wise gomod2nix positions itself right between vgo2nix and buildGoModule. It’s still a code generation tool like vgo2nix, but fully embraces the Go modules world and only supports Go modules based builds — the old GOPATH way is unsupported. It uses the same vendoring approach that buildGoModule uses, but instead of vendoring the actual sources in a derivation, it uses symlinks instead. In that way, dependencies can be fetched separately, and identical dependency source trees can be shared between multiple different packages in the Nix store.

From a user perspective the workflow is largely similar to vgo2nix:

• You write a basic expression looking like:

pkgs.buildGoApplication {
  pname = "gomod2nix-example";
  version = "0.1";
  src = ./.;
  modules = ./gomod2nix.toml;
}

• Run the code generation tool: $ gomod2nix

Conclusion

Go packaging looks very simple on the surface, but murky details lure around underneath, and there are lots of tiny details to get right to correctly create a Go package in a sandboxed environment like Nix.

I couldn’t get the best-in-class user experience I was hoping for and gotten used to with Poetry2nix. Code generation adds extra steps to the development process and requires either a developer or a test pipeline to keep the Nix expressions in sync with the language specific lock files, something that requires discipline and takes extra time and effort. Despite that, it turned out there were major wins to be had regarding creating a new packaging solution.

The development of gomod2nix is funded by NLNet through the PET(privacy and trust enhancing technologies) fund. gomod2nix is being developed as a part of Trustix.

• It constructs an image that runs a Linux and Docker compatible process manager as an entry point. Currently, it supports supervisord, sysvinit, disnix and s6-rc.
• The Nix process management framework is used to build a configuration for a system that consists of multiple processes, that will be managed by any of the supported process managers.

$ docker exec -it mycontainer /bin/bash

$ apt install file

Creating a function for building mutable Docker images

• Docker containers are reproducible, because they are constructed from images that consist of immutable layers identified by hash codes derived from their contents.
• Nix package builds are reproducible, because they are stored in isolation in a Nix store and made immutable (the files' permissions are set read-only). In the construction process of the packages, many side effects are mitigated.
  
  As a result, when the hash code prefix of a package (derived from all build inputs) is the same, then the build output is also (nearly) bit-identical, regardless of the machine on which the package was built.

Deploying the base system

supervisord --nodaemon \
  --configuration /etc/supervisor/supervisord.conf \
  --logfile /var/log/supervisord.log \
  --pidfile /var/run/supervisord.pid

[supervisord]

[include]
files=conf.d/*

Deploying process instances

$ nix-channel --add https://nixos.org/channels/nixpkgs-unstable
$ nix-channel --update

$ nixproc-supervisord-switch

• First, it builds supervisord configuration files from the processes model (this step also includes deploying all required packages and service configuration files)
• It creates symlinks for each configuration file belonging to a process instance in the writable conf.d directory
• It instructs supervisord to reload the configuration so that only obsolete processes get deactivated and new services activated, causing unchanged processes to remain untouched.

Initial deployment of the system

cat > /bin/bootstrap <<EOF
#! ${pkgs.stdenv.shell} -e

# Configure Nix channels
nix-channel --add ${channelURL}
nix-channel --update

# Deploy the processes model (in a child process)
nixproc-${input.processManager}-switch &

# Overwrite the bootstrap script, so that it simply just
# starts the process manager the next time we start the
# container
cat > /bin/bootstrap <<EOR
#! ${pkgs.stdenv.shell} -e
exec ${cmd}
EOR

# Chain load the actual process manager
exec ${cmd}
EOF
chmod 755 /bin/bootstrap

• First, a Nix channel is configured and updated so that we can install packages from the Nixpkgs collection and obtain substitutes.
• The next step is deploying the processes model by running the nixproc-*-switch tool for a supported process manager. This process is started in the background (as a child process) -- we can use this trick to force the managing bash shell to load our desired process supervisor as soon as possible.
  
  Ultimately, we want the process manager to become responsible for supervising any other process running in the container.
• After the deployment process is started in the background, the bootstrap script is overridden by a bootstrap script that becomes our real entry point -- the process manager that we want to use, such as supervisord.
  
  Overriding the bootstrap script makes sure that the next time we start the container, it will start instantly without attempting to deploy the system again.
• Finally, the bootstrap script "execs" into the real process manager, becoming the new PID 1 process. When the deployment of the system is done (the nixproc-*-switch process that still runs in the background), the process manager becomes responsible for reaping it.

A simple usage scenario

let
  pkgs = import <nixpkgs> {};

  nix-processmgmt = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt.git;
    ref = "master";
  };

  createMutableMultiProcessImage = import "${nix-processmgmt}/nixproc/create-image-from-steps/create-mutable-multi-process-image-universal.nix" {
    inherit pkgs;
  };
in
createMutableMultiProcessImage {
  name = "multiprocess";
  tag = "test";
  contents = [ pkgs.mc ];
  exprFile = ./processes.nix;
  idResourcesFile = ./idresources.nix;
  idsFile = ./ids.nix;
  processManager = "supervisord"; # sysvinit, disnix, s6-rc are also valid options
}

• The name, tag, and contents parameters specify the image name, tag and the packages that need to be included in the image.
• The exprFile parameter refers to a processes model that captures the configurations of the process instances that need to be deployed.
• The idResources parameter refers to an ID resources model that specifies from which resource pools unique IDs need to be selected.
• The idsFile parameter refers to an IDs model that contains the unique ID assignments for each process instance. Unique IDs resemble TCP/UDP port assignments, user IDs (UIDs) and group IDs (GIDs).
• We can use the processManager parameter to select the process manager we want to use. In the above example it is supervisord, but other options are also possible.

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  nix-processmgmt = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt.git;
    ref = "master";
  };

  ids = if builtins.pathExists ./ids.nix then (import ./ids.nix).ids else {};

  sharedConstructors = import "${nix-processmgmt}/examples/services-agnostic/constructors/constructors.nix" {
    inherit pkgs stateDir runtimeDir logDir cacheDir tmpDir forceDisableUserChange processManager ids;
  };

  constructors = import "${nix-processmgmt}/examples/webapps-agnostic/constructors/constructors.nix" {
    inherit pkgs stateDir runtimeDir logDir tmpDir forceDisableUserChange processManager ids;
  };
in
rec {
  webapp = rec {
    port = ids.webappPorts.webapp or 0;
    dnsName = "webapp.local";

    pkg = constructors.webapp {
      inherit port;
    };

    requiresUniqueIdsFor = [ "webappPorts" "uids" "gids" ];
  };

  nginx = rec {
    port = ids.nginxPorts.nginx or 0;

    pkg = sharedConstructors.nginxReverseProxyHostBased {
      webapps = [ webapp ];
      inherit port;
    } {};

    requiresUniqueIdsFor = [ "nginxPorts" "uids" "gids" ];
  };
}

$ nix-build

$ docker load -i result

$ docker run -it --name webapps --network host multiprocess:test
unpacking channels...
warning: Nix search path entry '/nix/var/nix/profiles/per-user/root/channels' does not exist, ignoring
created 1 symlinks in user environment
2021-02-21 15:29:29,878 CRIT Supervisor is running as root.  Privileges were not dropped because no user is specified in the config file.  If you intend to run as root, you can set user=root in the config file to avoid this message.
2021-02-21 15:29:29,878 WARN No file matches via include "/etc/supervisor/conf.d/*"
2021-02-21 15:29:29,897 INFO RPC interface 'supervisor' initialized
2021-02-21 15:29:29,897 CRIT Server 'inet_http_server' running without any HTTP authentication checking
2021-02-21 15:29:29,898 INFO supervisord started with pid 1
these derivations will be built:
  /nix/store/011g52sj25k5k04zx9zdszdxfv6wy1dw-credentials.drv
  /nix/store/1i9g728k7lda0z3mn1d4bfw07v5gzkrv-credentials.drv
  /nix/store/fs8fwfhalmgxf8y1c47d0zzq4f89fz0g-nginx.conf.drv
  /nix/store/vxpm2m6444fcy9r2p06dmpw2zxlfw0v4-nginx-foregroundproxy.sh.drv
  /nix/store/4v3lxnpapf5f8297gdjz6kdra8g7k4sc-nginx.conf.drv
  /nix/store/mdldv8gwvcd5fkchncp90hmz3p9rcd99-builder.pl.drv
  /nix/store/r7qjyr8vr3kh1lydrnzx6nwh62spksx5-nginx.drv
  /nix/store/h69khss5dqvx4svsc39l363wilcf2jjm-webapp.drv
  /nix/store/kcqbrhkc5gva3r8r0fnqjcfhcw4w5il5-webapp.conf.drv
  /nix/store/xfc1zbr92pyisf8lw35qybbn0g4f46sc-webapp.drv
  /nix/store/fjx5kndv24pia1yi2b7b2bznamfm8q0k-supervisord.d.drv
these paths will be fetched (78.80 MiB download, 347.06 MiB unpacked):
...

$ curl -H 'Host: webapp.local' http://localhost:8080
<!DOCTYPE html>
<html>
  <head>
    <title>Simple test webapp</title>
  </head>
  <body>
    Simple test webapp listening on port: 5000
  </body>
</html>

$ docker exec -it webapps /bin/bash

$ mcedit /etc/nixproc/processes.nix

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  nix-processmgmt = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt.git;
    ref = "master";
  };

  ids = if builtins.pathExists ./ids.nix then (import ./ids.nix).ids else {};

  sharedConstructors = import "${nix-processmgmt}/examples/services-agnostic/constructors/constructors.nix" {
    inherit pkgs stateDir runtimeDir logDir cacheDir tmpDir forceDisableUserChange processManager ids;
  };

  constructors = import "${nix-processmgmt}/examples/webapps-agnostic/constructors/constructors.nix" {
    inherit pkgs stateDir runtimeDir logDir tmpDir forceDisableUserChange processManager ids;
  };
in
rec {
  webapp = rec {
    port = ids.webappPorts.webapp or 0;
    dnsName = "webapp.local";

    pkg = constructors.webapp {
      inherit port;
    };

    requiresUniqueIdsFor = [ "webappPorts" "uids" "gids" ];
  };

  webapp2 = rec {
    port = ids.webappPorts.webapp2 or 0;
    dnsName = "webapp2.local";

    pkg = constructors.webapp {
      inherit port;
      instanceSuffix = "2";
    };

    requiresUniqueIdsFor = [ "webappPorts" "uids" "gids" ];
  };

  nginx = rec {
    port = ids.nginxPorts.nginx or 0;

    pkg = sharedConstructors.nginxReverseProxyHostBased {
      webapps = [ webapp webapp2 ];
      inherit port;
    } {};

    requiresUniqueIdsFor = [ "nginxPorts" "uids" "gids" ];
  };
}

$ nixproc-supervisord-switch

$ supervisorctl 
nginx                            RUNNING   pid 847, uptime 0:00:08
webapp                           RUNNING   pid 459, uptime 0:05:54
webapp2                          RUNNING   pid 846, uptime 0:00:08
supervisor>

$ curl -H 'Host: webapp2.local' http://localhost:8080
<!DOCTYPE html>
<html>
  <head>
    <title>Simple test webapp</title>
  </head>
  <body>
    Simple test webapp listening on port: 5001
  </body>
</html>

A more interesting example: Hydra

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  nix-processmgmt = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt.git;
    ref = "master";
  };

  nix-processmgmt-services = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt-services.git;
    ref = "master";
  };

  constructors = import "${nix-processmgmt-services}/services-agnostic/constructors.nix" {
    inherit nix-processmgmt pkgs stateDir runtimeDir logDir tmpDir cacheDir forceDisableUserChange processManager;
  };

  instanceSuffix = "";
  hydraUser = hydraInstanceName;
  hydraInstanceName = "hydra${instanceSuffix}";
  hydraQueueRunnerUser = "hydra-queue-runner${instanceSuffix}";
  hydraServerUser = "hydra-www${instanceSuffix}";
in
rec {
  nix-daemon = {
    pkg = constructors.nix-daemon;
  };

  postgresql = rec {
    port = 5432;
    postgresqlUsername = "postgresql";
    postgresqlPassword = "postgresql";
    socketFile = "${runtimeDir}/postgresql/.s.PGSQL.${toString port}";

    pkg = constructors.simplePostgresql {
      inherit port;
      authentication = ''
        # TYPE  DATABASE   USER   ADDRESS    METHOD
        local   hydra      all               ident map=hydra-users
      '';
      identMap = ''
        # MAPNAME       SYSTEM-USERNAME          PG-USERNAME
        hydra-users     ${hydraUser}             ${hydraUser}
        hydra-users     ${hydraQueueRunnerUser}  ${hydraUser}
        hydra-users     ${hydraServerUser}       ${hydraUser}
        hydra-users     root                     ${hydraUser}
        # The postgres user is used to create the pg_trgm extension for the hydra database
        hydra-users     postgresql               postgresql
      '';
    };
  };

  hydra-server = rec {
    port = 3000;
    hydraDatabase = hydraInstanceName;
    hydraGroup = hydraInstanceName;
    baseDir = "${stateDir}/lib/${hydraInstanceName}";
    inherit hydraUser instanceSuffix;

    pkg = constructors.hydra-server {
      postgresqlDBMS = postgresql;
      user = hydraServerUser;
      inherit nix-daemon port instanceSuffix hydraInstanceName hydraDatabase hydraUser hydraGroup baseDir;
    };
  };

  hydra-evaluator = {
    pkg = constructors.hydra-evaluator {
      inherit nix-daemon hydra-server;
    };
  };

  hydra-queue-runner = {
    pkg = constructors.hydra-queue-runner {
      inherit nix-daemon hydra-server;
      user = hydraQueueRunnerUser;
    };
  };

  apache = {
    pkg = constructors.reverseProxyApache {
      dependency = hydra-server;
      serverAdmin = "admin@localhost";
    };
  };
}

• The nix-daemon process is a service that comes with Nix package manager to facilitate multi-user package installations. The nix-daemon carries out builds on behalf of a user.
  
  Hydra requires it to perform builds as an unprivileged Hydra user and uses the Nix protocol to more efficiently orchestrate large builds.
• Hydra uses a PostgreSQL database backend to store data about projects and builds.
  
  The postgresql process refers to the PostgreSQL database management system (DBMS) that is configured in such a way that the Hydra components are authorized to manage and modify the Hydra database.
• hydra-server is the front-end of the Hydra service that provides a web user interface. The initialization procedure of this service is responsible for initializing the Hydra database.
• The hydra-evaluator regularly updates the repository checkouts and evaluates the Nix expressions to decide which packages need to be built.
• The hydra-queue-runner builds all jobs that were evaluated by the hydra-evaluator.
• The apache server is used as a reverse proxy server forwarding requests to the hydra-server.

$ nix-build hydra-image.nix
$ docker load -i result
$ docker run -it --name hydra-test --network host hydra:test

$ docker exec -it hydra-test /bin/bash

$ supervisorctl
apache                           RUNNING   pid 1192, uptime 0:00:42
hydra-evaluator                  RUNNING   pid 1297, uptime 0:00:38
hydra-queue-runner               RUNNING   pid 1296, uptime 0:00:38
hydra-server                     RUNNING   pid 1188, uptime 0:00:42
nix-daemon                       RUNNING   pid 1186, uptime 0:00:42
postgresql                       RUNNING   pid 1187, uptime 0:00:42
supervisor>

$ su - hydra
$ hydra-create-user sander --password secret --role admin
creating new user `sander'

• The outer box indicates that we are deploying to a single machine: localhost
• The inner box indicates that all components are managed as processes
• The ovals correspond to process instances in the processes model and the arrows denote dependency relationships.
  
  For example, the apache reverse proxy has a dependency on hydra-server, meaning that the latter process instance should be deployed first, otherwise the reverse proxy is not able to forward requests to it.

Building a Nix-enabled container image

let
  pkgs = import <nixpkgs> {};

  nix-processmgmt = builtins.fetchGit {
    url = https://github.com/svanderburg/nix-processmgmt.git;
    ref = "master";
  };

  createNixImage = import "${nix-processmgmt}/nixproc/create-image-from-steps/create-nix-image.nix" {
    inherit pkgs;
  };
in
createNixImage {
  name = "foobar";
  tag = "test";
  contents = [ pkgs.mc ];
}

Conclusions

Future work

Availability

This is another blog post on the upcoming content-addressed derivations for Nix. We’ve already explained the feature and some of its advantages, as well as the reasons why it isn’t easy to implement. Now we’re going to talk about about a concrete user-facing change that this feature will entail: the distinction between “derivation outputs” and “output paths”.

Note that the changes presented here might not yet be implemented or merged upstream.

Store paths

Store paths are pervasive in Nix. Run nix build? This will return a store path. Want to move derivation outputs around? Just nix copy their store path. Even if you can run nix copy nixpkgs#hello, this is strictly equivalent to nix build nixpkgs#hello --out-link hello && nix copy $(realpath ./hello). Need to know whether a derivation has been built locally or in a binary cache? Just check whether its output path exists.

This is really nice in a world where the output of the derivations are input-addressed, because there’s a direct mapping between a derivation and its output paths − the .drv file actually explicitly contains them − which means that given a derivation Nix can directly know what its output paths are.

However this falls short with the addition of content-addressed derivations: if hello is content-addressed then I can’t introspect the derivation to know its output path anymore (see the previous post on that topic). Locally, Nix has a database that stores (amongst other things) which derivation produced which outputs, meaning that it knows that hello has already been built and that its output path is /nix/store/1234-hello. But if I just copy this output path to another machine, and try to rebuild hello there, Nix won’t be able to know that its output path is already there (because it doesn’t have that mapping), so it will have rebuild the derivation, only to realise that it yields the output path /nix/store/1234-hello that’s already there and discard the result.

This is very frustrating, as it means that the following won’t work:

$ nix copy --to ssh://somewhereelse nixpkgs.hello
# Try to build with `--max-jobs 0` to make it fail if it needs to rebuild anything
$ ssh somewhereelse nix build nixpkgs.hello --max-jobs 0
error: --- Error ----- nix
252 derivations need to be built, but neither local builds ('--max-jobs') nor remote builds ('--builders') are enabled

We could ask for Nix to copy the mapping between the hello derivation and its output paths as well, but many derivations might have produced this path, so if we just say nix copy --to ssh://somewhereelse /nix/store/1234-hello, does that mean that we want to copy the 1234-hello store path? Or 1234-hello the output of the hello derivation? Or 1234-hello the output of the hello2 derivation? Nix has no way to know that.

This means that we need another way to identify these outputs other than just their store paths.

Introducing derivation outputs

The one thing that we know though, and that uniquely identifies the derivation, is the hash of the derivation itself. The derivation for hello will be stored as /nix/store/xxx-hello.drv (where xxx is a hash), and that xxx definitely identifies the derivation (and is known before the build). As this derivation might have several outputs, we need to append the name of the considered output to get a truly unique identifier, giving us /nix/store/xxx-hello.drv!out.

So given this “derivation output id”, Nix will be able to both retrieve the corresponding output path (if it has been built), and know the mapping (derivation, outputName) -> outputPath.

With this in hand, we now can run nix copy --to ssh://somewhereelse /nix/store/xxx-hello.drv!out, which will both copy the output path /nix/store/1234-hello and register on the remote machine that this path is the output out of the derivation /nix/store/xxx-hello.drv. Likewise, nix copy nixpkgs.hello will be a shortcut for nix copy /nix/store/xxx-hello.drv. And now we can do

$ nix copy --to ssh://somewhereelse nixpkgs.hello
# Try to build with `--max-jobs 0` to make it fail if it needs to rebuild anything
$ ssh somewhereelse nix build nixpkgs.hello --max-jobs 0
$ ./result/bin/hello
Hello, world!

In practice

What will this mean in practice?

This means that the Nix cli will now return or accept either store paths or derivation output ids depending on the context. For example nix build will still create symlinks to the output paths and nix shell will add them to the PATH because that’s what makes sense in the context. But as we’ve seen above, nix copy will accept both store paths and derivation output ids, and these will have different semantics. Copying store paths will just copy the store paths as it used to do (in the case you don’t care about rebuilding them on the other side) while copying derivation outputs will also register these outputs on the remote side.

Once more, right now, this feature is still under development, so the changes presented here might not yet be implemented or merged upstream. So don’t be surprised when the feature lands in the near future!

• Multiple operating systems support. The most common process management service was chosen for each operating system: On Linux, sysvinit (because this used to be the most common solution) and systemd (because it is used by many conventional Linux distributions today), bsdrc on FreeBSD, launchd for macOS, and cygrunsrv for Cygwin.
• Supporting unprivileged user deployments. To supervise processes without requiring a service that runs on PID 1, that also works for unprivileged users, supervisord is very convenient because it was specifically designed for this purpose.
• Docker was selected because it is a very popular solution for managing services, and process management is one of its sub responsibilities.
• Universal process management. Disnix was selected because it can be used as a primitive process management solution that works on any operating system supported by the Nix package manager. Moreover, the Disnix services model is a super set of the processes model used by the process management framework.

The s6 tool suite

• It is the first program loaded by the kernel and responsible for setting the remainder of the boot procedure in motion. This procedure is responsible for mounting additional file systems, loading device drivers, and starting essential system services, such as SSH and logging services.
• The PID 1 process supervises all processes that were directly loaded by it, as well as indirect child processes that get orphaned -- when this happens they get automatically adopted by the process that runs as PID 1.
  
  As explained in an earlier blog post, traditional UNIX services that daemonize on their own, deliberately orphan themselves so that they remain running in the background.
• When a child process terminates, the parent process must take notice or the terminated process will stay behind as a zombie process.
  
  Because the PID 1 process is the common ancestor of all other processes, it is required to automatically reap all relevant zombie processes that become a child of it.
• The PID 1 process runs with root privileges and, as a result, has full access to the system. When the security of the PID 1 process gets compromised, the entire system is at risk.
• If the PID 1 process crashes, the kernel crashes (and hence the entire system) with a kernel panic.

1. /sbin/init: the first userspace program that is run by the kernel at boot time (not counting an initramfs).
2. pid 1: the program that will run as process 1 for most of the lifetime of the machine. This is not necessarily the same executable as /sbin/init, because /sbin/init can exec into something else.
3. a process supervisor.
4. a service manager.

• The first userspace program: s6-linux-init takes care of the coordination of the initialization process. It does a variety of one-time boot things: for example, it traps the ctrl-alt-del keyboard combination, it starts the shutdown daemon (that is responsible for eventually shutting down the system), and runs the initial boot script (rc.init).
  
  (As a sidenote: this is almost true -- the /sbin/init process is a wrapper script that "execs" into s6-linux-linux-init with the appropriate parameters).
• When the initialization is done, s6-linux-init execs into a process called s6-svscan provided by the s6 toolset. s6-svscan's task is to supervise an entire process supervision tree, which I will explain later.
• Starting and stopping services is done by a separate service manager started from the rc.init script. s6-rc is the most prominent option (that we will use in this blog post), but also other tools can be used.

• The Unix philosophy: do one job and do it well.
• Doing less instead of more (preventing feature creep).
• Keeping tight quality control over every tool by only opening up repository access to small teams only (or rather a single person).
• Integration support: he is against the bazaar approach on project level, but in favor of the bazaar approach on an eco-system level in which everybody can write their own tools that integrate with existing tools.

A basic usage scenario of s6 and s6-rc

$ nix-shell -p s6

$ mkdir -p $HOME/var/run/service
$ s6-svscan $HOME/var/run/service

$ nix-shell -p s6 s6-rc execline

$ mkdir -p sv/webapp
$ cd sv/webapp

$ echo "longrun" > type

$ cat > run <<EOF
$ #!$(type -p execlineb) -P

envfile $HOME/envfile
exec $HOME/webapp/bin/webapp
EOF

• It creates a service with type: longrun. A long run service deploys a process that runs in the foreground that will get supervised by s6.
• The run file refers to an executable that starts the service. For s6-rc services it is common practice to implement wrapper scripts using execline: a non-interactive scripting language.
  
  The execline script shown above loads an environment variable config file with the following content: PORT=5000. This environment variable is used to configure the TCP port number to which the service should bind to and then "execs" into a new process that runs the webapp process.
  
  (As a sidenote: although it is a common habit to use execline for writing wrapper scripts, this is not a hard requirement -- any executable implemented in any language can be used. For example, we could also write the above run wrapper script as a bash script).

$ mkdir -p ../nginx
$ cd ../nginx

$ echo "longrun" > type
$ echo "webapp" > dependencies

$ cat > run <<EOF
$ #!$(type -p execlineb) -P

foreground { mkdir -p $HOME/var/nginx/logs $HOME/var/cache/nginx }
exec $(type -p nginx) "-p" "$HOME/var/nginx" "-c" "$HOME/nginx/nginx.conf" "-g" "daemon off;"
EOF

• It again creates a service of type: longrun because Nginx should be started as a foreground process.
• It declares the webapp service (that we have configured earlier) a dependency ensuring that webapp is started before nginx. This dependency relationship is important to prevent Nginx doing a redirect to a non-existent service.
• The run script first creates all mandatory state directories and finally execs into the Nginx process, with a configuration file using the above state directories, and turning off daemon mode so that it runs in the foreground.

mkdir -p ../default
cd ../default

echo "bundle" > type

cat > contents <<EOF
webapp
nginx
EOF

$ find ./sv
./sv
./sv/default
./sv/default/contents
./sv/default/type
./sv/nginx/run
./sv/nginx/type
./sv/webapp/dependencies
./sv/webapp/run
./sv/webapp/type

$ mkdir -p $HOME/etc/s6/rc
$ s6-rc-compile $HOME/etc/s6/rc/compiled-1 $HOME/sv

$ s6-rc-init -c $HOME/etc/s6/rc/compiled-1 -l $HOME/var/run/s6-rc \
  $HOME/var/run/service

$ s6-rc -l $HOME/var/run/s6-rc -u change default

Managing service logging

$ cd sv
$ mv webapp webapp-srv
$ cd webapp-srv

$ echo "webapp-log" > producer-for
$ cat > run <<EOF
$ #!$(type -p execlineb) -P

envfile $HOME/envfile
fdmove -c 2 1
exec $HOME/webapp/bin/webapp
EOF

• We rename the service from: webapp to webapp-srv. Using suffixes is a convention commonly used for s6-rc services that also have a log companion service.
• With the producer-for property, we specify that the webapp-srv is a service that produces output for another service named: webapp-log. We will configure this service later.
• We create a new run script that adds the following command: fdmove -c 2 1.
  
  The purpose of this added instruction is to redirect all output that is sent over the standard error (file descriptor: 2) to the standard output (file descriptor: 1). This redirection makes it possible that all data can be captured by the log companion service.

$ mkdir ../webapp-log
$ cd ../webapp-log

$ echo "longrun" > type
$ echo "webapp-srv" > consumer-for
$ echo "webapp" > pipeline-name
$ echo 3 > notification-fd

$ cat > run <<EOF
#!$(type -p execlineb) -P

foreground { mkdir -p $HOME/var/log/s6-log/webapp }
exec -c s6-log -d3 $HOME/var/log/s6-log/webapp
EOF

• We create a service named: webapp-log that is a long running service.
• We declare the service to be a consumer for the webapp-srv (earlier, we have already declared the companion service: webapp-srv to be a producer for this logging service).
• We configure a pipeline name: webapp causing s6-rc to automatically generate a bundle with the name: webapp in which all involved services are its contents.
  
  This generated bundle allows us to always manage the service and logging companion as a single deployment unit.
• The s6-log service supports readiness notifications. File descriptor: 3 is configured to receive that notification.
• The run script creates the log directory in which the output should be stored and starts the s6-log service to capture the output and store the data in the corresponding log directory.
  
  The -d3 parameter instructs it to send a readiness notification over file descriptor 3.

$ s6-rc-compile $HOME/etc/s6/rc/compiled-2 $HOME/sv

$ s6-rc-update -l $HOME/var/run/s6-rc $HOME/etc/s6/rc/compiled-2

One shot services

mkdir -p ../mount-proc
cd ../mount-proc

echo "oneshot" > type

cat > run <<EOF
$ #!$(type -p execlineb) -P
foreground { mount -t proc proc /proc }
EOF

Chain loading

Developing s6-rc function abstractions for the Nix process management framework

{createLongRunService, writeTextFile, execline, webapp}:

let
  envFile = writeTextFile {
    name = "envfile";
    text = ''
      PORT=5000
    '';
  };
in
createLongRunService {
  name = "webapp";
  run = writeTextFile {
    name = "run";
    executable = true;
    text = ''
      #!${execline}/bin/execlineb -P

      envfile ${envFile}
      fdmove -c 2 1
      exec ${webapp}/bin/webapp
    '';
  };
  autoGenerateLogService = true;
}

• It generates a service directory that corresponds to the: name parameter with a longrun type property file.
• It generates a run execline script, that uses a generated envFile for configuring the service's port number, redirects the standard error to the standard output and starts the webapp process (that runs in the foreground).
• The autoGenerateLogService parameter is a concept I introduced myself, to conveniently configure a companion log service, because this a very common operation -- I cannot think of any scenario in which you do not want to have a dedicated log file for a long running service.
  
  Enabling this option causes the service to automatically become a producer for the log companion service (having the same name with a -log suffix) and automatically configures a logging companion service that consumes from it.

Generating a s6-rc service configuration from a process-manager agnostic configuration

{createManagedProcess, tmpDir}:
{port, instanceSuffix ? "", instanceName ? "webapp${instanceSuffix}"}:

let
  webapp = import ../../webapp;
in
createManagedProcess {
  name = instanceName;
  description = "Simple web application";
  inherit instanceName;

  process = "${webapp}/bin/webapp";
  daemonArgs = [ "-D" ];

  environment = {
    PORT = port;
  };

  overrides = {
    sysvinit = {
      runlevels = [ 3 4 5 ];
    };
  };
}

• The name and description attributes are just meta data. The description property is ignored by the s6-rc generator, because s6-rc has no equivalent configuration property for capturing a description.
• A process manager-agnostic configuration can specify both how the service can be started as a foreground process or as a process that daemonizes itself.
  
  In the above example, the process attribute specifies that the same executable needs to invoked for both a foregroundProcess and daemon. The daemonArgs parameter specifies the command-line arguments that need to be propagated to the executable to let it daemonize itself.
  
  s6-rc has a preference for managing foreground processes, because these can be more reliably managed. When a foregroundProcess executable can be inferred, the generator will automatically compose a longrun service making it possible for s6 to supervise it.
  
  If only a daemon can be inferred, the generator will compose a oneshot service that starts the daemon with the up script, and on shutdown, terminates the daemon by dereferencing the PID file in the down script.
• The environment attribute set parameter is automatically translated to an envfile that the generated run script consumes.
• Similar to the sysvinit backend, it is also possible to override the generated arguments for the s6-rc backend, if desired.

{ pkgs ? import <nixpkgs> { inherit system; }
, system ? builtins.currentSystem
, stateDir ? "/var"
, runtimeDir ? "${stateDir}/run"
, logDir ? "${stateDir}/log"
, cacheDir ? "${stateDir}/cache"
, tmpDir ? (if stateDir == "/var" then "/tmp" else "${stateDir}/tmp")
, forceDisableUserChange ? false
, processManager
}:

let
  constructors = import ./constructors.nix {
    inherit pkgs stateDir runtimeDir logDir tmpDir;
    inherit forceDisableUserChange processManager;
  };
in
rec {
  webapp = rec {
    port = 5000;
    dnsName = "webapp.local";

    pkg = constructors.webapp {
      inherit port;
    };
  };

  nginx = rec {
    port = 8080;

    pkg = constructors.nginxReverseProxyHostBased {
      webapps = [ webapp ];
      inherit port;
    } {};
  };
}

$ nixproc-s6-svscan --state-dir $HOME/var

$ nixproc-s6-rc-switch --state-dir $HOME/var \
  --force-disable-user-change processes.nix

$ curl -H 'Host: webapp.local' http://localhost:8080
<!DOCTYPE html>
<html>
  <head>
    <title>Simple test webapp</title>
  </head>
  <body>
    Simple test webapp listening on port: 5000
  </body>
</html>

Constructing multi-process Docker images supervised by s6

let
  skelDir = pkgs.stdenv.mkDerivation {
    name = "s6-skel-dir";
    buildCommand = ''
      mkdir -p $out
      cd $out

      cat > rc.init <<EOF
      #! ${pkgs.stdenv.shell} -e
      rl="\$1"
      shift

      # Stage 1
      s6-rc-init -c /etc/s6/rc/compiled /run/service
      
      # Stage 2
      s6-rc -v2 -up change default
      EOF
      
      chmod 755 rc.init
      
      cat > rc.shutdown <<EOF
      #! ${pkgs.stdenv.shell} -e
      
      exec s6-rc -v2 -bDa change
      EOF

      chmod 755 rc.shutdown
      
      cat > rc.shutdown.final <<EOF
      #! ${pkgs.stdenv.shell} -e
      # Empty
      EOF
      chmod 755 rc.shutdown.final
    '';
  };

• rc.init is the script that the init system starts, right after starting the supervisor: s6-svscan. It is responsible for initializing the s6-rc system and starting all services in the default bundle.
• rc.shutdown script is executed on shutdown and stops all previously started services by s6-rc.
• rc.shutdown.final runs at the very end of the shutdown procedure, after all processes have been killed and all file systems have been unmounted. In the above expression, it does nothing.

mkdir -p /etc/s6
s6-linux-init-maker -c /etc/s6/current -p /bin -m 0022 -f ${skelDir} -N -C -B /etc/s6/current
mv /etc/s6/current/bin/* /bin
rmdir etc/s6/current/bin

groupadd -g 2 s6-log
useradd -u 2 -d /dev/null -g s6-log s6-log

mkdir -p /etc/s6/rc
s6-rc-compile /etc/s6/rc/compiled ${profile}/etc/s6/sv

let
  pkgs = import <nixpkgs> {};

  createMultiProcessImage = import ../../nixproc/create-multi-process-image/create-multi-process-image-universal.nix {
    inherit pkgs system;
    inherit (pkgs) dockerTools stdenv;
  };
in
createMultiProcessImage {
  name = "multiprocess";
  tag = "test";
  exprFile = ./processes.nix;
  stateDir = "/var";
  processManager = "s6-rc";
}

$ nix-build

$ docker load -i result

Discussion

Improvement suggestions

• I have noticed that the command-line tools have very brief help pages -- they only enumerate the available options, but they do not provide any additional information explaining what these options do.
  
  I have also noticed that there are no official manpages, but there is a third-party initiative that seems to provide them.
  
  The "official" source of reference are the HTML pages. For me personally, it is not always convenient to access HTML pages on limited machines with no Internet connection and/or only terminal access.
• Although each individual tool is well documented (albeit in HTML), I was having quite a few difficulties figuring out how to use them together -- because every tool has a very specific purpose, you typically need to combine them in interesting ways to do something meaningful.
  
  For example, I could not find any clear documentation on skarnet describing typical combined usage scenarios, such as how to use s6-rc on a conventional Linux distribution that already has a different service management solution.
  
  Fortunately, I discovered a Linux distribution that turned out to be immensely helpful: Artix Linux. Artix Linux provides s6 as one of its supported process management solutions. I ended up installing Artix Linux in a virtual machine and reading their documentation.
  
  This kind of unclarity seems to be somewhat analogous to common criticisms of microkernels: one of Linus Torvalds' criticisms is that in microkernel designs, the pieces are simplified, but the coordination of the entire system is more difficult.
• Updating existing service configurations is difficult and cumbersome. Each time I want to change something (e.g. adding a new service), then I need to compile a new database, make sure that the newly compiled database co-exists with the previous database, and then run s6-rc-update.
  
  It is very easy to make mistakes. For example, I ended up overwriting the previous database several times. When this happens, the upgrade process gets stuck.
  
  systemd, on the other hand, allows you to put a new service configuration file in the configuration directory, such as: /etc/systemd/system. We can conveniently reload the configuration with a single command-line instruction:
  
  

  
  $ systemctl daemon-reload
      

  I believe that the updating process can still be somewhat simplified in s6-rc. Fortunately, I have managed to hide that complexity in the nixproc-s6-rc-deploy tool.
• It was also difficult to find out all the available configuration properties for s6-rc services -- I ended up looking at the examples and studying the documentation pages for s6-rc-compile, s6-supervise and service directories.
  
  I think that it could be very helpful to write a dedicated documentation page that describes all configurable properties of s6-rc services.
• I believe it is also very common that for each longrun service (with a -srv suffix), that you want a companion logging service (with a -log suffix).
  
  As a matter of fact, I can hardly think of a situation in which you do not want this. Maybe it helps to introduce a convenience property to automatically facilitate the generation of log companion services.

Availability

In a previous post, I gave a taste of Nickel, a configuration language we are developing at Tweag. One cool feature of Nickel is the ability to validate data and enforce program invariants using so-called contracts. In this post, I introduce the general concept of programming with contracts and illustrate it in Nickel.

Contracts are everywhere

You go to your favorite bakery and buy a croissant. Is there a contract binding you to the baker?

A long time ago, I was puzzled by this very first question of a law class exam. It looked really simple, yet I had absolutely no clue.

“Ehm..No?”

A contract should write down terms and conditions, and be signed by both parties. How could buying a croissant involve such a daunting liability?

Well, I have to confess that this exam didn’t go very well.

It turns out the sheer act of selling something implicitly and automatically establishes a legally binding contract between both parties (at least in France). For once, the programming world is not that different from the physical world: if I see a ConcurrentHashmap class in a Java library, given the context of Java’s naming conventions, I rightfully expect it to be a thread-safe implementation of a hashmap. This is a form of contract. If a programmer uses ConcurrentHashmap to name a class that implements a non-thread safe linked list, they should probably be sent to court.

Contracts may take multiple forms. A contract can be explicit, such as in a formal specification, or implicit, as in the ConcurrentHashMap example. They can be enforced or not, such as a type signature in a statically typed language versus an invariant written as a comment in a dynamically typed language. Here are a few examples:

As often, explicit is better than implicit: it leaves no room for misunderstanding. Enforced is better than not, because I would rather be protected by a proper legal system in case of contract violation.

Programming with Contracts

Until now, I’ve been using the word contract in a wide sense. It turns out contracts also refer to a particular programming paradigm which embodies the general notion pretty well. Such contracts are explicit and enforced, following our terminology. They are most notably used in Racket. From now on, I shall use contract in this more specific sense.

To first approximation, contracts are assertions. They check that a value satisfies some property at run-time. If the test passes, the execution can go on normally. Otherwise, an error is raised.

In Nickel, one can enforce a contract using the | operator:

let x = (1 + 1 | Num) in 2*x

Here, x is bound to a Num contract. When evaluating x, the following steps are performed:

1. evaluate 1 + 1
2. check that the result is a number
3. if it is, return the expression unchanged. Otherwise, raise an error that halts the program.

Let’s see it in action:

$nickel <<< '1 + 1 | Num'
Done: Num(2.0)

$nickel <<< 'false | Num'
error: Blame error: contract broken by a value.
  ┌─ :1:1
  │
1 │ Num
  │ --- expected type
  │
  ┌─ <stdin>:1:9
  │
1 │ false | Num
  │         ^^^ bound here

Contracts versus types

I’ve described contracts as assertions, but the above snippet suspiciously resembles a type annotation. How do contracts compare to types? First of all, contracts are checked at run-time, so they would correspond to dynamic typing rather than static typing. Secondly, contracts can check more than just the membership to a type:

let GreaterThan2 = fun label x =>
  if builtins.isNum x then
    if x > 2 then
      x
    else
      contracts.blame (contracts.tag "smaller or equals" label)
  else
    contracts.blame (contracts.tag "not a number" label)
in

(3 | #GreaterThan2) // Ok, evaluate to 3
(1 | #GreaterThan2) // Err, `smaller or equals`
("a" | #GreaterThan2) // Err, `not a number`

Here, we just built a custom contract. A custom contract is a function of two arguments:

• the label label, carrying information for error reporting.
• the value x to be tested.

If the value satisfies the condition, it is returned. Otherwise, a call to blame signals rejection with an optional error message attached via tag. When evaluating value | #Contract, the interpreter calls Contract with an appropriate label and value as arguments.

Such custom contracts can check arbitrary properties. Enforcing the property of being greater than two using static types is rather hard, requiring a fancy type system such as refinement types , while the role of dynamic types generally stops at distinguishing basic datatypes and functions.

Back to our first example 1 + 1 | Num, we could have written instead:

let MyNum = fun label x =>
  if builtins.isNum x then x else contracts.blame label in
(1 + 1 | #MyNum)

This is in fact pretty much what 1 + 1 | Num evaluates to. While a contract is not the same entity as a type, one can derive a contract from any type. Writing 1 + 1 | Num asks the interpreter to derive a contract from the type Num and to check 1 + 1 against it. This is just a convenient syntax to specify common contracts. The# character distinguishes contracts as types from contracts as functions (that is, custom contracts).

To sum up, contracts are just glorified assertions. Also, there is this incredibly convenient syntax that spares us a whole three characters by writing Num instead of #MyNum. So… is that all the fuss is about?

Function contracts

Until now, we have only considered what are called flat contracts, which operate on data. But Nickel is a functional programming language: so what about function contracts? They exist too!

let f | Str -> Num = fun x => if x == "a" then 0 else 1 in ...

Here again, we ask Nickel to derive a contract for us, from the type Str -> Num of functions sending strings to numbers. To find out how this contract could work, we must understand what is the defining property of a function of type Str -> Num that the contract should enforce.

A function of type Str -> Num has a duty: it must produce a number. But what if I call f on a boolean? That’s unfair, because the function has also a right: the argument must be a string. The full contract is thus: if you give me a string, I give you a number. If you give me something else, you broke the contract, so I can’t guarantee anything. Another way of viewing it is that the left side of the arrow represents preconditions on the input while the right side represents postconditions on the output.

More than flat contracts, function contracts show similarities with traditional legal contracts. We have two parties: the caller, f "b", and the callee, f. Both must meet conditions: the caller must provide a string while the callee must return a number.

In practice, inspecting the term f can tell us if it is a function at most. This is because a function is inert, waiting for an argument to hand back a result. In consequence, the contract is doomed to fire only when f is applied to an argument, in which case it checks that:

1. The argument satisfies the Str contract
2. The return value satisfies the Num contract

The interpreter performs additional bookkeeping to be able to correctly blame the offending code in case of a higher-order contract violation:

$nickel <<< 'let f | Str -> Num = fun x => if x == "a" then 0 else 1 in f "a"'
Done: Num(0.0)

$nickel <<< '... in f 0'
error: Blame error: contract broken by the caller.
  ┌─ :1:1
  │
1 │ Str -> Num
  │ --- expected type of the argument provided by the caller
  │
  ┌─ <stdin>:1:9
  │
1 │ let f | Str -> Num = fun x => if x == "a" then 0 else 1 in f 0
  │         ^^^^^^^^^^ bound here
[..]

$nickel <<< 'let f | Str -> Num = fun x => x in f "a"'
error: Blame error: contract broken by a function.
  ┌─ :1:8
  │
1 │ Str -> Num
  │        --- expected return type
  │
  ┌─ <stdin>:1:9
  │
1 │ let f | Str -> Num = fun x => x in f "a"
  │         ^^^^^^^^^^ bound here

These examples illustrate three possible situations:

1. The contract is honored by both parties.
2. The contract is broken by the caller, which provides a number instead of a string.
3. The contract is broken by the function (callee), which rightfully got a string but returned a string instead of a number.

Combined with custom contracts, function contracts make it possible to express succinctly non-trivial invariants:

let f | #GreaterThan2 -> #GreaterThan2 = fun x => x + 1 in ..

A warning about laziness

Nickel is a lazy programming language. This means that expressions, including contracts, are evaluated only if they are needed. If you are experimenting with contracts and some checks buried inside lists or records do not seem to trigger, you can use the deepSeq operator to recursively force the evaluation of all subterms, including contracts:

let exp = ..YOUR CODE WITH CONTRACTS.. in builtins.deepSeq exp exp

Conclusion

In this post, I introduced programming with contracts. Contracts offer a principled and ergonomic way of validating data and enforcing invariants with a good error reporting story. Contracts can express arbitrary properties that are hard to enforce statically, and they can handle higher-order functions.

Contracts also have a special relationship with static typing. While we compared them as competitors somehow, contracts and static types are actually complementary, reunited in the setting of gradual typing. Nickel has gradual types, which will be the subject of a coming post.

The examples here are illustrative, but we’ll see more specific and compelling usages of contracts in yet another coming post about Nickel’s meta-values, which, together with contracts, serve as a unified way to describe and validate configurations.

During the last decade, many initiatives focussing on making builds reproducible have gained momentum. reproducible-builds.org is a great resource for anyone interested in how the work progresses in multiple software communities. r13y.com tracks the current reproducibility metrics in NixOS.

Nix is particularly suited for working on reproducibility, since it by design isolates builds and comes with tools for finding non-determinism. The Nix community also works on related projects, like Trustix and the content-addressed store.

This blog post summarises how nixbuild.net can be useful for finding non-deterministic builds, and announces a new feature related to reproducibility!

Repeated Builds

The way to find non-reproducible builds is to run the same build multiple times and check for any difference in results, when compared bit-for-bit. Since Nix guarantees that all inputs will be identical between the runs, just finding differing output results is enough to conclude that a build is non-deterministic. Of course, we can never prove that a build is deterministic this way, but if we run the build many times, we gain a certain confidence in it.

To run a Nix build multiple times, simply add the –repeat option to your build command. It will run your build the number of extra times you specify.

Suppose we have the following Nix expression in deterministic.nix:

let
  inherit (import <nixpkgs> {}) runCommand;
in {
  stable = runCommand "stable" {} ''
    touch $out
  '';

  unstable = runCommand "unstable" {} ''
    echo $RANDOM > $out
  '';
}

We can run repeated builds like this (note that the --builders "" option is there to force a local build, to not use nixbuild.net):

$ nix-build deterministic.nix --builders "" -A stable --repeat 1
these derivations will be built:
  /nix/store/0fj164aqyhsciy7x97s1baswygxn8lzf-stable.drv
building '/nix/store/0fj164aqyhsciy7x97s1baswygxn8lzf-stable.drv' (round 1/2)...
building '/nix/store/0fj164aqyhsciy7x97s1baswygxn8lzf-stable.drv' (round 2/2)...
/nix/store/6502c5490rap0c8dhvfwm5rhi22i9clz-stable

$ nix-build deterministic.nix --builders "" -A unstable --repeat 1
these derivations will be built:
  /nix/store/psmn1s3bb97989w5a5b1gmjmprqcmf0k-unstable.drv
building '/nix/store/psmn1s3bb97989w5a5b1gmjmprqcmf0k-unstable.drv' (round 1/2)...
building '/nix/store/psmn1s3bb97989w5a5b1gmjmprqcmf0k-unstable.drv' (round 2/2)...
output '/nix/store/g7a5sf7iwdxs7q12ksrzlvjvz69yfq3l-unstable' of '/nix/store/psmn1s3bb97989w5a5b1gmjmprqcmf0k-unstable.drv' differs from previous round
error: build of '/nix/store/psmn1s3bb97989w5a5b1gmjmprqcmf0k-unstable.drv' failed

Running repeated builds on nixbuild.net works exactly the same way:

$ nix-build deterministic.nix -A stable --repeat 1
these derivations will be built:
  /nix/store/wnd5y30jp3xwpw1bhs4bmqsg5q60vc8i-stable.drv
building '/nix/store/wnd5y30jp3xwpw1bhs4bmqsg5q60vc8i-stable.drv' (round 1/2) on 'ssh://eu.nixbuild.net'...
copying 1 paths...
copying path '/nix/store/z3wlpwgz66ningdbggakqpvl0jp8bp36-stable' from 'ssh://eu.nixbuild.net'...
/nix/store/z3wlpwgz66ningdbggakqpvl0jp8bp36-stable

$ nix-build deterministic.nix -A unstable --repeat 1
these derivations will be built:
  /nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv
building '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' (round 1/2) on 'ssh://eu.nixbuild.net'...
[nixbuild.net] output '/nix/store/srch6l8pyl7z93c7gp1xzf6mq6rwqbaq-unstable' of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' differs from previous round
error: build of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' on 'ssh://eu.nixbuild.net' failed: build was non-deterministic
builder for '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' failed with exit code 1
error: build of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' failed

As you can see, the log output differs slightly between the local and the remote builds. This is because when Nix submits a remote build, it will not do the determinism check itself, instead it will leave it up to the builder (nixbuild.net in our case). This is actually a good thing, because it allows nixbuild.net to perform some optimizations for repeated builds. The following sections will enumerate those optimizations.

Finding Non-determinism in Past Builds

If you locally try to rebuild a something that has failed due to non-determinism, Nix will build it again at least two times (due to --repeat) and fail it due to non-determinism again, since it keeps no record of the previous build failure (other than the build log).

However, nixbuild.net keeps a record of every build performed, also for repeated builds. So when you try to build the same derivation again, nixbuild.net is smart enough to look at its past build and figure out that the derivation is non-deterministic without having to rebuild it. We can demonstrate this by re-running the last build from the example above:

$ nix-build deterministic.nix -A unstable --repeat 1
these derivations will be built:
  /nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv
building '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' (round 1/2) on 'ssh://eu.nixbuild.net'...
[nixbuild.net] output '/nix/store/srch6l8pyl7z93c7gp1xzf6mq6rwqbaq-unstable' of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' differs from previous round
error: build of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' on 'ssh://eu.nixbuild.net' failed: a previous build of the derivation was non-deterministic
builder for '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' failed with exit code 1
error: build of '/nix/store/6im1drv4pklqn8ziywbn44vq8am977vm-unstable.drv' failed

As you can see, the exact same derivation fails again, but now the build status message says: a previous build of the derivation was non-deterministic. This means nixbuild.net didn’t have to run the build, it just checked its past outputs for the derivation and noticed they differed.

When nixbuild.net looks at past builds it considers all outputs that have been signed by a key that the account trusts. That means that it can even compare outputs that have been fetched by substitution.

Scaling Out Repeated Builds

When you use --repeat, nixbuild.net will create multiple copies of the build and schedule all of them like any other build would have been scheduled. This means that every repeated build will run in parallel, saving time for the user. As soon as nixbuild.net has found proof of non-determinism, any repeated build still running will be cancelled.

Provoking Non-determinism through Filesystem Randomness

As promised in the beginning of this blog post, we have new a feature to announce! nixbuild.net is now able to inject randomness into the filesystem that the builds see when they run. This can be used to provoke builds to uncover non-deterministic behavior.

The idea is not new, it is in fact the exact same concept as have been implemented in the disorderfs project by reproducible-builds.org. However, we’re happy to make it easily accessible to nixbuild.net users. The feature is disabled by default, but can be enabled through a new user setting.

For the moment, the implementation will return directory entries in a random order when enabled. In the future we might inject more metadata randomness.

To demonstrate this feature, let’s use this build:

let
  inherit (import <nixpkgs> {}) runCommand;
in rec {
  files = runCommand "files" {} ''
    mkdir $out
    touch $out/{1..10}
  '';

  list = runCommand "list" {} ''
    ls -f ${files} > $out
  '';
}

The files build just creates ten empty files as its output, and the list build lists those file with ls. The -f option of ls disables sorting entirely, so the file names will be printed in the order the filesystem returns them. This means that the build output will depend on how the underlying filesystem is implemented, which could be considered a non-deterministic behavior.

First, we build it locally with --repeat:

$ nix-build non-deterministic-fs.nix --builders "" -A list --repeat 1
these derivations will be built:
  /nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv
building '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' (round 1/2)...
building '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' (round 2/2)...
/nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list

As you can see, the build succeeded. Then we delete the result from our Nix store so we can run the build again:

rm result
nix-store --delete /nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list

We enable the inject-fs-randomness feature through the nixbuild.net shell:

nixbuild.net> set inject-fs-randomness true

Then we run the build (with --repeat) on nixbuild.net:

$ nix-build non-deterministic-fs.nix -A list --repeat 1
these derivations will be built:
  /nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv
building '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' (round 1/2) on 'ssh://eu.nixbuild.net'...
copying 1 paths...
copying path '/nix/store/vl13q40hqp4q8x6xjvx0by06s1v9g3jy-files' to 'ssh://eu.nixbuild.net'...
[nixbuild.net] output '/nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list' of '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' differs from previous round
error: build of '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' on 'ssh://eu.nixbuild.net' failed: build was non-deterministic
builder for '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' failed with exit code 1
error: build of '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' failed

Now, nixbuild.net found the non-determinism! We can double check that the directory entries are in a random order by running without --repeat:

$ nix-build non-deterministic-fs.nix -A list
these derivations will be built:
  /nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv
building '/nix/store/153s3ir379cy27wpndd94qlfhz0wj71v-list.drv' on 'ssh://eu.nixbuild.net'...
copying 1 paths...
copying path '/nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list' from 'ssh://eu.nixbuild.net'...
/nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list

$ cat /nix/store/h1591y02qff8vls5v41khgjz2zpdr2mg-list
6
1
2
5
10
7
8
..
9
4
3
.

Future Work

There are lots of possibilities to improve the utility of nixbuild.net when it comes to reproducible builds. Your feedback and ideas are very welcome to support@nixbuild.net.

Here are some of the things that could be done:

• Make it possible to trigger repeated builds for any previous build, without submitting a new build with Nix. For example, there could be a command in the nixbuild.net shell allowing a user to trigger a repeated build and report back any non-determinism issues.

• Implement functionality similar to diffoscope to be able to find out exactly what differs between builds. This could be available as a shell command or through an API.

• Make it possible to download specific build outputs. The way Nix downloads outputs (and stores them locally) doesn’t allow for having multiple variants of the same output, but nixbuild.net could provide this functionality through the shell or an API.

• Inject more randomness inside the sandbox. Since we have complete control over the sandbox environment we can introduce more differences between repeated builds to provoke non-determinism. For example, we can schedule builds on different hardware or use different kernels between repeated builds.

• Add support for listing known non-deterministic derivations.

One year ago nixbuild.net was announced to the Nix community for the very first time. The service then ran as a closed beta for 7 months until it was made generally available on the 28th of August 2020.

This blog post will try to summarize how nixbuild.net has evolved since GA four months ago, and give a glimpse of the future for the service.

Stability and Performance

Thousands of Nix builds have been built by nixbuild.net so far, and every build helps in making the service more reliable by uncovering possible edge cases in the build environment.

These are some of the stability-related improvements and fixes that have been deployed since GA:

• Better detection and handling of builds that time out or hang.

• Improved retry logic should our backend storage not deliver Nix closures as expected.

• Fixes to the virtual file system inside the KVM sandbox.

• Better handling of builds that have binary data in their log output.

• Changes to the virtual sandbox environment so it looks even more like a “standard” Linux environment.

• Application of the Nix sandbox inside our KVM sandbox. This basically guarantees that the Nix environment provided through nixbuild.net is identical to the Nix environment for local builds.

• Support for following HTTP redirects from binary caches.

Even Better Build Reuse

One of the fundamental ideas in nixbuild.net is to try as hard as possible to not build your builds, if an existing build result can be reused instead. We can trivially reuse an account’s own builds since they are implicitly trusted by the user, but also untrusted builds can be reused under certain circumstances. This has been described in detail in an earlier blog post

Since GA we’ve introduced a number of new ways build results can be reused.

Reuse of Build Failures

Build failures are now also reused. This means that if someone tries to build a build that is identical (in the sense that the derivation and its transitive input closure is bit-by-bit identical) to a previously failed build, nixbuild.net will immediately serve back the failed result instead of re-running the build. You will even get the build log replayed.

Build failures can be reused since we are confident that our sandbox is pure, meaning that it will behave exactly the same as long as the build is exactly the same. Only non-transient failures will be reused. So if the builder misbehaves in some way that is out of control for Nix, that failure will not be reused. This can happen if the builder machine breaks down or something similar. In such cases we will automatically re-run the build anyway.

When we fix bugs or make major changes in our sandbox it can happen that we alter the behavior in terms of which builds succeed or fail. For example, we could find a build that fail just because we have missed implementing some specific detail in the sandbox. Once that is fixed, we don’t want to reuse such failures. To avoid that, all existing build failures will be “invalidated” on each major update of the sandbox.

If a user really wants to re-run a failed build on nixbuild.net, failure reuse can be turned off using the new user settings (see below).

Reuse of Build Timeouts

In a similar vein to reused build failures, we can also reuse build timeouts. This is not enabled by default, since users can select different timeout limits. A user can activate reuse of build timeouts through the user settings.

The reuse of timed out builds works like this: Each time a new build is submitted, we check if we have any previous build results of the exact same build. If no successful results or plain failures are found, we look for builds that have timed out. We then check if any of the existing timed out builds ran for longer than the user-specified timeout for the new build. If we can find such a result, it will be served back to the user instead of re-running the build.

This feature can be very useful if you want to avoid re-running builds that timeout over and over again (which can be a very time-consuming excercise). For example, say that you have your build timeout set to two hours, and some input needed for a build takes longer than that to build. The first time that input is needed you have to wait two hours to detect that the build will fail. If you then try building something else that happens to depend on the very same input you will save two hours by directly being served the build failure from nixbuild.net!

Wait for Running Builds

When a new build is submitted, nixbuild.net will now check if there is any identical build currently running (after checking for previous build results or failures). If there is, the new build will simply hold until the running build has finished. After that, the result of the running build will likely be served back as the result of the new build (as long as the running build wasn’t terminated in a transient way, in which case the new build will have to run from scratch). The identical running builds are checked and reused across accounts.

Before this change, nixbuild.net would simply start another build in parallel even if the builds were identical.

New Features

User Settings

A completely new feature has been launched since GA: User Settings. This allows end users to tweak the behavior of nixbuild.net. For example, the build reuse described above can be controlled by user settings. Other settings includes controlling the maximum used build time per month, and the possibility to lock down specific SSH keys which is useful in CI setups.

The user settings can be set in various way; through the nixbuild.net shell, the SSH client environment and even through the Nix derivations themselves.

Even if many users probably never need to change any settings, it can be helpful to read through the documentation to get a feeling for what is possible. If you need to differentiate permissions in any way (different settings for account administrators, developers, CI etc) you should definitely look into the various user settings.

GitHub CI Action

A GitHub Action has been published. This action makes it very easy to use nixbuild.net as a remote Nix builder in your GitHub Actions workflows. Instead of running you Nix builds on the two vCPUs provided by GitHub you can now enjoy scale-out Nix builds on nixbuild.net with minimal setup required.

The nixbuild.net GitHub Action is developed by the nixbuild.net team and there are plans on adding more functionality that nixbuild.net can offer users, like automatically generated cost and performance reports for your Nix builds.

Shell Improvements

Various minor improvements have been made to the nixbuild.net shell. It is for example now much easier to get an overview on how large your next invoice will be, through the usage command.

The Future

After one year of real world usage, we are very happy with the progress of nixbuild.net. It has been well received in the Nix community, proved both reliable and scalable, and it has delivered on our initial vision of a simple service that can integrate into any setup using Nix.

We feel that we can go anywhere from here, but we also realize that we must be guided by our users’ needs. We have compiled a small and informal roadmap below. The items on this list are things that we, based on the feedback we’ve received throughout the year, think are natural next steps for nixbuild.net.

The roadmap has no dates and no prioritization, and should be seen as merely a hint about which direction the development is heading. Any question or comment concerning this list (or what’s missing from the list) is very welcome to support@nixbuild.net.

Support aarch64-linux Builds

Work is already underway to add support for aarch64-linux builds to nixbuild.net, and so far it is looking good. With the current surge in performant ARM hardware (Apple M1, Ampere Altra etc), we think having aarch64 support in nixbuild.net is an obvious feature. It is also something that has been requested by our users.

We don’t know yet how the pricing of aarch64 builds will look, or what scalability promises we can make. If you are interested in evaluating aarch64 builds on nixbuild.net in an early access setting, just send us an email to support@nixbuild.net.

Provide an API over SSH and HTTP

Currently the nixbuild.net shell is the administrative tool we offer end users. We will keep developing the shell and make it more intuitive for interactive use. But will also add an alternative, more scriptable variant of the shell.

This alternative version will provide roughly the same functionality as the original shell, only more adapted to scripting instead of interactive use. The reason for providing such an SSH-based API is to make it easy to integrate nixbuild.net more tightly into CI and similar scenarios.

There is in fact already a tiny version of this API deployed. You can run the following command to try it out:

$ ssh eu.nixbuild.net api show public-signing-key
{"keyName":"nixbuild.net/bob-1","publicKey":"PmUhzAc4Ug6sf1uG8aobbqMdalxW41SHWH7FE0ie1BY="}

The above API command is in use by the nixbuild-action for GitHub. So far, this is the only API command implemented, and it should be seen as a very first proof of concept. Nothing has been decided on how the API should look and work in the future.

The API will also be offered over HTTP in addition to SSH.

Upload builds to binary caches

Adding custom binary caches that nixbuild.net can fetch dependencies from is supported today, although such requests are still handled manually through support.

We also want to support uploading to custom binary caches. That way users could gain performance by not having to first download build results from nixbuild.net and then upload them somewhere else. This could be very useful for CI setups that can spend a considerable amount of their time just uploading closures.

Provide an HTTP-based binary cache

Using nixbuild.net as a binary cache is handy since you don’t have to wait for any uploads after a build has finished. Instead, the closures will be immediately available in the binary cache, backed by nixbuild.net.

It is actually possible to use nixbuild.net as a binary cache today, by configuring an SSH-based cache (ssh://eu.nixbuild.net). This works out of the box right now. You can even use nix-copy-closure to upload paths to nixbuild.net. We just don’t yet give any guarantees on how long store paths are kept.

However, there are benfits to providing an HTTP-based cache. It would most probably have better performance (serving nar files over HTTP instead of using the nix-store protocol over SSH), but more importantly it would let us use a CDN for serving cache contents. This could help mitigate the fact that nixbuild.net is only deployed in Europe so far.

Support builds that use KVM

The primary motivation for this is to be able to run NixOS tests (with good performance) on nixbuild.net.

Thank You!

Finally we’d like to thank all our users. We look forward to an exciting new year with lots of Nix builds!

A good few years ago Edward Yang gifted us an implementation of Backpack - a way for us to essentially abstract modules over other modules, allowing us to write code independently of implementation. A big benefit of doing this is that it opens up new avenues for program optimization. When we provide concrete instantiations of signatures, GHC compiles it as if that were the original code we wrote, and we can benefit from a lot of specialization. So aside from organizational concerns, Backpack gives us the ability to write some really fast code. This benefit isn’t just theoretical - Edward Kmett gave us unpacked-containers, removing a level of indirection from all keys, and Oleg Grenrus showed as how we can use Backpack to “unroll” fixed sized vectors. In this post, I want to show how we can use Backpack to give us the performance benefits of explicit transformers, but without having library code commit to any specific stack. In short, we get the ability to have multiple interpretations of our program, but without paying the performance cost of abstraction.

The Problem

Before we start looking at any code, let’s look at some requirements, and understand the problems that come with some potential solutions. The main requirement is that we are able to write code that requires some effects (in essence, writing our code to an effect interface), and then run this code with different interpretations. For example, in production I might want to run as fast as possible, in local development I might want further diagnostics, and in testing I might want a pure or in memory solution. This change in representation shouldn’t require me to change the underlying library code.

Seasoned Haskellers might be familiar with the use of effect systems to solve these kinds of problems. Perhaps the most familiar is the mtl approach - perhaps unfortunately named as the technique itself doesn’t have much to do with the library. In the mtl approach, we write our interfaces as type classes abstracting over some Monad m, and then provide instances of these type classes - either by stacking transformers (“plucking constraints”, in the words of Matt Parson), or by a “mega monad” that implements many of these instances at once (e.g., like Tweag’s capability) approach.

Despite a few annoyances (e.g., the “n+k” problem, the lack of implementations being first-class, and a few other things), this approach can work well. It also has the potential to generate a great code, but in practice it’s rarely possible to achieve maximal performance. In her excellent talk “Effects for Less”, Alexis King hits the nail on the head - despite being able to provide good code for the implementations of particular parts of an effect, the majority of effectful code is really just threading around inside the Monad constraint. When we’re being polymorphic over any Monad m, GHC is at a loss to do any further optimization - and how could it? We know nothing more than “there will be some >>= function when you get here, promise!” Let’s look at this in a bit more detail.

Say we have the following:

foo :: Monad m => m Int
foo = go 0 1_000_000_000
  where
    go acc 0 = return acc
    go acc i = return acc >> go (acc + 1) (i - 1)

This is obviously “I needed an example for my blog” levels of contrived, but at least small. How does it execute? What are the runtime consequences of this code? To answer, we’ll go all the way down to the STG level with -ddump-stg:

$wfoo =
    \r [ww_s2FA ww1_s2FB]
        let {
          Rec {
          $sgo_s2FC =
              \r [sc_s2FD sc1_s2FE]
                  case eqInteger# sc_s2FD lvl1_r2Fp of {
                    __DEFAULT ->
                        let {
                          sat_s2FK =
                              \u []
                                  case +# [sc1_s2FE 1#] of sat_s2FJ {
                                    __DEFAULT ->
                                        case minusInteger sc_s2FD lvl_r2Fo of sat_s2FI {
                                          __DEFAULT -> $sgo_s2FC sat_s2FI sat_s2FJ;
                                        };
                                  }; } in
                        let {
                          sat_s2FH =
                              \u []
                                  let { sat_s2FG = CCCS I#! [sc1_s2FE]; } in  ww1_s2FB sat_s2FG;
                        } in  ww_s2FA sat_s2FH sat_s2FK;
                    1# ->
                        let { sat_s2FL = CCCS I#! [sc1_s2FE]; } in  ww1_s2FB sat_s2FL;
                  };
          end Rec }
        } in  $sgo_s2FC lvl2_r2Fq 0#;

foo =
    \r [w_s2FM]
        case w_s2FM of {
          C:Monad _ _ ww3_s2FQ ww4_s2FR -> $wfoo ww3_s2FQ ww4_s2FR;
        };

In STG, whenever we have a let we have to do a heap allocation - and this code has quite a few! Of particular interest is the what’s going on inside the actual loop $sgo_s2FC. This loop first compares i to see if it’s 0. In the case that’s it’s not, we allocate two objects and call ww_s2Fa. If you squint, you’ll notice that ww_s2FA is the first argument to $wfoo, and it ultimately comes from unpacking a C:Monad dictionary. I’ll save you the labor of working out what this is - ww_s2Fa is the >>. We can see that every iteration of our loop incurs two allocations for each argument to >>. A heap allocation doesn’t come for free - not only do we have to do the allocation, the entry into the heap incurs a pointer indirection (as heap objects have an info table that points to their entry), and also by merely being on the heap we increase our GC time as we have a bigger heap to traverse. While my STG knowledge isn’t great, my understanding of this code is that every time we want to call >>, we need to supply it with its arguments. This means we have to allocate two closures for this function call - which is basically whenever we pressed “return” on our keyboard when we wrote the code. This seems crazy - can you imagine if you were told in C that merely using ; would cost time and memory?

If we compile this code in a separate module, mark it as {-# NOINLINE #-}, and then call it from main - how’s the performance? Let’s check!

module Main (main) where

import Foo

main :: IO ()
main = print =<< foo

$ ./Main +RTS -s
1000000000
 176,000,051,368 bytes allocated in the heap
       8,159,080 bytes copied during GC
          44,408 bytes maximum residency (1 sample(s))
          33,416 bytes maximum slop
               0 MB total memory in use (0 MB lost due to fragmentation)

                                     Tot time (elapsed)  Avg pause  Max pause
  Gen  0     169836 colls,     0 par    0.358s   0.338s     0.0000s    0.0001s
  Gen  1         1 colls,     0 par    0.000s   0.000s     0.0001s    0.0001s

  INIT    time    0.000s  (  0.000s elapsed)
  MUT     time   54.589s  ( 54.627s elapsed)
  GC      time    0.358s  (  0.338s elapsed)
  EXIT    time    0.000s  (  0.000s elapsed)
  Total   time   54.947s  ( 54.965s elapsed)

  %GC     time       0.0%  (0.0% elapsed)

  Alloc rate    3,224,078,302 bytes per MUT second

  Productivity  99.3% of total user, 99.4% of total elapsed

OUCH. My i7 laptop took almost a minute to iterate a loop 1 billion times.

A little disclaimer: I’m intentionally painting a severe picture here - in practice this cost is irrelevant to all but the most performance sensitive programs. Also, notice where the let bindings are in the STG above - they are nested within the loop. This means that we’re essentially allocating “as we go” - these allocations are incredibly cheap, and the growth to GC is equal trivial, resulting in more like constant GC pressure, rather than impending doom. For code that is likely to do any IO, this cost is likely negligible compared to the rest of the work. Nonetheless, it is there, and when it’s there, it’s nice to know if there are alternatives.

So, is the TL;DR that Haskell is completely incapable of writing effectful code? No, of course not. There is another way to compile this program, but we need a bit more information. If we happen to know what m is and we have access to the Monad dictionary for m, then we might be able to inline >>=. When we do this, GHC can be a lot smarter. The end result is code that now doesn’t allocate for every single >>=, and instead just gets on with doing work. One trivial way to witness this is to define everything in a single module (Alexis rightly points out this is a trap for benchmarking that many fall into, but for our uses it’s the behavior we actually want).

This time, let’s write everything in one module:

module Main ( main ) where

And the STG:

lvl_r4AM = CCS_DONT_CARE S#! [0#];

lvl1_r4AN = CCS_DONT_CARE S#! [1#];

Rec {
main_$sgo =
    \r [void_0E sc1_s4AY sc2_s4AZ]
        case eqInteger# sc1_s4AY lvl_r4AM of {
          __DEFAULT ->
              case +# [sc2_s4AZ 1#] of sat_s4B2 {
                __DEFAULT ->
                    case minusInteger sc1_s4AY lvl1_r4AN of sat_s4B1 {
                      __DEFAULT -> main_$sgo void# sat_s4B1 sat_s4B2;
                    };
              };
          1# -> let { sat_s4B3 = CCCS I#! [sc2_s4AZ]; } in  Unit# [sat_s4B3];
        };
end Rec }

main2 = CCS_DONT_CARE S#! [1000000000#];

main1 =
    \r [void_0E]
        case main_$sgo void# main2 0# of {
          Unit# ipv1_s4B7 ->
              let { sat_s4B8 = \s [] $fShowInt_$cshow ipv1_s4B7;
              } in  hPutStr' stdout sat_s4B8 True void#;
        };

main = \r [void_0E] main1 void#;

main3 = \r [void_0E] runMainIO1 main1 void#;

main = \r [void_0E] main3 void#;

The same program compiled down to much tighter loop that is almost entirely free of allocations. In fact, the only allocation that happens is when the loop terminates, and it’s just boxing the unboxed integer that’s been accumulating in the loop.

As we might hope, the performance of this is much better:

$ ./Main +RTS -s
1000000000
  16,000,051,312 bytes allocated in the heap
         128,976 bytes copied during GC
          44,408 bytes maximum residency (1 sample(s))
          33,416 bytes maximum slop
               0 MB total memory in use (0 MB lost due to fragmentation)

                                     Tot time (elapsed)  Avg pause  Max pause
  Gen  0     15258 colls,     0 par    0.031s   0.029s     0.0000s    0.0000s
  Gen  1         1 colls,     0 par    0.000s   0.000s     0.0001s    0.0001s

  INIT    time    0.000s  (  0.000s elapsed)
  MUT     time    9.402s  (  9.405s elapsed)
  GC      time    0.031s  (  0.029s elapsed)
  EXIT    time    0.000s  (  0.000s elapsed)
  Total   time    9.434s  (  9.434s elapsed)

  %GC     time       0.0%  (0.0% elapsed)

  Alloc rate    1,701,712,595 bytes per MUT second

  Productivity  99.7% of total user, 99.7% of total elapsed

Our time in the garbage collector dropped by a factor of 10, from 0.3s to 0.03. Our total allocation dropped from 176GB (yes, you read that right) to 16GB (I’m still not entirely sure what this means, maybe someone can enlighten me). Most importantly our total runtime dropped from 54s to just under 10s. All this from just knowing what m is at compile time.

So GHC is capable of producing excellent code for monads - what are the circumstances under which this happens? We need, at least:

1. The source code of the thing we’re compiling must be available. This means it’s either defined in the same module, or is available with an INLINABLE pragma (or GHC has chosen to add this itself).

2. The definitions of >>= and friends must also be available in the same way.

These constraints start to feel a lot like needing whole program compilation, and in practice are unreasonable constraints to reach. To understand why, consider that most real world programs have a small Main module that opens some connections or opens some file handles, and then calls some library code defined in another module. If this code in the other module was already compiled, it will (probably) have been compiled as a function that takes a Monad dictionary, and just calls the >>= function repeatedly in the same manner as our original STG code. To get the allocation-free version, this library code needs to be available to the Main module itself - as that’s the module that choosing what type to instantiate ‘m’ with - which means the library code has to have marked that code as being inlinable. While we could add INLINE everywhere, this leads to an explosion in the amount of code produced, and can sky rocket compilation times.

Alexis’ eff library works around this by not being polymorphic in m. Instead, it chooses a concrete monad with all sorts of fancy continuation features. Likewise, if we commit to a particular monad (a transformer stack, or maybe using RIO), we again avoid this cost. Essentially, if the monad is known a priori at time of module compilation, GHC can go to town. However, the latter also commits to semantics - by choosing a transformer stack, we’re choosing a semantics for our monadic effects.

With the scene set, I now want to present you with another approach to solving this problem using Backpack.

A Backpack Primer

Vanilla GHC has a very simple module system - modules are essentially a method for name-spacing and separate compilation, they don’t do much more. The Backpack project extends this module system with a new concept - signatures. A signature is like the “type” of a module - a signature might mention the presence of some types, functions and type class instances, but it says nothing about what the definitions of these entities are. We’re going to (ab)use this system to build up transformer stacks at configuration time, and allow our library to be abstracted over different monads. By instantiating our library code with different monads, we get different interpretations of the same program.

I won’t sugar coat - what follows is going to pretty miserable. Extremely fun, but miserable to write in practice. I’ll let you decide if you want to inflict this misery on your coworkers in practice - I’m just here to show you it can be done!

A Signature for Monads

The first thing we’ll need is a signature for data types that are monads. This is essentially the “hole” we’ll rely on with our library code - it will give us the ability to say “there exists a monad”, without committing to any particular choice.

In our Cabal file, we have:

library monad-sig
  hs-source-dirs:   src-monad-sig
  signatures:       Control.Monad.Signature
  default-language: Haskell2010
  build-depends:    base

The important line here is signatures: Control.Monad.Signature which shows that this library is incomplete and exports a signature. The definition of Control/Monad/Signature.hsig is:

signature Control.Monad.Signature where

data M a
instance Functor M
instance Applicative M
instance Monad M

This simply states that any module with this signature has some type M with instances of Functor, Applicative and Monad.

Next, we’ll put that signature to use in our library code.

Libary Code

For our library code, we’ll start with a new library in our Cabal file:

library business-logic
  hs-source-dirs:   lib
  signatures:       BusinessLogic.Monad
  exposed-modules:  BusinessLogic
  build-depends:
    , base
    , fused-effects
    , monad-sig

  default-language: Haskell2010
  mixins:
    monad-sig requires (Control.Monad.Signature as BusinessLogic.Monad)

Our business-logic library itself exports a signature, which is really just a re-export of the Control.Monad.Signature, but we rename it something more meaningful. It’s this module that will provide the monad that has all of the effects we need. Along with this signature, we also export the BusinessLogic module:

{-# language FlexibleContexts #-}
module BusinessLogic where

import BusinessLogic.Monad ( M )
import Control.Algebra ( Has )
import Control.Effect.Empty ( Empty, guard )

businessCode :: Has Empty sig M => Bool -> M Int
businessCode b = do
  guard b
  return 42

In this module I’m using fused-effects as a framework to say which effects my monad should have (though this is not particularly important, I just like it!). Usually Has would be applied to a type variable m, but here we’re applying it to the type M. This type comes from BusinessLogic.Monad, which is a signature (you can confirm this by checking against the Cabal file). Other than that, this is all pretty standard!

Backpack-ing Monad Transformers

Now we get into the really fun stuff - providing implementations of effects. I mentioned earlier that one possible way to do this is with a stack of monad transformers. Generally speaking, one would write a single newtype T m a for each effect type class, and have that transformer dispatch any effects in that class, and to lift any effects from other classes - deferring their implementation to m.

We’re going to take the same approach here, but we’ll absorb the idea of a transformer directly into the module itself. Let’s look at an implementation of the Empty effect. The Empty effect gives us a special empty :: m a function, which serves the purpose of stopping execution immediately. As a monad transformer, one implementation is MaybeT:

newtype MaybeT m a = MaybeT { runMaybeT :: m (Maybe a) }

But we can also write this using Backpack. First, our Cabal library:

library fused-effects-empty-maybe
  hs-source-dirs:   src-fused-effects-backpack
  default-language: Haskell2010
  build-depends:
    , base
    , fused-effects
    , monad-sig

  exposed-modules: Control.Carrier.Backpack.Empty.Maybe
  mixins:
    monad-sig requires (Control.Monad.Signature as Control.Carrier.Backpack.Empty.Maybe.Base)

Our library exports the module Control.Carrier.Backpack.Empty.Maybe, but also has a hole - the type of base monad this transformer stacks on top of. As a monad transformer, this would be the m parameter, but when we use Backpack, we move that out into a separate module.

The implementation of Control.Carrier.Backpack.Empty.Maybe is short, and almost identical to the body of Control.Monad.Trans.Maybe - we just change any occurrences of m to instead refer to M from our .Base module:

{-# language BlockArguments, FlexibleContexts, FlexibleInstances, LambdaCase,
      MultiParamTypeClasses, TypeOperators, UndecidableInstances #-}

module Control.Carrier.Backpack.Empty.Maybe where

import Control.Algebra
import Control.Effect.Empty
import qualified Control.Carrier.Backpack.Empty.Maybe.Base as Base

type M = EmptyT

-- We could also write: newtype EmptyT a = EmptyT { runEmpty :: MaybeT Base.M a }
newtype EmptyT a = EmptyT { runEmpty :: Base.M (Maybe a) }

instance Functor EmptyT where
  fmap f (EmptyT m) = EmptyT $ fmap (fmap f) m

instance Applicative EmptyT where
  pure = EmptyT . pure . Just
  EmptyT f <*> EmptyT x = EmptyT do
    f >>= \case
      Nothing -> return Nothing
      Just f' -> x >>= \case
        Nothing -> return Nothing
        Just x' -> return (Just (f' x'))

instance Monad EmptyT where
  return = pure
  EmptyT x >>= f = EmptyT do
    x >>= \case
      Just x' -> runEmpty (f x')
      Nothing -> return Nothing

Finally, we make sure that Empty can handle the Empty effect:

instance Algebra sig Base.M => Algebra (Empty :+: sig) EmptyT where
  alg handle sig context = case sig of
    L Empty -> EmptyT $ return Nothing
    R other -> EmptyT $ thread (maybe (pure Nothing) runEmpty ~<~ handle) other (Just context)

Base Monads

Now that we have a way to run the Empty effect, we need a base case to our transformer stack. As our transformer is now built out of modules that conform to the Control.Monad.Signature signature, we need some modules for each monad that we could use as a base. For this POC, I’ve just added the IO monad:

library fused-effects-lift-io
  hs-source-dirs:   src-fused-effects-backpack
  default-language: Haskell2010
  build-depends:    base
  exposed-modules:  Control.Carrier.Backpack.Lift.IO

module Control.Carrier.Backpack.Lift.IO where
type M = IO

That’s it!

Putting It All Together

Finally we can put all of this together into an actual executable. We’ll take our library code, instantiate the monad to be a combination of EmptyT and IO, and write a little main function that unwraps this all into an IO type. First, here’s the Main module:

module Main where

import BusinessLogic
import qualified BusinessLogic.Monad

main :: IO ()
main = print =<< BusinessLogic.Monad.runEmptyT (businessCode True)

The BusinessLogic module we’ve seen before, but previously BusinessLogic.Monad was a signature (remember, we renamed Control.Monad.Signature to BusinessLogic.Monad). In executables, you can’t have signatures - executables can’t be depended on, so it doesn’t make sense for them to have holes, they must be complete. The magic happens in our Cabal file:

executable test
  main-is:          Main.hs
  hs-source-dirs:   exe
  build-depends:
    , base
    , business-logic
    , fused-effects-empty-maybe
    , fused-effects-lift-io
    , transformers

  default-language: Haskell2010
  mixins:
    fused-effects-empty-maybe (Control.Carrier.Backpack.Empty.Maybe as BusinessLogic.Monad) requires (Control.Carrier.Backpack.Empty.Maybe.Base as BusinessLogic.Monad.Base),
    fused-effects-lift-io (Control.Carrier.Backpack.Lift.IO as BusinessLogic.Monad.Base)

Wow, that’s a mouthful! The work is really happening in mixins. Let’s take this step by step:

1. First, we can see that we need to mixin the fused-effects-empty-maybe library. The first (X as Y) section specifies a list of modules from fused-effects-empty-maybe and renames them for the test executable that’s currently being compiled. Here, we’re renaming Control.Carrier.Backpack.Empty.Maybe as BusinessLogic.Monad. By doing this, we satisfy the hole in the business-logic library, which was otherwise incomplete.

2. But fused-effects-empty-maybe itself has a hole - the base monad for the transformer. The requires part lets us rename this hole, but we’ll still need to plug it. For now, we rename Control.Carrier.Backpack.Empty.Maybe.Base).

3. Next, we mixin the fused-effects-lift-io library, and rename Control.Carrier.Backpack.Lift.IO to be BusinessLogic.Monad.Base. We’ve now satisfied the hole for fused-effects-empty-maybe, and our executable has no more holes and can be compiled.

We’re Done!

That’s “all” there is to it. We can finally run our program:

$ cabal run
Just 42

If you compare against businessCode you’ll see that we got passed the guard and returned 42. Because we instantiated BusinessLogic.Monad with a MaybeT-like transformer, this 42 got wrapped up in Just.

Is This Fast?

The best check here is to just look at the underlying code itself. If we add

{-# options -ddump-simpl -ddump-stg -dsuppress-all #-}

to BusinessLogic and recompile, we’ll see the final code output to STDERR. The core is:

businessCode1
  = \ @ sig_a2cM _ b_a13P eta_B1 ->
      case b_a13P of {
        False -> (# eta_B1, Nothing #);
        True -> (# eta_B1, lvl1_r2NP #)
      }

and the STG:

businessCode1 =
    \r [$d(%,%)_s2PE b_s2PF eta_s2PG]
        case b_s2PF of {
          False -> (#,#) [eta_s2PG Nothing];
          True -> (#,#) [eta_s2PG lvl1_r2NP];
        };

Voila!

Conclusion

In this post, I’ve hopefully shown how we can use Backpack to write effectful code without paying the cost of abstraction. What I didn’t answer is the question of whether or you not you should. There’s a lot more to effectful code than I’ve presented, and it’s unclear to me whether this approach can scale to the needs. For example, if we needed something like mmorph’s MFunctor, what do we do? Are we stuck? I don’t know! Beyond these technical challenges, it’s clear that Backpack here is also not remotely ergonomic, as is. We’ve had to write five components just to get this done, and I pray for any one who comes to read this code and has to orientate themselves.

Nonetheless, I think this an interesting point of the effect design space that hasn’t been explored, and maybe I’ve motivated some people to do some further exploration.

The code for this blog post can be found at https://github.com/ocharles/fused-effects-backpack.

Happy holidays, all!

Downloading binaries from well-known providers is the easiest way to install new software. After all, building software from source is a chore — it requires both time and technical expertise. But how do we know that we aren’t installing something malicious from these providers?

Typically, we trust these binaries because we trust the provider. We believe that they were built from trusted sources, in a trusted computational environment, and with trusted build instructions. But even if the provider does everything transparently and in good faith, the binaries could still be anything if the provider’s system is compromised. In other words, the build process requires trust even if all build inputs (sources, dependencies, build scripts, etc…) are known.

Overcoming this problem is hard — after all, how can we verify the output of arbitrary build inputs? Excitingly, the last years have brought about ecosystems such as Nix, where all build inputs are known and where significant amounts of builds are reproducible. This means that the correspondence between inputs and outputs can be verified by building the same binary multiple times! The r13y project, for example, tracks non-reproducible builds by building them twice on the same machine, showing that this is indeed practical.

But we can go further, and that’s the subject of this blog post, which introduces Trustix, a new tool we are working on. Trustix compares build outputs for given build inputs across independent providers and machines, effectively decentralizing trust. This establishes what I like to call build transparency because it verifies what black box build machines are doing. Behind the scenes Trustix builds a Merkle tree-based append-only log that maps build inputs to build outputs, which I’ll come back to in a later post. This log can be used to establish consensus whether certain build inputs always produce the same output — and can therefore be trusted. Conversely, it can also be used to uncover non-reproducible builds, corrupted or not, on a large scale.

The initial implementation of Trustix, and its description in this post are based on the Nix package manager. Nix focuses on isolated builds, provides access to the hashes of all build inputs as well as a high quantity of bit-reproducible packages, making it the ideal initial testing ecosystem. However, Trustix was designed to be system-independent, and is not strongly tied to Nix.

The developmentent of Trustix is funded by NLNet foundation and the European Commission’s Next Generation Internet programme through the NGI Zero PET (privacy and trust enhancing technologies) fund. The tool is still in development, but I’m very excited to announce it already!

How Nix verifies binary cache results

Most Linux package managers use a very simple signature scheme to secure binary distribution to users. Some use GPG keys, some use OpenSSL certificates, and others use some other kind of key, but the idea is essentially the same for all of them. The general approach is that binaries are signed with a private key, and clients can use an associated public key to check that a binary was really signed by the trusted entity.

Nix for example uses an ed25519-based key signature scheme and comes with a default hard-coded public key that corresponds to the default cache. This key can be overridden or complemented by others, allowing the use of additional caches. The list of signing keys can be found in /etc/nix/nix.conf. The default base64-encoded ed25519 public key with a name as additional metadata looks like this:

trusted-public-keys = cache.nixos.org-1:6NCHdD59X431o0gWypbMrAURkbJ16ZPMQFGspcDShjY=

Now, in Nix, software is addressed by the hash of all of its build inputs (sources, dependencies and build instructions). This hash, or the output path is used to query a cache (like https://cache.nixos.org) for a binary.

Here is an example: The hash of the hello derivation can be obtained from a shell with nix-instantiate:

$ nix-instantiate '<nixpkgs>' --eval -A hello.outPath
"/nix/store/w9yy7v61ipb5rx6i35zq1mvc2iqfmps1-hello-2.10"

Here, behind the scenes, we have evaluated and hashed all build inputs that the hello derivation needs (.outPath is just a helper). This hash can then be used to query the default Nix binary cache:

$ curl https://cache.nixos.org/w9yy7v61ipb5rx6i35zq1mvc2iqfmps1.narinfo
StorePath: /nix/store/w9yy7v61ipb5rx6i35zq1mvc2iqfmps1-hello-2.10
URL: nar/15zk4zszw9lgkdkkwy7w11m5vag11n5dhv2i6hj308qpxczvdddx.nar.xz
Compression: xz
FileHash: sha256:15zk4zszw9lgkdkkwy7w11m5vag11n5dhv2i6hj308qpxczvdddx
FileSize: 41232
NarHash: sha256:1mi14cqk363wv368ffiiy01knardmnlyphi6h9xv6dkjz44hk30i
NarSize: 205968
References: 9df65igwjmf2wbw0gbrrgair6piqjgmi-glibc-2.31 w9yy7v61ipb5rx6i35zq1mvc2iqfmps1-hello-2.10
Sig: cache.nixos.org-1:uP5KU8MCmyRnKGlN5oEv6xWJBI5EO/Pf5aFztZuLSz8BpCcZ1fdBnJkVXhBAlxkdm/CemsgQskhwvyd2yghTAg==

Besides links to the archive that contains the compressed binaries, this response includes two relevant pieces of information which are used to verify binaries from the binary cache(s):

• The NarHash is a hash over all Nix store directory contents
• The Sig is a cryptographic signature over the NarHash

With this information, the client can check that this binary really comes from the provider’s Nix store.

What are the limitations of this model?

While this model has served Nix and others well for many years it suffers from a few problems. All of these problems can be traced back to a single point of failure in the chain of trust:

• First, if the key used by cache.nixos.org is ever compromised, all builds that were ever added to the cache can be considered tainted.
• Second, one needs to put either full trust or no trust at all in the build machines of a binary cache — there is no middle ground.
• Finally, there is no inherent guarantee that the build inputs described in the Nix expressions were actually used to build what’s in the cache.

Trustix

Trustix aims to solve these problems by assembling a mapping from build inputs to (hashes of) build outputs provided by many build machines.

Instead of relying on verifying packages signatures, like the traditional Nix model does, Trustix only exposes packages that it considers trustworthy. Concretely, Trustix is configured as a proxy for a binary cache, and hides the packages which are not trustworthy. As far as Nix is concerned, the package not being trustworthy is exactly as if the package wasn’t stored in the binary cache to begin with. If such a package is required, Nix will therefore build it from source.

Trustix doesn’t define what a trustworthy package is. What your Trustix considers trustworthy is up to you. The rules for accepting packages are entirely configurable. In fact, in the current prototype, there isn’t a default rule for packages to count as trustworthy: you need to configure trustworthiness yourself.

With this in mind, let’s revisit the above issues

• In Trustix, if an entity is compromised, you can rely on all other entities in the network to establish that a binary artefact is trustworthy. Maybe a few hashes are wrong in the Trustix mapping, but if an overwhelming majority of the outputs are the same, you can trust that the corresponding artefact is indeed what you would have built yourself.

  Therefore you never need to invalidate an entire binary cache: you can still verify the trustworthiness of old packages, even if newer packages are built by a malicious actor.

• In Trustix, you never typically consider any build machine to be fully trusted. You always check their results against the other build machines. You can further configure this by considering some machines as more trusted (maybe because it is a community-operated machine, and you trust said community) or less trusted (for instance, because it has been compromised in the past, and you fear it may be compromised again).

  Moreover, in the spirit of having no single point of failure, Trustix’s mapping is not kept in a central database. Instead every builder keeps a log of its builds; these logs are aggregated on your machine by your instance of the Trustix daemon. Therefore even the mapping itself doesn’t have to be fully trusted.

• In Trustix, package validity is not ensured by a signature scheme. Instead Trustix relies on the consistency of the input to output mapping. As a consequence, the validity criterion, contrary to a signature scheme, links the output to the input. It makes it infeasible to pass the build result of input I as a build result for input J: it would require corrupting the entire network.

Limitations: reproducibility tracking and non-reproducible builds

A system like Trustix will not work well with builds that are non-reproducible, which is a limitation of this model. After all, you cannot reach consensus if everyone’s opinions differ.

However, Trustix can still be useful, even for non-reproducible builds! By accumulating all the data in the various logs and aggregating them, we can track which derivations are non-reproducible over all of Nixpkgs, in a way that is easier than previously possible. Whereas the r13y project builds a single closure on a single machine, Trustix will index everything ever built on every architecture.

Conclusion

I am very excited to be working on the next generation of tooling for trust and reproducibility, and for the purely functional software packaging model pioneered by Nix to keep enabling new use cases. I hope that this work can be a foundation for many other applications other than improving trust — for example, by enabling the Nix community to support new CPU architectures with community binary caches.

Please check out the code at the repo or join us for a chat over in #untrustix on Freenode. And stay tuned — in the next blog post, we will talk more about Merkle trees and how they are used in Trustix.

• Telegraf is an agent that can be used to gather measurements and transfer the corresponding data to all kinds of storage solutions.
• InfluxDB is a time series database platform that can store, manage and analyze timestamped data.
• Kapacitor is a real-time streaming data process engine, that can be used for a variety of purposes. I can use Kapacitor to analyze measurements and see if a threshold has been exceeded so that an alert can be triggered.
• Alerta is a monitoring system that can store, de-duplicate alerts, and arrange black outs.
• Grafana is a multi-platform open source analytics and interactive visualization web application.

Building the alerting system

Telegraf

[agent]
  interval = "10s"

[[outputs.influxdb]]
  urls = [ "https://test1:8086" ]
  database = "sysmetricsdb"
  username = "sysmetricsdb"
  password = "sysmetricsdb"

[[inputs.system]]
  # no configuration

[[inputs.cpu]]
  ## Whether to report per-cpu stats or not
  percpu = true
  ## Whether to report total system cpu stats or not
  totalcpu = true
  ## If true, collect raw CPU time metrics.
  collect_cpu_time = false
  ## If true, compute and report the sum of all non-idle CPU states.
  report_active = true

[[inputs.mem]]
  # no configuration

• System metrics, such as the hostname and system load.
• CPU metrics, such as how much the CPU cores on a machine are utilized, including the total CPU activity.
• Memory (RAM) metrics.

InfluxDB

> precision rfc3339
> select * from "cpu" limit 3

name: cpu
time                 cpu       host  usage_active       usage_guest usage_guest_nice usage_idle        usage_iowait        usage_irq usage_nice usage_softirq       usage_steal usage_system      usage_user
----                 ---       ----  ------------       ----------- ---------------- ----------        ------------        --------- ---------- -------------       ----------- ------------      ----------
2020-11-16T15:36:00Z cpu-total test2 10.665258711721098 0           0                89.3347412882789  0.10559662090813073 0         0          0.10559662090813073 0           8.658922914466714 1.79514255543822
2020-11-16T15:36:00Z cpu0      test2 10.665258711721098 0           0                89.3347412882789  0.10559662090813073 0         0          0.10559662090813073 0           8.658922914466714 1.79514255543822
2020-11-16T15:36:10Z cpu-total test2 0.1055966209080346 0           0                99.89440337909197 0                   0         0          0.10559662090813073 0           0                 0

• cpu identifies the CPU core.
• host contains the host name of the machine.
• The remainder of the fields contain all kinds of CPU metrics, e.g. how much CPU time is consumed by the system (usage_system), the user (usage_user), by waiting for IO (usage_iowait) etc.
• The usage_active field contains the total CPU activity percentage, which is going to be useful to develop an alert that will warn us if there is too much CPU activity for a long period of time.

> SHOW TAG KEYS ON "sysmetricsdb" FROM "cpu";
name: cpu
tagKey
------
cpu
host

• You can also automatically sample data and run continuous queries that generate and store sampled data in the background.
• Configure retention policies so that data is no longer stored for an indefinite amount of time. For example, you can configure a retention policy to drop raw data after a certain amount of time, but retain the corresponding sampled data.

Kapacitor

dbrp "sysmetricsdb"."autogen"

stream
    |from()
        .measurement('cpu')
        .groupBy('host', 'cpu')
        .where(lambda: "cpu" != 'cpu-total')
    |window()
        .period(1m)
        .every(1m)
    |mean('usage_active')
    |alert()
        .message('Host: {{ index .Tags "host" }} has high cpu usage: {{ index .Fields "mean" }}')
        .warn(lambda: "mean" > 75.0)
        .crit(lambda: "mean" > 85.0)
        .alerta()
            .resource('{{ index .Tags "host" }}/{{ index .Tags "cpu" }}')
            .event('cpu overload')
            .value('{{ index .Fields "mean" }}')

• A stream task does not execute queries on an InfluxDB server. Instead, it creates a subscription to InfluxDB -- whenever a data point gets inserted into InfluxDB, the data points gets forwarded to Kapacitor as well.
  
  To make subscriptions work, both InfluxDB and Kapacitor need to be able to connect to each other with a public IP address.
• A stream task defines a pipeline consisting of a number of nodes (connected with the | operator). Each node can consume data points, filter, transform, aggregate, or execute arbitrary operations (such as calling an external service), and produce new data points that can be propagated to the next node in the pipeline.
• Every node also has property methods (such as .measurement('cpu')) making it possible to configure parameters.

• The from node consumes cpu data points from the InfluxDB subscription, groups them by host and cpu and filters out data points with the the cpu-total label, because we are only interested in the CPU consumption per core, not the total amount.
• The window node states that we should aggregate data points over the last 1 minute and pass the resulting (aggregated) data points to the next node after one minute in time has elapsed. To aggregate data, Kapacitor will buffer data points in memory.
• The mean node computes the mean value for usage_active for the aggregated data points.
• The alert node is used to trigger an alert of a specific severity level (WARNING if the mean activity percentage is bigger than 75%) and (CRITICAL if the mean activity percentage is bigger than 85%). In the remainder of the case, the status is considered OK. The alert is sent to Alerta.

dbrp "sysmetricsdb"."autogen"

batch
    |query('''
        SELECT mean("usage_active")
        FROM "sysmetricsdb"."autogen"."cpu"
        WHERE "cpu" != 'cpu-total'
    ''')
        .period(1m)
        .every(1m)
        .groupBy('host', 'cpu')
    |alert()
        .message('Host: {{ index .Tags "host" }} has high cpu usage: {{ index .Fields "mean" }}')
        .warn(lambda: "mean" > 75.0)
        .crit(lambda: "mean" > 85.0)
        .alerta()
            .resource('{{ index .Tags "host" }}/{{ index .Tags "cpu" }}')
            .event('cpu overload')
            .value('{{ index .Fields "mean" }}')

• Stream tasks offer low latency responses -- when a data point appears, a stream task can immediately respond, whereas a batch task needs to query every minute all the data points to compute the mean percentage over the last minute.
• Stream tasks maintain a buffer for aggregating the data points making it possible to only send incremental updates to Alerta. Batch tasks are stateless. As a result, they need to update the status of all hosts and CPUs every minute.
• Processing data points is done synchronously and in sequential order -- if an update round to Alerta takes too long (which is more likely to happen with a batch task), then the next processing run may overlap with the previous, causing all kinds of unpredictable results.
  
  It may also cause Kapacitor to eventually crash due to growing resource consumption.
• Batch tasks may also miss data points -- while querying data over a certain time window, it may happen that a new data point gets inserted in that time window (that is being queried). This new data point will not be picked up by Kapacitor.
  
  A subscription made by a stream task, however, will never miss any data points.
• Stream tasks can only work with data points that appear from the moment Kapacitor is started -- it cannot work with data points in the past.
  
  For example, if Kapacitor is restarted and some important event is triggered in the restart time window, Kapacitor will not notice that event, causing the alert to remain in its previous state.
  
  To work effectively with stream tasks, a continuous data stream is required that frequently reports on the status of a resource. Batch tasks, on the other hand, can work with historical data.
• The fact that nodes maintain a buffer may also cause the RAM consumption of Kapacitor to grow considerably, if the data volumes are big.
  
  A batch task on the other hand, does not buffer any data and is more memory efficient.
  
  Another compelling advantage of batch tasks over stream tasks is that InfluxDB does all the work. The hosted version of InfluxDB can also horizontally scale.
• Batch tasks can also aggregate data more efficiently (e.g. computing the mean value or sum of values over a certain time period).

Alerta

Running experiments

$ dd if=/dev/zero of=/dev/null

Developing test cases

• Telegraf may not be running and, as a result, not capturing the data points that need to be analyzed by the TICK script.
• A subscription cannot be established between InfluxDB and Kapacitor. This may happen when Kapacitor cannot be reached through a public IP address.
• There are data points collected, but only the wrong kinds of measurements.
• The TICK script is functionally incorrect.

influxCmd="influx -database sysmetricsdb -host test1"

export ALERTA_ENDPOINT="https://test1"

### Trigger CRITICAL alert

# Force the average CPU consumption to be 100%
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=100   0000000000"
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=100  60000000000"
# This data point triggers the alert
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=100 120000000000"

sleep 1
actualSeverity=$(alerta --output json query | jq '.[0].severity')

if [ "$actualSeverity" != "critical" ]
then
     echo "Expected severity: critical, but we got: $actualSeverity" >&2
     false
fi
      
### Trigger WARNING alert

# Force the average CPU consumption to be 80%
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=80 180000000000"
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=80 240000000000"
# This data point triggers the alert
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=80 300000000000"

sleep 1
actualSeverity=$(alerta --output json query | jq '.[0].severity')

if [ "$actualSeverity" != "warning" ]
then
     echo "Expected severity: warning, but we got: $actualSeverity" >&2
     false
fi

### Trigger OK alert

# Force the average CPU consumption to be 0%
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=0 300000000000"
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=0 360000000000"
# This data point triggers the alert
$influxCmd -execute "INSERT cpu,cpu=cpu0,host=test2 usage_active=0 420000000000"

sleep 1
actualSeverity=$(alerta --output json query | jq '.[0].severity')

if [ "$actualSeverity" != "ok" ]
then
     echo "Expected severity: ok, but we got: $actualSeverity" >&2
     false
fi

• CRITICAL is triggered by generating data points that force a mean activity percentage of 100%.
• WARNING is triggered by a mean activity percentage of 80%.
• OK is triggered by a mean activity percentage of 0%.

offset="$(($(date +%s) - 3600))"

Automating the deployment

$ nixops create network.nix network-virtualbox.nix -d test
$ nixops deploy -d test

$ export NIXOPS_DEPLOYMENT=test
$ export NIXOPS_USE_NIXOPS=1

$ disnixos-env -s services.nix \
  -n network.nix \
  -n network-virtualbox.nix \
  -d distribution.nix

• The light-grey colored boxes denote machines. In the above diagram, we have two of them: test1 and test2 that correspond to the VirtualBox machines deployed by NixOps.
• The dark-grey colored boxes denote containers in a Disnix-context (not to be confused with Linux or Docker containers). These are environments that manage other services.
  
  For example, a container service could be the PostgreSQL DBMS managing a number of PostgreSQL databases or the Apache HTTP server managing web applications.
• The ovals denote services that could be any kind of deployment unit. In the above example, we have services that are running processes (managed by systemd), databases and web applications.
• The arrows denote inter-dependencies between services. When a service has an inter-dependency on another service (i.e. the arrow points from the former to the latter), then the latter service needs to be activated first. Moreover, the former service also needs to know how the latter can be reached.
• Services can also be container providers (as denoted by the arrows in the labels), stating that other services can be embedded inside this service.
  
  As already explained, the PostgreSQL DBMS is an example of such a service, because it can host multiple PostgreSQL databases.

test2.succeed("test-cpu-alerts")

$ nix-build release.nix -A tests

Availability

Acknowledgements

Presentation

In a previous post I explained why we were eagerly trying to change the Nix store model to allow for content-addressed derivations. I also handwaved that this was a real challenge, but without giving any hint at why this could be tricky. So let’s dive a bit into the gory details and understand some of the conceptual pain points with content-addressability in Nix, which forced us to some trade-offs in how we handle content-addressed paths.

What are self-references?

This is a self-reference

— Théophane Hufschmitt, This very article

A very trivial Nix derivation might look like this:

with import <nixpkgs> {};
writeScript "hello" ''
#!${bash}/bin/bash

${hello}/bin/hello
''

The result of this derivation will be an executable file containing a script that will run the hello program. It will depend on the bash and hello derivations as we refer to them in the file.

We can build this derivation and execute it:

$ nix-build hello.nix
$ ./result
Hello, world!

So far, so good. Let’s now change our derivation to change the prompt of hello to something more personalized:

with import <nixpkgs> {};
writeScript "hello-its-me" ''
#!${bash}/bin/bash

echo "Hello, world! This is ${placeholder "out"}"
''

where ${placeholder "out"} is a magic value that will be replaced by the output path of the derivation during the build.

We can build this and run the result just fine

$ nix-build hello-its-me.nix
$ ./result
Hello, world! This is /nix/store/c0qw0gbp7rfyzm7x7ih279pmnzazg86p-hello-its-me

And we can check that the file is indeed who it claims to be:

$ /nix/store/c0qw0gbp7rfyzm7x7ih279pmnzazg86p-hello-its-me
Hello, world! This is /nix/store/c0qw0gbp7rfyzm7x7ih279pmnzazg86p-hello-its-me

While the hello derivation depends on bash and hello, hello-its-me depends on bash and… itself. This is something rather common in Nix. For example, it’s rather natural for a C program to have /nix/store/xxx-foo/bin/foo depend of /nix/store/xxx-foo/lib/libfoo.so.

Self references and content-addressed paths

How do we build a content-addressed derivation foo in Nix? The recipe is rather simple:

1. Build the derivation in a temporary directory /some/where/
2. Compute the hash xxx of that /some/where/ directory
3. Move the directory under /nix/store/xxx-foo/

You might see where things will go wrong with self-references: the reference will point to /some/where rather than /nix/store/xxx-foo, and so will be wrong (in addition to leak a path to what should just be a temporary directory).

To work around that, we would need to compute this xxx hash before the build, but that’s quite impossible as the hash depends on the content of the directory, including the value of the self-references.

However, we can hack our way around it in most cases by allowing ourselves a bit of heuristic. The only assumption that we need to make is that all the self-references will appear textually (i.e. running strings on a file that contains self-references will print all the self-references out).

Under that assumption, we can:

1. Build the derivation in our /some/where directory
2. Replace all the occurrences of a self-reference by a magic value
3. Compute the hash of the resulting path to determine the final path
4. Replace all the occurrences of the magic value by the final path
5. Move the resulting store path to its final path

Now you might think that this is a crazy hack − there’s so many ways it could break. And in theory you’ll be right. But, surprisingly, this works remarkably well in practice. You might also notice that pedantically speaking this scheme isn’t exactly content-addressing because of the “modulo the final hash” part. But this is close-enough to keep all the desirable properties of proper content addressing, while also enabling self-references, which wouldn’t be possible otherwise. For example, the Fugue cloud deployment system used a generalisation of this technique which not only deals with self-references, but with reference cycles of arbitrary length.

However, there’s a key thing that’s required for this to work: patching strings in binaries is generally benign, but the final string must have the same length as the original one. But we can do that: we don’t know what the final xxx hash will be, but we know its length (because it’s a fixed-length hash), so we can just choose a temporary directory that has the right length (like a temporary store path with the same name), and we’re all set!

The annoying thing is that there’s no guarantee that there are no self-references hidden in such a way that a textual replacement won’t catch it (for example inside a compressed zip file). This is the main reason why content-addressability will not be the default in Nix, at first at least.

Non-deterministic builds − the diamond problem strikes back

No matter how hard Nix tries to isolate the build environment, some actions will remain inherently non-deterministic − anything that can yield a different output depending on the order in which concurrent tasks will be executed for example. This is an annoyance as it might prevent early cutoff (see our previous article on the subject in case you missed it).

But more than limiting the efficiency of the cache, this could also hurt the correctness of Nix if we’re not careful enough.

For example, consider the following dependency graph:

Alice wants to get foo installed. She already built lib0 and lib1 locally. Let’s call them lib0_a and lib1_a. The binary cache contains builds of lib0 and lib2. Let’s call them lib0_b and lib2_b. Because the build of lib0 is not deterministic, lib0_a and lib0_b are different — and so have a different hash. In a content-addressed word, that means they will be stored in different paths.

A simple cache implementation would want to fetch lib2_b from the cache and use it to build foo. This would also pull lib0_b, because it’s a dependency of lib2_b. But that would mean that foo would depend on both lib0_a and lib0_b.

In the happy case this would just be a waste of space − the dependency is duplicated, so we use twice as much memory to store it. But in many cases this would simply blow-up at some point — for example if lib0 is a shared library, the C linker will fail because of the duplicated symbols. Besides that, this breaks down the purity of the build as we get a different behavior depending on what’s already in the store at the start of the build.

Getting out of this

Nix’s foundational paper shows a way out of this by rewriting hashes in substituted paths. This is however quite complex to implement for a first version, so the current implementation settles down on a simpler (though not optimal) behavior where we only allow one build for each derivation. In the example above, lib0 has already been instantiated (as lib0_a), so we don’t allow pulling in lib0_b (nor lib1_b) and we rebuild both lib1 and foo.

While not optimal − we’ll end-up rebuilding foo even if it’s already in the binary cache − this solution has the advantage of preserving correctness while staying conceptually and technically simple.

What now?

Part of this has already been implemented but there’s still quite a long way forward.

I hope for it to be usable (though maybe still experimental) for Nix 3.0.

And in the meantime stay tuned with our regular updates on discourse. Or wait for the next blog post that will explain another change that will be necessary — one that is less fundamental, but more user-facing.